Constructed Wetlands for the Provision of Irrigation Water a Resource for a Production of Regrowing Raw Products?

R.A. Müller, P. Kuschk, D. Pareides and O. Baeder-Bederski Constructed Wetlands for the Provision of Irrigation Water a Resource for a Production of Regrowing Raw Products? Ecological Sanitation Symposium Damascus / Syria 11-13th December

Introduction: Motivation for Research Activities Global perspective European/German perspective Inadequate implementation of efficient and transferable technologies for water supply and waste water treatment Indicated by a mortality rate of app. 5 Million people per year (WHO) Biggest water consumer: agricultural plant production European Water Framework Directive (22.10.2002): River basin management Increasing importance of solutions for decentralized water management Necessity of intelligent opening-up strategies for new sites/areas Necessity to maintain the high hygienic standard

Decentralised Water Management water consumption partial flow 1 partial flow 2 decentralised treatment decentralised treatment water recycling groundwater recharge advantages systematic treatment of different partial flows no cost-intensive sewer system high variety high flexibility utilisation of nutrients direct relation to the polluter in agreement with a sustainable management of resources Training and Demonstration Centre for Decentralised Sewage Treatment

Alternative Water Management Strategies drinking water faeces, urine and waste closing the loop of water and nutrients nutrients Training and Demonstration Centre for Decentralised Sewage Treatment cleaned water

Possible mechanisms of Germ removal Chemical Parameters Physical mechanisms Redox Potential Oxigen Conc. Temperatur Salinity Protozoa TOC Biological Mechanisms Plant Rhizosphere Protozoa Bacteriophage Competing bacteria C-input Biocide O 2 -input In Matrix: Filtration Sedimentation Biofilm Adsorption

Objective: CW s for supply of irrigation waters Test and optimization of soil filters regarding the elimination of bacteria and parasites in a pilot plant scale and under practical conditions different basic design (hydraulics, filter materials, planting) different operating regimes (hydraulic surface loads, feeding cycles) Adaptation of the design, comparison of the performance, and dimension for an advanced reduction of faecal indicator organisms comparative test operation of two similar constructed pilot plant systems (35 p. e.) in Germany and Mexico, long-term test improvement of a full-scale plant for about 300 p e in Germany

Hygienic quality of irrigation water Maximum allowable concentrations WHO Techn. Rep. Ser. 778 (1989) Use of wastewater in agriculture and aquaculture DIN standard 19650 (1999) Hygienic concern of irrigation water coccus NOM-003-ECOL- 1997 (1998) Reuse of treated waste water in the public domain Coliform Bodies MPN/100 ml Cat. A a) : 200 (FC) Cat. A: 1000 (FC) Cat. B: - (FC) Class 1: n. d. (EC) Class 2: 200 (EC) Class 3: 2000 (EC) Dir.: 240 (FC) Ind.: 1000 (FC) Entero- MPN/100 ml Salmonellae detection/l Intestinal Nematodes counts/l FC Faecal coliforms (termotolerant coliform bodies) EC Escherichia coli Parasites: Ascaris sp., Trichuris sp., hookworms - no standard recommended n. d. not detectable a) Public lawns, possible contact of children age < 15 years b) Threshold for further tests - - - n. d. 100 400 - - - - - n. d. n. d. n. d. - - 0.1 1 1 n. d. n. d. n. d. 1 5 BOD 5 mg/l - - - 10 b) 10 10 20 30

Pilot plant system

Experimental Program Construction of two Sister Pilot Plants Leipzig Langenreichenbach/Mexico Xochitla-Site Year 2001: Adaptation/Optimization of pretreatment, modification of the bed construction Year 2002 Hydraulic loading tests: Single-stage systems 2003/2004 Long-term experiment: Optimized performance (e. g. coupled systems) 2005: Implementation of the technology Fundamental research

Pilot system Langenreichenbach Foto: Künzelmann/UFZ Site: Capacity: Waste water: Saxonia (Germany), Village Langenreichenbach 35 p. e. pretreatment, 1.5 p. e. each bed Operator: Center for Environmental Research Leipzig-Halle GmbH municipal, from an influent of a 15 000 p.e. sewage plant Design: 8 vertical-, 6 horizontal beds and 1 pond, planted with Phragmites C. Plant age: 4 years

Filter Design 200 600 200 2750 Vertical Filter A = 6 m 2 Horizontal Filter 4800 600 2400 1200

Raw Waste Water Design of the pilot system Horizontal Filters: H Force main Legend planted c P Soil Filter: Exclay/Sand f Soil Filter: Sand Pretreatment: Straw Filter Effluent Pumps + on-line Measurement Technique Vertical Filters: V

Pilot system Langenreichenbach Foto: Künzelmann/UFZ Quality of pretreated water C S C COD C BOD5 S NH4-N S NO3-N C Nt E. coli mg/l mg/l mg/l mg/l mg/l mg/l lg(mpn/100 ml) Median 75 490 220 65 0,8 76 6,9

