Government of Andhra Pradesh

Transcription

1 Public Disclosure Authorized Public Disclosure Authorized Public Disclosure Authorized Public Disclosure Authorized Government of Andhra Pradesh Rural Water Supply and Sanitation Department VOL. 1 Andhra Pradesh Rural Water Supply and Sanitation Project The World Bank Assisted Environmental Analysis And Environmental Management Framework Final Report November 2008 Samaj Vikas Development Support Organisation Hyderabad info@samajvikas.org

2 Environmental Analysis. Final Report. November 2008 Table of Contents 1. Introduction Background Andhra Pradesh Rural Water Supply and Sanitation Project Objectives Scope of the Project Brief profile of Andhra Pradesh Physiographic Profile Water Resources Environmental Analysis Objective Methodology Data Collection and Review Sample Habitations for Pilot Study Preliminary Site Visits Public Consultations Organisation of the Report Rural Water Supply and Sanitation in Andhra Pradesh - Policy, Regulatory Framework and Programme RWSS at National Context Sector Reforms Project Swajaladhara Sub - Mission Project (SMP) Total sanitation Campaign RWSS Coverage in Andhra Pradesh Drinking Water Sanitation Regulatory and Policy Framework The World Bank Safeguard Policies Sector Institutions Nodal Institution Nodal Institutions Converging Departments GOAP RWSS Sector Vision Proposed World Bank Assisted Project Baseline Environmental Status Introduction Physical Environmental Location Geomorphology Ecologically Sensitive Areas Climate and Rainfall Demographic Status Agriculture Water Resources Surface Water Groundwater Artificial Recharge of Groundwater Water Quality Samaj Vikas (~nfo$~ sal-nal via:ik~j~) 2

3 Environmental Analysis. Final Report. November Surface Water Quality Ground water Quality Current Water Supply and Treatment Practices Incidence of Water and Sanitation - Related Diseases House Hold and Environmental Sanitation Status of Toilet Construction Environment Management Framework...! t~ Environmental Analysis Key Environmental Issues Water Availability Water Quality Construction Stage Environmental Impacts Objectives of EMF Environmental Management Frame Work Key Elements of the EMF Application of EMF to Project Environmental Supervision and Monitoring Institutional Arrangements Village Level GPWSC and SOs Mandal Level Disrtict Level State Level Performance Indicators Training and Capacity Building Objectives Approach Institutions for Training Details of Training Programmes Budget Guidelines / Environmental Code of Practices Annexure 1 Terms of Reference for Environmental Analysis Annexure 2: List of Sample Habitations Selected for Field Study Annexure 3: Questionnaire for Field Data Collection Annexure 4: Summary Analysis of Data Collected Annexure 5: Issues identified during Village level Public Consultations Annexure 6: Summary of Public Consultation1 Disclosure Workshops Annexure 7: List of projects requiring prior environmental clearance as per EIA Notification Annexure 8: Water Quality Monitoring and Surveillance Annexure 9: District Wise- Fluctuation in water level in observation wells between May 2007 and November Annexure 10: Categorisation of Mandals In Andhra Pradesh According To Groundwater Exploitation As On April Annexure 11 : Disposal of Reject brine from RO Plant Annexure 14: Sanitary Protection of Water Supply Sources Annexure 15: Fluoride Mitigation Annexure 16: Guidelines for Sustainability of Groundwater Sources Annexure 17: Selection of Safe Sanitation Technologies and Environmental Considerations in Location of Toilets Samaj Vikas (ijj!'&~~~ua~\:j~~~~)~~) - - -

4 Environmental Analysis. Final Report. November 2008 Annexure 18: Recommended Construction Practice and Pollution Safeguards for Twin Pit Pour Flush Latrines Annexure 19: Guidelines for Safe Sullage Disposal at Household and Community Levels Annexure 20: Guidelines for Community Solid Waste Management Annexure 2 1: Formats for Environmental Data Sheets (EDS) Annexurc 22: Screening Tool for Categorizing Schemes Annexure 23: Internal Supervision of the Completed Schemes Annexure 24: External Audit of the Completed Schemes Annexure 25: Check list for Environmental Supemision/Audit Annexure 26: Sample Field Visit Reports for Internal Supervision / External Audit Annexure 27: Environmental Performance Indicators Annexure 28: Safety Provisions (Building) Convention, 1937 (No. 62) Annexure 29: Formt for Declaration by Contractor/ Consultant Sarnaj Vikas (--f-[lr'i;al~jaj i.ik.~s.org) 4

5 Environmental Analysis. Final Report. November 2008 List of Tables Table 1-1: The proposed scope of activities Table 2-1 :Water Supply Coverage Status of the Habitations in different districts (as on ) Table 2-2: Scope of Relevant Environment Regulations Table 2-3 : World Bank Safeguard Policies Table 3-1: Wildlife Sanctuaries & National Parks in AP Table 3-2: District wise demographic data (census 2001) Table 3-3: Different zones and their agro-climatic characteristics Table 3-4: Water requirement for various sectors Table 3-5: Depth to water level variations in different districts (as observed in October 2007) Table 3-6: Categorization of Mandals with reference to Groundwater Exploitation Table 3-7: Impact of artificial recharge structures on groundwater regime in water sheds areas Table 3-8: Mandal wise NSS / Quality affected Habitations (as on APRIL 2007) Table 3-9: Diarrhea incidence in Andhra Pradesh from 1998 to 2002, Table 3-10: Gastroenteritis incidence in Andhra Pradesh from 1998 to Table 3-11: District wise number of latrines constructed in AP between 2004 and Table 4-1: Additional Water Requirement Table 4-2: Environmental Management Framework Table 4-3: Institutional Arrangement for Implementation of the EMF Table 4-4: Number of Training Programs Table 4-5: Estimated cost of Training Table 4-6: Budget for Environmental Management Samaj Vikas (I rj tbcd sr.llrla.~has.c~rw) 5

6 Environmental Analysis. Final Report. November 2008 List of Figures Figure 1.1. Disrtict Map of Andhra Pradesh Figure 1.2. Methodology Flow Chart Figure 2.1. Status of Rural Water supply Coverage in Andhra Pradesh (2007) Figure 2.2. Present organization set up of RWSSD Figure 3.1. Map of Wildlife Sanctuaries & National Parks of AP Figure 3.2. Rainfall to Figure 3.3. District wise deviation of annual rainfall in the year 2007 from Figure 3.4. District wise Population Range Figure 3.5.Water level fluctuation- Decadal mean November ( ) Figure 3.6. District wise status of groundwater development in AP ( ) Figure 3.7 :Categorization of mandal based ground water development Figure 3.8. Type of water quality problems in affected habitations Figure 3.9. Status of Not safe Source (NSS) habitations Figure Status of Brackish water habitations as on Figure Status of Fluoride water habitations as on April Figure Gastroenteritis cases in Andhra Pradesh from Figure 3.13 :Types of sanitation facilities provided for the households Samaj Vikas (~jlt.(ig.;;ll~gj\~ikils.or.c ) 6

7 Environmental Analysis - Final Report -November 2008 List of Boxes Box 2-1: Guidelines for environmental safety as per Swajaldhara Projects 22 Box 2-2: Guidelines for Environmental Safety TSC 23 Box 2-3: National Water Policy aspects impacting Rural Water Supply Schemes 27 Box 3-1: Stage of Ground water Development - Terminology and Definitions 52 Box 3-2: Water Quality Classes and Criteria 5 6 Samaj Vikas (111 to:l{s:i~n~l~\ ~l\;x!rs) 7

8 ABBREVATIONS AND ACRONYMS ARWSP ADD AE AEE APRWSSP APWALTA BCM BC CCDU CGWB DDP CRSP DPAP DPMC DPR DRP DSR DSU DWSM DWSC EA EAS EDS ECOPs EIA EE EMF FC GoAP GP GWD IEC ISL IHHL ICR JGSY JE MCM MoEF M&E h4np MRP MTP MVS NSS NGO OD Accelerated Rural Water Supply Programme Acute Diarrheal Diseases Assistant Engineer Assistant Executive Engineer Andhra Pradesh Rural Water Supply and Sanitation Project Andhra Pradesh Water and Land Tree Act Billion Cubic Meter Beneficiary Committee Community and Capacity Development Unit Central Ground Water Board Desert Development Programme Central Rural Sanitation Programme Drought Prone Area Programme District Programme Management Cell Detailed Project Report District Resource Person Detailed Scheme Report District Support Unit District Water and Sanitation Mission District Water and Sanitation Committee Environmental Analysis Employment Assurance Scheme Environmental Data Sheet Environmental Codes of Practices Environmental Impact Assessment Executive Engineer Environmental Management Framework Fully Covered Government of Andhra Pradesh Gram Panchayat Ground Water Department Information, Education and Communication Individual Sanitary Latrines Individual Household Latrines Implementation Completion Report Jawahar Gram Samrudhdhi Yojana Junior Engineer Million Cubic Metre Ministry of Environment & Forests Monitoring and Evaluation Minimum Need Programme Mandal Resource Person Medium Term Program Multi Village Scheme Not Safe Sources Non Governmental Organization Operational Directive Samaj Vikas (mf~$(>;~~r~aj\-~h~:~,!,~g) 8

9 Environmental Analysis - Final Report -November 2008 NRCP OHT O&M PC PCs PIP PRED PRI PSU PWC RO RSF RSM RWSS RWSM RWSSD SA SEA SHP SMP SLC SLWM SMSC SPCB SRP SSF SWAP SSHE SWSM sos SEA svs TOR TSC TPPF UGD VWSC WB UNDP UNESCO UNICEF National River Conservation Programme Over Head Tank Operation and Maintenance Partially Covered Production Centres Project Implementation Plan Panchayat Raj Engineering Department Panchayat Raj Institution Project Support Unit Price Waterhouse Coopers Reverse Osmosis Rapid Sand Filter Rural Sanitary Mart Rural Water Supply and Sanitation Rural Water and Sanitation Mission Rural Water Supply and Sanitation Department Support Agency Sector Environmental Assessment Sanitation Hygiene Promotion Sub Mission Project Scheme Level Committee Solid and Liquid Waste Management State Management Support Consultant State Pollution Control Board Sector Reform Project Slow Sand Filtration Sector Wide Approach School Sanitation and Hygiene Education State Water Supply and Sanitation Mission Support Organizations Sector Environmental Analysis Single Village Scheme Terms of Reference Total Sanitation Campaign Twin Pit Pour Flush Under Ground Drainage Village Water Supply and Sanitation Committee World Bank United Nations Development Programme United Nations Educational, Scientific and Cultural Organization United Nations Children's Fund Samaj Vikas ("og<.:;1m~!i~:11.i1_y~gz) 9

10 Environmental Analysis - Final Report -November Background 1. Introduction Government of Andhra Pradesh (GOAP) formulated its Rural Water Supply and Sanitation (RWSS) Sector vision and policy in Key features of the Vision are: Transfer of responsibility for planning, design and construction of the RWSS infrastructure and for operating the RWSS services to the Panchayat Raj Institutions (PRIs) and Communities; and Evolution of the role of Rural Water Supply and Sanitation Department (RWSSD-nodal agency) into that of a provider of technical assistance to the PRIs. Similarly, key features of the policy are: Devolution of funds, functions and functionaries to the Panchayat Raj Institutions (PRIs); Enforcement of full recovery of Operation and Maintenance (O&M) cost and sharing of capital cost (taking into consideration affordability, particularly by disadvantaged groups); and Improvement of the 'accountability framework' by clarifying roles and responsibilities of various actors of the RWSS sector at the state, district and village level, including responsibilities for policy formulation, financing, regulation, construction, operations and maintenance. 1.2 Andhra Pradesh Rural Water Supply and Sanitation Project Towards realizing the sector vision, GOAP is currently preparing a Rural Water Supply and Sanitation Program (APRWSSP) with financial assistance from the World Bank. The project forms a part of the RWSS sector investment program and implementation action plan - Medium Term Program (MTP). This MTP would serve as a financial action plan for channeling investments and other resources for integrated rural water supply and sanitation development in the state during the program period Objectives Key objective of APRWSSP is to increase rural communities' access to reliable, sustainable and affordable Rural Water Supply and Sanitation (RWSS) services. The main objectives for the proposed APRWSS Project are: To improve the quality and quantity of rural water supply including environmental sanitation, service delivery, household sanitation and hygiene; To achieve sustainability of investments and generate health and hygiene and income benefits in the rural Andhra Pradesh; To assist the state in creating an enabling environment statewide for implementation of appropriate sector policy and institutional reforms; and, Samaj Vikas ( in~~s~~~~;~~~k:~~~g~y) 10

11 To demonstrate sustainable modalities of delivering water supply in Single Village Schemes (SVSs) and Multi Village Schemes (MVSs). The project aims at covering a total of 2,843 habitations over a period of five years, the breakup of which is as follows: 1,878 Not Covered (NC) and 199 No Safe Source (NSS) habitations. Apart from this, 766 Partially Covered (PC) habitations will be covered with water supply during the five years of MTP. This project will also cany out some augmentations and improvements to Single Village Schemes (SVS) and Multi Village Schemes (MVS). Household latrine and/ or sullage drainage activities will be taken up in about 2,843 habitations. Additionally, 55 Mandal headquarters will be provided with Under Ground Drainage (UGD) and Solid and Liquid Waste Management (SLWM) and 55 major Gram Panchayats (GPs) will be provided with pavements and drains. 1.3 Scope of the Project The proposed scope of activities of the APRWSSP is given below: Table 1-1: The proposed scope of activities Components svs SVS (PC to FC) 1 SVS (NC to FC) SVS (NSS to FC) Total MVS -.a. - I MVS (PC to FC) - common & intra village - 1 facilities 1 MVS (NC to FC) - common facilities & intra 1 I I I I I I I I Total 448 1, , ( 56 / 318 intra village facilities Total ,040 Rain water harvesting Innovative technology 1, , , , , , Improvements Augmentation of SVS (distribution system) Augmentation of MVS (distribution system) Improving ground water sources Catchment area protection for surface sources Environmental sanitation HHSLs Pavements, drains and SLWM in major GPs Soak pits in GPs UGD and SLWM in Mandal head quarters I I I I I I 8, , , , , , , , , , , The scope of the project is further elaborated under Section 2.6. Samaj Vikas (I n.fo~s~~\~j 4 i bic;l';,o!~) 11

12 1.4 Brief profile of Andhra Pradesh Andhra Pradesh (AP) is the fifth largest state in India both in geographical area (an area of 2,76,754 sq. km, accounting for 8.4 % of India's territory) and population wise (76.21 million accounting for 7.41 % of India's population of 1,028 million). Andhra Pradesh was formed on 1st November, 1956 under the States' reorganization scheme. AP lies between 12' 41' and 22' longitude and 77' and 84' 40' latitude. It forms the major link between the north and the south of India and is the biggest and most populous state in the south of India. It is bounded by Madhya Pradesh, Chattisgarh and Orissa in the north, the Bay of Bengal in the east, Tamil Nadu and Karnataka in the south and Karnataka and Maharashtra in the west. AP has the longest coastline of 972 km in India. There are three main regions in the state of AP - (1) Coastal Andhra, (2) Rayalaseema and (3) Telangana. AP has 22 districts, 1,104 Mandals and 2 1,856 GPs. Telugu is the official language of AP Physiographic Profile AP is endowed with a variety of physiographic features ranging from high hills, thick forests, undulating plains to a coastal deltaic environment. The state has the advantage of having most of the east flowing rivers in the heart of the state bringing in abundant supplies of surface water from the Western and Eastern Ghats and Deccan Plateau up to the Bay of Bengal. The major, medium and minor rivers that flow through the state number about 40. Of these, the most important rivers in AP are Godavari, Krishna, Pennar, Thungabhadra, Vamsadhara and Nagavali. Figure 1.1: Disrtict Map of Andhra Pradesh Like all the peninsular rivers, these too are rain fed rivers. Nearly 75% of its area is covered by the river basins of the Godavari, Krishna and Pennar, and their tributaries. There are 17 smaller rivers like the Sarada, Nagavali and Musi, as well as several streams. Godavari and Krishna are the two major perennial rivers, and with their extensive canal system, provide assured irrigation. The rainfall of AP is influenced by both the south-west, north-west and north-east monsoons. The average annual rainfall in the state is 925 rnm. A majority of the rainfall in AP is contributed by south-west monsoon (68.5%) during the months June to September, followed by north-east monsoon (22.3%) during the months October to December. The remaining (9.2%) of the rainfall is received during the winter and summer months. The rainfall distribution in the three regions of the state differs with the season and monsoon. The influence of the south-west monsoon is predominant in the Telangana region (764.5 rnm) followed by Coastal Andhra ( rnm) and Rayalaseema (378.5 mm). Where as, the Samaj Vikas (~to~~~gr~~i~l\r!s.org) 12

13 north-east monsoon provides a high amount of rainfall (316.8 mm) to Coastal Andhra area followed by Rayalaseema (224.3) and Telangana (97.1 mm). There are no significant differences in the distribution of rainfall during the winter and hot weather periods among the three regions Water Resources The State's (surface and ground) water resources are estimated to be BCM (3,820 TMC), out of which about BCM (2,200 TMC) are currently being utilised for drinking, agriculture, industry and power generation. The per capita annual water resources work out to be slightly more than 1,400 Cu.m. and utilization is about 800 Cu.m. The current percentage withdrawal of available water in AP is 58% (Source: Andhra Pradesh Water Vision, Water Conservation Mission, GOAP; 2005). However, there has been a dramatic increase in well construction and groundwater extraction during the last 15 years for groundwater based irrigation as well as for drinking water sources. The shift in well construction from open wells to bore wells represents a shift from groundwater extraction in shallow unconfined aquifers to extraction from deeper confined aquifers. Net groundwater extraction for irrigation, domestic and livestock use for the different districts was estimated at 8% to 11.O% of mean annual rainfall, while the groundwater recharge in the state is approximately 10% of annual rainfall only; this suggests that current levels of extraction in certain districts are not sustainable. Regarding water quality, Fluoride is widespread in AP. It has reached endemic proportions in Nalgonda, Ranga Reddy, Kurnool, Karimnagar and Prakasam districts. In about six thousand habitations (out of a total of about 72 thousand habitations in the state), fluoride content in water is high. This is affecting several thousands of people. In Nalgonda district where the occurrence is highest, about 70,000 people in 215 villages are suffering from fluorosis. In the recent past, fluorosis has been spreading to new areas. 1.5 Environmental Analysis The proposed APRWSSP falls under environmental category 'B' as per the World Bank's OP Accordingly, an Environmental Analysis (EA) of the proposed project was commissioned by the RWSSD. This EA provides insight into the environmental challenges facing the project including source sustainability, water quality management, drainage and disposal and household sanitation issues. Presently the project is under formulation. At this stage, while the project activities and number of villages have been determined, the specific sub-projects that will be taken up in the project villages are yet to be identified. Hence it is decided to do an EA and prepare an Environmental Management Framework. This EMF is expected to provide detailed guidance for conducting screening and environmental assessment for sub-projects to be taken up under the APRWSS. Accordingly, the Terms of Reference (TOR) for the EA study have been formulated as in Annexure 1. The purpose of the Environmental Analysis (EA) is to identify upfront the APRWSSP's potential environmental risks and impacts in its area of influence; examine project alternatives; identify ways of improving project selection, siting, planning, design and implementation by preventing, minimizing, mitigating, or compensating for adverse environmental impacts and enhancing positive impacts throughout project implementation. Samaj Vikas (ln t'0<11 sii!l~m:uka>.org) 13

14 EA has taken into account the natural environment (air, water and land); human health and safety including the country's overall policy framework, national legislation, and institutional capabilities related to the environment and obligations of the country, pertaining to project activities, under relevant international environmental treaties and agreements. The objectives of the EA are given below: Objective The key objective of the study is to conduct an Environmental Analysis (EA) with a view to identify the critical environmental concerns in the RWSS sector and address these as an integral part of the RWSS sector program design and implementation strategy. The specific objectives include: To assess the existing status of environment in the state and to identify threats and issues which have effect on RWSS sector; To identify the environmental issues associated with implementation of RWSS schemes (Single Village & Multi Village Schemes) and develop environmental codes of practices that need to be followed during various stages such as planning, construction and operation and maintenance; To identify water quality issues pertaining to bacteriological, chemical and heavy metal contamination in both ground and surface water sources in the state and suggest possible mitigation measures; To identify generic environmental issues that are beyond the scope of individual RWSS schemes, but related to the sector and recommend remedial measures to address these as part of the project; To identify household and environmental sanitation issues as well as to make an assessment of pollution level with regard to water supply and its usage & propose appropriate sanitation technology options; To prepare an Environment Management Framework including well defined performance indicators for addressing the identified issues, through the various activities1 tasks under the proposed project, and strategy for its implementation to achieve sustainable sources for water supply schemes and environmental sanitation benefits. 1.6 Methodology The methodology followed in conducting the Environmental Assessment Study is depicted in the figure and brief description below: Data Collection and Review The methodology basically comprised collection and collation of secondary data on water resources availability, their utilization, problems of water availability and quality as relevant in the context of the proposed APRWSS project, demographic, socioeconomic and health aspects, water supply and sanitation coverage and service levels and problems in O&M of existing water supply systems. The study also included an analysis of policy, legal and institutional framework related to water and sanitation with specific focus on AP. A review and analysis of this information led to the delineation of the baseline status of relevant environmental components pertaining to the State and provided the basis for assessment of Samaj Vikas (I!I~O<LI; s:~tr~:~~~:~~~s~~org) 14

15 Environmental Analysis - Final Report -November 2008 the potential environmental impacts due to the proposed project and preparation of Environmental Management Framework (EMF) for mitigating negative impacts and enhancing positive impacts. The present study has primarily relied upon the available secondary sources of data relevant to the proposed project. The main sources of such information comprised the RWSSD, the State Ground Water Directorate, Central Ground Water Board and the Andhra Pradesh State Pollution Control Board. The RWSSD, as the nodal agency for the provision of rural water supply and Sanitation in the state, has generated over the years, data pertaining to water services to rural areas. Such data includes water supply coverage in the State, sources of water supply, water quality of rural schemes, etc. Samaj Vikas (I! 11 i t.;!g?!al\i-! kx.om) 15

16 Figure 1.2: Methodology Flow Chart Analysis 1 I Inception Report 1 3 Regional ancl 1 State Level Public I I Envir~1in1etital Monituring and Performance Indic=lt~~rs Final Relaor? Samaj Vikas (jnf~/&~:i~~i~ i ~ikas.~x!rg) 16

17 1.6.2 Sample Habitations for Pilot Study 34 sample habitations were selected from 30 Mandals in 10 districts of Andhra Pradesh to assess the existing status of water supply, sanitation, public health and personal and environmental hygiene. The selection of villages for village level and household survey was done in consultation with RWSS Department based on the guidelines given by the World Bank. The villages were selected in such a way that each selected village matches at least one parameter in the given templates so as to represent in the best possible manner the typical conditions in the state. The parameters governing the selection of villages are given below: Presence1 Absence of functional water supply scheme Canal1 River water source1 Ground water source Adequatel Inadequate canai water siipply (a;! ycarj Adequatel Inadequate canal water supply (dry season) Adequatel Inadequate1 Declining yield of ground water Adequatel Inadequate water works infrastructure Potable water available (deep aquifer greater than 60 m) Shallow Ground water not potable due to salinity Deep ground water non potable due to fluoride1 salinity1 excess iron High incidence of disease related to water supply and sanitation Inadequate 0 & M of water supply by Gram Panchayat (GP) The list of sample habitations for field study is furnished in Annexure Preliminary Site Visits Site visits were taken up for field assessment using Participatory Rural Appraisal (PRA), household surveys and for conducting Focus Group Dsicussions (FGDs). During the field visits the local RWSSD Department personnel were contacted regarding water and sanitation status in the sampled villages and the area in general. The Gram Panchayat President and other key members of the village were consulted to list the issues related water and supply and in particular environmental issues related to water and sanitation. The site visits were conducted using participatorty approaches like trasact walks, field observations, mapping, FGDs, etc Public Consultations Preliminary Consultation In keeping with the World Bank's OP 4.01, Public Consultations were organized, as part of the environmental screening, in the 34 sample habitations. The objective of these consultations was to identify environmental issues, as related to the proposed activities under the APRWSSP, that need to be addressed. The consultation groups consisted mainly of local villagers, PRI representatives, line department staff, etc. During public consultations, the participation of the target population, elected representatives of the GP, local NGOs, economically1 socially weaker sections, informedl Samaj Vikas (!iifl)xi1!!1~~!j:l~:oi~) 17

18 knowledgeable public and opinion leaders, etc. was mobilized. The participants to the consultations were briefed on the proposed APRWSSP, its objectives, scope and the rules for participation in the project. The participants' opinions were solicited on the following main issues: 1. Quantity of current water supply 2. Quality of current water supply 3. Household sanitation facilities 4. Sullage disposal 5. Prevailing diseases 6. Their expectations from the proposed project A summary of the preliminary village level public consultation is firnished in Annexure Second Public Consultation I Disclosure Workshops A second public consultation process was undertaken following the drafting of Environmental Management Framework in consultation with RWSSD. Three regional level and one state level public consultation\ disclosure workshops were organized to invite suggestions1 inputs of the stakeholders to finalize the EMF document. The executive summary of EMF in Telugu language was circulated to PRI representatives, SHGs, line department staff, NGOs, etc., one week in advance of the consultation workshop. The regional public consultation workshops were held in Vijayawada, Kadapa and Hyderabad on 2nd, 4th and 7th of June The State level public consultation workshop was held in Hyderabad on 3oth June Inputs from stakeholders have been incorporated following the consultation process and the EMF was suitably revised. A report on the public consultation/ disclosure workshops is fimished in Annexure Organisation of the Report The report is presented in four chapters: Chapter-1: Introductory chapter presents a brief of project, the methodology followed, criteria for selection of sample habitations for preliminary site visits, schedule and the procedure followed for public consultations. Chapter-2: This chapter provides rural water supply and sanitation position in AP. This has information on the rural water policy and on the legal and regulatory framework relevant to the proposed project. This chapter describes rural water and sanitation institutions in the state, their roles and responsibilities with special focus on rural water supply and sanitation. Further it presents a profile of the proposed project and the rules for participation of the beneficiary community in the project. Chapter-3: This chapter presents the baseline data on relevant environmental components in the State. Based on a critical review and analysis of baseline data, the issues of environmental concern have been identified. Chapter-4: Fourht chapter has the environmental management framework. This analyses the potential environmental risks associated with the proposed project activities during the design, preparation, construction and operation phases as well as, the mitigation measures for removingl reducing the adverse impacts and Samaj Vikas ( ~n f<~>..;jgtl~jvi kx.;.o!:g) 18

19 enhancing the beneficial impacts of the project. The institutional and capacity building arrangements, monitoring and supervision arrangements as well as the financial arrangements for the implementation of the ENIF are presented in this chapter. Appropriate environmental performance indicators have been proposed which need to be integrated with other indicators as tools to assess the project performance. This report has several annexure including detailed tools for screening and environmental assessment, detailed guidelines and codes of practice for improved environmental management, etc. Samaj Vikas (~ntn~~.;:irnt~j~~li.~i: org) 19

20 2. Rural Water Supply and Sanitation in Andhra Pradesh - Policy, Regulatory Framework and Programme 2.1 RWSS at National Context The primary responsibility for providing drinking water and sanitation facilities in the country rests with the State Governments. Following the 73rd and 74th Constitutional Amendments, the States may give the water and sanitation responsibility and powers to the Panchayati Raj institutions (PRIs) and Urban Local Bodies (ULBs). The First Five Year Plan, introduced the 'National Water Supply and Sanitation Program' in 1954 and provided funds for development of Social Welfare Sector. During the initial years, the programme mainly concentrated on the construction of open wells in habitations having no/ inadequate drikng water wells. These works were executed with people's participation. During the sixties, only easy habitations were being attended to, leaving the difficult habitations. Recurring droughts made the situation worse with the falling ground water table and drying up of open wells resulting in acute scarcity of drinking water. At this juncture, the state government felt the need to develop deep bore wells particularly in difficult habitations. A bore wells programme was started by the Government in the early seventies with assistance from UNICEF and thus, there was a marked shift in emphasis from construction of open wells to bore wells. With the introduction of the Accelerated Rural Water Supply Programme (ARWSP) in by the Government of India (GOI) with 100% grant-in-aid to the states, greater emphasis was placed on coverage of difficult habitations in the state. The programme was withdrawn after , following the introduction of Minimum Needs Programme (MNP) under the Fifth Five Year Plan. The slow progress achieved by the states in the supply of safe drinking water to the rural population under the MNP led to the reintroduction of ARWSP in The approach to water supply and sanitation in the Eighth, Ninth, Tenth and Eleventh Plans broadly followed the guiding principles of the New Delhi declaration, adopted by the United Nations General Assembly in December These include (a) protection of the environment and safeguarding of health through integrated management of water resources and liquid and solid waste; (b) organisation of reforms, promoting an integrated approach including changes in procedures, attitudes, and behaviour, and the full participation of women at all levels; (c) community management of services, backed by measures to strengthen local institutions in implementing and sustaining water and sanitation programmes; and (d) sound financial practices, achieved by better management of existing assets and extensive use of appropriate technologies1. The Eleventh Five Year Plan ( ) targets to 'provide clean drinking water for all by 2009 and ensure that there are no slip-backs by the end of the Eleventh Plan. The Plan also 1 India Assessment 2002 Water Supply and Sanitation - A WHO-UNICEF Sponsored Study, Planning Commission, Government of India Samaj Vikas (~nfo:'~ srlmajviki~s.~rg) 20

21 targets to complete 7.29 crore individual toilets for achieving universal sanitation coverage in rural areas Sector Reforms Project Sector Reform Project (SRP) was the beginning of the reforms in the rural water supply and sanitation sector initiated in 1999 covering 67 districts in 26 states. The program was a paradigm shift from the regular supply based approach to demand based approach. This was initiated in 7 pilot districts of the AP state - Prakasam, Nellore, Guntur, Chittoor, Khammam, Nalgonda and East Godavari districts. Benefits from the sector reforms project include: 1. Improved public facilities for drainage 2. Reduction in incidence of water borne diseases amongst children 3. Reduction on time spent, predominantly by women, in collecting water 4. Introduction of appropriate technology and designs for water supply systems These in turn would increase the health and productivity standards in the rural areas of India Swajaladhara Sector Reform Project (SRP) has been scaled up throughout the country in the form of centrally sponsored Swajaladhara launched on 25th December This programme is a paradigm shift from supply driven to demand driven, centralized to decentralized implementation and Government's role from service provider to facilitator. A fundamental reform principle of Swajaladhara is the empowerment of villagers to ensure their full participation in the project through a decision making role in the choice of the drinking water scheme, planning, design, implementation, control of finances, management arrangements including full ownership of drinking water assets. The community has to share partial capital cost either in cash or kind or both as well as 100% responsibility of operation and maintenance (O&M). An integrated service delivery mechanism is also promoted which includes taking up conservation measures through rainwater harvesting and ground water recharge systems for sustained drinking water supply. Lessons learnt from "Swajaladhara" program are: 1. The empowerment of the PRIs is a viable and sustainable option for scaling up the decentralized service delivery model. 2. There is a need for consistent policy throughout the state, irrespective of the sources of financing. 3. The PRIs need to be well integrated into the institutional design of the project and organic links between user committees and GPs are essential for institutional sustainability. 4. The partial financing of capital cost by the users as well as user management and financing of O&M is a viable development concept. 5. The sustainability issue is best addressed by emphasis on beneficiary involvement and empowerment, and capacity building of state1 local governments and communities, along with promotion of cost recovery. Sarnaj Vikas (i!lfo:~.?ji;ru~s~~-i ~.:LS.u) 2 1

22 Box 2-1: Guidelines for environmental safety as per Swajaldhara Projects States would need to enact and implement law on effective ground water extraction control, regulation and recharge. State Government should integrate water conservation and rain water harvesting schemes with the drinking water supply schemes. Rural drinking water, sanitation, health, and hygiene programmes need to be integrated at the State, District, Block and GP levels. DWSM and the SWSM should arrange for periodic monitoring and review of the functioning of completed water supply schemes by officers, experts, NGOs, Institutions etc. Suitable monitoring mechanism and systems may be put in place in this regard by the State Government Sub - Mission Project (SMP) Sub Mission projects are taken up particularly for providing safe drinking water to the rural habitations facing water quality problems like fluorosis, brackishness, etc. and for ensuring source sustainability through rain water harvesting, artificial recharge, etc. This program is funded in the ratio of 75:25 by the GO1 and GOAP respectively Total sanitation Campaign A direct relationship exists between water, sanitation and health. Consumption of unsafe drinlung water, improper disposal of human excreta and lack of personal and food hygiene have been the major causes of many diseases in developing countries like India. High infant mortality rates are also attributable largely to poor sanitation. It was in this context the Central Rural Sanitation Programme (CRSP) was launched in 1986 with the objective of improving the quality of life of the rural people and to provide privacy and dignity to women. The concept of sanitation apart from disposal of human excreta includes liquid and solid waste disposal, food hygiene, and personal, domestic as well as environmental hygiene. The CRSP was restructured in 1999 to introduce the Total Sanitation Campaign (TSC). TSC is a comprehensive programme to ensure sanitation facilities in rural areas with a broader goal to eradicate the practice of open defecation. It follows a principle of "low to no subsidy" where a nominal subsidy in the form of incentive is given to rural poor households for construction of toilets. TSC gives strong emphasis on Information, Education and Communication (IEC), Capacity Building and Hygiene Education for effective behavior change with involvement of PRIs, Support Organizations (SOs), and NGOs, etc. The key intervention areas are individual household latrines (IHHL), School Sanitation and Hygiene Education (SSHE), Community Sanitary Complex, Anganwadi toilets, Rural Sanitary Marts (RSMs) and Production Centres (PCs). The main goal of the GO1 is to eradicate the practice of open defecation by To give fillip to this endeavour, GO1 has launched Nirmal Gram Puraskar to recognize the efforts in terms of cash awards for fully covered PRIs and those individuals and institutions who have contributed significantly in ensuring full sanitation coverage in their area of operation. The project is being implemented in rural areas with district as the unit. Guidelines for environmental safety of TSC are furnished in box below: Sarnaj Vikas (jnf0<&-;;~1~1~1~~~~.0rg) 22

23 Environmental Analysis - Final Report -November 2008 A Sanitary latrine should not Pollute or contaminate soil Pollute or contaminate ground water Pollute or contaminate surface water Act as medium to fly breeding or access to flies and animals Require handling excreta Produce odour and give ugly sight Require huge investment and high technology - - Box 2-2: Guidelines for Environmental Safety TSC 2.2 RWSS Coverage in Andhra Pradesh Drinking Water Only 43.3% of the rural habitations in the state are "Fully Covered" (FC) with water supply ( ). FC implies that they have access to a water source able to yield 40 liters per capita daily (lpcd), located within a radius of 1.6 kilometer fiom the center of the village and within an elevation of 100 meters fiom the village. The FC status thus implies that still many households have to travel long distances to fetch water. About 53.4% of the habitations are "Partially Covered" (PC) that implies that they have access to a source that does not meet the above criteria for FC. PC habitations are further classified into PC1, PC2, PC3 and PC4 depending on the yield of the source (in lpcd basis) as less than 10 lpcd, 10 to 19 lpcd, 20 to 29 lpcd and 30 to 39 lpcd respectively. Partially covered 1 (PC1): 8.08% Partially covered 2 (PC2): 17.82% Partially covered 3 (PC3): 15.82% Partially covered 4 (PC4): 11.68% 2,375 (3.30%) habitations are either 'Not Covered' (NC) or do not have access to a 'safe source' of water supply. Not covered (NC): 0.60% Not safe source (IVSS): 2.70% The following figure illustrates water supply coverage status of the rural habitations in Andhra Pradesh as on April, Samaj Vikas ( ~n t_og\:lrnrll\&;l, ory) 23

24 Chart 1 : Status of Water Supply in Andhra Pradesh (2007) 1 Fully Covered Hab~tat~ons Hab~tat~ons wth Not Safe Source Habltattons Part~ally Covered 2 Hab~tat~ons Part~ally Covered 3 Hab~tat~ons Partially Covered 4 Hab~tat~ons Not Covered Hab~tat~ons Figure 2.1: Status of Rural Water supply Coverage in Andhra Pradesh (2007) The following table lists the water supply coverage status of the habitations as on 31st March 2007 in each of the districts2. Percentage habitations falling in each category is furnished in each cell in parenthesis. S No Table 2-1:Water Supply Coverage Status of the Habitations in Different Districts (as on 01 March 2007) District Name Habitation status in water supply coverage 10 Srikakulam Vizianagarm Visakhapatnam East Godavari West Godavari Krishna Guntur Prakasam Nellore Chittoor Total Habs FC 1839 (46.70) 1600 (55.67) 2459 (45.13) 1082 (37.30) 1292 (59.87) 1248 (50.10) 633 (37.32) 796 (34.05) 1296 (42.44) 7023 PC1 360 (9.15) 269 (9.36) 453 (8.31) 751 (25.89) 167 (7.74) 278 (1 1.16) 89 (5.25) 87 (3.72) 42 (1.38) 666 PC2 615 (15.62) 245 (8.52) 780 (14.32) 425 (14.65) 142 (6.58) 21 1 (8.47) 427 (25.18) 542 (23.18) 560 (18.34) 1892 PC3 553 (14.04) 258 (8.98) 792 (14.54) 375 (12.93) 140 (6.49) 340 (13.65) 218 (12.85) 31 1 (13.30) 61 3 (20.07) 834 PC4 495 (12.57) 353 (12.28) 565 (10.37) 267 (9.20) 336 (15.57) 338 (13.57) 148 (8.73) 193 (8.25) 468 (15.32) 492 NC 0 (0.00) 16 (0.56) 389 (7.14) 1 0 (0.00) 0 (0.00) 0 (0.00) 0 (0.00) 0 (0.00) 0 (0.00) 0 NSS 76 (1.93) 133 (4.62) 10 (0.18) 1 (0.03) 76 (3.52) 76 (3.05) 18 1 (10.67) 409 (17.49) 75 (2.46) 0 I 2 RWSS Department, GoAP, 2007 Samaj Vikas (~nto~i\.i~r~,d;_~\ grg) 24

25 11 Kadapa 4542 (64.39) 1207 (26.57) 1764 (6.11) 596 (13.12) Anantapur (52.99) (1.32) 13 Kurnool (40.76) (0.72) 14 Mahaboobnagar (42.18) (13.24) 15 Rangareddy (21.84) (8.78) 16 Medak (28.10) (4.39) 17 Nizamabad (33.82) (6.25) 18 Adilabad (31.58) (14.74) 19 Karimnagar (13.81) (5.53) 20 Warangal (34.75) (8.39) 21 Khamrnam (38.47) (6.96) 22 Nalgonda (44.95) (1.03) Grand total (43.32) (8.07) Source: Rural Water Supply and Sanitation Department, April Note: (17.35) 1284 (28.27) (18.93) 631 (18.44) 461 (27.36) (7.65) 985 (21.69) 481 ( 14.45) 276 (18.15) 524 (15.32) 384 FC - Fully covered with a per capita water supply of 40 lpcd PC 1 - Partially covered with a per capita water supply of less than 10 lpcd PC 2 - Partially covered with a per capita water supply of 10 lpcd to 19 lpcd PC 3 - Partially covered with a per capita water supply of 20 lpcd to 29 lpcd PC 4 - Partially covered with a per capita water supply of 30 lpcd to 39 lpcd NC -Not covered with water supply NSS - Not safe sources. (4.51) 460 (10.13) 549 (16.49) 306 (20.11) 275 (8.04) 290 (17.21) 404 (17.05) 393 (24.08) 28 1 (7.78) 611 (27.05) 442 (12.48) 297 (9.27) 472 (14.26) 8435 (11.68) (21.48) 203 (12.44) 878 (24.32) 445 (1 9.70) 929 (26.23) 739 (23.06) 335 (10.12) (17.82) 2007 (22.79) 687 (28.98) 382 (23.40) 743 (20.58) 622 (27.53) 641 (18.10) 558 (17.41) 707 (21.36) (15.82) (0.00) (0.00) 0 10 (0.00) (00.22) 0 (0.00) 0 (0.00) 0 (0.00) 0 (0.00) 0 (0.00) 0 (0.00) 14 (0.38) 0 (0.00) 0 (0.00) 0 (0.00) 5 (0.15) 424 (0.59) The Rural Water Supply and Sanitation Department (RWSSD) currently provides safe drinking water facilities through bore wells with hand pumps, piped water supply through single village schemes (SVS) and piped water supply through multi village schemes (MVS). The type of the scheme depends on the availability of water sources and water demand. About 30% of habitations (1 1 million people) rely solely or mostly on hand pumps, 60 percent of the habitations (33 million people) on Single Village Schemes (SVS) and 10% of the habitations (1 1 million people) on Multi Village Schemes (MVS). Presently, there is an increasing demand for piped water supply and household connections in rural areas. With regard to type of source, about 75 percent of the rural water schemes are dependent on groundwater sources and nearly half of these schemes currently tap over exploited, critical and semi critical aquifers. The remaining are surface water based schemes. With regard to quality, nearly 3% of the total habitations rely on water sources with excess fluoride andlor salinity. 20 (1.3 1) 95 (2.78) 34 (2.02) 7 (0.00) 0 (0.00) 22 (0.61) 144 (6.38) 2 (0.05) 155 (4.84) 269 (8.13) (2.70) Samaj Vikas (i II~&&~~~~I:~~:I&~~.~)I-~) 25 -

26 Access to infrastructure however does not guarantee access to service. Inadequate operation and maintenance (O&M) due to shortage of funds and technical expertise is resulting in continuous slippage of FC habitations to PC and IVC categories. About 20 % of the schemes, including most schemes for which O&M has been transferred to Gram Panchayat (GPs) are not fully operational and require rehabilitation or augmentation Sanitation The present level of sanitation coverage in the state is only 53%. Out of a total of 1,01,50,779 households only 53,81,630 households have individual household latrines. But only half of the rural households with latrines are using them regularly. This implies that more than 70 percent of rural population practices open field defecation. Open defecation constitutes a major non-point source of pollution of surface and ground waters in addition to soil contamination. This problem is more acute in densely populated settlements, especially in coastal areas. Poor environmental sanitation conditions and lack of adequate supply of safe water are factors responsible for high incidence of water borne/ water related diseases among the rural population. In addition to the unsanitary disposal of human waste, the issues concerning the sanitation situation in rural areas are: Wastewater generated by households including cattle sheds flows into open surface drains that are often choked, leading to stagnation of wastewater in the lanes and bylanes. Presence of stagnant water in open drains and open areas is a breeding ground for mosquitoes and other harmful organisms, which lead to water related diseases. Facilities and practices for more efficient and hygienic conversion of animal dung and agriculture residues into manure/ compost are absent. Construction of dry pits to discharge sullage is done without any consideration to sanitary aspects. Discharge of septic tank effluents into the open drains instead of disposing to soak pits, creates unsanitary conditions. Lack of proper sanitation facilities for disposal of various wastes results in seepage into shallow aquifers which are sources of water supply through hand pumps, open dug wells, and percolation wells. Contamination of village ponds by wastewater and dumping of other wastes on its periphery. 2.3 Regulatory and Policy Framework Rural water supply is a state subject under the Constitution of India. However, states are guided by policies and regulations enunciated by the Government of India. These include: 1. 73rd Constitutional Amendment 2. The National Water Policy of The Environment (Protection) Act, No.29 of Water (Prevention and Control of Pollution) Act, 1974 (Central Act 6 of 1974) as amended in Samaj Vikas (i n fc)$~~satn:~l L ika2s.j)rw) 26

27 Environmental Analysis - Final Report -November Water (Prevention and Control of Pollution) Cess Act No 36 of Forest (Conservation) Act No. 69 of 1980 as amended in The Wildlife (Protection) Act 1972 as Amended in EIA Notification of 2006 The 73rd Constitutional Amendment designates PRIs as providers of basic services to rural communities which include drinking water and sanitation. The Andhra Pradesh Panchayat Raj Act, 1994 allows the Government to transfer to Panchayats the duty of protecting and maintaining any irrigation works or regulate distribution of water. The aspects of the National Water Policy that impact rural water supply schemes are presented in the box below: Box 2-3: National Water Policy aspects impacting Rural Water Supply Schemes Water is a scarce and precious national resource to be planned, developed and conserved as such, and on an integrated and environmentally sound basis, keeping in view the needs of the States concerned. Water should be made available to water scarcity areas by transfer from other areas including transfers from one river basin to another, based on a national perspective, after taking into account the requirements of the areas1 basins. Water resource development projects should, as far as possible, be planned and developed as multipurpose projects. Provision for drinking water should be a primary consideration. The study of the impact of a project, during construction and later, on human lives; settlements, occupations, economic and other aspects should be an essential component of project planning. In the planning, implementation and operation of projects, the preservation of the quality of environment and the ecological balance should be a primary consideration. The adverse impact, if any, on the environment should be minimized and should be offset by adequate compensatory measures. There should be an integrated and multidisciplinary approach to the planning, formulation, clearance and implementation of projects, including catchment treatment and management, environmental and ecological aspects, the rehabilitation of affected people and command area development. Special efforts should be made to investigate and formulate projects either in or for the benefit of areas inhabited by tribal or other specially disadvantaged groups such as Scheduled Castes and Scheduled Tribes and other weaker sections of society. In the planning and operation of systems, water allocation priorities, drinking water should have first priority. There should be a close integration of water use and land use volicies. The State adopts the national policy on water and sanitation which emphasizes participation by the PRIs. It lays emphasis on integration of water supply and environmental sanitation including personal hygiene. The State Water Policy accords high priority for drinlung water and underscores the need for regular programme of monitoring of fresh water bodies for protecting their water resource potential. Scope of relevant environment regulations and implications for the EMF are furnished in the table below. Samaj Vikas (!.nfc?isi!!nal! jk;:ls:s!rg) 27

28 The Environment (Protection) Act No.29 of 1986 Water (Prevention and Control of Pollution) Act, 1974 (Central Act 6 of 1974) as amended in1988 Water (Prevention and Control of Po1lution)Cess Act No. 36 of 1977 I Under this Act, the central government is empowered to take measures necessary to protect and improve the quality of the environment by setting standards for emissions and discharges; regulating the location of industries; management of hazardous wastes, and protection of public health and welfare. This Act prohibits the discharge of pollutants into water bodies beyond a given standard and lays down penalties for noncompliance. This Act provides for a levy and collection of a cess on water consumed by industries and local authorities. It aims at augmenting the resources of the central and state boards for prevention and control of water pollution. Wastewater should be treated before discharge into water bodies. Sludge from water treatment plants and sewage treatment plants must be properly processed and disposed. Prior clearance from State Pollution Control Board (SPCB) is necessary for disposing sludge from sewage treatment plants Forest (Conservation) Act No. 69 of 1980 and amended in 1988 The Wildlife (Protection) Act 1972, Amendment 1991 EIA Notification of MoEF 2006 APWALTA This Act restricts the powers of the state in respect of dereservation of forests and use of forestland for nonforest purposes. This Act provides for protection to listed species of Flora and Fauna in the declared network of ecologically important protected areas such as wild life sanctuaries and national parks. All projects listed under Schedule-I of the Notification require environmental clearance from the MoEF. Water supply and sanitation projects, however, are not covered in the Schedule. The list of project categories under Schedule I of the Environmental Impact assessment Notification is given in Annexure 7. All the existing wells must be registered with the Village Assistant. The Local Bodies shall monitor the construction of water harvesting structures in all existing and new residential, commercial, public and Permission is to be obtained from the Forest Department when forest land is required for the project activities. Ecologically sensitive areas, wild life sanctuaries and national parks should be avoided while selecting sites for project components. If this is not possible, permission should be obtained from the Forest Department and appropriate safeguards must be adopted. This project does not require EIA. However, the EMF is designed to ensure that environmental safety measures are integrated into the project. The EMF will include appropriate appraisal tools, institutional arrangements and capacity building to ensure that the all the relevant provisions of Samaj Vikas (int'o~<:g~~~~i~~~k:~s.o~_g) 2 8

29 open areas. The Authority (MWSC) may take over any well for drinking water to local people whenever water scarcity arises. Sinking of wells within 250 meters radius of a public drinking water source is prohibited. But sinking of any well for public drinking water supply, hand pump for public or private drinking water purpose shall be exempted. The Authority may declare a particular ground water basin as over exploited for a period of not more than six months and for not more than another six months after review. No well shall be permitted in such areas except wells for public or private drinking water purpose. The Authority may review from time to time and permit sinking of wells in these basins duly specifying the number of wells to be sunk, depth of the well, distance between two adjoining wells and other conditions as deemed fit. Sand mining shall not be permitted in over exploited basins. Authority may issue guidelines for constructing rainwater harvesting structures in all residential, commercial and other premises and open spaces having an area of not less than 200 square meters. The Authority may formulate guidelines including suitable incentives for recycling and reuse of waste water by industrial, commercial users and local bodies. No ground water resources shall be contaminated by anybody through direct disposal of wastewater. The authority may notify water bodies like lakes, village ponds and minor irrigation tanks etc., as heritage bodies and conservation areas. APWALTA are respected in the project activities. The proposed APRWSSP does not fall under any of the project categories listed in Schedule-I of the Environmental Impact Assessment Notification and hence does not require any formal environmental clearance of the Ministry of Environment and Forests, G01. The project area has not been notified as ecologically sensitive or fragile under the Environment Protection Act, Though the state of Andhra Pradesh is dotted with a number of sites of religious, cultural and historical importance, wildlife sanctuaries and national parks, the proposed APRWSSP is not expected to have any adverse impact on these Samaj Vikas (i~? fi):l~&i~~~~iy~ kig >~m) 29

30 sites. The proposed APRWSS project will address all the issues of concern as laid down in the OD 4.01 of World Bank on EA. Though there are no specific clearances required from the Ministry of Environment and Forests, GOI, all the provisions in the various central and state Acts listed in this chapter and relevant in the context of the proposed project would be incorporated during the implementation of the project The World Bank Safeguard Policies The below table describes the relevant safe guard policies of the World Bank and discusses their applicability to the project. Table 2-3 : The World Bank Safeguard Policies I Policy Key Features Applicability to this project OP/BP 4.01 Environmental Assessrilent OP/BP 4.04 Natural Habitats OP/BP 4.36 Forestry Potential environmental consequences of projects identified early in project cycle. EAs and mitigation plans required for projects with significant environmental impacts or involuntary resettlement. EAs should include analysis of alternative designs and sites, or consideration of "no option" Requires public participation and information disclosure before Board approval. Prohibits financing of projects involving "significant conversion of natural habitats unless there are no feasible alternatives". Requires environmental cost benefit analysis. Requires EA with mitigation measures. Prohibits financing for commercial logging operations or acquisition of equipment for use in primary moist tropical forests. Applicable to this project. The EMF includes a detailed description of assessment procedures for each of the activities proposed under the APRWSS project. Screening and assessment tools as well as detailed guidelines have been developed for all proposed schemes. Not applicable, since schemes to be taken up under the project would not convert or degrade natural habitats. However, assessment procedures and mitigation measures have been put into place through the EMF so that any negative impacts on the natural environment are minimized. Some of the schemes taken up under the Project will be located in forest areas. Mitigation measures have been appropriately included into the Environmental Management Framework (EMF) to ensure that in all schemes which have a component located on forest land, the required permission is taken through the Forest Department (for approval of the Government of India under Samaj Vikas (~jlfo~r.;nn~lgk~k+.;,grg) 3 0

31 Environmental Analysis - Final Report -November 2008 OP 4.09 Pest Management Supports environmentally sound pest management, including integrated pest management, but does not prohibit the use of highly hazardous pesticides. Pest management is the borrower's responsibility in the context of a project's EA. the Forest Conservation Act, 1980)~. Also, any required felling of trees in forest or nonforest areas is done with the permission of the Forest Department and in accordance with guidelines - for compensatory afforestation. Assessment procedures and mitigation measures have been put into place through the EMF to ensure that any felling of trees is done in accordance with the approval of the Forest Department and in accordance with guidelines for compensatory afforestation. Not Applicable. Vector control measures, if undertaken in the project will be in accordance with the OP 4.09 avoiding use of insecticides in classes la, I b and 2. OPBP 4.12 Involuntary Resettlement OPBP 4.20 Indigenous Peoples Implemented in projects which displace people. Requires public participation in resettlement planning as part of EA for project. Intended to restore or improve income earning capacity -of displaced populations. Purpose is to ensure indigenous peoples benefit from Bank financed development and to avoid or mitigate adverse affects on indigenous peoples. Applies to projects that might adversely affect indigenous peoples or when they are targeted beneficiaries. Requires participation of indigenous peoples in creation of "indigenous peoples development plans". Applicable to the project. The project will ensure that people are not displaced. Scheme components will be sited as far as possible on Government or Panchayat lands. Resettlement Policy Framework has been prepared separately. Involuntary acquisition will be avoided. Applicable to the project. Adverse effects on the indigenous people will be avoided. Indigenous people will be benefited with access to water supply and sanitation. 3 The Scheduled Tribes and other Traditional Forest Dwellers (Recognition of Forest Rights) Act, 2006 requires the Central Government to provide for diversion of forest land (of less than 1 ha, requiring felling of not more than 75 trees per hectare) for specific Government managed facilities including drinking water supply and water points, water or rainwater harvesting structures, tanks and other minor water bodies. Samaj Vikas (l~~f~!:~~ii~~l;~j~-lk:~:.grg) 3 1

32 Environmental Analvsis - Final Reuort - November OPfBP Physicla Cultural Resources Purpose is to assist in the preservation of cultural Not Applicable to the project. property, such as sites having archeological, No existing cultural property will paleontological, historical, religious and unique be damaged. cultural values. However, any cultural relics if Generally seeks to assist in their preservation found during any excavation and avoid their elimination. during the project works will be Discourages financing of projects that will deposited with the relevant damage cultural property. Government authority whose recommendation regarding further excavation will also be taken. OPBP 4.37 Safety of Dams Applies to large dams (15 meters or more in Not applicable since the project height). does not involve construction of Requires review by independent experts dams. throughout project cycle. Requires preparation of EA and detailed plans for construction and operation, and periodic inspection by the Bank. -- OPBP 7.50 Covers riparian waterways that form boundary Projects on between two or more states, as well as any bay, International gulf, strait or channel bordered by two or more Waterways states. Applies to dams, imgation, flood control, navigation, water, sewage and industrial projects. Requires notification, agreement between states, detailed maps, feasibility surveys. Not applicable since the project area does not involve international waterways. OPBP 7.60 Projects in Disputed Areas Applies to projects where there are territorial disputes present. Allows Bank to proceed if governments agree to go forward without prejudice to claims. Requires early identification of territorial disputes and descriptions in all Bank documentation. Not applicable as no project components will be proposed in disputed areas. Other World Bank Policies important to Social and Environmental Concerns The Bank's Policy on L>isclosure of Information, has been incorporated in the project implementation plan. 2.4 Sector Institutions Andhra Pradesh has one nodal department for rural water supply and sanitation, as Rural Water Supply and Sanitation Department (RWSSD) while four other institutions have a converging impact on water supply and sanitation. These institutions are as under: Nodal Institution 1. Rural Water Supply and Sanitation Department (RWSSD) Converging institutions Samaj Vikas (~~~~~Q~s.;II~~~I~I~I&~Is~. vrx) 32

33 1. Panchayat Raj and Rural Development Department 2. Department of Irrigation 3. Department of Agriculture 4. Andhra Pradesh Pollution Control Board The functions of these institutions (as relevant to the project context) are discussed in detail in the following sections Nodal Institutions Rural Water Supply and Sanitation Department During early 2008, the Panchayat Raj Engineering Department has been bifurcated into Panchayat Raj Department and Rural Water Supply and Sanitation Department (RWSSD). RWSSD is responsible for planning, execution, operation and maintenance of works related to water supply and sanitation in rural areas. RWSSD is currently implementing GO1 programmes such as Swajaladhara and Accelerated Rural Water Supply Programme (ARWSP). It is also the nodal department for the proposed World Bank assisted Andhra Pradesh Rural Water Supply and Sanitation Project (APRWSSP). It also implements Rural Water supply programme under state funded MNP and NABARD supported schemes. The RWSSD also implements the Total Sanitation Campaign. RWSSD operates under the independent charge of the Minister of Rural Water Supply. The Principal Secretary is its administrative head. The operation of the department is managed by three Chief Engineers with the support of 389 SEs, EEs and DEEs. They are further supported by around 1831 AEs/ AEEs besides other supervisory and technical staff to operate the waterworks. The organizational structure of RWSSD is presented in Figure below:

34 AEUAE, RWSS Legends: RWSS -Rural Water Supply & San~lat~on SWSM- Slate Walcr & San~lat~on Mzss~on PD,CCDU - Project D~rector, Comrnun~cat~on & Capacity Butldtng Unlt DWSM - D~rtncl Water & Sanltahon Mlrs~on DWSC - D~stnct Water & San~tahon Comrn~ltee MWSC - Mandal Water & San~latton Committee GPWSC - Vlllagc Water & San~tatton Comm~ltce CE Ch~el Englnecr SE - Supenntend~ng Englneer EE - Execuuvc Eng~neer DEE - Depuly Execut~ve Eng~neer AEEIAE - Ass~rtant Execut~ve Eng~neen : Asslrlant Engineers Regions (2) & CCDU (1) - 2 CEs In charge 012 regions & i CE ~n charge 01 Commun~calton & Capacity Development Unit Figure 2.2: Present organization set up of RWSSD The RWSSD has a network of water testing laboratories (there are 52 district laboratories4, one state level laboratory located at Hyderabad and 51 other laboratories spread over the state under the control of the RWSSD). Locations of the laboratories are furnished in Annexure 8. The State laboratories as well as the 22 district laboratories are equipped for testing of chemical and bacteriological parameters. The other 29 divisional laboratories are equipped with facilities for testing of chemical parameters only. However no laboratory is equipped with testing of biological and virological parameters. 4 RWSS Department, GoAP, 2007 Samaj Vlkas (~n ttlu- stlrla~\&g> 1)y) 34

35 Environmental Analysis - Final Report -November 2008 In addition, Institute of Preventive Medicine (IPM) has water quality testing labs in 15 districts and APPCB has state level and district laboratories for monitoring surface water quality of rivers and groundwater quality of 22 observation wells spread over the state Converging Departments Panchayat Raj and Rural Development Department (PR&RDD) The main functions of the Department are as follows: Implement schemes for rural development Improve the coverage and quality of infrastructure facilities in rural areas Execute minor irrigation and poverty alleviation programs The Department is implementing several schemes to improve living conditions of people in rural areas and to create economic awareness in rural areas. Some of these schemes include: Jawahar Gram Samrudhdhi Yojana (JGSY) Indira Kranti Patham Community Development Construction of Mandal Buildings Construction of small minor irrigation schemes and tanks Construction and maintenance of rural roads and drains Employment Assurance Scheme (EAS) Department of Irrigation The Department of Irrigation is responsible for 1. Designing and construction of dams, reservoirs and barrages. 2. Construction and maintenance of canals and drains, macro and micro hydel projects. 3. Lining of the existing channels and water courses. 4. Flood control interventions. 5. Regulation of the flow of waters in rivers and canals. 6. Control of water logging in the affected areas. The surface water1 canal based schemes of the RWSSD are critically dependent upon the water transmission and distribution network of canals under the Department of Imgation. Department of Agriculture The Department of Agriculture oversees all agriculture related activities in the state. It is also responsible for monitoring shallow ground water levels. Andhra Pradesh Pollution Control Board Andhra Pradesh Pollution Control Board was constituted under the Water (Prevention Control of Pollution) Act, 1974 with headquarters at Hyderabad. It is a regulatory authority for implementing various pollution control laws. The main functions of the Board are: To inspect industrial plants and manufacturing process, sewage or trade effluents plants or any control equipment for the treatment of sewage and trade effluent; to review plans and specification for installation of effluent treatment plants or air pollution control devices; to issue consents for installation and operation of industrial plant and to give such directions to such persons as it may consider necessary to take steps for the prevention and control of water or air pollution. Samaj Vikas ( 1 ~ ~ ~ ~ \:,~~.i~-?~.i~~rs) s h ~ ~ g j 35

36 Environmental Analysis - Final Re~ort - November 2008 To assess the water quality of river, streams, well and ambient air in the state and to plan the prevention, control and abatement of their pollution. The Board has also undertaken various studies of ground water, soil and air to take remedial steps to control pollution. 2.5 GOAP RWSS Sector Vision The RWSS Sector Vision and Policy Note has been issued by GOAP in October 2006, mainly to clarify its objectives for ensuring access to a reliable (40 lpcd water supply), financially and environmentally sustainable and affordable RWSS service to the entire rural population. Key elements of GOAP's 'Vision' are: a devolution of funds, functions and functionaries to the PHs; enforcement of full recovery of O&M costs and sharing of capital costs from user charges (taking into consideration affordability, particularly by disadvantaged groups); and improvement of the 'accountability framework' by clarifying the roles and responsibilities of the various actors of the RWSS sector at the state, district and village level, including responsibilities for policy formulation, financing, regulation, construction, operations and maintenance. The two significant changes introduced by the 'Vision' are the transfer of the responsibility for planning, design and construction of the RWSS infrastructure and for operating the RWSS service to the PRIs and communities; and the evolution of the role of the PRED to that of a provider of technical assistance to the PHs. The GoAP envisaged distribution of responsibilities between key agencies such as state water and sanitation mission (SWSM), district water supply and sanitation mission (DWSM) and Gram Panchayat Water and Sanitation Committee (GPWSC) as summarized below: (i) State Level Principal Secretary, Rural Water Supply and Sanitation Department (RWSSD): Overall RWSS policy formulation; definition of RWSS sector program objectives and implementation arrangements; State Water and Sanitation Mission (SWSM): RWSS program planning and management including detailed policy formulation, approval of annual plans and budget allocations; capacity building coordination; monitoring and evaluation (M&E), channeling of funds to GPs and GPWSCs; Rural Water supply and Sanitation Department (RWSSD): Planning and implementation of complex MVS and SVS; operation and maintenance of complex MVS under contract with served GPs; provider of technical assistance and engineering services under contract with PRIs andlor GPWSCs. Jii) District Level a District Water and Sanitation Mission (DWSM): (reporting to SWSM) review and implementation of RWSS sector program, approval of schemes proposed by GPWSCs and GPs, channeling of funds to GPWSCs; capacity building of GPs and GPWSCs, Monitoring and Evaluation, etc. Samaj Vikas (info~~is:ilni~~vik:~s,~)rg) 36

37 Environmental Analysis - Final Report -November 2008 (iii) Gram Panchayat (GP) and Community Level Gram Panchayat: capacity building of GPWSCs; approval of RWSS schemes, account management, account auditing, conflict resolution, Operation and Maintenance (O&M), cost recovery of RWSS schemes, Monitoring and Evaluation, etc. Gram Panchayat Water and Sanitation Committees (GPWSCs): RWSS scheme planning, design, procurement of works, construction supervision, with assistance of engineering consultant or RWSSD under contract; O&M of SVS, setting of user charges (capital and O&M), accounts management, etc. 2.6 Proposed World Bank Assisted Project The proposed World Bank assisted APRWSS project would aim to scale up demand responsive and decentralized service delivery approach across the state in the medium term. The project will cover all the 22 districts in Andhra Pradesh. The different key components of the project are as given in Chapter 1. A unique feature of the proposed project is its bottom up planning process in which the beneficiary community is actively involved in all stages of development of the project and its implementation including O&M of facilities created under the project. The key objectives of the proposed project are: a) To improve the quality of rural water supply and sanitation services and to achieve Sustainable development, Poverty reduction, Sustainable health and hygiene benefits to the rural population, Empowerment and inclusion of community in general and rural poor and women in particular, and Strengthening the decentralization process. b) To promote the long term sustainability of the rural water supply and sanitation sector by identifying and implementing an appropriate policy framework and strategic plan. These objectives will be achieved through: Adopting a demand responsive approach and use of participatory process for delivery of sustainable service to project communities, Phased implementation of appropriate policy and institutional reforms for changing role of the government from provider to facilitator, Community and Village Panchayat capacity building, Women's development initiatives built into the project, Targeted Tribal Development Plan. Construction1 up gradation of drinking water supply, drainage and sanitation schemes, including water quality monitoring programs, Groundwater recharge and rainwater harvesting will be integral parts of drinking water source development. Promoting integrated water resource management, and Establishing financial viability and sustainability of rural water supply and sanitation services Samaj Vikas (1_nto:~~~,uy1ajc1h,14 org) 37

38 The baseline environmental conditions are elaborated under chapter 3, while the project environmental issues and impacts are elaborated in Chapter 4. Further the existing and potential adverse environmental impacts are listed under Annexures 4, 5 and 6. The project social issues are captured in the Social Assessment Study which comprises of Social Assessment, Resettlement Policy Framework and Tribal Development Plan. Samaj Vikas (1nfo2i ssnmai ~ilg~'.org) 3 8

39 3.1 Introduction 3. Baseline Environmental Status This chapter provides an overview of the physical geography of the state, with special emphasis on water resources. This environmental baseline has been developed mainly on the basis of data collected through secondary sources, and has been supplemented by public consultations and field surveys in sample villages. 3.2 Physical Environmental Location The state of Andhra Pradesh is flanked by Maharashtra, Chhattisgarh and Orissa in the north, Karnataka in the west and Tamil Nadu in the south. The Bay of Bengal is to the east. Spread over an area of 2,75,100 sq.krns, Andhra Pradesh is the most populous state in the south of India. It lies between 12'41' and 22'N latitude and 77" and 84'40'E longitude. For the purpose of administration, the State is divided into 23 districts including Hyderabad district. There are 1,127 Mandals, 26,6 14 villages and 72,23 1 habitations in the state Geomorphology There are three main regions in Andhra Pradesh: Coastal Andhra comprising Srikakulam, Vizianagaram, Visakhapatnam, East Godavari, West Godavari, Krishna, Guntur, Ongole and Nellore districts; Rayalaseema comprising Kumool, Cuddapah, Chittoor and Anantapur districts; and Telangana comprising Khammam, Nalgonda, Warangal, Karimnagar, Medak, Nizamabad, Adilabad, Mahaboobnagar, Rangareddy and Hyderabad districts. The state has a tropical climate with moderate diffusion to subtropical weather. Humid to semihumid conditions prevail in the coastal area while arid to semiarid situations pronounce in the interior parts of the state, particularly Rayalaseema and some districts of Telangana. The areas covered by Deccan plateau are characterized by hot summers with relatively pleasant winters. The average annual rainfall received in the state ranges from mm in the Scarce Rain fall Zone to about mm in the North Telangana region5. The state is dotted with hill ranges from the north to the south, running erratically down the middle. In the north, there are Simhachalam and Annavaram hills, in the middle country, there are the Srisailam hill ranges and in the south are the Tirumalai Tirupati hills. The state has two great rivers, Godavari and Krishna which spring from the Westem Ghats in Maharashtra and flow eastward and joins the Bay of Bengal. The Godavari enters the state of Andhra Pradesh direct from Maharashtra, but the Krishna first goes to Karnataka where it flows for a considerable distance before entering Andhra Pradesh. Besides these two big rivers, there are the Tungabhadra, the Pennar and many other small rivers and rivulets. Tungabhadra and Pennar originate in the Kamataka plateau. Like all the peninsular rivers all these are rain fed rivers. 5 Source MQ 'ig1.1 lip cl11.1n;lt~' h1111l (viewed on 1 l August 2008) Samaj Vikas (i n.f-.~~:';~~g~~j\:i~k/l';,~rg) 3 9

40 Environmental Analysis - Final Report -November Ecologically Sensitive Areas There are 22 wildlife sanctuaries and 4 national parks in Andhra Pradesh. The figure below shows the map of the National Parks and Sanctuaries in Andhra Pradesh. Figure 3.1: Map of Wildlife Sanctuaries & National Parks of AP. Source: Forest Department, GOAP The table below gives the details of the ecologically sensitive areas such as wildlife sanctuaries and national parks in Andhra Pradesh. S. No. 1. Name of ParWSanctuary Kawal Wildlife Sanctuary Table 3-1: Wildlife Sanctuaries & National Parks in AP District located Adilabad Significant trees Dry Deciduous Teak Forests mixed with Bamboo, Significant animals and birds Tiger, Panther, Gaur, Cheetal, and other wild animals and a variety of Shivaram Wildlife Sanctuary Manjira Wildlife Sanctuary Adilabad & Karirnnagar Medak - Riverine forest mixed with Teak, Terminalia, Bamboo, Ipomea, Babool, Prosopis, Vallisnaria, Marsh Crocodile, Tiger, and other wild animals Marsh Crocodile, fresh water Turtles and a variety - Samaj Vikas (~~~f(@i;j~~fi~\ikgg~(!~)