Parameters and additional methods

Waste water analysis Microbiological/Parasitological Physicochemical Parameters Parameters total bacterial number (CFU) at chemical oxygen demand COD 22 C and 36 C thermotolerant coliform bacteria biological oxygen demand BOD 5 Escherichia coli ammonia- nitrogen Enterococci nitrate- nitrogen Salmonella total nitrogen Clostridia ortho-phosphate Cryptosporidium oocysts water balance Giardia cysts bromide (tracer tests) Intestinal nematodes (Ascaris spp., turbidity Tichuris spp., Hookworm)

General results

1st stage vertical flow (exp. clay) 2nd stage horizontal flow (sand) Reduction of the Chemical Oxygen Demand O 2 -Demand [mg/l] Effluent q e [L/m 2 d] 600 500 400 100 80 60 2 nd stage 40 20 0 Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Jan 50 50 40 30 20 10 1st stage 0 0 Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Jan qnom 40 30 20 10 BOD 5 2 nd stage COD 1 st stage COD 2 nd stage BOD 5 1 st stage T Soil [ C] COD Influent q e (HfP1) T Soil (HfP2) T Soil (VcP1)

10 9 Reduction of E. coli by means of singlestage filters Influence of the filter design Feed 40 L/m 2 d (Jun. - Sep. 2002) E. coli [MPN/100 ml] 10 8 10 7 10 6 10 5 10 4 10 3 10 2 10 1 Samples = Determinations = DIN Class 3 17 (34) 17 (34) I r I p 8 (16) 10 (19) VcP1 Vc 14 (28) 6 (12) HfP1 Hf 9 (18) 9 (17) HcP1 Hc 6 (6) 7 (7) VfP1 Vf I influent H horizontal filter V vertical filter r Raw water p pretreated water f fine material: sand c coarse material: exclay P1 planted, basin 1

10 9 Reduction of E. coli by means of combined filters Influence of the filter design Feed 40 L/m 2 d (Sep. - Oct. 2003) E. coli [MPN/100 ml] 10 8 10 7 10 6 10 5 10 4 10 3 10 2 10 1 Samples = (Determinations) = WHO 5 (5) I r 5 (5) I p 5 (5) Hc 5 (5) Hf 5 (5) 5 (5) V f P1 H cp1 minimum value 30 MPN/100 ml 5 (5) 5 (5) V cp1 H fp1 I influent H horizontal filter V vertical filter r Raw water p pretreated water f fine material: sand c coarse material: exclay P1 planted, basin 1

Reduction of E. coli by means of combined filters E.coli [MPN/100ml] 1e+9 1e+8 1e+7 1e+6 1e+5 1e+4 1e+3 1e+2 1e+1 1e+0 E.coli (DIN EN ISO 9308-3) n = 15 n = 14 n =15 n = 13 n = 15 n = 14 n = 15 Minimal Value 15 [MPN/100 ml] VfA HcA VcT HfT VfT HcT Inflow H horizontal filter V vertical filter A Arundo Donax p pretreated water f fine Tezontle c coarse tezontle T Typha latifolia

Influence of temperature Stability of performance

1st stage vertical flow (exp. clay) 2nd stage horizontal flow (sand) Effluent q e [L/m 2 d] E. coli [lg(mpn/100 ml)] 9 8 7 6 5 4 3 2 E. coli reduction minimum value 30 MPN/100 ml 1 Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Jan 50 50 40 30 20 10 0 0 Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec Jan qnom HfP VcP Ip DIN 19650 class 2 40 30 20 10 T Soil [ C] q e (HfP1) T Soil (HfP2) T Soil (VcP1)

Additional microbiological parameters

Reduction of intestinal nematodes Results from the Langenreichenbach plant, Germany Lab A June 2005 Lab B August 2005 Lab B October 2005 Combination Sample Type hydr. load Test volume eggs test volume eggs test volume eggs L/m2 d L per 1 L L per 1 L L per 1 L ROH Raw 10 22 1 n.n. 1 10 NF Pretretated 10 12 1 2 1 n.n. V -H VfP1 1. vertical flow 40 10 0.7 9 n.n. 10 n.n. 2. horizontal flow n.n. 10 n.n. HcP1 10 n.n. 9 V - H VcP1 1. vertical flow 40 10 7 - - 10 n.n. 2. horizontal flow - 10 n.n. HfP1 10 11 - V - H VcP2 1. vertical flow 60 10 4 10 n.n. 10 n.n. 2. horizontal flow n.n. 10 n.n. HfP2 10 1 10 V - V VcP3 1. vertical flow 40 10 0.3 10 n.n. 10 n.n. Vcc 2. vertical flow 10 n.n. 10 n.n. 10 n.n. 1. aerated pond 10 n.n. n.n. - - P - H P 20 10 0,8 10 2. horizontal flow 10 n.n. - - HcP2 2,7 10 eggs Identified nematode eggs of Ascaris-, Trichuris-, or hookworm type H horizontal filter c coarse material: exclay/sand V vertical filter P1 planted, basin 1 f fine material: sand