41 4. Eturangaram Wildlife Sanctuary Warangal Eichornia, Reeds. Dry deciduous Teak forest with Bamboo of aquatic birds Tiger, Panther, Gaur, Sambar, Cheetal, and migratory Birds Pranahita Pakhal Kinnera Sani Papikonda Adilabad Warangal Khamrnam East Godavari, West Godavari & Khammam Dry deciduous and riverine Forests with Teak, Bamboo etc. Dry deciduous Teak forest with Bamboo, Mohua, Terminalia, Pterocarpus Dry deciduous Teak forest with Bamboo, etc. Dry deciduous Teak forest with Bamboo, Terminalia, Pterocarpus, Cassias Tiger, Panther, Sloth and other wild animals and a variety of aquatic Birds & 1 Reptiles Tiger, Panther, Gaur, wild animals and migratory Birds Tiger, Panther, Gaur, Cheetal, and other wild animals and aquatic birds Tiger, Panther, and other wild animals; Marsh Crocodile and a variety of birds. 9 Koleru West Godavari Srisailam (Nagarjunasagar) Wildlife Sanctuary Rolla Padu Kaundinya Wildlife Sanctuary (Project Elephant) Krishna and Guntur Medak & Nizamabad Medak Guntur, Prakasham, Kmool, Mahaboobnagar Kurnool Chittor 1 Dry deciduous forest with patches of scrub grassy plains. Ipomea, Babool, Prosopis, and Reeds. ' Estuarine Crocodile and a I variety of birds. I Panther, Sloth Bear, and other wild animals Marsh Crocodile, fresh 1 water Turtles and a variety ' of aquatic birds Teak, Bamboo, Tiger, Panther, and other Terminilias, wild animals, Mugger 1 Hardwickias, 1 Crocodile, Rock Python and Peafowl. Anogeissus and hundreds of medicinal ulants Open dry grassland Dry deciduous and thorn forests consisting of Albizzias, Accacias, Lagerstroemea, Ficus, Bamboo. Wild animals, Russell's Viper and Cobra. Indian Elephant, Sloth Bear, Panther, Cheetal, and other wild animals. Sanctuary 17 Gundala Brahmeshwara East Godavari Kurnool & Prakasam Mangrove vegetation Mixed deciduous forest of Teak, & Bamboo. Otter, Fishing Cat, Jackal, Marine. Turtle and Estuarine Crocodile. Most common birds. Tiger, Panther, and Wild animals, and Marsh Samaj Vikas (~ntc)~~>,lln;~c_~h,~\ ors)

42 Environmental Analysis - Final Report -November Sri Lankamalleshwara Nelapattu Pulicut Sri Peninsula Narasimha Kanbalakonda National Parks Sri Venkateswara National Park Mahavir Harina National Park Kasu Brahrnananda Reddy National Park Mrugavani National Park. Cuddapah Nellore Nellore Nellore Visakhapatnam Tirupathi Kadapa & Chittor Hyderabad Hyderabad Dry deciduous mixed thorn forests A fresh water tank with Barringtonia trees A vast coastal shallow, brachsh water lake Dry evergreen forest Dry evergreen forest Flora and fauna Flora and fauna Crocodile. Panther, Sloth Bear, Cheetal, and other wild animals. Variety of birds Variety of birds Panther, Cheetal, and other wild animals, large number of Reptile and Bird species. Panthers, Spotted Deers and other wild animals Wild animals Wild animals Climate and Rainfall The climate of Andhra Pradesh is generally hot and humid. The average annual rainfall of Andhra Pradesh state is 940 mrn. The average annual rainfalls of coastal Andhra Pradesh, Telengana and Rayalaseema are 1094mm, 961 mm and 680mm respectively. Annual rainfall details for the past years from to are illustrated in figure below: Rainfall in mm from to Rainfall in mm Water Year (June-May) Figure 3.2: Rainfall to Note: Water year is the period from June of previous year to May of the current year Samaj Vikas (i!hfo~qsai~n~i~i&.;.or!) 42

43 The district wise deviation of annual rainfall in the year 2007 is presented in the figure below: 'a.. -., CENTRAL GROUND WATER BOARD,. ".. DEVIATION OF RAINFALL DEVIATION (%) -50 to to 0 0 to 25 w 225 Figure 3.3: District wise deviation of annual rainfall in the year 2007 from 1997 Source: Central Ground Water Board The normal annual rainfall is 940 mm. The rainfall also shows that droughts are fairly recurrent in the state. The analysis of state rainfall during indicates deficit rainfall in all the 30 years in one or the other parts of the state. The State receives about 66% of rainfall from south west monsoon (June - September) and about 25% from north east monsoon (October - December). The remaining 9% is received during winter and summer months Demographic Status The population of the state is million as per 2001 census. The State has population density of 277 per sq. krn. (as against the national average of 324). The decadal growth rate of the state from 1991 to 2001 is 14.59% (against 21.54% for the country) and the population of the state is growing at a slower rate than the national rate million (72.70%) of the state population lives in rural areas. Hyderabad district has no rural Samaj Vikas (~fo>~~;!~~~gly~.k;li:.~.~~_r~) 43

44 pppp-- Andhra Pradesh Rural Water Supply and Sanitation Project Environmental Analysis - Final Report -November 2008 population. Except Ranga Reddy district all other districts have rural population more than 60% of the district population. Mahaboobnagar district has the highest rural population (89.43%) and Ranga Reddy district has the lowest rural population (45.79%) The district wise demographic data of the state including total population and rural population as per 2001 census is presented in the table below: Table 3-2: District wise demographic data (census 2001) S1. No Adilabad District Nizamabad Karimnagar Medak Hyderabad Ranga Reddy Mahaboobnagar Nalgonda Warangal Khamrnam Srikakulam Vizianagaram Visakhapatnam East Godavari West Godavari Krishna Guntur Prakasam Nellore Kadapa Kurnool Anantapur Chittoor Total Total Population Percent to total population of the State The district wise population range is shown in the figure below: I I Rural Population Percent of Rural population in the District Samaj Vi kas (!r!&$~.;a~~i~~1k:~~.or~1) 44

45 YAHPRASHTRA HHATTISGA Source: Census Department I Map n& b &ah Copyright Compata Infobase ilmltsd Figure 3.4: District wise Population Range Agriculture The agriculture and allied sectors contribute close to 30% of the State's GDP and provide employment to 64.55% of the population. The cropped area in Andhra Pradesh is divided into seven zones based on the agroclimatic conditions. The classification mainly concentrates on the range of rainfall received, type and topography of the soils. The districts covered by the different zones and their agroclimatic characteristics are given below6: Table 3-3: Zone Krishna - Godavari Iifferent zones and ti Districts East Godavari Part, West Godavari, Krishna, Guntur, and contiguous areas of Khammam, Nalgonda and Prakasam eir agroclimatic characteris Rainfall I Temperature South West ( Max C Monsoon Min C ic s Soil Type Deltaic alluvium, Red soils with clay, Black Cotton soils, Red Loams, coastal sands & saline Crop Grown Paddy, Groundnut, Jowar, Bajra, Tobacco, cotton, chilies, Sugarcane and Horticultural 6 h1~1 Jrrrl ap 111c In cllm:r~r. htrr~l viewed on 11 August 2008 Samaj Vikas (~nti~rc_\,~inaj\ I~,I. org) 45

46 Environmental Analysis - Final Report -November 2008 Coastal Zone Southern I Telangana Zone Southern Telangana Zone Rain Fall Zone of Rayalasee Srikakulam, Vizianagaram, Visakhapatnam and uplands of East Godavar i Hyderabad, Rangareddy, Mahabubnagar (except Southern border), Nalgonda (except North eastern boarder), Medak (Southern parts), Warangal (North western Part) Adilabad, Karirnnagar, Nizamabad, Medak (Northern part), Warangal (Except N.W.Part), Eastern tips of Nalgonda and Khammai Hyderabad, Rangareddy, Mahabubnagar (except southern border), Nalgonda (except North eastern border), Medak (Southern parts), Warangal (North Western Part). Kurnool, Anantapur, Prakasam (Western parts) Cuddapah (Northern part) Mahabubnagar (Southern Border) Northern borders of Altitude Srikakulam, Vizianagaram, Areas Visakhapatnam, East Godavari and Khammam South West Monsoon mm South West Monsoon mm. South West Monsoon mm South West Monsoon mm Both from South West Monsoon & North East Monsoon mm South West Monsoon Over 1400 mm Min C Max C Min C Ma C Min "C Max "C Min "C Max "C Min "C soils Red soils with clay base, Pockets of acidic soils, laterite soils, soils with ph 4-5 Red soils having Red earths with loamy subsoils (Chalkas) Chalkas, Red sandy soils, Dubbas, Deep Red loamy soils, Very deep B.C. Soils Red earths with loamy subsoils (Chalkas) Red Earths with loamy soils (Chalkas), Red Sandy Soils and B.C. Soils in pockets Crops Paddy, Groundnut, Mesta, Jute, Sunhemp, Sesamum, Jowar, Bajra, Blackgram and Horticultural crops Paddy; Sunflower, Safflower, Grapevine, Sorghum, Millets, Pulses and Orchard crops Paddy, Sugarcane, Castor, Jowar, Maize, Sunflower, Turmeric, Pulses and Chillies Paddy, Sunflower, Safflower, Grapevine, Sorghum, Millets, Pulses and Orchard crops Cotton, Korra, Sorghum, Millets, Groundnut, Pulses, Paddy -- Horticultural crops, Millets, Pulses, Chillies, Turmeric and Pepper Samaj Vikas (I 11 ~O~LI; S~~IIIZ~~J-I~I~.. ors) 46

47 The total cultivable area, which includes net area sown, current fallow, fallow other than current fallow and cultivable waste is around million hectares or 57 per cent of the total geographical area. While this area has remained unchanged over the years, the net area sown has declined from 41 per cent during the triennium ending to about 37 percent during the triennium ending The decline in net area sown has been accompanied by an increase in cultivable waste, fallow land and land put to nonagricultural uses. The increase in underutilized land (the difference between the total cultivable area, and net area sown), fiom 28 per cent of the total cultivable area to about 33 per cent during this period is a cause of concern in the state. Almost 19, sq. krn. of land in the state, which is about 7 per cent of the total geographical area (and per cent of the cultivable area), is categorized as degraded and 45, sq. krn. are total wastelands7. Incidence of degradation is more in Rayalaseema and Telangana regions where agriculture is predominantly dry land based dependent on rainfall. Agricultural inputs - fertilizers, pesticides in irrigation have shown a trend towards increased consumption. The consumption of total fertilizer nutrients recorded a sharp increase of 24.1% from MT during to MT during Per hectares consumption of total fertilizer nutrients increased from kg during to kg during ~. The consumption of pesticides in the state, however, has declined from 3700 MT in (6th place in the country) to 1051 MT in (10th place in the country)9. The percentage of well irrigation, which was only 33 per cent in the state during the triennium ending 1992, rose to 51 per cent by the end of the triennium ending lo. Implications for EMF Agriculture, being the main utilizer of ground water, impacts both seasonal water availability as well as long term sustainability of ground water resources. Agricultural inputs impact water quality of surface water resources as well as shallow ground water resources. The source selection for water supply schemes in the APRWSS must include safeguards against close proximity to competing agricultural wells, and regular monitoring of the quality of water (both surface and ground water sources) to ensure that it is safe for drinking. 3.3 Water Resources The State's (surface and ground) water resources are estimated to be BCM (3,820 TMC), out of which about BCM (2,200 TMC) are currently being utilised for drinking, agriculture, industry and power generation. The per capita annual water resources work out to be slightly more than 1,400 Cu.M, and utilisation is about 800 Cu.M. The current percentage withdrawal of available water in Andhra Pradesh is 58%". The State Government's estimation of water requirement for various sectors is furnished in the table below: 7 Andhra Pradesh Human Development Report, Sourcc.: l~ttl~:.'~'~va.w.ip~~i,nct 9 Source: 10 Andhra Pradesh Human Development Report, Andhra Pradesh Human Development Report, 2007 Samaj Vikas (!!~ti).~~~~~?i\l&i~~.(~r~) 47

48 Environmental Analysis - Final Report -November 2008 Table 3-4: Water requirement for various sectors Sector (Million Cubic Metres) Industries Power generation Ecological and other needs 1,08, , , I I 1 Total Source: Water Conservation Mission - Water Vision Percentage of total 3.04 Based on the present availability of 1,08,012 MCM of water, the 2025 projections for water requirement cannot be met, unless measures to conserve more rainwater or judicious use of the current water available through appropriate recycling are ensured. One of the steps would be to regenerate more natural ecosystems that help in tapping and conserving water, while the other would be the more extensive use of natural ecosystems to recycle the wastewater. Another step to be undertaken is to adopt modem irrigation techniques such as spray irrigation and sprinkler irrigation and reuse of treated sewage in agriculture sector, which will reduce the water needed for irrigation, which is estimated to be % of the total water use. The guidelines of APWALTA should be implemented to control over extraction of groundwater Surface Water Godavari, Krishna, Vamsadhara and Pennar are important rivers among the 40 major and minor rivers in Andhra Pradesh. Krishna and Godavari alone contribute almost 90% of the State's surface water resources. The State's share of dependable flows at 75% dependability from the river system is estimated at BCM (2,746 TMC), and BCM (1,753 TMC) has currently been utilised. The State is divided into 40 river basins. Of these, 28 basins have surplus water for further development. Godavari river basin has about BCM (760 TMC) surplus water, while other river basins have about BCM (230 TMC). The water resources of Krishna and Pennar have been utilised completely Groundwater The net groundwater availability per mum is estimated to be 32,203 MCM'~. The range of ground water development for different districts varies from 5-52% in command areas and from % in noncornmand areas (against the State average of 56% - in 2003). The sustainable development and management of groundwater resources requires precise quantitative assessment based on valid scientific principles. During the last three decades, groundwater utilization in Andhra Pradesh has increased tremendously. According to the Minor Irrigation Census ( ), ground water levels in about 60% of the villages in the state are within a depth of 25 m. About 10% villages have ground water at 12 State of Environment, AP, 2003 Samaj Vikas (~!lt.~.<~~:,tt~n:~pj ksx.rr) 48

49 Environmental Analysis - Final Report -November 2008 depths at or exceeding 70 m. The remaining 30% have depth of groundwater ranging from 25 m to 65 m13. Andhra Pradesh State Ground Water Directorate has established 2,986 observation wells, 1,017 piezometers and a network of 908 piezometer wells fitted with automatic water level recorders, and, is monitoring the changes in groundwater regime. The following table shows the depth to water level variation in different districts (October, 2007). Table 3-5: Depth to water level variations in different districts (as observed in October 2007) State of Environment, AP, 2003 Source: Data on depth to water level observed from observation wells in different districts in November, 2007 are furnished in the figure below: Data on water level fluctuation observed from observation wells in different districts from November 2006 to November, 2007, through May 2007 is furnished in Annexure 9. The corresponding figures (including a figure on decadal mean for November ) are given below: 13 Source: Samaj Vikas (in si!g~;~ly-ik:~s.o~.rr) 49

50 Data on water level observed from observation wells as decadal mean for the month of November, 2007 in different districts are furnished in the figure below. WATER LEVEL FLUCTUATDN ANDHRA PRADESH Source: Central Ground Water Board Figure 3.5:Water level fluctuation - Decadal mean November ( ) There has been a dramatic increase in well construction and groundwater extraction during the last 15 years primarily for groundwater based irrigation as well as for drinking water sources. Shallow tube wells in the state have increased from 2,46,770 in to 6,56,359 in Deep tube wells have increased from 32,359 in to 87,482 in In both cases, an increase of over 2.5 times in each casei4. Further in recent years, groundwater extraction per well has increased substantially as a result of the availability of submersible pumps and electricity. The shift in well construction from open wells to bore wells represents a shift from groundwater extraction that exploited shallow unconfined aquifers to extraction from deeper confined aquifers. Net groundwater extraction for irrigation, domestic and livestock use for different districts was estimated at 8 to 11.0% of mean annual rainfall respectively. As the Andhra Pradesh 14 Source: Samaj Vikas (! n <i?h'.lu~ri;~j>jj.;~~s grg) 50

51 Environmental Analysis - Final Report -November 2008 Groundwater Directorate estimate of groundwater recharge in the state is approximately 10% of annual rainfall only, this suggests that current levels of extraction in certain districts are not sustainable if the extraction is more than the recharge. Of the 6,56,359 shallow bore wells (in ), 5,208 (0.8%) had dried up and of the 87,482 deep bore wells, 349 (0.4%) had dried up15. Since the extraction from groundwater for irrigation is in the order of 85 to 90%, it may affect the drawal of water (though very negligible quantity) from groundwater source for drinking water supply during summer (the Minor Irrigation Census of reports that 10,73 1 (1.6%) shallow bore wells and 1,054 (1.2%) deep bore wells were temporarily not in usei6). In order to achieve sustainability of drinking water sources optimizing the extraction of water for irrigation purposes from groundwater sources is necessary especially in areas where the existing level of ground water exploitation is a concern. State average for ground water development stands at 45%". In 15 of the 21 districts (for which data is available) the groundwater development is less than 70%. This is illustrated in the figure below: Chart 2: Status of Ground Water Development in Andhra Pradesh ( ) - District 1 Figure 3.6: District wise status of groundwater development in AP ( ) Excessive ground water withdrawal is an issue in parts of the state. The districts of Chittoor, Kadapa, Anantapur, IVizamabad, Medak and Ranga Reddy range between 70% and >loo% groundwater development la. Of the 1,108 mandals in the state, 15% (1 72) are classified as over exploited and 5% (58) are classified as critical with respect to groundwater status19. The Annexure 10 presents the categorization of Mandals according to groundwater exploitation. 15 Source: 16 Source: 17 Central Ground Water Board, Directorate of Economics and Statistics, GoAP, Central Ground Water Board Samaj Vikas (! 11 t(!$~.~i:~~~~:~ji-!kgs.ow) 51

52 Environmental Analysis - Final Report -November 2008 Box 3-1: Stage of Ground water Development - Terminology and Definitions Safe: A sub unit is categorised as "safe" with potential for future groundwater development if one of the following two criteria is fulfilled: i) the stage of groundwater development is less than or equal to 70% and the water table during at least one of the two intervals (either premonsoon or postmonsoon) does not show a falling trend and ii) the stage of groundwater development is greater than 70% but less than or equal to 90% and the water table during both premonsoon and postmonsoon intervals does not show a falling trend. Semicritical: A sub unit is categorised as "semicritical" with caution to be executed for future groundwater development if the following criterion is fulfilled: the stage of groundwater development is greater than 70% but less than or equal to 90% and the water table during only one of the two intervals (either premonsoon or postmonsoon) shows a falling trend. Critical: A sub-unit is categorised as "critical" with only very marginal scope for future groundwater development if one of the following criteria is fulfilled: i) the stage of groundwater development is more than 90% and the water table during only one of the two intervals (either premonsoon or postmonsoon) shows a falling trend and ii) the stage of groundwater development is equal to 100% and the water table during both premonsoon and postmonsoon intervals shows a falling trend. Over exploited: A subunit is categorised as "over exploited" with practically no scope for any future groundwater development if the following criterion is met: the stage of groundwater development is more than 100% and the water table during both premonsoon and postmonsoon intervals shows a falling trend. Table 3-6: Categorization of Mandals with reference to Groundwater Exploitation Total No. Name ofthe of District Mandals Safe Semicritical Critical Overexploited No. % No. % No. % No. % 1 Adilabad Samaj Vikas (IF ti,:.~ siua18j \:~I\;IC. wg)

53 Note: SC : Semi Critical; C: Critical: OE: Over ex~loitation Samaj Vikas (!ti.fg~&~ig~a~~gis<~rg) 53

54 ANDHRA PRADESH CATEGORISATION OF MANDALS BASED ON ( %) OF DEVELOPMENT OF GROUNDWATER- March 2004 ( Source:CGW@ *+, L LEGEND Category Stage (%) of Development No.Mdls < 70 % = ( c % 77 =75 +2 ( c) 21 9 P 9 E 3 1 S r: L P. :,.:%:- : -<:

55 Environmental Analvsis - Final Re~ort - November 2008 Implications for EMF Source selection criteria specified in the EMF will need to include sustainability of the available ground water (specifically, the category in which it falls; safe, semicritical, critical or over exploited). Source selection will generally be limited to safe and semicritical aquifers. In critical and over exploited zones, ground water recharge measures (including rain water harvesting) will be undertaken as Dart of the vrovosed schemes Artificial Recharge of Groundwater Under the State Government's watershed development programme, over 9,637 watershed projects were undertaken across 22 districts in Andhra Pradesh (till 2005) covering an area of 42 lakh ha. Mandals with stage of groundwater development at >70% and water levels >10 m with declining trend were given priority in these programmes. More than 30 per cent of the watershed projects are in the dry regions of the state, in Anantapur (1,204), Mahabubnagar (1,077) and Kurnool(981) districts, covering an area of 5.0, 4.4 and 4.3 lakh ha respectively. These three districts together constitute more than 32 per cent of the total area brought under the watershed development programme. Nearly 40 per cent of the rainfed area has been brought under watershed programmes in the state and across districts it ranges from over 70 per cent in Ranga Reddy, Nalgonda and Chittoor districts to 2 per cent in West Godavari district2'. Between , RWSSD constructed the following groundwater recharging structures: Check Dams Percolation Tanks Sub Surface Dykes Roof Top Rain water harvesting structures Infiltration rings Recharge pits Runoff breakers Desilting of drinking water tanks Injection wells/ recharge wells Breach fillingsf runoff baniers The following table illustrates impact of the artificial recharge structures built as part of the watershed programmes on the groundwater regime. Table 3-7: Impact of artificial recharge structures on groundwater regime in water shedsareas District No. of water No. of wells Increase in % Increase in sheds Preproject Postproject water level Command evaluated (m) area Srikakulam Nellore Cuddapah Andhra Pradesh Human Development Report, 2007 Sarnaj Vikas (!~ti~/isu!li~,yi k;ks.c?rv) 55

56 Implications for EMF Ground water recharging structures (including rain water harvesting structures) should be incorporated as source sustainability measures in areas where the groundwater extraction is at critical or over-exploited levels Water Quality Water quality describes the chemical, physical, and biological characteristics of water with respect to its suitability for a particular use. Water quality criteria are based on specific levels of pollutants that would make the water harmhl if used for drinking, bathing, agriculture, fisheries, or industrial processes Surface Water Quality In Andhra Pradesh surface waters are mostly of good quality, but pollution is increasing. Rivers such as Godavari, Krishna, Musi, Pennar etc., are found to be polluted at different stretches, mainly due to industrial, domestic and agriculture pollution. Among all the rivers, Musi is the most polluted. The Godavari river water quality is within the safe limits until Manchiryal but polluted hrther down stream. The major source of pollution is sewage, discharges of untreated effluents from industries and agriculture run off. None of the main surface water sources in the state are safe for drinking or bathing without conventional treatment2'. Box 3-2: Water Quality Classes and Criteria CLASS - A: Drinking water source without conventional treatment but after disinfection. Note: There shall be no visible discharge of domestic and industrial wastes into the river CLASS - B: Out door bathing, swimming and water contact sports. Note: All the domestic and industrial wastewater discharges upstream of bathing places shall be so regulated that the stream standards are maintained and that there is no visible floating matter including oils at the bathing places. CLASS - C: Drinking water source with conventional treatment followed by disinfection. Note: All domestic and industrial wastewater discharges into this class waters shall necessarily be treated to ensure maintenance of stream standards and the discharge points shall be kept sufficiently away from the abstraction points. CLASS - D: Propagation of Wildlife and Fisheries I 1 CLASS - E: Irrigation, cooling and controlled waste disposal Based on Designated Best Use: Source: APPCB I 21 Source: State of Environment of Andhra Pradesh, 2003, APPCB, GoAP samaj Vikas (ir~ri? k~glj~~rlj>:i&a.;,s~:<)~) 56

57 Kolleru lake and Pulicat lake have also been found to be polluted. Apart from these, several inland water bodies i.e. lakes and tanks have been polluted mainly because of industrial and domestic wastewater discharges. Implications for EMF Avoiding pollution of surface water bodies. Surface water quality should be protected by preventing contamination by sewage and solid wastes. Sewage should be treated, recycled and reused. Solid wastes should be segregated at the source and organic portion of the waste should be processed into compost and used in the agricultural field. Utilization of ground water for source selection. Source selection should give priority to groundwater whenever it is of better quality than surface water and requires less treatment Ground water Quality Groundwater is an important source of drinking water and is generally of better quality than surface water sources. However, it may also get polluted by the wastes generated in the industrial, agriculture and domestic sectors. In Andhra Pradesh, the groundwater in about 0.5 M Ha is of poor quality, mostly due to the geological salts and in the coast, due to marine influence. In Krishna and Godavari delta, the quality of groundwater varies with the depth. In the shallow zone it is within the potable limits, but deteriorates rapidly with depth. In 36 Mandals (East Godavari 6, West Godavari 17, and Krishna 13)" of coastal districts, shallow groundwater quality is found to be saline. The box below indicates the implications of groundwater to EMF (Source: Report on Groundwater Resources in AP). Implications for EMF l~efore selecting the source for water supply scheme the quality of water should be tested to ensure I lthe water is safe for drinking. 1 In case the local ground water is unsafe, and no alternate safe source (surface or ground) is available, the ground water should be treated through RO to remove the excess concentration of pollutants before supply. Proper measures should be taken for the disposal of rejects from the RO plant (Refer Annexure 1 I). RO schemes come under category 2 (Tools for categorization of schemes are included in Annexure 22). Fluorosis is widespread in some districts of Andhra Pradesh. Of the affected districts, Prakasam, Nalgonda, Khammam, Ranga Reddy, Kumool, Karirnnagar and Ananthapur districts are more severely affected. The groundwater in habitations has high fluoride concentration beyond the permissible 1.5 mg/l'3. This affects several thousands of people. In Nalgonda district where the occurrence of fluoride is the highest, about 70,000 people in 2 15 villages are suffering from this disease. Overextraction of groundwater also leads to change in groundwater quality. It has been found that fluoride content in groundwater is increasing in nontraditional areas due to 22 State of Environment of AP, EPTRI, RWSS Department, GoAP, 2007 Samaj Vikas (i n ti$<.; ;lnjajjvfii~ssc)rg) 57

58 overextraction of water. Potassium content is also increasing due to use of potassium based fertili~ers~~. Salt water intrusion affects groundwater quality in Coastal Andhra. Mandal wise details of number of habitations affected by NSS are furnished in the table below: Table 3-8: Mandal wise NSS / Quality affected Habitations (as on APRIL 2007) S No. Name of District Total No. of No. of Mandals No. of NSS Mandals in the affected with Water Habitations district quality issues Adilabad Ananthapur Eastgodavari I Kadapa Karirnnagar Khamrnam Krishna Kurnool Mahabubnagar Nalgonda ( I Nellore Prakasam Rangareddy Srikakulam Visakhapatnam Vizianagaram Warangal Westgodavari Chittoor Medak Nizamabad Total , , State Groundwater Directorate Samaj Vikas (~njo!iis:~~~~i~l>;~~jg~r~)

59 Environmental Analvsis - Final Re~ort -November 2008 The following figure shows the type of water quality problems in the affected habitations. I Type of Water Contamination in Affected Habitations (2003) Hh& Fluiiide Nitrate Salirity 0 Im I Sllphate Rysid and E!idcgid CCdamiPalial Figure 3.8: Type of water quality problems in affected habitations The figures in the following pages illustrate the Status of Not Safe Source (NSS) habitations, brackish habitations and fluoride habitations. Samaj Vikas (~!~t<&~!r_~;_n~~~;i&~~o.rg) 5 9

60 ANDHRA PRADESH STATUS OF NSS HABITATIONS AS ON APR 2007 LEGEND Apdrsf. No.of Habs r-- lo

61 ANDHRAPRADSEH STATUS OF BRAKISH HABITATIONS AS ON LEGEND Apdist No of Habs r - 0 Dl m Apdist. Apdist Apdist DAIA:WAlER SVFT ', 4

62 Source: AP RWSS Department Figure 3.11: Status of Fluoride water habitations as on April 2007 Samaj Vikas 62

63 Environmental Analysis - Final Report -November 2008 The Fluoride Problem Minimum of lmgllt. of fluoride may be required to prevent dental carries, but beyond 1.5 mg/lt. in drinking water may cause mottling of teeth or dental fluorosis, a condition resulting in the discoloration of the enamel, with chipping of the teeth in severe cases, particularly in children. In Indian conditions where the temperatures are high, the occurrence and severity of mottling increases when the fluoride levels exceed 1.0 mgll t. With higher levels, skeletal or bone fluorosis with its crippling effects are observed. The chief sources of fluorides in nature are (i) fluorapatite (phosphate rock), (ii) fluorspar, (iii) cryolite and (iv) igneous rocks containing fluorosilicates. Fluorides are present mostly in ground waters and high concentrations have been found in various districts of Andhra Pradesh. While majority of values range from 1.5 to 6.0 mg /It., some values as high as 16 to 18 mg/lt. have been reported. Treatment units set up in India for removal of excessive fluorides in rural water supply schemes are so far not functioning satisfactorily. Before selecting the source of water for the supply scheme, the quality of water should be tested to ensure that it is safe for drinking. Implications for EMF 1 A Flouride Strategy is developed as part of the EMF. This includes the safeguards with respect to ) source selection, technology alternatives, IEC requirements, etc. for addressing the fluoride problem. I Current Water Supply and Treatment Practices The existing rural water supply schemes essentially have two sources: tube well and river/ canal. About 75% schemes are tube well based. The tube well schemes constitute a bore well fitted with a submersible pump. A chlorination unit is connected to the pumping main for the disinfection of water. The water, after being chlorinated, is pumped to the overhead tank where it is stored and subsequently supplied to the users through the distribution network and public stand posts. This may be for either SVSs or MVSs. The remaining 25% schemes are surface water (river/ canal) based. The raw water is transmitted through an intake point in the source to a water treatment plant. Water treatment is provided by means of slow sand filters followed by chlorination in the ground level clear water storage reservoir. The water is then pumped to an overhead tank. The canal based water schemes are dependent on Irrigation Department for release of water flow in the canal. Normally, canals receive water on a rotational basis. However, during harvesting season, the canal water supply is only once a month.there are certain issues faced during the operation and maintenance of the schemes: 1. Inadequate cleaning of filters, and OHTs. 2. Improper disposal of sludge from treatment plants. 3. Non flushing of pipelines. 4. Reduced duration of pumping due to reduced duration of electrical power availability. These actions severely impact drinking water supply. 4 Im lications for EMF Maintenance of the water treatment plant, OHT and Pipelines Periodical cleaning of filters Flushing of transmission and distribution pipelines Samaj Vikas ( ini~~~~~i~.fij~!k_~s.~~~r~) 63

64 Periodic cleaning of OHTs Proper disposal of sludge from the settling tank of water treatment plant to avoid environmental pollution While designing considering hours of pumping to suit the electric power availability Maintaining diesel generators as standby to avoid disturbance to pumping due to scheduled and unscheduled power supply failures Incidence of Water and Sanitation - Related Diseases Environmental factors account for about 20 per cent of all the diseases in Andhra Pradesh. More than 90 per cent of this is associated with traditional environmental problems such as lack of access to protected water supply and sanitation, and indoor air pollution resulting from the use of biomass fuelsz5. One fifth of the total ailments in the State are due to environmental causes. Water supply and sanitation related diseases emerge as largest in AP influenced by environmental causes. The prevalence of diarrhea clearly indicates a seasonal variation mainly due to lack of water (premonsoon) and poor availability of safe drinking water during the monsoon peak when protozoan and bacterial agents are rampant and overflow from sewers and latrines contaminating drinking water sources. Outbreaks of cholera, dysentery, typhoid, hepatitis and E.coli are all attributed to exposure to waterborne pathogens. The gastroenteritis is declining since., 1991 due to improved water supply as indicated in the figure below: S- I.IJ1I1Y* of- M*, Dlpf opahr 0 Wadr Wa*r/Mpu. xhdd Source: Institute of Preventive Medicine, Hyderabad Figure 3.12: Gastroenteritis cases in Andhra Pradesh from The below table shows the trend in diarrhea incidences in the state from Even though the overall numbers indicate a decreasing trend in the cases, the numbers are increasing in the districts of Ananthapur, Kurnool, Mahaboobnagar, Visakhapatnam, Ranga Reddy, Hyderabad, Srikakulam, East and West Godavari. 25 Andhra Pradesh Human Development Report, Samaj Vikas (!mt.od~ <aina1c ~ki~~.orr!) 64

65 Table 3-9: Diarrhea incidence in Andhra Pradesh from 1998 to 2002, 20 )Visakhapatin/ ( C: Cases; D: Deaths Source: Institute of Preventive Medicine, Hyderabad The below table shows the trend in gastroenteritis incidences for the same period. There is a declining trend in all the districts in the state. Table 3-10: Gastroenteritis incidence in Andhra Pradesh from 1998 to 2002 Samaj Vikas (~~n.l>.g!. s+!!l~rj y~!k;~.;.org) 65

66 > > - Andhra Pradesh Rural Water Supply and Sanitation Project I I I I I I I I I I I I C: Cases; D: Deaths Source: Institute of Preventive Medicine, Hyderabad (2003) Implications for EMF l~he EMF integrates measures to monitor adequate continuous disinfection of water supply to 1 lprevent the disease prevalence, (for example, moditoring of residual chlorine). 3.4 House Hold and Environmental Sanitation Access to sanitation facilities is low in Andhra Pradesh. Nearly 67% of the households in the state do not have latrines within the house. Of the households which have sanitation facilities, only 18% have water closet facilities while 8.5% of the households use pit latrines and 6.32% use other types of latrines. While among the urban households only about 22% do not have latrines in their houses, it is as high as 82% among rural households. The situation is slightly better in a few of the coastal districts like Knshna, East Godavari and West Godavari - however, even in these districts, about 70% of the households do not have latrines. Among other districts, the coverage is better in Ranga Reddy and Krishna districts where only 12 and 14% of the households do not have sanitation facilities. But in districts like Vizianagaram, Adilabad and Srikakulam, the percentage of households without any sanitation facility is as high as 40%. Across regions, Rayalseema has the maximum number of households without latrines in both urban and rural areas. The provision of drainage facilities in the state is also very inadequate. Nearly half the households in the state do not have any drainage facilities. Around 38% of the households with drainage are connected to open drains26. - Implications for EMF The EMF supports a focused and appropriate IEC campaign on personal, household and community and behaviour change communication for achieving the intended outcomes Status of Toilet Construction Traditionally sanitation in rural India relied heavily on high levels of subsidies for latrine construction. In Andhra Pradesh between 2001 and 2008 around lakh Individual 26 Andhra Pradesh Human Development Report, Samaj Vikas (in tb(~i.samai\.;~l;~~.c,rg)