Outlook: Bamboo Production from domestic Wastewater - a Columbian Case Study

ecosan Kreislaufwirtschaft und Stoffstromorientierung im Abwassermanagement Excrements are valuable resources Million tons per year (N + P 2 O 5 + K 2 O) 150 125 100 75 50 25 0 135 global mineral fertilizer consumption 50 Global Fertilizer equivalent from Wastewater source: www.fertilizer.org more than 1/3 of global mineral fertilizer consumption can be covered by the recycling of human excrements fertilization materials in the value of 15 billion USS are down-rinsed the toilet annually 26

ecosan Kreislaufwirtschaft und Stoffstromorientierung im Abwassermanagement Material flow quantities and their contents 20 12,3 kg 14,1 kg 10.000 200.000 l 6 0 0 5,3 kg 3,6 kg K P N 0,8 kg 1,0 kg Organic kg COD/ (Person Year) Nutrients kg N,P,K / (Person Year) Grey Water 500 l 50 l Grauwasser Urin Fäkalien Urine Faeces Volume Liter / (Person Year) source: Otterpohl 27

ecosan Kreislaufwirtschaft und Stoffstromorientierung im Abwassermanagement Fertilizer Equivalence Fertilizer Equivalence of Yearly per Capita Excreted Nutrients and Fertiliser Requirements for Producing 250 kg of Cereals 6 Nutrient (kg) 5 4 3 2 cereal requirements faeces urine 1 0 N P K N N P P K K source: Drangert, 1998 28

General Concept Construction Wastewater Economic Benefits Environmental Benefits Furniture Laminated flooring Charcoal Mat board Hygienization Contaminants removal

General concept: Bamboo Big distribution along Latin America. Guadua angustifolia. Different uses and high demand. High growth rate.

Use of Bamboo for wastewater treatment Colombian experience: Small scale experiments (8 m 2 ). Domestic wastewater (UTP campus). BOD removal higher than 80% (HRT 1 d). Total and fecal coliforms removal rate higher than 10 2 log (HRT 1 day). With domestic wastewater Guadua shows similar or even higher growth rate in comparison with natural and optimum conditions. Fertilizers increase productivity in 45%

Economical Analysis Operation and Maintenance Costs in WWT System in Pereira, Colombia Item COP $ Salary (1 person) 4200000 1556 1826 Sludge Removal (Septic tank) 5000000 1852 2174 Monitoring 2500000 926 1087 Total 11700000 4333 5087 WWT System: Population: 550 inhabitants Sewerage system: Combined Wastewater: 210 l/p/d Average flow: 1,34 l/s (2002) Average temperature: 22 C Septic Tank and subsurface constructed wetland

Economical Analysis (II) Tree Density (Trees/Ha) 6300 Yield (Trees/Ha/year) 800 Production costs ( /tree) 1.11 Tree price at the farm ( /tree) 1.52 Profitability ( /tree) 0.41 Income ( /Ha/Year) 326 Area for the pilot project (Ha) 3 Total Income ( /year) 978 It is possible to spare, in this case, 23% of the running costs. Bigger projects will be more profitable!

Outlook It is possible to perform constructed wetlands as a basic decentralised technological module in sustainable water management strategies. technical Low operation costs especially in terms of energy consumption, sludge removal and maintenance Pathogen-removal efficiency works well and enables this passive technology to overtake a function in water-supply and wastewater-treatment strategies (water recycling) According to the social relevance the active transfer of technology by an intensive dialogue/co-operation between scientists, politicians, companies, technologyusers has to be prepared (tool: Demonstration plants)

Offer for Co-Operation Transfer of experiences towards site specific conditions in Syria Installation of a Demonstration and Training site Syrian-German Cooperation: Precondition for Implementation of decentralized technical solution in water management systems

Contact Dr. Roland A. Müller UFZ-Leipzig-Halle GmbH E-mail: roland.mueller@ufz.de www: bdz-abwasser.de

Frequency of occurrence of Salmonellae spp. Results from the Langenreichenbach plant, Germany 90 80 70 60 50 40 30 20 10 Samples = 23 (Median) Determinations: 3-4 Raw Pretreated Pond Hc Hf VcP3 Vcc VfP1 HcP1 VfP2 HcP2 Vcp1 HfP1 VcP2 HfP2 H horizontal filter c coarse material: exclay/sand V vertical filter P1 planted, basin 1 f fine material: sand P Pond Samples Salmonellae detected [%] 0

Pretreatment Straw filter for primary treatment to charge red bed sand filters (Germany)