67 House Hold Latrines (IHHLs) have been built. Out of which lakh built as IHHLs, 66,096 as school toilets in schools and 3149 toilets in Balwadis. But only about 50% of them are in use. The details of types of sanitation facilities provided for the households are furnished in the figure below. Focus on 'Triggering' behavior change for the collective, and not simply for individuals is necessary. Details of toilets constructed in the last five years, district wise are furnished in the table below: Households with Sanitation Facilities (2001) 8.55% Pit latrine Water Closets Other Latrines, 0 No Latrines Figure 3.13 :Types of sanitation facilities provided for the households Table 3-11: District wise number of latrines constructed in AP between 2004 and 2008 Total School Balwadi IHHL Toilets Toilets Total S. No District Adilabad Anantapur Chittoor Cuddapah East Godavari Guntur Karimnagar Khammam Krishna Kurnool Mahbubnagar Medak Nalgonda Nellore I 15 Nizamabad Prakasam i Samaj Vikas ( ~ > J ~. ~ & ~ ~ n i ~ l ~, ~ ~ t ~ ~ ~ ( ~ ~ ~ ) 67 -

68 , Rangareddi Srikakulam Visakhapatnam Vizianagaram Warangal West Godavari Total ,93, , , ,34,662 Samaj Vikas (i tifo<~is;111~;g\-s.~~~g) 68

69 Environmental Analysis - Final Report -November Environmental Analysis 4. Environment Management Framework This chapter presents an overview of the key environmental issues related to the proposed APRWSS project and the Environment Management Framework (EMF). An analysis of the baseline environmental situation, observations during site visits, discussions with state, district and village level functionaries as well as the public consultations have clearly brought out the following key environmental issues that need to be addressed in the project design and implementation. While this report deals with the environmental issues related to APRWSSP, the social issues related to the project are dealt with by the Social Assessment (identifies all social issues related to the project), Resettlement Policy Framework (deals with land and displacement issues) and Tribal Development Plan (deals with the tribal groups affected by the project) by a separate study. 4.2 Key Environmental Issues Water Availability Groundwater has been the major source of water for drinking, irrigation and industrial uses in Andhra Pradesh. Owing to large-scale extraction of groundwater for irrigation, combined with increasing demands in other sectors due to population and industrial growth, the aquifers are under stress. Some of the sources have become either unsustainable or contaminated (in coastal areas). For a large number of rural households which are dependent on handpumps or tubewells, the declining and fluctuating groundwater levels are adversely affecting the water supply. About 75% of RWSS schemes in Andhra Pradesh are based on groundwater supply. There are complaints from the community that some of these sources go dry during summer season (dry period). The remaining 25% of the water supply schemes in Andhra Pradesh are based on river1 canal water supply, and in some cases the water supply is adversely affected during the periods of river1 canal nonflowl maintenance shutdown. Estimation of additional water requirement The APRWSS project will involve augmentation, rehabilitation and implementation of single village schemes (SVS) and multivillage schemes (MVS), in about 1,878 NC, 199 NSS and 766 PC habitations as well as augmentation of water supply schemes of 1,389 SVSs and 754 MVSs. The project is expected to benefit a total population of about 22 million (about 40% of the state's rural population)27. Accordingly the additional estimated water requirement for this project is as under: Table 4-1: Additional Water Requirement Particulars Unit Population to be covered Lakhs Average increased water supply Lpcd Quantity APRWSS PIP, 2008 Samaj Vikas (in <C?T~~IT~~U\&.~~~~LI~~) 69

70 MCMI year ( Compared to the estimated yield of the groundwater aquifers of 32,203 MCM, this additional withdrawal from groundwater resource is only about 1%. The sustainability of the groundwater aquifer is, therefore, depending on the extraction for irrigation. Since drinking water supply is the first priority as per the National Water Policy and also as per the provisions in APWALTA Act the required water extraction for the project is not a problem. Environmental Issues Inadequate andlor disrupted water supply affects human health and environmental sanitation. In coastal area tapping the overexploited aquifers will result in saline water intrusion and the groundwater becoming saline. It is an irreversible process. In upland hardrock areas further tapping of overexploited areas may cause quality deterioration with increased concentration of harmful substances like fluoride. Overextraction of groundwater for irrigation may lead to drying up of drihng water wells. Measures to Augment Water Supplies Augmentation of existing water supplies could be achieved through one or more of the following options. Augmentation through rehabilitation/ upgrading of existing water supply schemes should be a priority wherever feasible. The existing resources should be conserved and the availability augmented by maximizing retention, eliminating pollution and minimizing losses. For this, measures like rehabilitation of existing tanks for storing rainwater and augmenting groundwater recharge, recycling and reuse of treated effluents for nonpotable uses are to be implemented. In case where water supply from river1 canal based schemes is unreliable during the canal shutdown periods, the schemes should be designed either with enhanced storage commensurate with the shutdown periods, or with other sources which may be more distant but more reliable. Distant surface sources could be tapped to augment water supply with simple treatment (Slow Sand Filters or conventional Rapid Sand Filters), chlorination or appropriate blending of ground water and treated canal water to obtain a drinking water of desired quality standards. In cases where the drinking water supply source involves extraction from a critical or overexploited aquifer the emphasis must be on water conversation (including ground water recharge and rainwater harvesting). In the long term, regulation of extractions from the groundwater aquifers for irrigation needs to be ensured (by efficient implementation of the APWALT Act). Efficiency of use of water should be promoted through education, regulation, incentives and disincentives Water Quality Surface Water Quality Samaj Vikas (hfo<~~.sp!n+g~kas,~~.r~) 70

71 Environmental Analysis - Final ~ e~ort - November 2008 The major canal networks of Andhra Pradesh are kept relatively free of industrial or municipal discharges, and the irrigation drainage flows are also seldom routed into the canal system. The water quality in the main canals is therefore generally better than the river courses, except in the upper reaches of rivers where the pollutant load is minimal. The quality problems with respect to surface water sources are more acute in the locations and during the periods when the flow in the river is not sufficient to cause acceptable dilution of the discharged effluents. Environmental Issues 1. Non point sources of pollution in the catchment areas due to the widely prevalent practice of open defecation, and agricultural run off containing fertilizers and pesticides, washing, bathing and other human activities in rivers/ irrigation canals serving as water supply sources 2. Discharge of inadequately treated municipal and industrial wastes in receiving water bodies or on land 3. Inefficient and irregular disinfection of drinking water supplies 4. Breakage1 leakage in rising main, distribution lines and valve chambers 5. Improper collection, storage and handling of water at the individual household level Ground Water Quality The shallow groundwater quality in many parts of Andhra Pradesh is poor owing to natural presence of salinity and fluoride at concentrations exceeding the permissible levels for drinking water use. The groundwater quality in coastal area of Andhra Pradesh is poor owing to natural presence of salinity and groundwater quality in uplands with fluoride at concentrations exceeding the permissible levels for drinking water use. In addition, the quality of groundwater may also indicate bacteriological or chemical contamination due to inadequate treatment and disposal of sullage, effluent from septic tanks or industrial discharges. According to RWSS department estimates, about 45% of villages in Andhra Pradesh suffer from poor water quality conditions. Environmental Issues Presence of salinity and fluoride at concentrations exceeding the permissible levels for drinking water use; Bacteriological or chemical contamination due to inadequate treatment and disposal of sullage, effluent from septic tanks or industrial discharges. Operational problems including inefficient and irregular disinfection Mitigation Measures The siting, planning, design, and operation of the schemes should ensure that source selection is conducted with due regard to water quality of the source, and that water quality at household delivery level meets the drinking water norms. More specifically: 1. The selection of source for the water supply should be after thorough investigation of both surface and groundwater sources. The priority of the source for selection should be based on the guidelines provided in Annexure 12. The water quality testing should be done prior to source selection of water supply schemes (refer Samaj Vikas (jl~ti)~i;_a~~~.~&:~~rg) 7 1

72 Annexure 8). Further a sanitary survey need to be taken up in accordance with the guidelines given in Annexure 13. Sanitary protection of water supply sources is prescribed in Annexure 14. Annexure 16 presents guidelines for sustainability of groundwater sources. 2. For fluoride affected villages the strategy should be distant safe groundwater (SVS) or distant surface water (MVS) as detailed in Annexure In case quality of available water is very poor and no distant surface water source is available, advanced treatment options like iron removal units, Reverse Osmosis (RO) plants can be opted. Dual water supply can be adopted, supply of limited quantity of safe, potable water (say Lpcd) from systems which are expensive to build operate and maintain (eg. RO Plant) and continue with existing supplies (rejected by community due to quality problem) for not potable purposes. 4. Effective and regular disinfection, as well as preventive and corrective maintenance of water distribution systems should be ensured. 5. Institutional arrangements should be put in place for preventive and corrective maintenance of water distribution system (leak detection, repair and control) and for preparedness in crisis management during major breakdowns. 6. Water supply sources need to be protected as per the guidelines given in Annexure A protocol for regular water quality testing and control (refer Annexure 8) has been developed by RWSSD, which will be implemented through the operations phase of the water supply schemes. Water quality testing for industrial and agricultural chemical contaminants shall be conducted by the RWSSD, in a phased manner based on an initial sampling of groundwater and river/ canal waters in all districts of the state before taking up subprojects in that area. This cost will be included in the project preparation cost Environmental Sanitation The present level of sanitation coverage in the rural areas of the state is only 53%. Only about half of the rural households with latrines are using them regularly. This implies that still nearly 75% of rural population resorts to open field defecation with its associated risk to water supply sources and public health. Open defecation constitutes a major nonpoint source of pollution of surface and ground waters. This problem is more acute in densely populated settlements, especially in coastal areas. Poor environmental sanitation conditions and lack of adequate supply of safe water are factors responsible for high incidence of water borne1 water related diseases among the rural population. Environmental Issues 1. Rampant open field defecation due to inadequate latrines, low usage of latrines and low levels of awareness. 2. Wastewater generated by the households, including the wastewater from cattle sheds, flows into open surface drains leading to stagnation in the lanes and bylanes. Instances have been reported of effluent overflowing from the septic tanks and finding its way to the village drains. 3. Without adequate arrangements for treatment and disposal, the wastewater often seeps into hand pumps, open dug wells and pipelines, and the village ponds leading to contamination of aquifers and loss of productive uses. Samaj Vikas (1.n fi)((i'sarnai\:~k:~.:. yrg) 72

73 4. The presence of stagnant water in the villages combined with poor personal hygiene leads to the incidence of malaria and other vector borne diseases, diahorreal diseases, etc. 5. Solid wastes of decomposable and nondecomposable natue are collected together and disposed by mere dumping along streets and public places leading to stinking and vector breeding. Mitigation Measures 1. Construction of latrines and awareness creation for increased usage. Selection of safe sanitation technologies and environmental considerations in location of toilets is given in Annexure 17. Annexure 18 presents recommended construction practices and pollution safeguards for Twin Pit Pour Flush Latrines. 2. Efficient design of surface sullage drains and adoption of good construction practices, along with a system of regular maintenance can ensure that stagnant pools of sullage are eliminated. Guidelines for safe sullage disposal at household and community levels is given in Annexure Installation of small bore sewer systems for conveyance of sewage can eliminate environmental and public health hazards associated with open drain system. Suitable consultants will be commissioned to do the required studies, preparation of detailed project reports and for construction supervision for these schemes. Costs of these consultancies will be borne under the project preparation and management costs. 4. Adopting the recommended practice of laying water and sullage lines on different sides of the road reduces the risk of cross contamination. 5. Existing ponds can be remodelled to accommodate increased sullage flow. 6. Adequate treatment and gainful utilization of the treated effluentl sullage is possible in agriculture, aquaculture and agro forestry. The treatment system could be any of the following: Stabilization ponds, Duckweed ponds, Constructed wetlands, etc. Suitable consultants will be commissioned to do the required studies, preparation of detailed project reports and for construction supervision for these schemes. Costs of these consultancies will be borne under the project preparation and management costs. 7. Vector control measures should be provided to the ponds and drains carrying sullage by way of avoiding stagnation and spraying with nonhazardous insecticides in accordance with OP The project will need to ensure that the benefits of improved water supply are not compromised by poor personal hygiene standards, by supporting sustained IEC campaign to create and enhance awareness on hygiene aspects pertaining to hand washing, safe water collection, storage and handling practices. 9. Solid waste management including segregation of wastes at source, collection at door step, recycling of nondegradable wastes, composting of biodegradable wastes, safe disposal of hazardous wastes, demarcated land fill sites, etc. Guidelines for community solid waste management are given in Annexure Construction Stage Environmental Impacts During the implementation phase of the project, there is a likelihood that the construction activities cause temporary negative environmental impacts, which would need to be addressed. Some of the likely issues are the following: Sarnaj Vikas (~nto;\,lnl,~l\ ~h,l>org) 73

74 Environmental Analysis - Final Report -November 2008 During the construction of components of water supply schemes, underground drainage, drains and sanitation facilities, significant earth work may be involved, which may cause erosion of land and cutting of trees. Possible damage to places of cultural, heritage and recreational importance. Impact on human health and safety due to dust and noise pollution, and inadequate safety measures. The safety provisions (Building) convention 1937 (No. 62) is given at the end of annexures uinder Annexure 28. Mitigation Measures All project interventions will be appropriately designed to ensure that they do not impact the forest lands or wet lands. All the physical works should be on public/ Panchayat lands. Suitable changes in location1 alignment shall be made in the schemes to avoid cutting of trees and also avoid erosion and ensure soil stabilization. In the absence of an alternate location, permission from the forest department shall be obtained for felling of trees and the department's guidelines on compensatory afforestation will be followed. In case of some physical works associated with construction and maintenance there might be chance finds of objects of cultural/ archaeological importance. In such cases, the regional offices of the relevant agency (e.g. the Archaeological Survey of India) will be immediately notified. 4.3 Objectives of EMF The proposed Andhra Pradesh Rural Water Supply and Sanitation Project will finance investments in rural water supply and sanitation improvement schemes to serve the rural populations in Andhra Pradesh. The project interventions are, therefore, expected to result in public health benefits in the rural communities, through improved quality and delivery levels of RWSS services. Some of the main environmental health benefits expected under the project include: increased and better quality water supply for drinking, cooking, washing, bathing and cleaning purposes; time and energy savings through providing water supply closer to homes; improvements in personal hygiene and village sanitation levels; and reduced fecal oral contamination of drinking water resulting in lower occurrence of diseases. While the proposed project interventions are expected to result in overall environmental and public health improvements in the state, potential adverse environmental impacts can occur if the schemes are not properly designed, sited, implemented, and maintained. In order to ensure that the environmental issues are systematically identified and addressed in the various stages of the implementation of subprojects, an Environment Management Framework (EMF) has been developed for this project. The specific objectives of the EMF are as under: To provide a systematic approach for identifying the various possible environmental impacts at the different stages of the scheme cycle. To identify appropriate mitigation measures for addressing the identified environmental impacts. To devise an institutional arrangement for mainstreaming environmental management in project implementation processes. Sarnaj Vikas (ill t~~~~~~~~~>j.i.r:!s:rj~~) 74

75 4.4 Environmental Management Frame Work Key Elements of the EMF The key elements of the EMF as applied to a project sponsored scheme are discussed below: 1. Collection of Basic Environmental Data: The EMF requires that basic environmental data pertaining to the proposed scheme be compiled at the field data collection stage. For this purpose, a simple Environmental Data Sheet (EDS) has been formulated for schemes on water supply, sanitation, solid and liquid waste management, etc. The formats for the EDSs for different types of schemes are furnished in Annexure 21. The AEEI EE of the RWSSD fills up the EDS in consultation with the GPWSC and with the facilitation support of the NGOI SO. 2. Environmental Classification of Schemes: At the Detailed Scheme Report (DSR) preparation stage, the available environmental information in the EDS will be evaluated and based on the level of expected environmental and public health impacts, the proposed scheme would be classified as either Category I (basic) or Category I1 (detailed environmental appraisal required). The EDS formats are given in Annexure 21. The screening tool for the categorization of schemes is furnished in Annexure 22. The environmental classification of schemes by using the screening tool is done by the EE of the RWSSD. 3. Environmental Appraisal and Approval: For all category I schemes, there shall be no separate environment appraisal other than filling up of EDS included in the DSR. For category I1 schemes, a detailed environmental appraisal of the proposed scheme is required. This will be done by the district level environmental expert attached to DPSU. In extreme cases, where the district level resources are not sufficient for conducting the environmental appraisal and designing the appropriate mitigation measures, support from the environmental experts of state level PSU may be requested. The environmental appraisal for category I1 schemes shall not take more than 30 days. The Detailed Scheme Report (DSR) for Category I schemes should be accompanied by the Environmental Data Sheet (EDS). The EE of the RWSSD will ensure this. The Detailed Scheme Report (DSR) for Category I1 schemes should be accompanied by the Environmental Data Sheet (EDS) as well as the Category I1 environmental appraisal. The EE of the RWSSD will ensure this. 4. Environmental Compliance Monitoring during Implementation and O&M phases: The EMF will ensure that: 1. The prescribed environmental mitigation measures (including construction stage measures) as identified through the environmental appraisal process are adequately implemented. The Implementation Completion Report of each scheme will include an Environmental Compliance Certificate given by the GPWSC for SVS and MWSC for MVS indicating that the mitigation measures identified in the appraisal have been implemented. Samaj Vikas ( i~~fo~~~s:i~r~yi,~:~s.or~) 75

76 Environmental Analysis - Final Report -November Periodic supervision and monitoring including an independent external audit is conducted, as a part of the overall project monitoring program (see section for details). 3. Capacity building and IEC activities are undertaken to enable effective implementation of the EMF including assessment procedures, supervision, monitoring, etc. as well as for community awareness and sensitization on personal hygiene, environmental sanitation, water conservation, etc Application of EMF to Project In order to mainstream environmental management and to ensure that the EMF is systematically implemented for all the project sponsored schemes, the EMF needs to be integrated in the scheme cycle. The below table provides an overview of various EMF activities in the preplanning, planning, implementation and O&M phases of the proposed scheme cycle for the project sponsored schemes. The responsibilities are indicated in the table, against the respective tasks. Table 4-2: Phase PreplanningPla nning L Environmental EMF Activity Environmental Data Sheet Environmental classification of the scheme Environmental appraisal and approval required Management Objectives To collect basic information on environmental aspect of the proposed scheme. To ensure that schemes with potentially significant environmental or public health issues are identified at an early stage for detailed environmental appraisal. To ensure that relevant environmental issues have been identified and appropriate mitigation measures have been designed to a~-*+.~~.l Framework Process Discuss scheme with community and identify environmental issues of concern. Complete EDS with supplementary notes if required. Evaluate all the available information on environmental aspects as provided in the Environmental Data Sheet and, assess whether the proposed scheme is Category I or Category 11 by referring to the Screening Tool. For category I schemes, there shall be no separate environmental appraisal but environmental aspects shall be included in the normal appraisal and evaluation process for the proposed scheme, based on the EDS included in the DSR. Responsibility Result NGOsiSOs, EDS prepared with assistance and attached to of AEEIAEI DSR. RWSSD. AEEiAEi RWSSD with assistance from SO and ~ ~ 0 s ~ '. EEIRWSSD with District Level Environmental Expert, DPSU. District level Environmental Expert, DPSU. Scheme classified as Category I or Category I1 using the screening tools. Environmental appraisal of the scheme is made using the Checklist for Environmental Appraisal of Category I1 Schemes and -c 28 If Technical Support is out sourced, then they should be part of EDS filling, classification and appraisal. Sarnaj Vikas ( ~n to&..unx\.!k..q ow) 76

77 For category I1 schemes, a detailed environmental appraisal of the proposed scheme is required, including evaluation of environmental and public health impacts, risk assessment if needed, and design of mitigation measures. Implementation O&M Implementation of Environmental mitigation measures. Environmental supervision, monitoring, and evaluation IEC and capacity building on hygiene and environmental issues. To ensure that mitigation measures and their cost are integrated in scheme design and implementation plans To ensure that the prescribed environmental mitigation measures (including construction stage) are implemented. To ensure that environmental aspects are integrated in the O&M phase. Technical Sanction for the scheme will not be accorded without Environmental Clearance from PSU Implementation Completion Report (ICR) for scheme will need to include compliance certificate that all prescribed environmental mitigation measures (including construction stage) have been 1 implemented. Water quality monitoring will be conducted as per project water quality monitoring protocol. Internal supervision will be conducted for 20% of the schemes completed once in a year. All UGDI Sewerage schemes will be supervised twice a year. Monitoring of external environmental parameters relevant to the project will be conducted once in a year. Environmental Audit through external agency will be conducted once in a year by selecting about 10% of schemes completed IEC on (i) need for drainage improvementi sullage treatment in villages, (ii) personal and public hygiene, and (iii) need for water conservation. EE for Category I schemes. Category I1 schemes (upto 10 lakhs EE, upto 50 lakhs SE and above 50 lakhs CE) GPWSC for SVSs. MWSC for MVSs. State Level Environmental Expert supported by District Level Environmental Experts. State Level Environmental Expert (SPSU) with assistance from State Level Technical Expert (SPSU). Technical Sanction for scheme with environmental mitigation measures and accordingly its costs are integrated in scheme design and implementation plans. ICR with environmental compliance information. Water quality monitoring reports. Periodic environmental supervision, monitoring and audit reports. Training and IEC activity reports Environmental Supervision and Monitoring The EMF requires detailed supervision, monitoring and evaluation of the impact of the project on the environment. This includes: Samaj V~kas (I I I ~ I ~ \.LITI~IJ! I h:l>.org) 77

78 Environmental Analvsis - Final Re~ort -November Environmental supervision: A sample of 10% of the completed schemes will be visited at six monthly intervals by a team from the DWSC (including the District Resource Persons - Environmental Management) to check if all safeguard requirements are met and to identify any issues that need to be addressed. The selected sample will have representation of both Category I and Category I1 schemes in water supply, sanitation and waste management. All Under Ground Drainage schemes will be selected for supervision. Annexure 23 gives details of the sampling procedure for the supervision and Annexure 26 gives the format of the supervision report. However, internal environmental monitoring will be done as part of the regular monitoring by the RWSS Department Monitoring of relevant external environmental parameters: Once every year, the state Project Support Unit (PSU) will prepare a report of the environmental situation in the state including data and analysis of relevant parameters such as rainfall, depth to water levels, status of groundwater basins, incidence of water borne diseases, etc., as well as a listing of relevant new legislation and regulations that have a bearing on the environmental performance of the project. The EMF will be suitably revised annually on the basis of this document by the PSU Environmental audit: Once every year, the SPSU will appoint an external agency to undertake an independent audit of the environmental performance of the project. 5% of the completed schemes will be covered in the audit having representation of both Category I and Category I1 schemes in water supply, sanitation and waste management. All Under Ground Drainage schemes will be selected for audit. The Annexure 24 presents details of sampling and the Annexure 27 gives a list of performance indicators to be used in these audits. 4.5 Institutional Arrangements Village Level GPWSC and SOs GPWSC is a local level institution set up as a subcommittee of the Gram Panchayat which is expected to shoulder full responsibilities for all activities related to RWSS at the village level. They will be supported by (non government) Support Organizations (SOs), selected for a cluster of villages within a particular geographical boundary. SOs will primarily be responsible for providing community development and external liaison support to the GPWSCs on a day to day basis. The responsibility of facilitating planning and implementation of EMF activities at the village level is vested with the GPWSC and SOs. One SO is expected to service GPs. The TOR for the SO would include specific responsibilities pertaining to the EMF including facilitation of the GPWSC's participation in filling up the EDS, in certifying the implementation of the environmental mitigation measures, in identifying and meeting capacity building needs, etc. The AEEI AE, RWSSD will support the GPWSC and SOs in the execution of these functions. The project will develop capacities of both GPWSC and SO through training and other information sharing measures to execute these functions effectively.. Scheme Level Committee (SLC) for MVSs - - Samaj Vikas (~ntiqfi$y~uaj viki~s.o~g) 7 8

79 Environmental Analysis - Final Reuort - November 2008 Keeping in view the complexity of MVSs, the decisions regarding environmental appraisal, implementation of mitigation measures, supervision will be jointly taken up by the ZP or MP and RWSS department in consultation with the SLC. SLC will have one member from each of GPWSCs related to GPs of the MVSs. The EE, RWSSD will be the chair person of the SLC Mandal Level At the Mandal level the Mandal Water and Sanitation Committee (MWSC) will facilitate IEC and capacity building activities to the GPs and GPWSCs. The MWSC will do the scrutiny of the schemes, including EDS, submitted by the GP and then forward them to DWSC. MWSC will also cooperate with the SOs for social mobilization, capacity development, communication, project management and supervision. MWSC will also sensitize public representatives, officials and general public about the project principles. MWSC will provide guidance and support to institutions for imparting training for capacity development of all stakeholders, and undertaking communication campaign. Mandal Water & Sanitation Committee (MWSC) will be headed by a Deputy Executive Engineer (DEE). The DEE will be responsible for ensuring the EMF implementation at Mandal level. One of the resource persons, appointed by the DWSC, would be trained in Environmental management and would assist the MWSC in discharging the mandated duties and functions relevant to the EMF at Mandal level Disrtict Level Similar arrangements are envisaged in DWSMs through District Water and Sanitation Committee (DWSC) to ensure all RWSS plans follow and are in conformity with the EMF, and to ensure proper planning and monitoring of EMF activities at the district level, and coordination between the District and SWSM. The SE will be responsible for ensuring EMF implementation within the district. He will also select the external experts for appraisal of Category I1 schemes, if required. There will be a District Support Unit at the district level under the control of the SE. This DSU will be responsible for implementation of the environmental management activities in accordance with the EMF at the district level. The DSU will have a District Level Environmental Expert in the unit. The DSU will have number of District Resource Persons (DRPs) in the cadre of Executive Engineer (EE) and one of the DFWs will be trained in environmental management (EM) State Level At the State level the EC committee prepares the environment policy and sets the guidelines for the EMF implementation, monitoring and evaluation. This committee also liaises with other departments with regard to environmental issues. The Project Director, SWSM will be responsible for ensuring the implementation of the EMF across the state. One State Level Environmental Expert in the state PSU will ensure that environmental management activities are in conformity with the EMF and that necessary guidance and budget is provided to implement these plans. Samaj Vikas ( ~to?~ qan~'~ I L,I> o~ g) 79

80 The following table depicts the role and responsibilities of the major players in implementing the EMF. Table 4- Level State District : Institutional Institution State water Sanitation Mission (SWSM)/ PSU District Water and Sanitation Mission (DWSM)/ DWSC DPSU irrangement for Implementation of the EMF Function Ensure overall implementation of the EMF in the project. Arrange funds required for implementing the provisions of EMF. Ensure availability of required human resources for implementation of EMF. Ensure that recommendations from supervision and monitoring are integrated into the project and the EMF is updated periodically as necessary. Recruit external experts for conducting Environmental Audit once in a year and ensure that the relevant recommendations are integrated into the project. Conduct environmental supervision of all Under Ground Drainage/ Sewerage schemes on a half yearly basis. Training and Capacity Building of SOs, GPWSC, Mandal Resource Persons - Environmental Management (MRP-EM) and District Resource Person - Environmental Management (DRP-EM)on EMF. Coordination between various players and actors involved in EMF. Coordinate with other line departments on environment related issues; in particular with State Ground Water Directorate for water level monitoring. Day-to-day management, responsible for undertaking all activities necessary for implementation of the EMF. Cany out regular monitoring and supervision of the EMF implementation hrough appropriate mechanisms (and report the same to SWSM and DWSM as necessary). Supervising the accuracy of the environmental appraisal conducted by AEEJAE, RWSSD as part of the scrutiny of the schemes - including checking if the screening is accurate, if the Environmental Data Sheet has been filled in as required etc. Evaluation of EDS and categorize the scheme into one of the categories I & 11. Conduct Category 11 environmental appraisal using the Detailed Appraisal Sheet, if required or in cases where external technical support is required for conducting Category I1 appraisal - forwarding to the SE for decision on selection of suitable expert for conducting detailed appraisal for category I1 schemes and preparation of Detailed Appraisal Sheet (DAS) to identify the environmental impacts and designing mitigation measures. The mitigation measures are included in Environmental Management Plan (EMP) to be implemented along with various components of the scheme. Conduct supervision visits to 20% of the completed schemes twice in the year (in coordination with the PSU). Provide technical advice and guidance on environmental management to SO, GPs & GPWSCs. Provide inputs to DWSC on relevant environmental policies. Ensure capacity building of all stakeholders in environmental management. Design and implement IEC campaigns on environmental management. Maintain a database consisting of relevant baseline environmental information of the district, environmental appraisal of the various ongoing and completed schemes, findings of supervision, etc. Coordinate with institutions, agencies and individuals relating to environmental management including the regional offices of the APPCB, Forest Department, etc. Collect, collate and publish data and information on EMF implementation in the Res onsibili supported by the State Level Environmental Expert supported by District Level Environmental SE, DWSM, District Level Environment Expert, DPSU, DRP-EM Mandal Mandal Water 1 and Sanitation Committee ~nvironmesal management and monitoring of sector projects at the Mandal level. As part of the scrutiny of the schemes submitted by the GP- will check if environmental screening and appraisal has been properly done before forwarding them to the DWSC. Coordination with NGOs for ensuring integration of EMF in all relevant project activities including capacity development, communication, project management and su~ervision. Sensitizing the public representatives, officials and the general public about the provisions of the EMF. Chairman, MWSM, DEE, RWSSD Samaj Vikas (~fo~~sg!n~y\.:~.~a.;.~) 80

81 Level Village Institution GP Water and Sanitation Committee (GPWSC) with the support of Support Organization (so) Support Organization (so) Scheme Level Committee (SLC) Function Participation in preparation of Environmental Data Sheet (EDS) to be enclosed to Detailed Scheme Report (DSR). The committee shall deliberate on environmental safeguards relevant to the schemes and adopt the same during construction and implementation Certifying the implementation of environmental mitigation measures as part of the implementation completion report. Facilitate IEC activities regarding water conservation, sanitation and hygiene among the villagers. Provide support to the AEEIAE RWSSD in preparing the EDS. Facilitating participation of the community in preparation of EDS as part of the DSR preparation and in certification process (for environmental mitigation measures) for implementation completion report. Liaison with forest department, APPCB, and other related departments at scheme level for ensuring implementation of identified mitigation measures (permissions, technical support, etc.). Provide support in execution of the IEC activities on EMF. Provide support to the RWSSD in the supervision, monitoring and audit activities of the EMF. Train the GPWSCI MWSC in conforming to EMF requirements in operation and maintenance of Under Ground Drainage1 Sewerage schemes. Participation in EDS preparation of MVS. Participation in certification process for implementation of environmental mitigation measures as part of implementation completion report. To make efforts for spreading awareness regarding sanitation and hygiene among the member villages of the MVSs. Responsibility President, GPWSC, so, AEEI AE, RWSSD Directors of SO President, GPWSC, so, AEE/ AE, RWSSD Performance Indicators A list of environmental performance indicators which have been integrated with the overall project indicators for monitoring and evaluation of the project performance are given in Annexure Training and Capacity Building The state currently has limited capacity for environmental management. The capacity building and IEC strategy has been outlined as part of the EMF program developed for the project aims at building environmental awareness and environmental management capacity in the project administration structure as well as in the intended target communities. Capacity building for environmental management will be integrated with overall capacity building component of the project Objectives The objectives of the capacity building initiatives are: To build and strengthen the capability of rural water and sanitation service delivery institutions (PRIs and RWSSD) and other partners (NGOs, Contractors, Consultants) to integrate sound environmental management into water and sanitation service delivery. To orient the service delivery staff and elected PRI representatives to the requirements of the project's environmental management framework Approach Systematic capacity building initiatives will be introduced only after completion of training needs assessment. The training will be of cascade mode. All the trained staff and others will in Samaj Vikas (i11fo:ci~s;1r11:1iviki1s,~y:g) 8 1

82 turn conduct further trainings at state, district, mandal and village levels. However, since capacity building goes beyond mere imparting training, institutionalization of best practices becomes a prerequisite for improved service delivery Institutions for Training In view of the specialized training and capacity building envisaged under the EMF of the project, it is necessary to identify nodal training institutes that will work closely work with capacity building wing of PSU for conceptualizing, designing, conducting and managing training programs on the EMF. Some such specialized institutions are: Academy of Rural Development (AMR- APARD) National Institute of Rural Development (NIRD) Engineering Staff College of India (ESCI) National Academy of Construction (NAC) Details of Training Programmes TI. Training on the Environmental Management Framework Purpose of the training: To equip with knowledge and skills necessary for undertaking environmental appraisal as per the requirements of the EMF To prepare for undertaking periodic supervision of environmental performance of schemes To prepare for implementing Community Based System for Water Quality Monitoring and Surveillance Participants: Key officials of the project including AEEIAE, EE, SE as well as State and District Level Environmental Experts and District Resource Persons - Environmental Management. The Superintending Engineer of the district will be responsible for selection of suitable candidates for the training, and the expense will be borne by the overall project capacity building budget. Schedule: The training will include an initial orientation workshop, a main and annual refresher training workshops on environmental assessment. The main and refresher training programs will be for duration of 2-3 days each, whereas the initial orientation workshop will be of one day duration. 10 Training programs will be conduced during the first year and 5 refresher programs per year will be conducted for the next 4 years. This will total to 30 programs. T2. Training on Environmental Management Purpose of the training: To equip with knowledge and skills necessary for meaningful participation in the environmental appraisal as per the requirements of the EMF To prepare for planning and monitoring implementation of environmental mitigation measures identified through the appraisal process Samaj Vikas (&lfi,?>.i~nl:t i\.~ ka?.~[?rg) 82

83 To equip with skills necessary for water quality testing using the field kits under the Community Based System for Water Quality Monitoring and Surveillance Participants: SOs, members of GPWSC and Mandal Resource Persons - Environmental Management. The Superintending Engineer of the district will be responsible for selection of suitable candidates for the training, and the expense will be borne by the overall project capacity building budget. Schedule: The training will include an initial orientation workshop, a main and annual refresher training workshops on environmental assessment. The main and refresher training programs will be for duration of 2-3 days each, whereas the initial orientation workshop will be of one day duration. There will be about 2,843 GPWSCs, about 284 SOs and about 100 Mandal resource persons totaling to about 3,200. At about 50 per batch there will be about 64 training programs. Considering that an equal number of refresher trainings will be conducted, the total T2 training programs will be about 120 for the project duration. T3. Environmental Awareness and Sensitization Purpose of the training: To build awareness on safe drinking water, water conservation, environmental sanitation and personal hygiene. Participants: AEEsI AEs, SOs, Members of GPWSC and NGOs. Schedule: The training will involve one day workshops at the mandal level. There will also be one day refresher workshops organized annually. There will be about 2,843 GPWSCs, about 284 SOs and about 100 resource persons totaling to about 3,200. At about 50 per batch there will be about 60 training programs. Considering that an equal number of refresher trainings will be conducted, the total T3 training programs will be about 120 for the project duration. T4. Quality Construction Practices for Artisans Purpose: To equip with knowledge and skills for quality construction and maintenance of water and sanitation structures (including aspects of environmental conservation, human health and safety, etc.) Participants: Masons, mechanics, electricians, plumbers etc., and for the contractors' workforce involved in the project. Schedule: The training will involve one day workshops at the mandal level. There will also be one day refresher workshops organized annually. There will be about 2,843 artisans at one per GPWSCs and about 200 resource persons totaling to about 3,000. At about 50 per batch there will be about 60 training programs. Considering that an equal number of refresher trainings will be conducted, the total T4 training programs will be about 120 for the project duration. The number of suggested training programs is presented in table below: Samaj Vikas (~!~fg~f&~gq~;~y~k_;~+,~?rg) 83

84 Environmental Analysis - Final Revort - November 2008 Table 4-4: Number of Training Programs (. No. Topics I Number of Trainings About 40 to 50 trainees would participate in each of the training programs. It is intended that these trained persons will in turn provide on site training to RWSSD staff, SOs, GPWSCs, NGOs, Contractor staff, etc. onsite at village level Budget T 1 Environmental Management Framework T2 - Environmental Management T3 - Environmental Awareness and Sensitization T4 - Quality Construction Practices for Artisans Total The total estimated cost of training on environmental management for members of GPWSCs, NGOsI SOs, Engineers of RWSSD, and artisans, under the proposed APRWSSP is presented in the table below: Table 4-5: Estimated cost of Training S. No. Training T 1 T2 T3 and T ,00,000 1 o,oo,ooo 50,000 60,00,000 20,000 48,00,000 5 Workshops (District) Total 25 20,000 5,00,000 1,25,50,000, The total budget for environmental management activities under the proposed APRWSS project has been worked out as Rs crore. The detailed break up of the budget is presented in the table below. Table 4-6: Budget for Environmental Management 1 S No. I Activity I Amount in Rs. ] IT I 5 6 Training and workshops (as estimated) 1,25,50,000 Internal supervision visits Environmental Audit by the external agency once in a year (5 Rs lakhs per year Preparation of specific environment related community awareness 1 2 lakh per district and 6 lakh at state level EA for Category 2 10 lakhs per year for 5 years External -- Environmental Rs. 2.0 lakhs per year for 5 yearsly Sub Total 10% Total 50,00,000 10,00,000 3,85,50,000 38,50,000 4,23,50, Includes remuneration to MRPs, DRPs and other resource persons. Samaj Vikas (i11fo:(i~s~l1l1ilkiki1>~&1a) 84

85 4.7 Guidelines 1 Environmental Code of Practices Guidelines1 Environmental Code of Practices (ECOP) have been prepared for addressing the following environmental issues and are furnished in the Annexures as indicated. 1. Guidelines for Identification and Selection of water supply sources: The criteria for the selection of source for water supply are specified in Annexure Guidelines for Sanitary survey of water supply sources: Periodic survey of the source is necessary to identify if any new pollution sources are emerging. The guidelines for groundwater surface water sources are detailed in Annexure ECOP for sanitary protection of water supply sources: The well to tap groundwater sources and intake arrangements to tap surface water sources are located at certain distance away from the pollution existing sources and the structures are protected with certain measures to protect the quality of water from getting contaminated. The detailed guidelines are furnished in Annexure Differential Pressure Bleach Powder Solution Dosing Equipment: The disinfection is an important treatment of both surface and ground water to ensure safe water supply. A simple disinfection method with bleaching powder applicable to small water supplies is sufficient. 5. Guidelines for Sustainability of Sources: The yield from the sources in. general and ground water source in particular is likely to decrease during summer. In order to ensure sustainable yield throughout the year certain measures such as artificial recharge of the groundwater source with rainwater harvesting structures are necessary. These measures are furnished in Annexure Water Quality Monitoring and Surveillance: The water quality of the sources and in the distribution system is deteriorating due to contamination especially after rains in surface water sources and in summer months in groundwater sources. Water quality monitoring should be undertaken periodically in order to take corrective measures if the quality changes. The procedure and protocol for water quality monitoring and surveillance are described in Annexure Selection and installation of safe sanitation technologies; the checklist for choice of technology and selection of location is furnished in Annexure Recommended Construction Practice and Pollution Safeguards for Twin Pit Pour Flush toilets: Twin Pit Pour Flush Latrines (TPPFL) are the most commonly adopted sanitation technology which is suitable in most of the environmental conditions except coastal areas with high groundwater table. Recommended construction practice and Pollution Safeguards for TPPFTs are described in Annexure A format for attachment to the contracts of contractors/ consultants is given in Annexure 29. This format need to be filled for each contract package and signed by the respective contractor/ consultant for conforming to the EMF and implementing the measures suggested under the EMF. Samaj Vi kas (~inti~:~~_;!!naj~:i k~1.s.iwz) 85

86 ANNEXURES Samaj Vikas (i~lfi)~rr,sani:~j\:ik~~~;.-o!.g) 8 6

87 Annexure 1 Terms of Reference for Environmental Analysis 1. Background 1. The main objectives for the proposed APRWSS Project are: o To improve the quality and quantity of rural water supply including environmental sanitation, service delivery, house hold sanitation and hygiene, o To achieve sustainability of investments and generate health and hygiene and income benefits in the rural Andhra Pradesh. o To assist the state in creating an enabling environment statewide for implementation of appropriate sector policy and institutional reforms; and, o To demonstrate sustainable modalities of delivering water supply in Single Village Schemes (SVSs) and Multi Village Schemes (MVSs). 2. The Project's geographical scope will aim at scaling up of the Swajaladhara concept and will include all the districts and besides Single village water supply schemes the Project will also study the scopes of Multi Village Schemes. The APPRED will be the nodal agency. The SWSMIPSU will be responsible for project planning and implementation. The DWSMPSU will be responsible for management of project implementation in the districts. The Gram Panchayats will be the responsible entity for undertaking planning and construction of the schemes and other community empowerment activities. The institutional arrangements of PRIs and RWSS sector may undergo changes and need to be taken into account, before finalization of the study report. 3. As a part of the project preparation, the PSU proposes to carry out a detailed environmental analysis of the project and prepare an appropriate environmental management framework and intends to hire a consultant to assist PSU in carrying out this task. 4. Water Quality Management: Chemical contamination mainly due to fluoride and salinity exits in the select pockets in the state. During the last 10 years, the PRED has installed community based Fluoride treatment units, hand pumps attached fluoride removal units and also provided activated alumina based house hold domestic filters. However, except for alumina based household domestic filter, none of these are functional today. While they are few reported cases of pesticide residue in the ground water samples (Ground Water Resources Report, May2005, and GOAP), the spread and the magnitude of the problem is yet to be established. As per Ground Water Department there is a possibility of heavy metal contamination in few industrial pockets of the state which may not be used as drinking water sources.the state has 52 laboratories at the district level which are managed by PRED, generally used field test kits with basic equipment. 5. Source Sustainability: Despite large scale investment in rural water schemes, the source protection and sustainability of these schemes remains a concern.. Past experience in the state suggests that the rural water supply projects are not able to provide the design supply. Source sustainability for these projects primarily relates to the quantity and quality of water supply, proximity to these sources and fluctuation in Samaj Vikas (in ij>:~i.>:~!l~~<~k~~~.~~!.g) 87

88 water discharge rate (at the source) especially during lean period.in addition the state has been facing wide spread water scarcity in the recent past due to successive years of drought. About 35% mandals (blocks) are in 'overexploited' and 'critical' areas which are declared as water stressed. The efforts of the PRED and ground water department in mapping different categories of water stressed areas, including overexploited, critical, semi critical, as well as safe areas will help in planning environmental mitigation measures. The GoAP is currently investing in large scale surface water irrigation projects which have a priority for rural drinking water supply and could be potential; sources of supply in water stressed are quality affected areas. 6. The Environmental assessment will provide insight into the environmental challenges that deal with source sustainability, water quality management, drainage and disposal and house hold sanitation issues. based on the analysis, a detailed Environmental Management Framework (EMF) shall be finalized 2. Objective of the Study: The key objective of the study is to conduct Environmental Analysis (EA) with a view to identify the critical environmental concerns in the RWSS sector and address them as an integral part of project design. The specific objectives include: i. To assess the existing status of environment in the state and to identify threats and issues which have effect on RWSS sector. i i. To identify the environmental issues associated with implementation of RWSS schemes (Single Village & Multi Village Schemes) and develop environmental codes of practices that need to be followed during various stages such as planning, construction and operation and maintenance. iii. To identify generic environmental issues that are beyond the scope of individual RWSS schemes, but related to the sector and recommend remedial measures to address them as part of the project. iv. To identify household and environmental sanitation issues as well as to make an assessment of pollution level with regard to water supply and its usages & propose appropriate sanitation technology options. v. To prepare an Environment Management Framework including well defined performance indicators for addressing the identified issues, through the various activities / tasks under the proposed project, and strategy for its implementation to achieve sustainable sources for water supply schemes and environmental sanitation benefits. 3. Scope of works: 3.1. The specific tasks of the study are to: a) Collect and compile district/mandal level data on water resources and water quality for assessing the availability of safe drinking water from surface / groundwater sources. In addition to presenting the present status, the consultant shall undertake a trend analysis such as depleting sources, declining ground water tables, degrading water quality and drying of surface sources in various districts/ mandals. District level maps need to be prepared by categorizing the water sources into distinct categories such as safe for drinking, safe with treatment and unsafe for drinking purpose. b) Examine the extent and possible causes of chemical and biological contamination of drinking water sources and propose mitigation plan for the same (district level). Wherever applicable the consultant should also identify any policy/regulatory measures - - Samaj Vikas (info~~i,~san~ai~:ika~.otg) 8 8

89 Environmental Analysis - Final Report -November 2008 that may be required to protect the water resources from further contamination. The consultant shall also recommend various cost effective treatment options for contaminations that are very common in the state. The Consultant should collect information from secondary sources to examine possible point and nonpoint sources of contamination. The water quality hotspots need to be clearly identified for each district. c) Assess adequacy of current water quality monitoring programs and institutional capacity in the State, and provide recommendations for enhancing these as well as disseminating water quality information to the rural public. d) Assess current programs for disinfecting / treatment besides chlorination of drinking water supplies and provide recommendations for enhancing as well as making these effective. The accent should be on preserving water quality by up stream intervention and effective locally available and manageable low cost treatment techniques. e) Assess household and environmental sanitation issues, including personal hygiene, health, household environment and sanitation issues. Collect information on major diseases and their causes, and assess how these can be reduced through various project interventions. Assess need for personal health and hygiene programs; f) Assess environmental sanitation issues pertaining to the rural areas, including need for pavement of internal village roads and properly designed network of sullage and water drains. g) Review rural drinking water and sanitation sector related policies, legislations and institutions and recommend appropriate policies and institutions for addressing the environmental issues and attaining sustainable water and sanitation services. h) To find out alternate usages of wastewater and to explore possibility of economic recycling of solid waste for income generating activities. i) To assess the extent of usage of water by livestock in the villages from drinking water supply schemes and to find out effect of this practice on quantity and quality of available water and suggest appropriate recommendations to address the problem. j) Develop village environmental quality indicators and propose appropriate water quality monitoring indicators, along with the methodology and institutional arrangements for measuring / assessing and disseminating the same. k) Assess ecological impact of changes /alteration in natural water flow/path because of the tapping of natural sources and provide recommendations for synergizing the positive effects and minimizing the antagonistic effects for both short and long term durations and possible integration with socio economic development. 1) Prepare guidelines/environmental codes of practices (ECOPs) for addressing the identified environmental issues in RWSS schemes. Sample examples of guidelines to be prepared are given below: i. Guidelines/ECOPs for identification of sources of water supply ii. Guidelines/ECOPs on protecting surface water supply sources and ensuring sustainability iii. Guidelines/ECOPs on protecting ground water supply sources and ensuring sustainability iv. Guidelines/ECOPs on Water Quality Management. Samaj Vikas (jgf~.c~,~~ri!i~y!kk;!~,pg) 89

90 v. GuidelinesIECOPs on selection of Safe Sanitation Technology Options (including drainage) at individual household and community level. vi. GuidelinesIECOPs on selection of location for community toilets vii. Guidelines/ECOPs on Safe Sullage Disposal and Organic waste management. viii. Guidelines on Safe Solid Waste Management at individual household and community level. These guidelines/ecops shall be prepared, based on local soil characteristics, hydrogeology, and accessibility of water sources, socio cultural environment etc. The sanitation and environment related issues guidelines prepared by UNICEF, Rural Development Department, Watershed Management Directorate, etc. will be particularly useful in developing the guidelines for safe sanitation technology options. The "State Environment Report" of Government of Andhra Pradesh is under preparation by EPTRI, which should be studied, and WATSAN related issues must be analyzed and incorporated in the Environmental Management Plan. 4. The environmental issues should be presented in detail, using Charts, Tables and Maps for clarity. Use of pie charts will be especially useful for analyzing the hotspots. The EMP and performance indicators should be presented in a matrix format. The consultants will provide all relevant data / information in this regard. All assumptions made should be clearly stated along with their justification. 4. Suggested Methodology for the Study a) The consultant will collect the existing information about Environmental issues of RWSS sector, from the sector institutions and other sources like report of the surveys conducted in the past, the report of the relevant studies done earlier, official records of various concerned departmentstorganizations etc.. [The consultant shall preferably use latest satellite data to map the water resources including water quality for each district on a GIs platform to enable easy identification of safe drinking water supply sources by the implementing agency.] b) The consultant shall hold detailed interactions with the organizationststakeholders such as Rural Water Supply wing of PRED ISWSMPSU, EPTRI, NIT, JNTU,WALMTARI, APARD, NIRD, NG Ranga Agriculture University, AP pollution control Board, Depts. of Forests, Agriculture, Horticulture etc. to collect information regarding environmental issues done by them. c) The methodology to be adopted for conducting the field study will be on a participatory approach. The target groups will be consulted during the study both at the level of planning and also at the level of finalization and as and when required. The prime source of information will be based on the key informat, House-to-House interviews, field visits and observation, focus group discussion (members of PRIs, Community based organizations, other stakeholders etc.), Participatory Rural Appraisal, and household survey. The study will require sample examination and sample data collection from the field to prove environmental condition and to suggest remedial measures. The consultant will hold requisite number of interviews, observations, and group discussions in atleast 22 representative GPs (from each district). Samaj Vikas ( i~~t~~csa~~~iviki~x.~~~'g) 90

91 5. All the sources of information will be required to be enlisted and validated by support documents. The final outcome of the study should meet the objectives and should cover the scope of the works. 6. Schedule and Outputs of the Study: The study is proposed to be carried out in five stages: Stage 1: Preparation of study tools, approach and methodology, identification of data requirements, mode of data collection and outline of the final report. Field Surveys in select, representative areas for getting information on the nature and severity of the water pollution and environmental issues prevalent in the State. Stage 2: Stakeholder consultations in representative Gram Panchayats; Data collection from secondary sources; A preliminary assessment of environmental issues, based on secondary sources of information, conducting field surveys and holding public consultations. Stage 3: Detailed analysis of baseline environmental issues, policies, legislations and institutions; analysis of alternative scenarios; and recommendations regarding mitigation measures, monitoring and evaluation strategies and institutional responsibilities; Preparation of the Environment Management Framework and Performance Indicators; and Preparation of Intermediate status Report-I1 covering full analysis and recommendation. All relevant data should be presented in detail in annexure. Stage 4: Preparation of Draft Final Report on Environmental Analysis, incorporating PSUISWSM comments on the Draft Report. Stage 5: Preparation of final Report, incorporating comments from PSUISWSM and World Bank on Draft Final Report. Bench Marks: The study should be completed within 16 weeks from the date of commissioning of the study. SWSM/PSU should provide comments at each stage of Report preparation within one week of submission of the report and the consultant should address these at each stage of report preparation. The following are the benchmarks from the date of commissioning of the Study: Stage I - Inception Report Completion of Stage 2 and Intermediate Status Re~ort ~-~ 1 Intermediate Status Report I1 Completion of Stage 4 and Draft Final Report Final Report 2 weeks 4weeks 4 weeks 2 weeks 4 weeks 2 weeks 6 weeks 1 Oweeks 12weeks 16 weeks 7. Data, Services and Facilities for the Study The Project Director, PSU for the current project would supervise the study and facilitate interaction and exchange of information between the consultants, concerned GoAP departments and Panchayat Raj Institutions (PRIs) GPs, MPPs, ZPs. PSU staff may join the - -- Samaj Vikas ( i!nfo~~sgl~~jy~.~!~) 9 1

92 Environmental Analysis - Final Report -November 2008 consultant team during selected field visits. The Gram Sarpanch shall be involved to facilitate all processes during the field visit, wherever necessary. 8. The Outputs of the Study will be: a. Inception Report together with the tested check lists 1 instruments proposed to be used and the formats of the expected results (3 copies); b. Intermediate Status Report I after completing field work (5 copies): c. Intermediate Status Report I1 after completing field work (5 copies): d. Draft Final Report (5 copies): and e. Final Report (I 0 copies) In addition to the paper copies, the consultants will make available electronic copies of: a) All reports in MS Word. b) All raw data in tabulated form, together with relevant summary tables, in MS Excel /MS Access Oracle Database at the time of submission of draft report and revised final report 9. Review Committee to Monitor Consultants Work The Project Director, PSU or his nominee will be the chairperson of the review committee comprising of (i) Unit Coordinator (Environment), (ii) Unit Coordinator (Engineering) (iii) Unit Coordinator (M&E) & (iv) Finance Controller. The Director may include more experts in the committee. The committee may also seek comments and inputs on the consultants work from the World Bank staff and other experts as appropriate. The review committee to monitor the works of the consultant will monitor the progress of work done by the consultants. The presence of the consultants in these meetings is compulsory, which will incorporate the suggestions given by the committee. 10. Qualification of Key Professional Staff (Whose CV and Experience would be evaluated). The consultant should have considerable experience and professional expertise in the area of Water Resources and Environmental Management, especially relating to water supply and sanitation projects. List of Key Professionals and Required Experience Key personnel Minimum Qualification Environmental Specialist and Team Leader Hydrologist1 Geologist Biochemistry/Mic robiology Specialist Water Supply & Post Graduate degree in Environmental Engineering1 Environmental Science with experience in Environmental Impact Analysis Post Graduate degree in the relevant field with experience in Ground Water and Watershed Management. Knowledge on interpretation of satellite data and GIs mapping preferred. Post Graduate degree in the relevant field with experience in Community Development/Social Projects. Post Graduate Degree in relevant field Minimum Experience No. of Personnel Man Months 15 years 1 10 years 10 years 10 years Sarnaj Vikas ( i~~_fo~a m ~ i i ~ i>~g) ~ k ~ ~ ~. 92

93 Andhra Pradesh Kural Water Supply and Sanitation Project Environmental Analysis - Final Report -November 2008 Sanitation Engineering Specialist with experience in Rural water supply sector 2 8 The total man month's input is 20.0nly the CVs of key professionals shall be evaluated. Trained field investigators and research assistants, as necessary should assist the team for data collection and tabulation. The services of the team should be exclusively provided for the study and their contact addresses1 numbers should be provided to PSU to facilitate constant and regular contact. 11. Terms of Payment i 10% of the contract value on submission and acceptance of the inception report % of the contract value on submission and acceptance of intermediate status report- I % of the contract value on submission and acceptance of intermediate status report- I1 iv 30% of the contract value on submission and acceptance of draft final report. v 20% of the contract value on submission of test report on piloting of 66 GPs and final report Samaj Vikas (itifo'cdsalnaivika~.~)~'~) 93

94 1 Andhra Pradesh Rural Water Supply and Sanitation Project Annexure 2: List of Sample Habitations Selected for Field Study ( District I Mandal / Village 1 Habitation 1 Andhra Region Srikakulam 1 Seethampeta Marripadu Marripadu I Arnadalavalasa I Dusi I Dusi West Godavari Rayalaseema Region Chittor I V. Kota I Pamuganipalli I Kothachinnaiahpalle Kumool Ichapuram Duduluru D. Tirumala Undi Gurramkonda Satyavedu Alur Bhirlangi Dosapadu Pangidigudem Vandram Kandriga Kalamnaidupeta Moosanahalli Bhirlangi Dosapadu Pangidigudem Vandram Kandriga Kalarnnaidupeta Moosanahalli I Kulkacherla, Fluoride Affected Villages Prakasam Martur S. Konda Mundlamur Kanigiri Kanigiri Nalgonda Bhongir Bibinagar -- - B. Ramaram Thurkapalli Kattangur 1 Chevella 1 Malkapur 1 Malkapur I Adavi Venkatapur Martur S. Konda Marella Disrasavancha Polavaram Basavapur Bibinagar Fakeerugudem Gandhamalla Kattangur Martur S. Konda Marella Disrasavancha Polavaram Basavapur Bibinagar Fakeerugudem Gandhamalla Kattangur Samaj Vikas (j!it:o~&pnl;lj?jk~~ss_c~~~) 94

95 Environmental Analysis - Final Revort - November 2008 Annexure 3: Questionnaire for Field Data Collection 1. HH ENVIRONMENTAL INTERVIEW FORMAT Identification Habitation Mandal Village I District I Demographic Profile 1. Name of the Household Head: 2. Religion 1- Hindu/ 2- Muslim13- Christiad4-Others 3. Caste 1 - GeneraU2- SCI 3- STl4- BC 4. Sub caste 1 sub tribe HH Environmental Sanitation 5. Where do you defecate? Open Defecation Sewerage If ISL, do all members of your family use? Is your ISL /Public Latrine connected to How do you dispose effluent from Septic Tank? Where do you dispose septic tank/ leach pit waste? Do use this waste as Manure? If Open defecation, then where do you go Do you resort to open defecation? Is your HH connected to Sewerage? I 1- yes1 2- NO If Yes, any treatment is done? Where it is disposed finally? Waste Water 16. Where do you dispose sullage? 17. Where this waste water leads to 18. Do this waste water is treated? Personal Hygiene Do you practice hand washing aftcr tjci;.c.llllo1l? When do you generally wash hands? 21. What do you use for cleaning hands? 22. How often do member of your family bath? 1- Individual Sanitary Latrine (ISL)l2 - Public Latrine1 3- Open 1- Yes1 2- No 1 - Leach pit/ 2- Septic Tank 1- Outside village 12- In village 1 3- Near fields1 Other 1 - Yes1 2- No 1- Near Water Source1 2- Slope grounds1 3- Catchments1 4-Others 1 -Yes/ 2- No 1- Yes1 2- No 1- NallaW 2-Tank/ 3- Irrigation canal1 4- Pond 5-Rivulet/ 6-Others 1 - Drain1 2- Soak pit 1- NallaW 2-Tank1 3- Irrigation canal1 4- Pond 5-Rivulet/ 6-Others 1- Yes1 2- No 1 - Yes1 2- No 1- Before & After eating/ 2- After Defecatiod 3 - Both 1- Soap1 2- Mud 3- Ash1 4- Others 1. Daily1 2. Once in two days1 3. Twice a week. 4. Weekly once1 5. DKCS.. Samaj Vikas (,~ifoii!~,~.~>i;il!:~k~,~~~) 95

96 1 Andhra Pradesh Rural Water Supply and Sanitation Project Cleaning practice after defecation in open Where do your children defecate? How do you dispose children fecal matter? 26. ' Do you wash your hands after cleaning children's feces? Drinking Water 27. Where from you get your drinking water? 28. Do you treat drinking water in case obtained from open well? 29. If Yes, how do you treat? How do you handle drinking water? Solid Waste 1- Water1 2- Stone1 3- Leaves1 4- Sticks1 5- Paper/ 6- others 1- Inside housel 2- Outside1 3- latrine1 4- Field 5- Others 1 - Yesl 2- No 1- Panchayat tap1 2- Hand pump1 3 - Public Open wely 4- Individual open well 1- Yes1 2- No 1- Filtering using Cloth1 2- Candles1 3- Boiling1 4- Chlorine Tablets1 5- Alum or herbs1 6 - Others I-Use ladle1 2- Cover or lid 3- Customized pot or tank with tapl 4- Other I Where do you dispose Solid waste? 1- In bins1 2- Outside on lane1 3. In front of housel 4. In compost pit Livestock 32. Where do you dispose fodder wasteldung? 33. Do you have a compost pit for this waste? 1 - House back yard I 2- Outside village1 3 - Others I. Yes1 2. No. 2. Village Information Format (Collect information form Village Sarpanch, Village Secretary and other responsible village leaders) Identification Name of the Habitation Name of the Mandal General Information 1 Area in Acres ~o~ulation I Distance from Mandal Headquarters in Krn Nature of Soil (Clay, sand, gravel, rock) Depth of Water Table (Location wise) Name of the Village (GP) Name of the District Terrain I 1. Plaid 2. Sloping1 3. Hilly1 4. Forest I 5. Other (Specify) Water Supply Type of Scheme Source 1. SVS 12. MVSI 3. HPs 1. Bore well1 River1 =Specify) - - Samaj Vikas (~!lfi)~(~;sar~l~~v~ki~~org)

97 I Andhra Pradesh Rural Water Supply and Sanitation Project Environmental Analysis - Final Report -November 2008 t I Treatment Type of treatment - Type of Storage Distribution Supply duration Supply Frequency Quality Perception Quality Parameter (Specify parameter and value in ppm) Environmental Sanitation No of ISLs ISL Coverage (% of households) No of Public Latrines Solid Waste Disposal? Use of waste as Manure? Open Defecation places Presence of Sewerage Sewerage Coverage (% of households) Sewage treatment Where Sewerage is disposed finally? Where this waste disposed finally? Roads Total Road Length (Km.) Type of Roads (specify length in Km) 1. Yes1 2. No. 1. Slow sand Filtration/ 2. Defluoridatiod 3. Chlorination/ 4. Others (Specify) 1. HSCI 2. PSPI 3. Others From Hrs to Hrs 1. Daily1 2. Once in Days 1. Muddy1 2. Salty1 3. Fluoride1 4. Smell/ 5. Other (specify) 1- Outside village I 2- In village I 3- Near fields/ Other 1- Yes1 2- No 1- Near Water Source1 2- Sloping grounds1 3- Catchments1 4-Others 1- Yes1 2- No 1. Yesi 2. No. 1- Nallahi 2-Tank13- Irrigation canal1 4- Pond 5-Rivulet/ 6-Others 1- Nallahi 2-Tank/ 3- Irrigation canal/ 4- Pond 5-Rivulet/ 6-Others 1. CC- 12. Metal I 3. Kutcha I 4. Other Presence of Road side Drains 1 - yes1 2- No Coverage in Km Solid waste Where do you dispose solid waste? 1- Inside the Village1 2- Out Side1 3- I Others / Where do you dispose fodder wasteldung? Locations Distance from village Km, What is done with the waste? Health Health facility Health staff in village 1- Compost/ 2- Burnt1 3. leave it alone1 4.0ther (specify) 1. PHCI 2. Sub-Centerl 3. Others 1 1. Govt. Doctor1 2. Private Qualifid Doctor1 3. ANMI 4. QuacW 5. None1 6.0thers (specify) Common Diseases 1. Malarial 2. Typhoid 3. GEI 4. JEI 5. 1 Others (Specify) / Season for Typhoid, Malaria, GE, JE, 1 1. Rainy Season/ 2. Winter1 3. Summer I Samaj Vikas (j!li:c?i.~s.a~n~j"kkgb.~~t~) 97

98 Environmental Analysis - Final Report -November 2008 etc. Other Information Position Name Phone1 Mobile No. GP Secretary Revenue Secretary AE (RWS) in charge Village " Leader 1 1 Village Leader 2 Village Leader 3 Village Leader 4 3. Focus Group Discussions/ Public Consultation Facilitator Checklist 1. Background Information, Date and Time of FGD Habitation, LocationNenue of FGD Focus Group Category General1 Women, SCISTI Others I Sub-category (specify) Number of Participants I Men: Women: 4 o t a l : ( Moderator Project introduction The Government of Andhra Pradesh is preparing the Andhra Pradesh Rural Water Supply and Sanitation Project. This project aims to make investments for augmentation, rehabilitation or construction of SVS and MVS, including improvement of water sources in about 15,000 habitations located in about 7,000 GPs, and representing a total population of about 12 million. This project further aims at improvement of operational performance of all SVS and MVS schemes and take up sanitation and environmental sanitation programs including liquid and solid waste management. Further this project aims at building capacity of the PRIs in the field of community mobilization, RWSS project formulation and implementation and management. Further this project will monitor water quality and put in place a management information system. This project is in preparation stage and your views during this public consultation on the possible project impacts (both positive and negative) and mitigation measures are invited for incorporation into the project design. 2. Water Sources What are the major sources of water supply? What are your main sources of drinking water? Which sources do you use for cattle purposes? What is the quality of these sources? How do these sources get contaminated? What are the probable areas for groundwater extraction? What are the groundwater levels during the last 10 years? 3. Present Sanitation (Human Waste, Waste Water, Animal Waste, Samaj Vlkas (111fof[1 sanlillukai-o~g)

99 How many have ISLs in the village? How many do use them? What are the reasons for not using the ISLs? What are the reasons for not building ISLs? Where do you dispose of the contents of the septic tanks1 leach pits? What percentage of village is covered with drainage? Why the remaining portion is not covered? How often your drainage is clogged? Who maintains the drainage? Would contribute for providing underground drainage to the entire village? How much? Would you contribute to maintain the underground drainage properly? How much? Where does the village wastewater go finally? Do you think your village is clean? How far it is clean? Can it be better? What are your suggestions to keep it clean? Are the roads paved in your village? 4. Water Quality What are your perceptions about the drinking water quality? If the water is not good do you have any other means? What is sustainability of these sources? Has the quality deteriorated over past few years? How and Why? (e.g. color, taste, smell) Due to what reasons the water quality has deteriorated? 5. Awareness Generation What are the various awareness programmes regarding water and sanitation taken up in your village? How can the people be motivated to water sources clean and keep water at home clean? How can people be motivated to built ISLs and use them? Who all need to be educated and on what specific aspects? (e.g. women, children, general public, officials) 6. Indigenous Knowledge1 Village Wisdom How do you protect your drinking water sources? How do you traditionally clean1 treat water? At household level1 community level: Are there any occasions during which the whole village is compulsorily cleaned and sanitized? 7. Suggestions What are the environmental problems that you perceive from the project? What are your suggestions to overcome these problems? Samaj Vikas (jpfil:o,>i~n~<~ixrika~~[?rg) 99

100 Environmental Analysis - Final Report -November Introduction Annexure 4: Summary Analysis of Data Collected The objectives of the primary data collection through household survey is to know water supply and sanitation situation in the sample villages, to gauge the extent of quantity and quality issues and to know the peoples perceptions on the services. This survey was conducted during January- February 2008 in about 3,000 sample households in the sample villages. 2.0 Water Supply 2.1 Type of Scheme An analysis of source of water supply vis-a-vis SVS and MVS has been made and the results are presented in the table below. Of the 1889 respondents, more than half (53. 47%) belong to SVS villages and 9.63% belong to MVS villages. The balance 36.9% depend on a variety of sources ranging from privately owned hand pumps and bore wells to sources belonging to the public domain such as public hand pumps and rivulets. The detailed analysis of responses indicate that, of the 1,620 responses under the SVS, about 8.95% (own hand pump, own dug well and private bore well) depend entirely on privately owned sources; where as a large majority (over 90%) depend entirely on public sources other than SVS (public hand pump, public dug well, rivulet) When the same analysis is applied to MVS villages, the pre-dominance of privately owned sources goes as high as 30.49%. 2.2 Scheme Sources Among the sampled villages majority (71%) of the villages depend on groundwater as scheme source, while the remaining (29%) of the village schemes have surface water as source. 2.3 Quantity of Water / Source of HH Water Supply SVS MVS Own Own Public Public Pvt. Riwlet HandpumpDu~UHandpumpDugweU Borewell \ J source Surface Groundwater Total SVS YO (N0.s) (8) (30) MVS YO (N0.s) Total % (N0.s) When the type of scheme is taken into account, most (73%) of the SVS schemes have groundwater as source while the remaining (27%) of the SVS have surface water as source. Nearly half of the MVS schemes have surface water as source while the remaining half has groundwater as source. The below table explains these details by scheme and source. \ - ~ - - Samaj Vikas (illff~);~~;sanii~~k:~~>rg)

101 The overall analysis of quantity of water supplied per capita per day indicates the following: i. Only a small fraction of the surveyed households (0.42% and 3.18%) get supply either less than 20 litres per capita per day or more than 50 litres per capita per day, respectively. ii. A large majority of the households (96.4%) fall in the three middle bands viz litres, litres and litres per capita per day Considering the minimum supply standard of 40 litres of supply per capita per day, the percentage of households falling in the 'just about sufficient' (30-40 litres), 'deficient' (20-30 litres) and 'extremely inadequate' (less than 20 litres) supply ranges works out to be 85.66%. Water is used for multiple domestic purposes. Data from the household survey was analyzed to understand the use of water by households for various purposes, under SVS and MVS. 1 It is evident from the results that there is no significant variation in the use of water, whether SVS and MVS. While the average total consumption is about litres per capita per day, close to one third (11.36 litres) of it is used for washing clothes; Dd4ng Coolung Washing Bathing Washing Toilers followed by 7.60 litres for bathing and Urend uo rhr washing utensils (6.08 litres) stands third hue) S T El in consumption quantity. Cooking ( likes), drinking (3.11 litres) and toilet use (2.20 litres) constitute the last three in descending order. 2.4 Quality of Water Based on the prior knowledge and experience of respondents and their visual and sensory observation of drinking water, the quality of water is classified into two categories: Good (sweet, colour less, odourless) and Bad (salty/sour, coloured, odour, fluoride content). While, close to 7 1 % of the respondents perceived the quality of water to be 'Good', about 29% reported it to be 'Bad'. When this analysis is applied to SVS and MVS villages separately, the perception of 'Good' increases significantly under MVS villages (85%). Quality of Water Hard Water Saline Bad Smell SVS YO MVS % Total YO / Freq Muddy Water ( 5.57 ( 31 Samaj Vikas (!I&) ~~h~il,g\ I ka\ U I ~ ) 101

102 Environmental Analvsis - Final Re~ort - November Fluoride Can't Say1 Don't Know Total Further analysis of the quality of water (MVS and SVS) and the reasons for the perception of 'Bad' quality points out issues as detailed out in the table. While the problem of high fluoride content is the key issue under SVS villages (54.63%), this problem is completely absent under MVS villages. The next level of quality problems under SVS villages includes hardness (21.43%), salinity (12.16%) and bad smell (6.37%). The major quality problems under MVS villages are reported to be i) muddy water (30.77%) followed by ii) hard water (28.21%) and iii) Bad smell (12.82%). It may be pertinent to note that drinking water quality problems such as hardness and salinity are directly related to the source and difficult to overcome. However, the problems of muddiness and bad smell can be efficiently managed. 2.5 Water Treatment and Handling Practices Various practices are used in handling water 7-- at the household level. In more than 85% of 1 the households water is consumed directly 1 without any treatment, even in fluoride I affected regions. About 11% of the 1 HH Drinkinn Water HsndlingPractice or herbs. Use Ladle Cover or Lid Customized Poflank! with Tap 1 Using safe practices like taking water with laddle from the container is very rare (6.56%), but protecting water container with cover or lid is widely practiced (69.35%). Customized tanks or tanks with taps are used in about 25% of the households. 3.0 Sanitation 3.1 Latrine Ownership The phenomenon of owning of individual household latrines (IHL) is only 34% across the sample villages. It may be noted that the coverage for the state is about 53%. The situation is further worsened when we consider the fact that use of latrine is at least partly de-linked from owning one (refer usage). There is enough empirical evidence to indicate that owning a latrine does not necessarily mean putting it to use, because open defecation has a general social sanction Samaj Vikas (:!!~fo~(iisanli~ivikns.c~~~)

103 Total 1 loo(296) 1 loo(451) 1 loo(1142) The region-wise break-up of ownership of household toilets present a dismal picture. The percentage of households not owning toilets range from a minimum of 55% in Andhra region to a maximum of about 78% in Rayalseema region with Telangana region falling somewhere in between (64%). The sanitation situation and public hygiene in all the three regions therefore, is very poor and deserves a high priority attention. 3.2 Latrine Usage and Open Defecation The usage of latrine is about 25.89% in the state, which is a pointer to the fact that close to 75% of households do not use toilets, despite owning one. Typical example Latrine Usage is: Valbapur village in Elakathurtthy Andhr Rayalasee Telanga mandal of Karirnnagar district. This a ma na Total village won the NGP award in 2006, % YO 'YO % Freq but about 20 HH (of a total of 300 Yes HH) continue to practice open No defecation. Total The use of latrine is as low as 9.7% in Andhra where as it is relatively high in Telangana region (32.37%). In Rayalseema region the use of toilets stands at 20.79%. While the reasons for this wide regional variation in toilet use are not known, significant investments are required to inform and educate community members on the merits of toilet use and the link between water When asked the reasons for not using individual latrine many of the HH (33.45%) have fear of getting pit filled fast. About 17% HH have expressed inconvenience in defecating in latrine that points to poor design and construction. 17% defecate while in fields during work and about 5% said that they are not in habit of defecating in confined places. Samaj Vikas (~~~V:<F>&I~~:~~V~~:I~.~~TP) 103

104 Environmental Analysis - Final Report -November 2008 The practice of open defecation is wide spread in almost all the villages. It is carried out either in the open fields or in earmarked corners of the village. In some extreme cases it is carried out in any open space, whether within the village or outside. Response was sought to the question, from those who do not own toilets, 'where do they defecate' and the results are that a a very high percentage (99.6%) responded that they do so in the open fields and only about 0.40% choosing public latrine options. 3.3 Personal Hygiene A series of questions were asked to understand the personal hygiene practices of respondents and the results are tabulated below. From the data it can be inferred that good personal hygiene practices exist in all the three regions with a high percentage of households washing hands before and after eating and also after defecation. Soap is the commonly used cleaning agent for washing hands followed by ash and mud. Only less than 5% of households wash hands with water alone. 3.4 Solid Waste Disposal Indiscriminate disposal of garbage are observed in all the surveyed villages. Drainage maintenance is poor; they remain clogged at many places due to careless dumping of solid wastes into the drains. Only about 12.28% of the households use compost pit options, with a large majority dumping the waste either on roads (44.10%) or filing it in bins (12.02%). Information regarding various methods of garbage disposal was sought from the surveyed households and based on the current practices they were categorized into four major types viz. i) bins ii) outside on the road iii) in front of the house and iv) in compost pits. Once again, large regional variation has been observed as summarized below: i. Dumping the waste in bins is observed by about 42% of the households in Andhra region, where as the same practice is relatively low in Rayalseema (13.30%) and Telangana region (3.68%). ii. Disposing off waste outside the road is common in Rayalseema (56.98%) and Andhra regions (48.99%), where as in Telangana this practice is lower with about 38% of the Samaj Vikas (111to (I >ani'l1\ I~:I>J>I~) 104

105 Environmental Analysis - Final Report -November 2008 households practicing it. Dumping the waste infront of the house is practiced by about 45%, 14% and 9% in Telangana, Rayalseema and Andhra regions respectively. The unhygienic practice of disposing off waste in the open (outside the road or in ftont of the house) is widely practiced in all the regions. iii. Compost pit option is used by a very few number of households in all the three regions (0.34% in Andhra 15.74% in Rayalseema and 14.01% in Telangana). 3.5 Waste Water Disposal At an aggregate level, 45% of the households use soak pit for waste water disposal, followed by 36% opting for drains. About 19% leave the waste water in the open. - I - Drain Soak Pit Open Total HH Waste Water Disposal / Andhra I Rayalaseema I Telangana 1 Total YO YO YO % Freq Sewage Disposal The region-wise analysis offers a different 'trend. While in Andhra region, disposing off the waste water in drains is the most frequently used option (68%), in the Rayalseema, soak pits take a precedent with an overwhelming majority (93%) choosing that option. In the Telangana region, it is roughly an even three way spilt between Drains (41%), Soak pits (32%) and Open Disposal (27%). Most (92%) of HH which have ISL let the sewerage into own pitfseptic tank. Only 3% HH let out the sewerage onto open ground and the remaining 5% chose other options, including letting it off in the drains. 3.7 Fodder Waste1 Dung Disposal Disposal of Fodder Waste/ Dung by Region House Back Yard % % % % Freq 276 Samaj Vikas (~j~f.~~~.~n~;~j>:ik~~s~>~g) 105

106 Environmental Analysis - Final Report -November 2008 Outside Village Compost Pit Total Live stock related waste is another major challenge faced by most villages. State-wide analysis indicates that about 53% of HH dispose it off in the house backyard (as a compost heap) and about 42% leave it outside the village (as a compost heap). Only about 5% use the compost pit option. Composting in heaps is a more inefficient practice as compared to pit composting. It is also unhygienic as the heap is rarely managed (covering, periodic turning, etc.). 3.7 Awareness of Water Borne Diseases Around 63% of HH in the state have reported that they have some knowledge about water borne diseases. However, deeper explorations revealed that their knowledge is limited to knowing about the occurrence diarrhea and other stomach related infections. The regional analysis of knowledge levels indicate that the awareness is relatively high (over 70%) in Andhra and Rayalaseema regions, where as Telangana region ranks low with only about 57%. 4.0 Conclusions There are multiple sources water supply and different type of schemes. l 71% of the schemes are ground water based. About 82% of the sample households get about 20 to 40 litres of water per day Most people perceive MVS water supply is good in terms of quality l Most respondents consume water without further treatment at household level. Only 34% of sample household have latrines and among them only 26% use them. Most (33%) households do hot use the latrines for fear of pits getting filled faster. Most (90%) wash hands both after defection and before eating food. l 76% household throw solid waste on roads and in front of their houses 45% households have soak pits for wastewater disposal. Most (92%) of households which have ISL let the sewerage into own pidseptic tank. Very few (5%) households have compost pits for fodder and dung disposal A significant number of households (37%) are not aware of waterborne diseases Samaj Vikas ( hf(zsang~~ki~> org) 106

107 Environmental Analvsis - Final Report - November 2008 Annexure 5: Issues identified during Village level Public Consultations Samaj Vikas Development Support Organisation has conducted Environmental Analysis for this project preparation. During the field work consultations were conducted in the 34 sample villages using focus group discussions during January- February All the available stakeholders such as PRI representatives, SHG members, Panchayat Secretary, etc. were gathered at a central place. The Samaj Vikas field team facilitated the discussions. The issues brought out in these consultations are listed below: Water Supply Related Inadequate water supply, insufficient source Poor water quality, Fluoride contents in water Inadequate infrastructure: Inadequate distribution lines Inefficient use of infrastructure: Over Head Tank not in use, Chlorination system not in use Poor maintenance of infrastructure: Frequent breakdown of pumps, Bursting of pipes, Wastage of Water, Inadequate maintenance, No proper staff Disruptions in Water Supply: Inadequate water supply during summer, Frequent power cuts Sanitation Related Inadequate number of ISLs Low usage of latrines, Open defecation Low coverage of drains, Stagnation of sullage, Wastewater stagnation in streets; Improper solid waste disposal Poor sanitation conditions in SCI ST colonies - -- Samaj Vikas ( I:l!f_ias;;mgyi~~) 107

108 Environmental Analysis - Final Report -November 2008 Annexure 6: Summary of Public Consultation/ Disclosure Workshops 1.1 Organisation Samaj Vikas Development Support Organisation has conducted Environmental Analysis for this project preparation. It is the policy of the project to disseminate the study findings to the stakeholders and to invite their inputs. These workshops were planned in consultation with Project Director, APRWSSP. A detailed list of stakeholders to be invited was prepared and communicated to the Superintending Engineers. Accordingly Disclosure Workshops were planned and conducted at Vijayawada, Kadapa and Hyderabad. A final state level workshop was conducted at Hyderabad. 1.2 Vijayawada On 2"* June 2008, first disclosure workshop was conducted at Vijayawada at The Institution of Engineers (India), Vijayawada Local Centre. A total of 59 participants attended the workshop from districts of Guntur, Krishna, West Godavari, East Godavari, Prakasam, Vishakatpatnam, Vizianagaram and Srikakulam. The participants were drawn from key stakeholders like RWSSD staff, PRI representatives, NGOs, SHG leaders, Staff of other stakeholder departments like Health, Women and Child Welfare, etc. Also representatives fiom PSU, APRWSSP attended. A press meet was conducted on 31 May 2008 to invite interested persons and organizations to participate in the workshop and to give their suggestions. The workshop was inaugurated by Superintending Engineer (RWS) Krishna District and the dais was shared by SE (RWS) Viskhapatnam, Prof Narsimha Reddy, Consultant, PSU, APRWSSP and Dr BKD Raja, Samaj Vikas. The first session consisted of a brief introduction to the project including the objective and components by Dr. BKD Raja. Following this, the primary objective of the workshop was explained (to inform about the project, to share findings of the EA study and the draft EMF and to gather suggestions). After a detailed presentation on the findings of the EA study and the EMF was presented, a discussion session was held. The issues raised and the suggestions given by the participants were noted. The queries raised and clarifications requested were attended to. 1.3 Kadapa The second disclosure workshop was held in Kadapa on 4 June 2008 at The Institution of Engineer (India), Kadapa local Center. The number of participants attending was 64. They were fiom Kadapa, Nellore, Kumool, Chittoor and Ananthapur districts. The participants were drawn from key stakeholders like RWSSD staff, PRI representatives, NGOs, SHG leaders, Staff of other stakeholder departments like Health, Women and Child Welfare, etc. Also, a press meet was conducted by the Samaj Vikas representative on 30 May 2008 to invite interested persons and organizations. The workshop was started by a welcome note fiom Superintending Engineer (RWS), Kadapa. The other dignitaries present are SE (RWS) Ananthapur and DE, PSU, APRWSSP.

109 The first session was with brief introduction of the project and explaining the objective and components of the project by Dr. BKD Raja. He said that information on the project would be provided and the primary objective of the workshop was to inform the people about the project study findings and gather suggestions. The finding of the Environmental Analysis study was presented. After presenting the findings the next session started for discussions. The issues and suggestion given by the participants were noted. Replies to these queries and clarifications were given to the participants. 1.4 Hyderabad The workshop was held at Hyderabad on 7 June The programme was conducted at National Institute for Micro, Small and medium Enterprise (ni-msme) (formerly nisiet), Yousufguda, Hyderabad. A press note was released on 31 May 2008 for inviting interested persons and organizations to participate in the discussions. The workshop was attended by 56 participants from the districts of Hyderabad, Ranga Reddy, Nalgonda, Warangal, Mahaboobnagar, Nizamabad, Adilabad, Medak and Karimnagar. The participants were drawn fiom key stakeholders like RWSSD staff, PRI representatives, NGOs, SHG leaders, Staff of other stakeholder departments like Health, Women and Child Welfare, etc,etc. Mr. S.S.R. Anjaneyulu, Deputy Project Director, APRWSSP welcomed the dignitaries and the audience. He said that the primary objective of the workshop was to inform the people about the project and disseminate the EA study findings and gather suggestions on the EMF. The other dignitaries present were Superintending Engineer (RWS) Ranga Reddy, Superintending Engineer (RWS) Nalgonda and the World Bank Consultant. The first session was with brief introduction of the project and explaining the objective and components of the project by Dr. BKD Raja. He said that information on the project would be provided and the primary objective of the workshop was to inform the people about the project study findings and gather suggestions. The findings of the Environmental Analysis study was presented. After presenting the finding the next session started for discussions. The issues and suggestion given by the participants were noted. Replies to these queries and clarifications were given to the participants. 1.5 Hyderabad - State level workshop The workshop was held at Hyderabad on 30 June The program was conducted at Hampshite Plaza Hotel, Lakdi-ka-pul, Hyderabad. Interested persons and organizations wee invited by letters, s, personal invitations and phone calls. The workshop was attended by 40 participants fiom Hyderabad as well as from a few districts. The participants were drawn from key stakeholders like RWSSD staff, PRI representatives, NGOs, SHG leaders, Staff of other stakeholder departments like Health, Women and Child Welfare, etc. Mr. V. Vaidyanatha Sastry, Project Director, APRWSSP welcomed the dignitaries and the audience. He said that the primary objective of the workshop was to inform the people about the project, disseminate the EA study findings and gather suggestions on the EMF. The first session was with brief introduction of the project and explaining the objective and components of the project by Dr. BKD Raja. He said that information on the project would be provided and the primary objective of the workshop was to inform the people about the project, study finding and gather suggestions. The finding of the Environmental Analysis - -- Samaj Vikas (,i!l_:o,if ~ ; I I J I ~ ~ ~ ~ ~ ~ ~. c >! ' ~ ) 109

110 Environmental Analysis - Final Report -November 2008 study was presented. After presenting the finding the next session started for discussions. The issues and suggestion given by the participants were noted. Replies to these queries and clarifications were given to the participants. 1.6 Thematic Issues - Vijayawada Water availability: In Tribal areas, there are pockets with 10 HH and even less, providing water supply to these pockets is very difficult and they always remain as NC. These HH pockets need to be clubbed with an existing near by village water supply scheme. Pit tapping and absence of taps for public fountains results in no supply/ inadequate pressure for the HH at end of distribution. What measures are planned to discourage usage of motor pumps for drawing water from pipelines? Water quality: In villages the sewage, waste water and agricultural waste water is let into tanks. The water from tanks is again used as source for supply of drinking water. Instead, water supply schemes for these villages should be designed drawing water from rivers. Waste management: People are constructing toilets near canal bunds without collecting pits. They are letting the waste into the canal and also depositing solid waste in the canal. The government needs to take necessary steps to stop this practice and also to strengthen. canal bunds. What measures are planned to address the problem of sewage being let into drains causing stagnation and posing as a health risk. Sanitation: What are the steps being taken to encourage people to stop practicing open defecation and for improving the utilization of ISLs? Project management: With whom does the responsibility for implementation and O&M of MVS lie? Is it with the RWS or with the PRIs? What is the duration of this project? More coordination between line departments is necessary. Training should be given to grass root level functionaries to achieve good results. As the plan is to conduct capacity building programs for 57,700 people, a detailed plan is necessary. The awareness programs on Pulse Polio and HIVIAIDS has created significant impact. Similarly IEC activities including street plays, video clips etc. can be used for awareness building on drinking water supply and sanitation schemes. 1.7 Thematic Issues - Kadapa Water Supply In AP about 80% women are members of SHGs. Inclusion of these SHGs in project from planning to implementation will crease the sustainability of the project as these can take up O&M issue if trained. Present water supply schemes are not being maintained properly. APRWSSP need to take these O&M problems into account and design the project accordingly? Samaj Vikas (infoitr sam,y 11,'is o~g) 110

111 Environmental Analysis - Final Report -November 2008 Frequent power cuts are the major hurdle in running the water supply schemes. The project need to establish coordination between RWSSD and Electricity Dept. for proper running of water supply schemes. Sanitation As the construction cost has gone up the subsidy for ISL need to be revised as per the latest rates. 1.8 Thematic Issues - Hyderabad Water Supply Presently water supply schemes are designed taking present population into account. New water supply scheme should be designed to cater the needs of people at least for next 10 years The water supply schemes should be designed based on actual data. For example presently SVS schemes are designed for 16 hr pumping and 8 hr distribution. But practically villages in AP are getting power supply for 7 hr. only. Due to this, most of the schemes are not functioning to their designed capacity. In villages, schemes should be designed based on actual demand. As there are more than one scheme in some villages, the maintenance suffers and water is wasted. This is leading to stress on ground water level. A committee should be formed to look after O&M and some amount should be earmarked for this. The project should insist on proper implementation of WALTA Act Sanitation Generally the Tribal HHs are scattered and are used to open defecation. These people should trained to use pit latrines then gradually to use ISLs. Care should be taken to design and construct drains and UGD with proper slope and outlets for final disposal. 1.9 Thematic Issues - Hyderabad - State level Water Supply Community need to be involved in regular water quality monitoring, in particular during monsoons. The project should propose initiatives to prevent new sources from getting contaminated in the future. Rain water harvesting should be made mandatory for all housing schemes and schools. Likewise recharge structures be made mandatory in low ground water table areas. The Project should have a fluoride policy to tackle fluoride contamination. It will be good if the project forms Hand Pump Level Committee with about 5 members from the users, care takers, Self Help Groups, Hygiene Educators and Sanitation Educators. As the Electric supply is a major problem, the project should think of alternate energy resources like solar power. Sanitation Samaj Vikas (i!jj:(~s.:'~g>: ilia$.erg)

112 Environmental Analysis - Final Report -November 2008 Littered solid waste is a major source for contamination for ground water. The project should look into this issue as well. Project Management The community need to be trained in filling of EDS and segregation of negative and positive impacts due to the project. The project should involve the existing IKP staff at mandal and village level. Samaj Vikas (infoi,itr;sarn~tivilia~.org) 112

113 Andhra Pradesh Rural.Water Supply and Sanitation Project Annexure 7: List of projects requiring prior environmental clearance as per EIA Notification 2006 Category with threshold limit Conditions if any 1 (2) Mining of minerals Offshore and onshore oil and gas exploration, development & production River Valley projects I Mining, extraction of natural resources and power generation (for a specified production capacity) (i) 3 50 MW hydroelectric power generation; (ii) 0 10,000 ha. of (i) < 50 MW 25 MW hydroelectric power generation; (ii) < 10,000 ha. of I (3) 1 (4) (5) 50 ha. of mining - lease ( <50 ha General Condition shall area G 5 ha.of mining lease apply area. Note Asbestos mining irrespective of mining area Mineral prospecting (not involving drilling) are exempted provided the concession areas have I- got previous clearance for physical survey All projects Note Exploration Surveys (not involving drilling) are exempted provided the concession areas have got previous clearance for physical survey General Condition shall apply I culturable command area ( culturable command area I l(d) I Thermal Power I 500 MW 1 < 500 MW 1 General Condition shall (1) 1 (e) 2 1 Plants (coal/lignite/naphta& gas based); i3 50 MW (Pet coke diesel and all other fuels (2) Nuclear power projects and processing of nuclear fuel 1 (3) All projects Primary Processing (coalilignitelnaptha & gas based); <50 MW 5MW (Pet coke,diesel and all other fuels ) (4) (5) Coal washeries throughput of coal throughput of coal General Condition shall apply (If located within mining area the proposal shall be appraised together with the mining proposal) Samaj Vikas (inrotli s~111:1ivika>.org) 113

114 beneficiation Category with threshold limit I Conditions if any A B G 0.lmillion tonlannum ( < 0.lmillion tonlannum mineral throughput I mineral throughput 1 apply General Condition shall $+- 3(a) Metallurgical industries (ferrous & non ferrous) I Materials Production (3) a)primary metallurgical industry All projects (4) (Mining proposal with Mineral beneficiation shall be appraised together for grant of clearance) (5) b) Sponge iron manufacturing 2 200TPD Sponge iron manufacturing <200TPD General Condition shall apply for Sponge iron manufacturing c)secondary metallurgical processing industry Secondary metallurgical processing industry All toxic and heavy metal producing units I7 20,000 tonnes lannum i.)all toxic and heavy metal producing units <20,000 tonnes lannum 4-3( b) Cement plants industry C 1.0 million tonneslannum production capacity Materials Processing (3) All projects ii.)all other non -toxic secondary metallurgical processing industries >SO00 tonneslannum 4.0 million tonneslannm production capacity. All Stand alone grinding units (4) General Condition shall apply (5) I 4(b) Coke oven plants 72,50,000 tonneslannum <2,50,000 & 725,000 tonneslannum (c ) Asbestos milling All projects and asbestos based products p Samaj Vikas (info~ii,sa~n;~ivii;:~s.~) 114

115 I Category with threshold limit ( Conditions if any A B Chlor-alkali industry Soda ash Industry Leatherlskinhide processing industry TPD production capacityor a unit located out side the notified industrial areal estate All projects New projects outside the industrial area or expansion of existing units out side the industrial area <300 TPD production capacity and located within a notified industrial area/ estate All new or expansion of projects located within a notified industrial area/ estate Specific Condition shall apply No new Mercury Cell based plants will be permitted and existing units converting to membrane cell technology are exempted from this Notification Specific condition shall apply 5 5(a) 5(b) 5(c) 5(d) I ManufacturingIFabrication I Chemical fertilizers All projects Pesticides industry All units producing and pesticide technical grade pesticides specific intermediates (excluding formulations) Petro-chemical complexes (industries based on processing of petroleum fractions & natural gas andlor reforming to 1 aromatics) Manmade fibres manufacturing Petrochemical based I Located out side the processing notified industrial area/ (processes other estate than cracking & reformation and not covered under the complexes) Synthetic organic Located out side the chemicals industry notified industrial area/ (dyes & dye estate intermediates; bulk drugs and intermediates excluding drug formulations; I I Ray on I Others I General Condition shall Located in a notified industrial area/ estate Located in a notified industrial area/ estate I I apply Specific Condition shall I Specific Condition shall Samaj Vikas (info>cs:ln:ii\ ika?:~?~) 115

116 1 Category with threshold limit 1 Conditions if any 5(h) synthetic rubbers; basic organic chemicals, other synthetic organic chemicals and chemical intermediates) Distilleries Integrated paint industry (2) Pulp & paper industry excluding manufacturing of paper from waste paper and manufacture of paper from ready pulp with out bleaching Sugar Industry Inductiodarc fumaces/cupola furnaces 5TPH or more Oil & gas transportation pipe line (crude and refinery/ petrochemical products), passing through national parks /sanctuaries/coral reefs /ecologically sensitive areas including LNG Terminal Isolated storage & handling of hazardous chemicals (As per ( (i)all Molasses based distilleries (ii) All Cane juice1 nonmolasses based distilleries 030 KL Pulp& Paper manufacturing industry - Service Sectors All projects All Cane juicelnonmolasses based distilleries - <30 KLD All projects 1 General Condition shall industry without pulp manufacturing O 5000 tcd cane crushing capacity All projects General Condition shall General Condition shall apply General Condition shall apply 1 (5) 1 General Condition shall Samaj Vikas (infoctr:sam;~;vi kas.org) 116

117 ' Andhra Pradesh Rural Water Supply and Sanitation Project 7 7(a) threshold planning quantity indicated in column 3 of schedule 2 & 3 of MSIHC Rules 1989 amended 2000) Air ports All ship breaking yards including ship breaking units Industrial estates/ parks/ complexes/ areas, export processing Zones (EPZs), Special Economic Zones (SEZs), Biotech Parks, Leather 1 Complexes. waste treatment, storage and disposal 1 facilities (TSDFs) 7(f) 1 Highways Category with threshold limit 1 Conditions if any A Physical Infrastructure including Environmental Services All projects All projects If at least one industry in the proposed industrial estate falls under the Category A, entire industrial area shall be treated as Category A, irrespective of the area. Industrial estates with area greater than 500 ha. and housing at least one Category B industry. All integrated facilities having incineration &landfill or incineration alone (3) 5 million TPA of cargo handling capacity (excluding fishing harbours) i) New National High ways; and ii) Expansion of National High ways greater than 30 KM, involving additional right of way greater than 20m involving land acquisition and passing through more than one State. B Industrial estates housing at least one Category B industry and area <500 ha. Industrial estates of area> 500 ha. and not housing any industry belonging to Category A or B. All facilities having land fill only (4) < 5 million TPA of cargo handling capacity andlor ports/ harbours U 10,000 TPA of fish handling capacity i) New State High ways; and ii) Expansion of National / State Highways greater than 30 km involving additional right of way greater than 20m involving land acquisition. I Special condition shall apply Note: Industrial Estate of area below 500 ha. and not housing any industry of category A or B does not require clearance. General Condition shall apply (5) General Condition shall apply 1 General Condition shall apply 7(g) 7(h) Aerial ropeways Common Effluent Treatment Plants (CETPs) 1 All projects ) General Condition shall, All projects apply General Condition shall apply Samaj Vikas (~nlb tr sarnal\ ~ hdk o~g) 117

118 ~ :;~;rtion Andhra Pradesh Rural Water Supply and Sanitation Project 7(i) (1) 8 8(b) Common Municipal Solid Waste Management Facility (CMSWMF) (2) Building and Townships and Area Development projects. Category with threshold limit A B All projects I Conditions - i General Condition shall apply (3) (4) (5) Building /Construction projectslarea Development projects and Townships?20000 sq.mtrs and <1,50,000 sq.mtrs. of built-up area# --- Covering an area 1 50 ha and or built up area?1,50,000 sq.mtrs ++ #(built up area for covered construction; in the case of facilities open to the sky, it will be the activity area ) *All projects under Item 8(b) shall be appraised as Category B 1 General Condition (GC):Any project or activity specified in Category 'B' will be treated as Category A, if located in whole or in part within 10 krn from the boundary of: (i) Protected Areas notified under the Wild Life (Protection) Act, 1972, (ii) Critically Polluted areas as notified by the Central Pollution Control Board from time to time, (iii) Notified Eco-sensitive areas, (iv) inter-state boundaries and international boundaries. Specific Condition (SC): If any Industrial Estate1 Complex1 Export processing Zones/ Special Economic Zones1 Biotech Parks1 Leather Complex with homogeneous type of industries such as Items 4(d), 4(f), 5(e), 5(f), or those Industrial estates with pre-defined set of activities (not necessarily homogeneous, obtains prior environmental clearance, individual industries including proposed industrial housing within such estates1 complexes will not be required to take prior environmental clearance, so long as the Terms and Conditions for the industrial estate1 complex are complied with (Such estates/ complexes must have a clearly identified management with the legal responsibility of ensuring adherence to the Terms and Conditions of prior environmental clearance, who may be held responsible for violation of the same throughout the life of the complex/ estate). Note: 7h and 7i are not applicable to APRWSSP as the project will not build any common effluent treatment plans are common solid waste management plants. APRWSSP is basically rural water and sanitation project where the quantities of sewage and solid waster generated are too little when compared to municipal areas. The APRWSSP opts for individual latrines (in some cases groups latrines) and composting of solid waste.

119 Environmental Analysis - Final Report -November 2008 Annexure 8: Water Quality Monitoring and Surveillance Water Quality Standards The Bureau of Indian Standards specifications IS: govern the quality of drinking water supplies in India by public agencies. These are based on International standards for drinking water quality issued by the WHO and the manual of standards of quality for drinking water supplies, ICMR, Physical and chemical Parameters S1.No. Characteristics 1. Turbidity (NTU) 2. Colour (unit on Pt. Cobalt scale) ph TDS (mg/l) 5. Total hardness (mg/l) Acceptable limits 1.O to Maximum Limits <6.5 or > Bacteriological Parameters In 100 ml sample, the count of coliforrn organism and E-coli should be zero. Current Water Quality Monitoring Efforts Therer are 51 Water Quality Testing Laboratories functioning at the divisional level in all districts. There also exists a state level Water Quality Testing Laboratory. The details of these laboratories are provided at the end of this Annexure 8. However, lack of manpower and infrastructure coupled with resource constraints has been a major obstacle for water quality monitoring. In view of this, the Government of India through the Department of Drinking Water Supply has established a community based Water Quality Monitoring and Surveillance system. Under this programme, the RWSS Department of the Government of Andhra Pradesh has procured field kits for testing water quality and organized state, district and block level training programmes in RWSSD procured 24,000 field kits and 13,50,000 H2S Vials were procured and are being distributed to all the laboratories (mentioned in this annexure), Mandal and Gram Panchayats offices. As on August 2008, more than 50% of the procured material has been distributed. Rajiv Gandhi National Drinking Water Mission of Department, Drinking Water Supply, Ministry of Rural Development, Government of India has issued an Implementation Manual for National Rural Water Quality Monitoring and Surveillance Programme during Based on this, the SWSM, GoAP has forwarded these guidelines for water quality monitorin of the RWS schemes vide Memo No. Chemist/ SLLI SWSMI Epidemics dated 20 Guidelines for WQM&S in APRWSS Samaj Vikas (i~l~f~"lz'.:~~~ii~~i~~ik:is.(~r~)

120 Environmental Analysis - Final Report -November 2008 The guidelines given in this Annexure are in line with the guidelines of the Community-based Water Quality Monitoring and Surveillance system documented in the Implementation Manual on National Rural Water Quality Monitoring and Surveillance Programme published in 2004 by the Rajiv Gandhi National Drinking Water Mission, Department of Drinking Water Supply, Ministry of Rural Development, Government of India. These guidelines will be applied in the APRWSS. Plan for WQM&S in APRWSS Community-based systems for Water Quality Monitoring and Surveillance: The actions planned for integrating a Community-based systems for Water. Quality Monitoring and Surveillance programme as part of the APRWSS are: Identifying suitable user-friendly field kits for Water Quality Testing. Initiating an action research (pilot) on Community-based systems for Water Quality Monitoring and Surveillance in few villages. Using the piloting experience to develop a scaling-up strategy for all the project villages. Using the pilot villages as models for training (a) first, the Technical and Community Development Staff of all DSUs, and through them, (b) the engineers at mandal/ subdivision level and technical staff of Sos, and (c) the GPWSCs. Implementing the Community-based systems for Water Quality Monitoring and Surveillance programme in all the project villages through the use of user-friendly Water Quality Testing Kits and by involving the GPWSCs, community institutions (such as SHGs), local educational institutions, PHCs, etc. Water Quality Monitoring and Surveillance through Laboratory Infrastructure: The water to be supplied is tested at two stages. Firstly, at the time of development of source to ascertain if the source would yield water within safe chemical-content limits. Secondly, after commissioning of the water supply schemes, to monitor any change in quality of the water supply source over the years. Water samples, apart from the source, are also taken from different points in the distribution system including the consumer end and tested in the laboratories. Testing personnel Pump operator1 caretaker of water distribution Assistant Executive Engineer Deputy Executive Engineer Frequency Once in a day Once in a week Once in a month Once in three months Responsibility Checking and ensuring the safety of water Maintaining a record of residual chlorine Checking turbidity of treated water from filters in case of surface water sources Testing residual chlorine Checking the water quality record maintained by operator Maintaining the record of treated water quality Testing residual chlorine in the water sample Checking the record of tests conducted by the pump operator and AEIAEE and will record his comments over the results. Collecting and sending samples for bacteriological analysis; Maintaining the records of bacteriological water quality Samaj Vikas (jnfo'irsa~~~;livikas.q) 120

121 Environmental Analysis - Final Report -November 2008 I Twice in a year before and after monsoon Key guidelines for WQM&S in the APRWSS Collecting and sending samples to district laboratories for Chemical analysis; Maintaining the records of chemical water quality 1 Objective of the water quality monitoring: To ascertain the quality of water in various rural water supply schemes (tubewells or canal based) as well as in the distribution network. To examine physico-chemical and bacteriological quality to establish whether the drinking water is fit for human consumption and meets the drinking water standards as laid down in IS : Sampling: Recommended Frequency: Source Ground Water Shallow tube wells with hand pump Deep tube wells with hand pump Minimum frequency of sampling and analysis Bacteriological I PhysicaVChemical Every fortnight Once initially, then as situation demands 4 times yearly Once initially, then 4 times yearly Once initially, then two4 times yearly. Residual chlorine test - daily Once initially, then 4 Remarks Situations requiring testing: change in environmental conditions, outbreak of water borne disease or increase in incidence of waterborne diseases demands residual chlorine if Surface Water Filtered and/or chlorinated and piped supplies Once monthly Once initially, then 4 times yearly. Residual chlorine test - daily Increase frequency of bacteriological test if situation demands Recommended Location: Selection of location for sampling should indicate true representative samples. Public stand posts (PSPs) Selected consumer locations at random In addition to above, raw water source and treated water should also be analyzed in case of canavsurface water based water supply schemes. Water Quality Record: The water quality test results should be entered in a logbook as per the prescribed format (sample shown below) and should be submitted to the DSU once every 3 months. Samaj Vikas (G~l'o!cl >iit~~i~i~ik>~>.(~~_g) 121

122 1 ' Andhra Pradesh Rural Water Supply and Sanitation Project Sampling (Distributio n system) Turbidit Y (NTU) MPNI looml Quantity of bleaching powder1 sodium hypochlorite being addedlday 6 The information on water quality will be integrated into the Computerized Sector Management Information System. Details of laboratories under the control of RWSSD 1. State level Laboratory at Hyderabad Initials of Pump operator carrying 6.Locations and Addresses of District Laboratories under the control of RWSSD ' 15 No' Name of the district 1.Srikakulam 2.Vizainagaram 3.Visakhapatnam 4.East Godavari 5.West Godavari 6.Krishna 7.Guntur Location of the Laboratory Srikakulam Uddanam Palasa Vizianagaram Parvathipuram Visakhapatnam Paderu Kakinada Raj ahmundry Eluru Kovvuru Vijayawada Gudivada Guntur Address of the Laboratory (Office of) E.E, RWS, Srikakulam Dy.E.E, RWS (P), Uddanam E.E, RWS, Palasa E.E, RWS, Vizianagaram E.E, RWS, Vizianagaram E.E, RWS, Visakhapatnam E.E, PR, Paderu E.E, RWS, Kakinada E.E, RWS, Rajahmundry E.E, RWS, Eluru E.E, RWS, Kovvuru E.E, RWS, Vijayawada E.E, RWS, Gudivada E.E, RWS, Guntur Narasaraopet E.E, RWS, Narasaraopet Tenali E.E, RWS, Tenali 17 8.Prakasam Ongole E.E, RWS, Ongole 18 Darsi Dy. E.E, RWS (NAP), Darsi I 19 9.Nellore Nellore E.E, RWS, Nellore 20 Gudur E.E, RWS, Gudur, Chittoor Chittoor E.E, RWS, Chittoor 22 Tirupat i E.E, RWS, Tirupati 23 Madanapalli E.E, RWS, Madanapalli Kadapa Kadapa I E.E, RWS, Kadapa 25 I Rajampet 1 E.E, RWY s, " Kajampet I Pulivendula I E.E, RWS, Pulivendula 27 I 12.Ananthapur ( Anan thapur (South) 1 E.E, RWS, Ananthapur (South) I Ananthapur (North) I E.E, RWS, Ananthapur (North) Kurnool Penukonda Kurnool Adoni Nandyal E.E, RWS, Penukonda E.E, RWS, Kurnool E.E, RWS, Adoni E.E, RWS, Nandyal Initials of Engineer carrying test Remarks Samaj Vikas (~nl'o:tr\arn:yiv~l<,~\ 11%) 122

123 Environmental Analysis - Final Report - Novemkr 2008 Samaj Vikas ( i~lfoi~~:s~i~~~.;~~kjj~~) 123

124 Annexure 9: District Wise- Fluctuation in water level in observation wells between May 2007 and November 2007 Districts Adilabad Anantapuram Chittoor Kadapa East Godavari Guntur Hyderabad Karimnagar Khamrnam Krishna Kumool No. of wells anlaysed Range of Fluctuation (m) Min Rise Max Fall Min Max to % % % % % % % % % % % No. of wells/ Percentage showing fluctuation Rise 2 to % % % % % % % % % % % > % % % % % % % % % % % 0 to % % % % % % % % % % % Fall 2 to % % % % % % % - 0) 0.00% % % % > % % % % % % % Total No. Rise A-P % % % % of wells Fall Samaj Vikas (~~~,:asamit~i\~iki~s.org) 124

125

126 Environmental Analysis -Final Report -November 2008 Samaj Vikas (iiifo:r~.saniaiviki~s.c~rg) 126

127 SI'OP 1 SLZ %68'LS 11 %6E'6E 10'0 PO'O PP'OP~ LLZ S 10'0 Z0'0 1 S6'L ZS'I SO'CI 8Z'E OC'L 0s %00'0 0 %00'0 60'11 9L %6L'SI E %ZI'ZI SS9 61 PS'SS ZOP PI a5a~iiztad IEJ0.L pv~epof) ~ s a ~ 06'1 1 %00'0 0 %00'0 66's ZP %00'0 0 %90'9 SS'ZC CZZ %ZE'9Z 5 %ZP'ZP

128 Environmental Analvsis - Final Re~ort - November 2008 Annexure 10: Categorisation of Mandals In Andhra Pradesh According To Groundwater Exploitation As On April 2007 (Terminologies as per Box. 3.1) No. of S. 1 S.N ( Districts ( MandPls I No I Semi-critical I 0 S.N 1 Critical 0 1 S'N 1 Over-exploited I 0 I 11 I Srikalahasti / 1 I 1 Ramasamudram I Samaj Vikas (rnt'o'tr \:+rnal\ rl,ds org) 128

129 Environmental Analysis - Final Report -November 2008 Samaj Vikas (~nlo'lr s~lrn;ll\ ihas ol g) 129

130 Environmental Analysis - Final Report -November 2008 Samaj Vikas (ir~lb/c~.sam;~ivikas.o~~~) 130

131 Samaj Vikas (~nlb'ct sa~llukas or?)

132 (Data source: CGWB-2007) Samaj Vikas (111io/(1 s:1111~111 ikab OIE) 132

133 Environmental Analvsis - Final Revort - November 2008 Annexure 11: Disposal of Reject brine from RO Plant Desalination process with RO plant for treating the brackishlsaline groundwater with high TDS is the solution to supply drinking water to isolated habitations where the groundwater is brackish and supplying water from the distant surface water source is not feasible. Production and disposal of reject brine are an intagxi: part of an overall desalination process. Reject brine is in the range of 4Q :O bo% of the feed water depending upon the TDS of the feed water. For in!zn;nd jiocated away from the sea coast) desalination plants, this poses a serious challenge, as the option of ocean disposal of reject brine is not available. Various disposal options currently used for the reject brine are: disposal in lined evaporation ponds (lined with polyethylene or other polymeric sheets), where land is available disposal in unlined evaporation ponds, where land is available deep well injection after assessment of geological conditions disposal in natural depressions if no drinking water supply is depending on ground water in the vicinity of 100 m. An alternative approach is further processing the reject brine to extract all the salts involving multiple-evaporation andlor cooling, supplemented by chemical processing. However, this may not be economically viable. Of all the disposal options, disposal of brine in lined evaporation ponds is preferable (technologically simple, risk of groundwater contamination is lesser). Samaj Vikas (c!fo'tr 5:imaivil;as or.) 133

134 Environmental Analvsis - Final Re~ort - November 2008 Annexure 12: Guidelines for the Identification and Selection of Water Supply Sources Groundwater aquifers are the main source of water in AP state for tapping water for various uses. The aquifers are classified as confined aquifer and unconfined aquifer. The wells tapping water from confined aquifer are called deep wells, which have the recharge zone far away from the well location. In some locations the water quality of deep wells may have problems (fluoride/salinity/nitrate/iron etc.). The wells tapping water from unconfined aquifer are called shallow wells, which have the recharge zone around the wells. These wells are likely to dry up during summer and liable for contamination from local pollution sources unless they are sanitary protection is provided. Presently the RWSSD broadly follows the below procedure for identification of sources. A. Priority for the selection of sustainable sources for rural water supply 1. Groundwater source with acceptable quality (without any treatment except disinfection). These sources are preferred for single village schemes (SVSs). 2. When option (1) is not possible as the groundwater quality is problematic (fluoride/brackish/nitrate/iron etc.), distant surface water source which requires only simple filtration and disinfection will be preferred. These sources are preferred for multi-village schemes (MVSs) involving number of habitations (MVSs may be located away from the habitations and require treatment and pumping adding to O&M costs). 3. When option (1) and (2) are not possible due to isolation of the habitation and its location at high elevation, and if the local groundwater source is sustainable throughout the year but high TDS (> 2000 mg/l) is the only problem, the local source will be selected. Water from the local source will be treated with innovative technology such as Reverse Osmosis (RO). As RO plants have certain problems (for example, safe disposal of brine) as listed in Annexure 11, this option will be chosen only under exceptional circumstances. B. Water Quality Testing Before selecting the source the raw water quality will be tested to check conformity with the drinking water standards. C. Spacing between'the proposed well and the existing groundwater structure to avoid interference When a new well is located close to an existing well, the cone of influence of both wells may overlap and affect the yielding potential of both the wells. While locating new wells the spacing between new well and the existing well will, therefore, be fixed appropriately. The following table recommends the spacing between the existing groundwater abstraction structures and the proposed wells. S. No. 1. Situation Non-command area Recommended spacing between any two wells (m) Filter point or shallow wells I Deep bore wells 120 ( Samaj Vikas (infoitr samalk &?>AS) 134

135 Environmental Analysis - Final Report -November Command area I Near perennial source like river or pond (within 200 m) I 4. I Non-perennial stream ( Source: NABARD Samaj Vikas (infoitr srl~naivikrlh 11;)

136 Environmental Analysis - Final Report -November 2008 Current Practice Annexure 13: Sanitary Survey of Water Supply Sources The RWSSD has an existing practice of sanitary survey of rural water supply sources while initially installing the source. However annual survey of the sources after installation is not being done systematically. Guidelines for Sanitary Survey in APRWSS The guidelines for Sanitary Survey given in this Annexure are in line with the guidelines documented in the Implementation Manual on National Rziral Water Quality Monitoring and Surveillance Programme published in 2004 by the Rajiv Gandhi National Drinking Water Mission, Department of Drinking Water Supply, Ministry of Rural Development, Government of India. These guidelines will be applied for Sanitary Surveys in the APRWSS. Sampling Frequency SOURCE AND MODE OF WATER SUPPLY Ground Water Shallow tubewells with hand pumps Minimum number of sanitaty inspections per year By CPWSSC, SO By AEE I DEE 4 (including once Once initially (while initially while filling the filling the EDS) and EDS of the scheme) thereafter as situation demands By EE I DSU 1 ~ e &bewells e ~ with 4 (including once Once initially (while1 hand pumps initially while filling the filling the EDS) and EDS of the scheme) thereafter as situation demands Wells and piped supplies 1 (including once 1 (including once Once initially thereafter initially while filling the initially while filling the once every 5 years or as EDS of the scheme) EDS of the scheme) situation demands (Surface Water and/or chlorinated and piped supplies 1 Population upto (including once 2 (including once 1 Once initially thereafter initially while filling the initially while filling the once every 5 years or as EDS of the scheme) EDS of the scheme) situation demands (Population (including once Once a year 1 initially while filling the I EDS of the scheme) - - Community rainwater 1 (including once 1 (including once 1 collection systems initially while filling the initially while filling the EDS of the scheme) EDS of the scheme) 1 Sanitary Survey Procedure and Recording Forms Sanitary inspection requires detailed examination of the water-supply system, especially at its key points in order to check whether the installations are satisfactory and whether the various operations are being carried out properly. The recommended method of undertaking an - I Samaj Vlkas (~nlb iz zarnai, i l a org) 136

137 Environmental Analvsis - Final Report - November 2008 inspection is to follow the natural sequence: starting with the source water and its intake, and going on to treatment, disinfection, storage, distribution, etc. Observations are recorded on preset forms. Formats for various sources are given below: Samaj Vikas ([nth (1 \a~rraiv~kas org)

138 SANITARY SURVEY FOR THE ASSESSMENT OF RISKS OF CONTAMINATION OF DRINKING WATER SOURCES I Type of facility : SHALLOW AND DEEP HANDPUMPS (TUBEWELL) General Information i. Location : Village... : Gram Panchayat..... : District..... ii. CodeNo... HI. Water authority Panchayat President Community Representative Signature iv. Date of Visit v. Is Water Sample Taken Sample No Acceptable/Rejectable 11. Specific Diagnostic Information for Assessment Risks Yes No Is there a latrine with in 10 m of handpump The nearest latrine or ground than the handpump? a pit latrine - that 3. Is there any other source of pollution within 10m of the handpump? 4. Is there any of stagnant water with in 2m of the cement floor of handpump? 5. Is the handpump drainage channel? It is broken perrninege Containment Risk Score: 9:10 = V.high 6-8 = High 3-5 = Intermediate 0-3 = low Number of YES to be counted 111. Result and recommendation: The following importance point of risks (Senirallly from top) were noted and the authority advised on remedial action. - Samaj Vikas (~lfo!c~;sarn;~ivikaz.o~'~)

139 Environmental Analysis - Final Report -November 2008 SANITARY SURVEY FOR THE ASSESSMENT OF RISKS OF CONTAMINATION OF DRINKING WATER SOURCES I Type of facility : DEEP BOREHOLE General Information i. Location : Village..... : Gram Panchayat : Distnct..... ii. Code No Water authority Panchayat President Community Representative Signature iv. Date of Visit v. In Water Sample Taken... Sample NO Acceptable Rejectable 11. Specific Diagnostic Information for Assessment Risks I Yes I No Is there any other source of pollution within 10m of the handpump? Is there any other source of pollution within area of the well? Is the drainage are samed the pumphouse fully? Is there fencing around the installation drainage is any way which allow animals access or any entry? Is the floor of the handpump permanent to water? I I I 8. 1 Is the well seal insanitarv? I 10. Is the free chlorine residual at the sample tap less than 0.2 mgll? Total Score of risks I10 Containment Risk Score: 9-10 = V.high 6-8 = High 3-5 = Intermediate 0-2 = low Number of YES to be counted 111. Result and recommendation: UIUl The following importance points of risk (serially from top) were noted and the authority advised on remedial action. Samaj Vikas (~fih'c~ sarnai\ ikas o1.g) 139

140 SANITARY SURVEY FOR THE ASSESSMENT OF RISKS OF CONTAMINATION OF DRINKING WATER SOURCES I Type of facility : GRAVITY FEED PIPED SUPPLIES General Information i. Location : Village..... : Gram Panchayat..... : District..... ii. Code No iii. Water authority Panchayat President Community Representative Signature iv. Date of Visit v. 1s water Sample Taken... Sample NO Acceptable/Rejectable 11. Specific Diagnostic Information for Assessment Risk Containment Risk Score: 9-10 = V.high 6-8 = High 3-5 = Intermediate 0-2 = low Number of YES to be counted 111. Result and recommendation: UlzU The following importance points of risk (serially from top) were noted and the authority advised on remedial action. Samaj Vikas (III~OI(LS~ITIZLI\ ~ha, erg) 140

141 SANITARY SURVEY FOR THE ASSESSMENT OF RISKS OF CONTAMINATION OF DRINKING WATER SOURCES I Type of facility : RAIN WATER TANK CATCHMENT General Information i. Location : Village..... : Gram Panchayat..... : District... ii. Code No iii. Water authority Panchayat President Community Representative Signature iv. Date of Visit V. 1s Water Sample Taken... Sample NO AcceptableRejectable 11. S~ecific Diannostic Information for Assessment Risks I Yes I No I Containment Risk Score: 9-10 = V.high 6-8 = High 3-5 = Intermediate 0-2 = low Number of YES to be counted 111. Result and recommendation: E m n The following importance points of risk (serially from top) were noted and the authority advised on remedial action. Samaj Vikas (~nto[i sslrncll\ has 012) 141

142 Environmental Analysis - Final Report -November 2008 Annexure 14: Sanitary Protection of Water Supply Sources Presently the RWSSD is following some of the sanitary protection measures given below. The recommended procedures are for strengthening the existing RWSSD practices for ensuring safe quality water supplies. The objectives of sanitary protection of the water supply sources are to avoid the sources getting contaminated. 1. Sanitary Protection of Surface Water Supply Sources The area around the source should be inspected at least once in a year to identify and control any new pollution source. Discharge of industrial/domestic wastewater on the upstream of the off-take arrangement should be prevented. Activities that lead to contamination of the water such as washing clothes, washing cattle, dumping of solid waste and defecation should be prevented. The area around sources including intake arrangements and upstream of river should be well protected and fenced. Trespassing by people and cattle around the source should be prevented. 2. Sanitary Protection of Ground Water Supply Sources 1. Direct runoff of rain water into bore well sources should be prevented; 2. A concrete mat of sufficient thickness for 75 cm radius around the bore well shall be provided to seal the outer periphery of the bore well. The casing pipe should be raised 60 cm above ground level and provided with a sanitary plug until the pump is installed. 3. Rainwater harvesting and recharge structure should be located at least 15 m away from the bore well to avoid direct contamination. 4. Soak pit for the disposal of effluent from septic tank or other sanitation facility should not allowed within 15 m radius from the bore well of water supply source to avoid direct contamination. 5. For bore wells, the annular open space on the outside of the well casing needs to be filled with neat cement grout. 3. Other preventive measures for maintaining quality of drinking water i. Sources of water supply including wells fitted with hand pumps should be disinfected regularly. Free residual chlorine level of not less than 0.2 mg/l and more than 0.5 mg/l should be maintained through out the distribution system ii. OHTs and storage sumps should be periodically cleaned at least once in three months iii. Leakages in pipelines should be arrested iv. Pit taps both at public stand posts and house service connections should be prevented- all taps and stand posts should be above ground level provided with platforms around v. Surroundings of the OHTs, public stand posts and hand pumps should have clean and hygienic environment Samaj Vikas ~ san~;~ivil;a~.org) 142

143 Effects of excess fluoride in water Annexure 15: Fluoride Mitigation Excessive fluoride > 1.5 mg/l in drinking water may cause dental fluorosis, a condition resulting in the discoloration of the enamel, with chipping of the teeth in severe cases, particularly in children. With higher levels of fluorides > 3 mgl, skeletal fluorosis with its crippling effects is observed. Non-skeletal and allergic manifestations of fluorosis can also occur. The effects of fluorosis are irreversible and there is no treatment. Avoiding excessive intake of fluoride can help in prevention. Fluorides are present mostly in ground waters and high concentrations have been found in Prakasam, Nalgonda, Khammam, Ranga Reddy, Kurnool, Karirnnagar and Anantapur districts of Andhra Pradesh. Strategy for mitigation When high levels of fluoride are detected in local ground waters, the ideal course of action to take would be: 1. Using alternate water sources. 2. Improving the nutritional status of the population at risk. 3. Removing excess fluoride (defluoridation). Experience with Mitigation in Andhra Pradesh 1. Using alternate water sources: In the table below, the number of fluoride affected habitations has reduced from 12,068 habitations (or 17%) in 1990 to 1,269 habitations (or 1.8%) in 2005 as a result of supply of alternate water sources. However, in some districts (including the worst-affected Prakasam, Nalgonda and Ananthapur) the fluoride problem is yet to be addressed completely. Status of NSS Habitations (Fluoride) in Andhra pradesh3' Fluoride Habitations Number of affected mandals Identified in Remaining Not Covered in October 2005 Not Covered % out of habitations 30 RWSSD, 2006 as quoted in Hutchison, A. 2006, An Investigation into Groundwater DeJluoridation Techniques and Management in Andhra Pradesh, India. M.Sc. Thesis. Cranfield University. Sarnaj Vikas (~nlbrtr.;a~nal>ikax or.)

144 Environmental Analvsis - Final Reuort -November 2008 Srikakulam Vizianagaram Visakhapatnam East Godavari West Godavari Krishna Guntur Prakasam Nellore Chittoor Kadapha Ananthapur Kurnool Mahabubnagar Ranga Reddy Medak Nizamabad Adilabad Karirnnagar Warangal Khammam Nalgonda TOTAL The Government of Andhra Pradesh under the Medium Term Sector Program (MTSP) plans to provide safe and adequate water supply to 100% of the Not Covered (NC) and No Safe Source (NSS) habitations and 12% of the PC habitations by Of this, the APRWSS project aims at covering a total of 2,843 habitations, including: 1878 Not Covered (NC), 199 No Safe Source (NSS) and 766 Partially Covered (PC) habitations. Thus, all the NSS

145 Environmental Analysis - Final Report -November 2008 habitations (including fluoride affected habitations) are planned to be covered with safe water supply schemes. However, there may still exist a need for alternate water sources in view of seasonal disruptions in water supply, remoteness of certain habitations preventing coverage by a supply scheme, etc. 2. Alternate water sources include surface water, rainwater and low-fluoride groundwater. The Government of Andhra Pradesh has explored the use of rooftop rainwater harvesting structures for fluoride mitigation. For example, in 2006, the state government had approved installation of rooftop rainwater, harvesting structures for individual households in the most fluoride affected districts of Anantapur, Nalgonda and Prakasam. 3. Removing excess fluoride (defluoridation): The following table gives an overview of the various defluoridation technologies that have been implemented in Aridhra Pradesh. Defluoridation Process Activated Alumina Nalgonda technique Principle Adsorption Coagulation and precipitation using alum and lime Advantages Removes fluoride up to 90%. Treatment is costeffective. I Limitations Sensitive to ph fluctuations, TDS, presence of other elements, etc. Regeneration needed every 4-5 months. Effectiveness reduces with each regeneration. Disposal of fluoride sludge is a problem. Does not involve Removes only I regeneration of 18-33% of media. fluoride. Employs Regular analysis chemicals which of feed and are readily treated water is available. Colour, required to odour, turbidity, calculate the bacteria and correct dose of organic chemicals to be contaminants are added, because Experience in AP Both community scale treatment plants as well as domestic defluoridation units (DDFs) for individual households promoted by both Government and NGOs (DDFs were distributed to BPL households in Ananthapur, Nalgonda, Guntur, Prakasam, Karimnagar, Warangal and Ranga Reddy). Some are in operation. Both hand pump attached plants as well as large community treatment plants (fill and draw type) were installed. However the majority are now inoperative Samaj Vikas (hfoilz sa111i1jvikw.c~rg) 145

146 Environmental Analysis - Final Report -November 2008 RO membrane process Bone Charcoal Physical filtration through semipermeable membrane Adsorption Flouride removal (up to 98%) and disinfection are achieved simultaneously. Low maintenence and regeneration requirements. Efficiency of the material in fluoride removal is independent of raw water characteristics such as hardness and alkalinity. water quality changes with time and season. High maintenance costs. Large space requirement for drying of sludge. Expensive. Nearly all ions are removed so remineralization and ph correction may be needed. Lot of waste brine water is generated and its disposal poses a problem. There is no technology to regenerate used bone char, so the material must be replaced periodically. Community operated plants and plants run by private entrepreuners are in existence. Community defluoridation units installed - some are in operation. Recommended Strategy for Flouride Mitigation In any attempt to mitigate fluoride contamination, it is recommended that the provision of safe, low fluoride water from alternative sources, either as an alternative source or for blending, should be investigated as the first option3'. The following table presents the available options for fluoride affected villages and the situation for which they seem appropriate. Recommended Options for Fluoride Affected Villages 1 Available options I Situation for which the option seems appropriate 1. Alternate local 1 distant ground water Where isolated small number of source (with appropriate water 1 habitations are affected recharge arrangements) 2. Localldistant surface source Where large number of contiguous World Health Organization (WHO). Fluoride in Drinking-water by J. Fawell, K. Bailey, J. Chilton, E. Dahi, L. Fewtrell and Y. Magara. - - Samaj Vikas (i t~fo;~~, s:iln:l iiii(11:g)

147 Andhra Pradesh Rural Water Supply and Sanitation Projecf villages are affected 3. Blending with non-fluoride water wherever Where fluoride concentration is feasible I marginally higher (1.5-2 mg/l) and fluoride free water is available 4. Dual supply with different service level (drinking, cooking and other purposes) Where community is aware and able to distinguish the difference (on pilot basis) J Information, Education, Communication (IEC): In addition to providing alternative safe water, the project will focus on creating awareness on fluoride in the affected habitations. The focus of the IEC efforts will be on generating awareness: fluoride, flurosis and flurosis prevention the role of nutrition (reducing fluoride-rich foods and cosmetics, intake of calcium and Vitamin C rich foods, etc.) in fluoride mitigation the need for use of alternate safe water sources identification of unsafe water and need to discontinue its use for consumption The IEC on fluoride will be part of the overall IEC strategy of the project. Samaj Vikas (Illfotr sarn;il\ ~h,\s or

148 - Andhra Pradesh Rural Water Supply and Sanitation Project Annexure 16: Guidelines for Sustainability of Groundwater Sources Existing Practices in Ground Water Recharge in Andhra Pradesh The RWSS Department, Government of Andhra Pradesh has implemented schemes involving several different types of water harvesting structures (depending on the local site conditions). These include: Check Dams Percolation Tanks Sub-surface Dykes Rooftop Rain Water Harvesting Structures Infiltration Rings Recharge Pits Injection WellsIRecharge Wells Guidelines for Ground Water Recharge in APRWSS The guidelines presented in this Annexure are based on the guidelines provided in the publication Water Harvesting and Artijcial Recharge published by the Rajiv Gandhi National Drinking Water Mission, Department of Drinking Water Supply, Ministry of Rural Development, Government of India (2004). These guidelines will be followed in the APRWSS. The Recommended Water Harvesting Measures for Andhra Pradesh are presented in the following table. Agro-climatic zone South-Central Deccan Plateau Zone South-Eastern Brown Red Soil Zone Eastern Coromandal Recommended water harvesting measures for Andhra pradesh3' Region in Andhra Pradesh Deccan plateau Part of the plains (excluding the 4-5 krn wide coastal belt) Entire coastal belt Recommended water harvesting structures Ponds I Check dams Percolation tanks Bandhara Gully plugging Sub-surface dams Contour bunding -- ~ Traditional ponds, tanks Percolation tanks and Sub-surface dams in the vicinity of drinking water sources like dug wells, hand pumps and tube wells Ponds, tanks, kuntas Nadi Check dams Percolation tanks Sub-surface dams Gully plugging 32 Department of Drinking Water Supply, Ministry of Rural Development, Government of India, 2004 Samaj Vikas (i~ilb:~-sani;~ivik~~.c~!:g) 148

149 Environmental Analysis - Final Report -November 2008 Roof Top Water Harvesting Systems Roof top water harvesting systems can provide good quality potable water with the design features outlined below are taken into account: The substances that go into the making the roof should be non-toxic in nature Roof surfaces should be smooth, hard and dense since they are easier to clean and are less likely to the damage and released material / fiber into the water. Roof painting is not advisable since most paints contain toxic substances and may peel off. No overhanging tree should be left near the roof. The nesting of birds on the roof should be prevented. All gutter ends should be fitted with a wire mesh screen to keep out leaves etc. A first-flush rainfall capacity, such as detachable down pipe section, should be installed. A hygienic soak away channel should be built at water outlet and a screened overflow pipe should be provided. The storage tank should have a tight fitting roof that excludes light a, manhole cover and a flushing pipe at the base of the tank (for standing tanks). There should be a reliable sanitary extraction device such as a gravity tap or a hand pump to avoid contamination of the water in the tank. There should be no possibility of contaminated wastewater flowing into the tank (especially for tanks installed at ground level) Water from other sources, unless it is reliable source, should not be emptied into the tank through pipe connections or the manhole cover. During the rainy season, the whole system (roof catchment, gutters, pipes, screens, first-flush and overflow) should be checked before and after each rain and preferably cleaned after every dry period exceeding a month. At the end of the dry season and just before the first shower of rain is anticipated, the storage tank should be scrubbed and flushed all sediment and debris (the tank should be re-filled afterwards with a few centimeters of clean water to prevent cracking). Ensure timely service (before the first rains are due) of all tanks features, including replacement of all worm screened and servicing of the outlet tap or handpump. Percolation Tanks Percolation tanks should normally be constructed in a terrain with highly fractured and weathered rock for speedy recharges; in case of alluvium the bouldary formations are ideal. However, the permeability shouldn't be to high that may result in the percolated water escaping the downstream. Submergence area should be uncultivated as far as possible. Rainfall pattern based on long-term evaluation is to be studied so that the percolation tanks gets filled up fully during mansoon ( preferably more than once) Soil in the catchment area should preferably be of light sandy type to avoid silting upon the tank bed. The location of the tank should preferably be downstream of runoff zone or in the upper part of the transition zone, with a land slope gradient of 3 to 5%. Samaj Vikas (ililbrir saln:~ivilas.oi.g) 149

150 Check Dams While designed, due care should be taken to keep the height of the ponded water column about 3 to 4.5 m above the bed level. It desirable to exhaust the storage by February since evaporation losses becomes substantial from February on wards. It is preferable that in the downstream area, the water table it is depth of 3 to 5 m below level during the post monsoon period, impaling that the benefited area possesses a potential shallow aquifer. Construction-wise there is not much difference between a percolation tank and a minor irrigation tank, except for providing outlets for surface irrigation and the depth of the cut-off trench. The cut-off trench is to be provided below the earthen bund with depth limited to one fourth of the height between bed level and full storage level. Check Dams are constructed in the drainage course of narrow streams in low rainfall area to impound run-off rainwater. The following are some guidelines for consturcin of check dams. The total catchment of the nala should normally be between 40 to 100 hectares though the local situations can be guiding factor in this The rainfall in the catchment should be less than 1000mm/ annum The Nala bunds should be preferable located in area where contour or graded bunding of lands have been carried out The rock strata exposed in the ponded area should be adequately permeable to cause ground water recharge through ponded water Nala bund is generally a small earthen dam with cutoff core wall of bricks work, though masonry and concrete bunds/plugs are now prevalent Dams should be built at sites that can produce relatively high depth to surface area so as to minimize evaporation loses. Rocky surface should not be fractured or cracked, which may cause the water to leak away to deeper zones or beneath the dam. Dam foundation must of solid impermeable rock with no soil pockets or fracture line No soil erosion in the catchment area Dams should be site along the edges of depressions or directly across the lower ends of deep gullies into rock. Ponds/ Tanks A good pond should possess the following traits: The site should be narrow gorge with a fan shaped valley above: so that amount of earthwork gives a large capacity. Junctions of two tributaries, depressions and other sites of easily available fill material and favourable geology should be preferred The capacity catchment ratio should be such that the pond can be fill upto about 2-3 months of rainfall. The capacity should not be too small to be choked up with sediments very soon The pond should be located where it could serve a major purpose e.g. if irrigation it should be above irrigated field The site should not have excessive seepage losses The catchment areas should be put under conservative practices Samaj Vikas (info:i~ samai\:ikaa.o~'g) 150

151 Bandhara The following care need to be taken in maintaining Bandhras: Nadis Periodically it should be checked for seepage of surface pollutants Periodic checking of the dam site for erosion after each large flood and correction by refinishing the clay and protecting it with large rocks. Any any channel erosion that might undermine or expose the dam should be arrested by filling it with large boulders and using silting traps to catch sandy material. With raised dams, the gravity pipe should be checked frequently along its length for signs of damage or leaks and the tapping station should be kept in good order. Ensure there is no open defecation idnear the river bed upstream No tethering of animals at the well Check bathing1 laundry upstream of the dam There must be no pit-latrines on the bank upstream There must be no unprotected wells in the river bed near the protected well Regular maintenance of the protected well-site and the hand pump must be assured Ensure use and maintenance of a downstream gravity out-take Avoid use of pesticides1 chemicals upstream of the dam site Precaution should be taken while adopting Nadis due to poor maintenance and improper utilization, the Nadi water is highly polluted and is not free from health hazards. Periodically test water to ensure guinea worm not present. Make sure that water hyacinth, mosses, algae etc. does not grow. Gully plugging, Contour bunds The gully plugging measures includes vegetative plantings and brushwood check dams, boulder bunds, brick masonry and earthen bunds or a combination of both, sand bag plugs etc. Contour bunds involve construction of horizontal lines of small earthen or boulder bunds across the slopping land surface. Ensure there is no open defecation idnear strucrture No tethering of animals at the site There must be no pit-latrines on the bank upstream Avoid use of pesticides1 chemicals upstream of the site Rainwater Harvesting Structures Guidelines for Implementation of Rainwater Harvesting Structures for Sustainability of Drinking water supply sources: Samaj Vikas (~nfo~ci samaix ika> ow) 151

152 The rainwater harvesting (RWH) structures should be site specific closer to the source but 15 m away from the bore well to prevent direct contamination; the location should be certified by the hydrogeologist of the APRWSS department. The local geological and hydrogeological conditions have to be studied in conjunction with the location of the groundwater source to facilitate maximum recharge from the structure. No RWH structure should be installed in the supplylfeeder channel of tanks. RWH structure should be simple and suitable to the location and economically viable to the community. All the works of RWH structure should be implemented before the onset of the monsoon. Pre and post water level and water quality monitoring should be camed out in the well for water supply source to evaluate the benefit accrued of the RWH structures. Erosion control in catchment There is no unique solution for erosion control. The following are some of the erosion control measures used in many parts of the country. Conservation cover: Establish and maintain perennial vegetative cover to protect soil and water resources. Contour bundingttrenching: Forming contour bunding or trenching along the contour in steep sloped areas may be taken up for reducing runoff and erosion. Terraces are constructed with earthen embankments that retard runoff and reduce erosion by breaking the slope into numerous flat surfaces separated by slopes that are protected with permanent vegetation. Critical area planting: Planting vegetation such as trees, shrubs, grasses or legumes on highly erodable or eroding areas. While undertaking any plantation programme care must be taken to plant only indigenous species with involving and close coordination with local people Samaj Vikas (inf~~:trsamaivik~~s_~~~)

153 Annexure 17: Selection of Safe Sanitation Technologies and Environmental Considerations in Location of Toilets Selection of Safe Sanitation Technology Selection and installation of safe sanitation technologies to suit the local soil characteristics and hydrogeology is necessary so as to minimise ground water contamination. For selecting the most appropriate system for any location the following factors are to be considered: Number of people to be served Per capita water supply rate and the water availability for ablution and flushing Extent of space available within the plodstreet for sanitation facility Hydrogeologic characteristics of the subsoil Depth to groundwater table from the ground surface (summer and rainy season) Quality of groundwater in the vicinity and their present uses Locations of the existing water supply wells sources Latrine Type Direct Single Pit Latrine Without Pour flush Direct Twin Pit Latrine Without Pour flush Offset Single Pit Latrine with Pour-flush Offset Twin Pit Latrine Suitable for high Ground Water table Yes, if raised flush Solar Heated 1 Single-vault eco-sanitary latrine with urine separation Yes Single-vault ecosanitary latrine with Yes Suitable for areas prone to floods, tidal floods or flushes Yes, if raised Yes, if raised Yes, if raised Yes, if raised and with soak away 1 Yes, if raised Yes, if raised and Technology Different Suitable for soils Suitable of low for loose permeabil soils ity Yes, if fillly clay soils lined Yes, for fillly lined Yes, for fillly lined Not for Not for, clay soils Yes, with soak away with Pour- 1 with soak Yes, with away ( Yes, if raised 1 lined I soak away Yes Yes Yes requi nt No 1 No Yes uction Easy 1 Easy Fairly Easy Ease of ance Easy 1 EASY Fairly 1 1 Difficult Difficult 1 ge : : : Remarks Sludge unsafe Safe sludge easy Safe dehydrate 1 "a1 dehydrate d material Samaj Vikas (info<tisam;~ivikar.(~) 153

154 1 Andhra Pradesh Rural Water Supply and Sanitation Project urine separation Urinal Yes Yes Yes Yes Yes a bit Easy Easy Considering the various sanitation options available and the factors to be considered, the following on-site sanitation options are recommended as suitable sanitation for the rural habitations: two-pit pour-flush toilet (TPPT) composting toilet or eco-sanitation (Eco-san) The SOs should play a crucial role in facilitating the choice of appropriate sanitation system for the site specific situation. Environmental Considerations in Location of Toilets Specific topic on which information/ data is needed Type of soil -stability Loose, sides of wall collapse Hard to dig permeability (how water is absoorder by soil) Clay soil oarses sand - Hard Latrine Ground water level in wet season (deepest level) Water rises higher than one meter from bottom of the latrine pit,-but never completely floods the latrine pits Water rises to or above the ground level and sludge comes out the latrines Distance to Water sources Distance from latrines pit to drinking water sources I Considerations Line the pits. In very sandy soils,sink cement rings that are perforated or set on top of each other without cement. Use the pits. In very sandy soils, sink cement rings that are perforated or set on top of each other without cement. I Test by pouring water into a hole and measuring how long it takes to be absorbed. Pits in dense clay may need back filling about 1.2 meters with more sandy soil. Back fill around the rings with denser soil and lor locate the latrine pipes far 9 for example, 40 meters or more)from a well used for 1 drinking. I If there might be cracks in the laterine, the latrine pits can pollute nearby drinking water sources. Place the latrine far from these sources. Locate thelatrine pit far from any well used for drinking purpose and should be away for example, 40 meters or more Raise the latrines above the ground level so that the top third of the pit is always above the water level. Place latrines far from drinking water sources. I At least 15 meters Samaj Vikas (& samalr ~l~b-ol~)

155 Environmental Analysis - Final Report -November 2008 Children or teachers may be spent extra time, for example, more than 15 minutes going one-way to collect water. VIP latrine is preferred as it uses less water. Samaj Vikas (~nfoicz san~al~~kas erg) 15.5

156 Environmental Analysis - Final Report -November 2008 Annexure 18: Recommended Construction Practice and Pollution Safeguards for Twin Pit Pour Flush ~atrines" Construction of Pits 1. Pits in Water logged, Flood Prone and High Sub-soil Water Areas In high sub-soil, water logged or flood-prone areas, the pits should be raised above the ground level to a height such that the invert of the incoming drainslpipes is just above the likely flood water or sub-soil water level. Raising the pipes will necessitate raising the latrine floor also. In pits located in water logged or flood prone areas, earth should be filled and well compacted all around the pits in 1000 mm width and up to the top. It is not necessary to raise the pits by more than 300 rnm above the plinth of the house. In these situations, the pits should be designed as wet pits, taking into consideration the infiltration rate of the type of soil. 2. Pits in Rocky Strata In rocky strata with soil layers in between, leach pits are designed on the same principles as those for low sub-soil water level taking the infiltration capacity of the soil as 20 litres per sq.m per day. However, in rocks with fissures, chalk formations, or old root channels, pollution can flow over a very long distance; hence these conditions demand careful investigation and adoption of pollution safeguards. In impervious rocky strata the pits will function as holding tanks since there will be no infiltration of liquid. In such situations, a PF latrine with leaching pits is not a suitable system. 3. Pits in Soils with Low Infiltration Capacity Leaching capacity tends to be the limiting factor when the infiltration capacity of soil is low. In these circumstances, there are two options: construct a larger pit, or increase the critical leaching area by backfilling and compacting with brick ballast, gravel, sand etc., for the required width all around the pit. Emptying of PitsISeptic tanks Emptying of pits becomes essential when they get filled. The three most important issues related to emptying of pits are frequency, cost, and hygiene. Manual methods of emptying are common for pour-flush latrines. The responsibility for emptying latrines is with the users. The main guidelines relating to latrine emptying include Advising householders that the filling1 emptying cycle is likely to be between three to six years and that they need to make their own arrangements for emptying the pits. Emptying costs are location-specific; anticipated emptying costs should be ascertained with local contractors during programme planning. Groundwater pollution Technical Guidelines on Twin Pit Pour Flush Latrines (1992), Ministry of Urban Development, Government of India Samaj Vikas (info~sanii~il~ii;:~~.(~~_g) 156

157 A problem that is related to on-site sanitation is the potential for pollution of groundwater that is associated with these systems. Groundwater under or near pit latrines may become polluted, which can be a serious problem when it affects the quality of drinking-water drawn from wells and boreholes. Water in leaky pipes may also be contaminated if the pressure drops and polluted groundwater levels are above the pipes. A particular problem in densely populated areas is the possible proximity of latrine pits and shallow wells on neighbouring plots. The key guideline is that a minimum distance of 15 m, other than in fractured formations, between a pit and a downstream water-point, is normally sufficient to remove all contaminants. Pollution safeguards for twin pit pour flush latrines To ensure that the risk of polluting ground water and drinking water sources is minimal, the following safeguards should be taken while locating the pits of the pour flush latrines: Drinking water should be obtained from another source or from the same aquifer but at a point beyond the reach of any fecal pollution from the leach pits. If the soil is fine (effective size 0.2 rnm or less), the pits can be located at a minimum distance of 3 m from the drinking water sources, provided the maximum ground water level throughout the year is 2 m or more below the pit bottom (low water table). If the water table is higher, i.e., less than 2 m below the pit bottom, the safe distance should be increased to 10 m. If the soil is coarse (effective size more than 0.2 mm), the same safe distances as specified above can be maintained by providing a 500 rnrn thick sand envelope, of fine sand of 0.2 mrn effective size, all around the pit, and sealing the bottom of the pit with an impervious material such as puddle clay, a plastic sheet, lean cement concrete, or cement stabilized soil. If the pits are located under a footpath or a road, or if a water supply main is within a distance of 3 m from the pits, the invert level of the pipes or drains connecting the leach pits should be kept below the level of the water main, or 1 m below the ground level. If this is not possible due to site considerations, the joints of the water main should be encased in concrete. Operation and Maintenance - Dos and Don't s of Twin-pit Pour-flush Latrines Keep a bucket full of water outside the toilet. Keep a 2 liters can in the toilet filled with water for fushing. Before use, pour a little quantity of water to wet the pan so that excreta can slide smoothly into the pit. Flush the excreta after each use. o Pour a little quantity of water, say half a liter, in the squatting pan after urination. o The squatting pan should be cleaned daily with a soft broom or soft brush with a long handle after sprinkling a small quantity of water and detergent powderlsoap. Samaj Vikas (1nFo (L sarn'ii~ ihas osg)

158 DON'T s o Use minimum quantity of water in washing the pan and toilet floor. o Wash hands, using soap or ash, after defecation at the assigned place. o If any construction defect is observed during the defect-liability period, report the matter to the local authority or the construction agency. o When the pit in use is full, divert the flow to the second pit o If the trap gets choked, rodding should be done from the pan side as well as from the rear side by means of a split bamboo stick, after removing the cover of the drain or junction chamber. Care should be taken while desludging the pits located in water-logged or high water sub-soil water areas and in case of combined pits, as humus may not be safe for handling. Do not use both the pits at the same time. Do not use more than 2 litres of water for each flushing (if the waste is not flushed with 2 litres, pour more water at the specific spots for flushing the waste). Do not use caustic soda or acid for cleaning the pan. Do not throw sweepings, vegetable or fruit peelings, rags, cotton waste, and cleaning materials like corn cobs, mud balls, stone pieces, leaves, etc. in the pan or the pits. Do not allow rain water, kitchen or bath waste to enter the pits. Do not provide water tap in the toilet. Do not throw lighted cigarette butts in the pan. Do not desludge the pit before 1% years of its being in use. Samaj Vikas (IIII~o~(~ bani;^^^ ~ b urz) a ~ 158

159 Annexure 19: Guidelines for Safe Sullage Disposal at Household and Community Levels 1.0 Introduction The APRWSS will undertake the following sullage disposal activities during the project period: Drains and liquid waste disposal in 55 major Gram Panchayats 2843 soak pits at household level in Gram Panchayats Underground drainage and liquid waste disposal in 55 mandal head quarters The guidelines in this annexure on sullage disposal at household and community levels are based on the guidelines in the publication - 'Solid and Liquid Waste Management in Rural Areas - A Technical Note' (TSC, UNIECF). These guidelines will apply to the sullage disposal activities undertaken in the APRWSS. 2.0 Technical options for household level management The village level water management system should be as simple as possible for a village level person to understand and implement and it should be decentralized. The technological options should based on domestic (Household) level management and/ or community level management. It will always be better to manage and treat domestic greywater generated in the house in the area,courtyard/land surrounding the house. The following technological options will be suitable for this purpose: Kitchen Garden with piped root zone system Kitchen Garden without piped root zone system Leach pit Soakage pit. Out of these options only soak pits are planned in APRWSS. There is a possibility that the other options may be taken up as innovative sub-projects. 3.0 Soak Pit Soak pit is a dug out pit.lled with stones or preferably over burnt bricks. The large numbers of stones or bricks increase the surface area over which biological and chemical action takes place. The water seeps into the ground and reduces danger of polluting the ground water sources. Advantages This is the cheapest technology for management of water at household level Prevents greywater stagnation Prevents vector breading. Operation and maintenance (O&M) Samaj Vikas (hfoicr sainalb ihas org) 159

160 Environmental Analysis - Final Report -November 2008 Filter to be cleaned every fortnight or month, depending on accumulation of dirt Make a hook of thick wire and pierce it in the.lter and take.lter media out and cleanlwash it and dry and replace it in the earthen pot Soak pit looses its capacity within a period of 7 to 8 years of work. At that time take out the boulders from the pit, scrap the walls of the pit in order to remove the oily layer; let the pit dry for a period of 2 to 3 days and clean and dry the boulders and replace into the pit. Limitations Soakage pit is not suitable for rocky terrain It will over.ow if wastewater.ow in the pit exceeds the design.ow If suspended solids get into the pit, the choking of the pit will take place earlier. 4.0 Off Site Community Level Management: For the community greywater of this type, the.rst step would be to establish a system for collecting and transporting this greywater for the final treatment on a suitable location. It will be necessary to establish a suitable drainage system for this purpose. This drainage system could be of two types a. Open drain with technically sound design, involving semicircular base and trapezoidal cross section so as to maximize self cleansing velocity for carrying away silt in greywater b. Closed drain-small bore greywater draining system with intercepting tanks at suitable points. 1. Open or Surface Greywater Drainage System For collection and transportation of greywater.owing out from the houses, surface drain has been the simplest system, whereby, the community greywater is carried away from the village for onward.nal treatment. This system can be established easily with available local mason at minimum cost. Operation and maintenance (O&M) Gram Panchayat will have to establish a system for periodical cleaning and silt removal from the drain Community will have to be educated to keep the drain free from garbage, so as to avoid blockages in drain Care needs to be taken to avoid over. flow water (effluent) from septic tank, from.owing to the open drain. This effluent should be led to leach pit covered at the top. 2. Closed Drainage a. Small bore greywater drainage system Samaj Vikas (~nt'o(i balnalv~ k a m ) 160

161 Environmental Analysis - Final Report -November n rural areas, closed drain system alun to conventional sewerage systems will not be feasible because of the excessive capital & operation maintenance expenditure and the elaborate maintenance requirements. The small bore greywater drainage system which is laid close to the soil surface is suitable and appropriate as it is low cost and requires minimum maintenance which is easy. Advantages: As the system is closed, materials like garbage, road side solid wastes, plastics, building materials etc. will not.nd access to the system Operation and maintenance becomes easily manageable by Gram Panchayat Construction cost is comparable to the cost for surface drain. It may be only marginally varying Road space is fully utilized. 5.0 Final Treatment of Community Greywater Once the community greywater is collected at one or multiple points outside the village, final treatment is required to convert it into harmless and reusable water. The treatment technologies need to suit the following requirements. As low cost as possible O&M should be easy and low cost for Gram Panchayat Same cost recovery may be possible by the farmers Selling the treated water. Treated water could be used for public gardens or horticulture. The produce may be sold portably Vector breeding is avoided Pollution of water from nala or river is prevented. Some appropriate technologies easily manageable by Gram Panchayat could be as follows: o Sullage stabilization pound and reuse o Sedimentation and.itration and reuse o Screening stabilization tank systems like DOSIWAM, DEWATS etc. A. Sullage Stabilization Ponds The greywater collected via drainage system is passed to large shallow basins or ponds excavated at suitable land site and placed serially as a stabilization system in which greywater is stabilized, its pathogenicity is reduced and the stabilized water becomes useable. a. Anaerobic ponds The greywater reaching the pond via drain, usually has high solid content. In the anaerobic pond, these solids settle at the bottom, where these are digested anaerobically. Thus, the partially clari.ed liquid is discharged onwards into a facultative pond for further treatment. b. Facultative ponds The partially clari.ed water is led to facultative pond. 1n this pond oxidation of greywater takes place. It is called 'facultative' because in this pond in the upper layer aerobic conditions are maintained while in the lower layer, anaerobic conditions exist. Samaj Vikas (~nfo tr san~i~~v~ha~ org) 161

162 Environmental Analysis - Final Report -November 2008 c. Maturation pond The stabilized water from facultative pond is led to a maturation pond. The main function of the maturation period is the destruction of pathogens. This pond is wholly aerobic. Operation and maintenance It will be the responsibility of GP Maintenance requirements are minimal. Regular cutting of grass on embankments and removal of any.oating scum from pond surface are the only requirements Occasional anti mosquito spraying treatment may be necessary. B. Screening, Sedimentation and Filtration The greywater collected from drainage system can be passed through a screening, sedimentation and filtration tank system. The treated water can be used for irrigation etc. C. Reuse of Stabilized Water Greywater stabilized and cleaned by the use of any of the above mentioned systems can be reused in many ways. Irrigation for agricultural use Irrigation for horticulture Fish farming. - Samaj Vikas (1jlfi1(1 \;~ITI~IIVI~L~~ 01%)

163 Annexure 20: Guidelines for Community Solid Waste Management 1.0 Introduciton The APRWSS will undertake the following solid waste disposal activities during the project period: Solid waste disposal in 55 major Gram Panchayats Solid waste disposal in 55 mandal head quarters The guidelines in this annexure on solid waste disposal at household and community levels are based on the guidelines in the publication - 'Solid and Liquid Waste Management in Rural Areas - A Technical Note' (TSC, UNIECF). These guidelines will apply to the solid disposal activities undertaken in the APRWSS. Types of Solid Waste Biodegradable and recyclable Kitchen waste Food Cow dunglanimal waste Agriculture Leaves Egg cells Henna paste Vegetable Peels, Meat, Bones Dead animals Paper Wood Non-biodegradable Recyclable Plastic - carry bags, milk covers PVC pipes etc. Syringes, Glucose bottles etc. Cotton and nylon cloth Tyres & Tubes Shampoo Bottles Glass Bookslnotebook Wires Caps of mineral water bottles Plastic Tin can Metal Ashldirt Non-recyclable Nitrozen sealed packing for chi~s Tetrapacks Thermo cal Carbon paper Plastic coated visiting cards Sachets Modern packing materials (plastic) for food packing PET mineral water bottles 2.0 Approaches for Solid Waste Management For effective management of solid waste in rural areas, focus should be on management at household level. That which cannot be managed at household level should be managed at the community level. In general, the following approach should be followed: Segregation of solid waste at the household level (Biodegradable and non biodegradable) Reuse of non biodegradable waste at the household level to the extent possible Household level treatment of bio degradable waste Collection and transportation of segregated waste at the household level to a place identified at the community level (in cases where household level treatment is not possible) Community level treatment or recyclinglreuse of waste l d w l a a t l d ~ ~ ~. ~ I sddrrtr *-mu- ebaor*kb*. r r""""" ~~srrtnlnqdi *wmp dulm Samaj Vikas (!gtm.qa~~~:~lvika> erg) 163

164 o All the biodegradable waste should be composted at the community level o Non biodegradable waste may be further segregated and sold or recycled o Waste which cannot be composted, reused or recycled may be disposed at the land.11 sites following appropriate procedure, (such waste may usually be construction waste, debris etc). 3.0 Community level composting Community level composting may be resorted to when management of solid waste at household level is not possible. For community level composting, Panchayat should select a suitable site as Compost Yard for the village. Site should be selected taking into consideration wind flow direction, so that the inhabited areas don't get any foul odour. The site should be easily accessible for transportation of waste and manure. It should not be a low lying area to avoid water logging. A. Underground unlined manure pit or garbage pit: This is applicable for rural areas with low rainfall and villages where there is lack of space at household level for composting. This is not suitable for heavy rainfall areas and rocky terrain. Use and maintenance of the pits Go on adding collected garbage in the pits (only biodegradable type) Wherever possible, it is advisable to add cow dung slurry to the garbage to enhance the composting process Spread a very thin layer of soil over it (once a week) to avoid odour &.y nuisance Continue to add garbage everyday Follow the above procedure & repeat the layers till the pit is full. It is recommended to.i1 the pit up to about 300mm above ground level After 3-4 days the garbage above ground settles down Plaster it with soil Leave the pit as it is for 3-6 months for maturation and start other pits sequentially After 3-6 months take out the compost & use it in the.fields. B. Under ground brick lined manure pit or garbage pit: This is applicable for rural areas with low rainfall and villages where there is lack of space at household level for composting. This is not suitable for heavy rainfall areas and rocky terrain and is a capital intensive option Use and maintenance of the pit Go on adding collected garbage from the houses in the pits (only biodegradable type) Wherever possible, it is advisable to add cow dung sluny to the garbage to enhance the composting process Spread a very thin layer of soil over it (once a week) to avoid avoid odour & fly nuisance Continue to add garbage everyday Follow the above procedure & repeat the layers till the pit is full. It is recommended to.ll the pit up to about 300mm above ground level After 3-4 days the garbage above ground settles down Plaster it with soil Leave the pit as it is for 3-6 months for maturation and start other pits sequentially After 3-6 months take out the compost & use it in the.elds. - - Samaj Vikas (~lfoiiiis:~~~~:~irikls.c~r..) 164

165 C. Overground heap: This is applicable for rural areas with high rainfall and rocky terrain and for villages where there is lack of space at household level for composting. Use and maintenance of the heap Go on adding garbage collected from the houses over the platform (only biodegradable type) Wherever possible, it is advisable to add cow dung slurry to the garbage to enhance the composting process Spread a very thin layer of soil over it (once a week) to avoid odour &.y nuisance Continue to add garbage everyday The heaps should be sprinkled with water periodically to maintain the moisture level Follow the above procedure & repeat the layers till the heap attains the height of 0.8m After 3-4 days the garbage above ground settles down Plaster it with soil Leave the heap as it is for 3-6 months for maturation and start another heap After 3-6 months take out the compost & use it in the.elds Till the manure in the heap matures, make another heap of the same dimensions at a minimum distance of lm from the.rst heap. D. Overground brick lined compost tank: This is applicable for rural areas with high rainfall and rocky terrain and for villages where there is lack of space at household level for composting. Use and maintenance of the tank Go on adding collected garbage from the houses in the tank (only biodegradable type) Wherever possible, it is advisable to add cow dung slurry to the garbage to enhance the composting process Spread a very thin (1-2 inch) layer of soil over it (once a week) to avoid odour &.y nuisance Continue to add garbage everyday Follow the above procedure & repeat the layers till the heap attains the height of lm After 3-4 days the garbage above ground settles down Plaster it with soil Leave the heap as it is for 3-6 months for maturation After 3-6 months take out the compost & use it in the.elds Till the manure in the tank matures, make another tank of the same dimensions at a minimum distance of lm from the first tank. 4.0 Vermicomposting at Community Level The following steps need to be followed for vermicomposting at community level: Appropriate site selection: the site should be protected from direct sunlight and should not be in low lying areas Vermiculture site preparation; Proper ramming of soil or preparation of platform is required before preparation of vermicompost beds Samaj Vikas (infohl.sam~livik;~s.ol.~) 165

166 Construction of appropriate shed: thatched roof/tin sheds on bamboolmetal poles with proper slope to drain rain water, and proper ventilation The biodegradable waste should be predigested in a separate bed before transferring to the treatment beds. Precautions to be taken Proper covering of feed bed (local available materials such as coconut leaves etc may be used for covering of the vennicompost pit) Avoid excess water (only sprinkling) Protect the shed area and the beds from red ants, cockroaches etc. by using haldi (turmeric) sprinkling atta (.our) all around the perimeter of the shed and the bed Keep the feed beds away from birds/chicken/ducks/rodents from eating the worms. 5.0 Recycling A. Recycling of Papers It is possible to convert waste paper into useful recyclable product. Making pulp from waste paper is an old art. The process has now been refined. Various articles including showpieces may be made using the pulp. The articles are so sturdy that they can be an alternative to wood to some extent. Hence it is also called Pepwood. Women/ SHG members1 Unemployed youths after receiving thorough training can undertake this activity. It is also necessary to attain a certain level of skill. Materials such as Waste paper, Flour of fenugreek or tamarind seed as adhesive, Water, Rough.at stones for macerating paper, Colors, Moulds of different shapes and sizes, Well ventilated cupboard for storing the articles, etc. are required. B. Recycling of Plastics In all types of solid waste in rural areas, plastics have become a major cause of concern due to Non-biodegradability, nuisance value in waste stream and blockage of drainage channels, pollution of surface water and random burning here and there causing air pollution problem. There is no proper collection or disposal system of plastic waste. 6.0 Land Fill In spite of composting, re-use and recycling, some waste remains untreatedunmanaged which requires final disposal, either by incineration or by land filling. Incineration is a technology where waste is burnt in a specially engineered machine called Incinerator. Incineration is not simply burning, but complete combustion. Incinerators are considered to be causes of air pollution. This is not a viable option for waste management. A landfill is a properly designated area and used for the disposal of non-biodegradable and non-recyclable inorganic solid waste. Landfill is considered to be a viable option. This land fill takes care of the problem of disposal of non recyclable solid waste. Selection of Landfill Site: Gram Panchayat in consultation with Zilla ParishadBlock Panchayat (as the case may be) should select the landfill site which should be: o Located at the outskirts of the village o Accessible

167 o On vacant/uncultivated land o Located in the natural depressions with slight slopes o Waste from landfills leaches into the aquifer below site should be such as to avoid surface water and groundwater pollution o Before establishing any landfill site, baseline data of ground water quality in the area shall be collected and kept as a record for future reference. Procedures to be followed for landfill construction o Wastes should be compacted to achieve high density o Wastes should be immediately covered with a minimum 10cm of soil/debris/ o Before the monsoon season, an intermediate cover of soil approximately 40-65cm thick should be placed on the landfill to prevent infiltration o Proper drainage system should be constructed to divert run-off water o After the completion of landfill a final cover should be provided to prevent infiltration and erosion. This should be according to the given diagram o Landfill site should be properly fenced with a provision of a gate with locking arrangements by the gram panchayatlcommunity o Plantation at landfill site should be encouraged to combat pollution. It should be in sufficient density to minimize soil erosion o The plants should be locally adapted, non-edible, drought and extreme temperature resistant, short rooted and of low nutrient demanding variety. Operation and maintenance Gram Panchayatlcommunity should prevent entry of stray animals and unauthorized persons through protective measures Regular Monitoring of groundwater is required for maintaining groundwater quality. Avoid entry of cattle and grazing on the landfill site in an unfenced landfill as it would be hazardous. Samaj Vikas (111fortr sarnaix i k w )

168 Annexure 21: Formats for Environmental Data Sheets (EDS) Formats for Environmental Data Sheets (EDS) A. EDS for Water Supply.S. No. 1 Description GENERAL 1. Name of Habitation - 2. Name of Gram Panchayat 3. Name of Mandal 4. 1 ~zkne of District - 5. Population (present) 6. Total water demand (Litres per day) 7. Present water supply (Litres per day) 8. 1 Present classification of habitation 9. 1 Problem with present water supply 10. ( Net demand of water from the proposed source (Litreslday) Type of source Type of scheme 13. ( Is de-fluoridation planned? LOCATION 14. ] Where is the source located? Has a sanitary survey of the source location been done? 15. (Enclose the report of the sanitary survey) Is any component of the scheme located in a forest area? Is the source is near (within 5 km) any ecologically sensitive area (National Parks, Wildlife Sanctuaries)? Are any trees likely to be cut at the location for construction of the scheme? If yes, mention the number of trees. Particulars NC I NSS I PC Groundwater source Single Village Scheme (SVS) Yes Yes Yes Remarks -- Surface water (MVS) No Refer to Annexure: 13 If yes, obtain permission in writing from the Forest Department Avoid the sensitive areas. If not possible, obtain permission in writing from the Forest Department and follow mitigation measures as suggested by the Forest Department If yes, obtain permission in writing from the Forest Department Samaj Vikas (ilj,fi~m~~~~l~~yilias.(~g) 168

169 IN CASE OF GROUNDWATER SOURCE AQUIFER STATUS AND SUSTAINABILITY 19. What is the type of aquifer? 20. Total depth of well (metres) 2 1. Depth to groundwater table below GL (m) 22. Summer 23. Winter Is the groundwater tapping in safe zone (classified based on 24. exploitation)? 25. What are the measures proposed for source sustainability? LOCATION OF THE WELL What is the distance of this source from the nearest leach pit of any existing sanitation facility? (It should be more than metres) What is the distance of this source from the nearest rain 27. water harvesting pit? (It should be more than 15 metres) What is the distance of the source from the nearest existing 28. well? (It should be more than 300 metres) 29. STRUCTURE OF THE WELL Will the well be provided with sanitary plug till the pump is 30. installed? Is a concrete mat (of at least 75 cm radius) planned around 3 1. the bore well? 32. Is grouting of the space outside the well casing planned? WATER QUALITY 33, Is the quality of water acceptable? (enclose the water quality test report) If not acceptable, mention the type of water quality problem What is the alternative proposed? If the water is to be treated, mention the treatment process What is the frequency planned for testing water for bacteriological contamination? (should be I initially and later as required) What is the frequency planned for testing water for physical and chemical contal~lination? (should be 4 timeslyear) Shallow aquifer Yes Groundwater recharging structure Yes Yes Yes Yes Deep aquifer No Limiting the draft to safe yield No No No No Samaj Vikas (iiifb!g~samajvik~~s.i~~) 169

170 ~ - Andhra Pradesh Rural Water Supply and Sanitation Project What is the frequency planned for testing residual chlorine? 39. (should be at least once a week) What is the frequency planned for sanitary inspection by 40. GPWSSC? (should be 4 timeslyear) What is the frequency planned for sanitary inspection by AEE? (should be onleiyear) IN CASE OF SURFACE WATER SOURCE l l i " m, there be anv, significant - land disturbance resulting - in 1 1 ti' 42. erosion, subsidence and instability? I yes ( No Will the scheme involve alteration of natural drainage? If yes, indicate the measures for the drainage. I Yes I No SUSTAINABILITY Is the expected safe yield from the source greater than water I What is the Turbidity of raw water (NTU)? (Enclose water quality test report) I Is this source within 100 m from the nearest 1 I sewage/industrial effluent disposal point (disposal into the I details. (~nclose water q;ali& test report) - What is the frequency planned for testing water for bacteriological contamination? (should be 1 every month) What is the frequency planned for testing water for physical and chemical contamination? (should be 4 timeslyear) I What is the frequency planned for testing residual chlorine? I Yes --I I ( yes I NO present? ' If yes, furnish the 1 $1 Yes No I AEE? (should be 2 times /year if population serviced is less than 5000; should be times /year if population serviced 52 is between ) WATER TREATMENT Samaj Vikas (iufo:icsania,ivikas.org)

171 Environmental Analysis - Final Report -November What is the method of water treatment proposed? How will the sludge and other residue from the water 54. treatment plant be disposed? Note: Refer Guidelines Vide Annexures 8 to 10 and 12 to 16. Samaj Vikas (i11fo:l~.banl,ijv!kah.org) 17 1

172 B. EDS for Rainwater Harvesting S. No. I Description GENERAL 1. I Name of Habitation 2. Name of Gram Panchayat 3. Name of Mandal 4. Name of District Population (present) Total water demand (Litres per day) Present water supply (Litres per day) 8. Problem with present water supply LOCATION What is the distance of the RWH Structure from the nearest borewell? (should be 15 m 9. away) Is the RWH located away from any supply / feeder channel of tanks? (RWH must not Particulars Source is inadequate in summer Water table is depleted in summer Remarks 19 disinfection, gravity tap) MAINTENANCE RWH structure been certified by a hydrogeologist of the I I. I RWSSD? Is there any possibility of contaminated water flowing into the RWH structure? STRUCTURE 13. Type of RWH structure 14. Intended use of rain water HOUSEHOLD ROOFTOP RWH STRUCTURE Is the roof smooth, free from any toxic materials (including paint)? Are there any overhanging trees nearby? Is there provision planned for discarding first flush of rain water? Is there provision planned for wire mesh screens at gutter heads? Is there provision for safe extraction of the harvested rain water? (filtration. What is the planned frequency of conducting complete maintenance check and cleaning of the RWH system? (recommended before and after every rain; cleaning after every dry period of I month) - Samaj Vikas (i~.g~;aniaivikiissc~::) 172

173 r j h a t is the planned frequency of cleaning storage tank? (recommended at end of dry season, before the first rain) 2 Note: Refer Guidelines Vide Annexures 16. I Samaj Vikas (1~lfo((1~~:1nxi\1iki1s.olg) 173

174 ' Andhra Pradesh Rural Water Supply and Sanitation Project C. EDS for Sewerage Schemes (All the sewerage schemes are classified as Category I1 Schemes) Description Particulars Remarks Name of Gram Panchayat 3. 1 Name of Mandal 5. Population (present) 6. Total water demand (Litres per day) 7. Sewage generation (Litres per day) 8. Length of roads in the habitation LOCATION 9. Is any component of the scheme located in a forest area? Are any trees likely to be cut at the location for construction of the scheme? If 10. yes, mention the number of trees. 1 I. I Type of substrata Will there be any significant land disturbance resulting in erosion, subsidence 1 and instability? Will the scheme involve alteration of natural drainage? If yes, indicate the measures for the drainage. Depth to groundwater table *winter *summer STRUCTURE How many pumping stations will be required? 18. / What is the type of land proposed for pumping station? Is the proposed sewer line involved any crossing of Railway/ Highway/ Canal/ Water course? Yes No department Yes Yes Yes No No No Avoid the forest area If yes, obtain permission in writing from the Forest Department Municipal/ Private If private land, follow recommended I guidelines for acquisition I Obtain permission from the concerned been made for safety gear for the operating and maintenance TREATMENT What is the type of sewage treatment proposed? Samaj Vikas ( inti,:~~~:lnl,~~~i<i~>~) 174

175 22. What is the type of land proposed for pumping station? 23. What is the extent of land required for the STP? 24. What is the mode disposal of treated effluent? 25. Is reuse of treated effluent is planned? Furnish details. 26. How will the sludge and other residue be disposed? Note: Refer Guidelines vide Annexure 7 Municipal1 Panchayat Private If private land, follow recommended guidelines for acquisition Obtain clearance from APPCB Obtain clearance from APPCB Samaj Vikas (iilfo:(~,.s:mnxij\~i k;~s.org) 175

176 D. EDS for Sanitation Schemes S. No. I Description GENERAL I Name of District 5. Population (present) 6. No. of ISL proposed LOCATION I I Name of Habitation Name of Gram Panchayat Name of Mandal Are any trees likely to be cut at the location for construction of the scheme? If yes, mention the number of trees. Type of substrata Depth to groundwater table, in metres *winter *summer Is a shallow aquifer used as source for drinking water supply in the habitation? Is the habitation located in an coastal area? Is a minimum distance of 15 metres maintained between the pits and the nearest 14. drinking water sources? (for all the ISLs proposed) In case of high ground water table and in case of highly permeable soils, is a minimum distance of 40 metres maintained between the pits and the nearest drinking water sources? (for all the ISLs proposed) STRUCTURE 16. What is the type of toilet proposed? 17. For ISL 18. What are the precautions taken to prevent groundwater contamination? Particulars Pervious earth filling outside along sides of pit planned? 1 Yes I No 1 In case of flood prone area, is is raising of platform and earth filling outside along I In case of high ground water table, is raising of platform, bottom sealing of pit and Yes Yes Impervious sides of pit planned? In case of loose soils, is lining of pits with perforated cement rings planned? In case of soils with low permeability, is back filling of part of pit with more Yes Yes No No sandy - ~ Remarks I Not applicable soil planned? Yes I No 23. ] In case of soils with high permeability, is earth filling around rings with denser soil I Yes I No I Not applicable No No If yes, obtain permission in writing from the Forest Department Not applicable Refer Annexure 17. Not applicable Not applicable Not applicable Samaj Vikas ( ~II~O;~+S;I~~~~~~Y~I<~IS.LII~~)

177 I planned? MAINTENANCE 24, 25. Is an awareness programme for prospective users on proper use and maintenance of the IHLs being planned? Is adequate water available for use? (2 litres per each use) What is the expected cleaning interval of pits? (a pit should not be emptied before I '/2 years after its being in use) What is the method of disposal of materials removed from pits? Note: Refer Guidelines vide Annexure 17 and 18 Samaj Vikas (~&,~!2~amai\.iIiq~~) 177

178 Environmental Analysis - Final Report -November 2008 E. EDS for Storm water / Sullage Drainage Scheme Are any trees likely to be cut at the location for construction of the Samaj Vikas (ill fo:i~~s:lni;tiuikas.org) 178

179 I removal from the drains? Is there a plan to educate the community to avoid throwing solid waste I I into the drain (to keep it free from blockages)? TREATMENT 24. What is the treatment proposed for the sullage? (Suspended solids must be removed through settling - for example, in sullage stabilization pond) 25. Is a single treatment pond planned or are a series of ponds planned? (a series of interconnected shallow ponds is recommended - it is better to I have multiple ponds of smaller size than few large ponds) Is the soil very permeable? (If yes, plastic sheeting topped with soil may be laid at bottom) Is any reuse proposed for the sullage? What are the precautions taken to prevent - groundwater contamination I from sullage? Note: Refer Guidelines vide Annexure 19 - Samaj Vikas (i11fo;g,~~:1n1i1ivikiis.<~r~) 179

180 P Andhra Pradesh Rural Water Supply and Sanitation Project F. EDS - for - Household Soak Pits S. No. I Description 1 Particulars GENERAL ' 1. Name Habitation 2. Name of Village Panchayat 3. Name of Mandal 4. Name of District 5. 1 Population (present) T nn A rp~nx~ ak - STRUCTURE pit located in rocky terrain? (Not suitable for rocky terrain) Will the wastewater flow exceed the design flow of the soak pit? (calculate design flow as per requirement for bathing llpld, kitchen 5-10 Vpld, washing clothes Ilpld, and other uses) Is filling material of appropriate size available? (Should be pebbles of sizes mm, I mm and mm) 9. Is the pit to be filled loosely? (Filling material must not be tightly packed) Is the pit to be filled with murram, brickbats or sand? (These materials must not be 10. used) MAINTENANCE What is the frequency planned for cleaning the filter of the soak pit? (Must be cleaned I 1. every fortnight or month) What is the frequency planned for cleaning the pit and replacing the filling material? I I I I Yes Yes Yes Yes Yes I No No No No No I Remarks Samaj Vikas (i.qt&gc~~!iii~il<i~s.l!!g) 180

181 G. EDS for Communitv Solid Waste Management S. No. I Description GENERAL 1. I Name of Habitation 2. 1 Name of Gram Panchavat Particulars Legal requirements 4. 1 Name of District 5. 1 Population (present) LOCATION Type of substrata Depth to groundwater table in metres *winter Pervious Impervious expected quantity of non-biodegradable waste (waste that can be I composted) per day? (tons) WASTE MANAGEMENT WASTE SEGREGATION AND COLLECTION 13. Are awareness programmes on household waste segregation planned to be organized? Yes No 14. Is segregation of wastes at household level (into biodegradable and non-biodegradable wastes) being planned? Yes No 15. How will the household waste be collected? Community Door-to-door I waste bins I collection the community waste bins planned to be located at least 15 m away from any water ( 14 sources? What is the planned frequency of collecting waste (from community bins or from I individual households)? COMPOSTMG OF BIODEGRADABLE WASTE 18. What is the type of composting planned? Underground (lined or unlined) pits - suitable for low rainfall areas Overground heap or tank - suitable for high rainfall areas and rocky terrain I Vermi-compost units FOR COMPOSTING UNITS I I Samaj Vikas (~iifo:(r~.~an~~tlviki~~.og) 181