ZEMedS ds: Case studies
|
|
- Bernadette Todd
- 5 years ago
- Views:
Transcription
1 ZEMedS: Case studies
2 Case study: ITC EINSTEIN High School, Ancona, Italy The sole responsibility for the content of this publication lies with the authors. It does not necessarily reflect the opinion of the European Union. Neither the EASME nor the European Commission are responsible for any use that may be made of the information contained therein. August 215
3 General data 3 Name of the School Type of school ITC EINSTEIN High School High School Number of students Owner 436 public Location Year of construction Municipality of Loreto, Italy 1966
4 General data ITC EINSTEIN High School, Municipality i of Loreto, Italy 4 Building typology Heated area (m 2 ) 4 floors building 2998 m 2 Site Urban Plain Heating degree days (base 18): 1897 Cooling degree days (base 26): 82
5 Current Situation 5 Renovation needs High Priority: energy efficiency and building facade safety. Building use Schedule for High school: Standard Use: From 9 th of September till 14 th of June Reduce Use: From 15 th of June till 12 th of August From 19 th of August till 6 th of September 2 nd, 3 rd, 4 th of January 12 th, 16 th of April 23 rd, 24 th, 27 th, 3 th, 31 st of December Standard Use: Monday till Thursday: 8: to 14: and Friday: 8: to 18: Reduce Use: Monday till Friday: 7: to 8: Wednesday: 14: to 18: Friday: 14: to 15:
6 Current Situation ITC EINSTEIN High School, Municipality i of Loreto, Italy 6 Building envelope: Walls Brickwall with wall cavity U = 1 W/m².K Building envelope: Roof Roof with insulation and waterproofing U =.4 W/m².K Building envelope: Groundfloor Ground floor consists of concrete U =.9 W/m².K Building envelope: Windows Single glazed windows with wooden frames Uw = 6 W/m².K
7 Current Situation 7 Airtightness: No measurements Heating/Cooling: 2 natural gas boilers (347 kw). A secondary system, fed by aseparated boiler (cargomax 31) placed on the terrace roof (first level) provide heating to the gymnasium, through two wall mounted air heaters. All the other spaces of the school are heated through radiators, fed by the two boilers placed in the thermal central. At the ground floor, the distribution is not embedded in the walls/floors as in the other floors, but pipes are hung to the ceiling, in the corridors and in the classrooms, often not insulated. Ventilation: No mechanical Ventilation Ventilation by opening windows
8 Current Situation 8 Lighting: Mainly, fluorescent tubes controlled by users Appliances: Lab: PC, Projector, Printer Office: PC, Printer, Copy Machine Gym: PC, Refrigerator, Dryer DHW: DHW is present just in the Gym, managed through the CARGOMAX 31 boiler Cooking: No cooking
9 Current Situation 9 Current final energy consumption kwh/m2 conditioned area (from bills, metering etc.): electricity kwh/m2 y; 12 natural gas kwh/m2 y; 193 Total of energy consumption (bills ): 614,949 kwh/year, 25 kwh/year m2 conditioned area Running cost: electricit y /y ; 8148 natural gas /y ; 6522 Energy (bills ): 65,22 /year (natural gas), 8,148 /year (electricity). VAT included. Water: no data Maintenance: no data
10 1 Design approach: Deep renovation towards ZEMedS nzeb Schools requeriments. ZEMedS Goals: Requeriment 1: C PE Prod RES Primary energy consumption yearly (heating, cooling, ventillation, DHW and lighting) is produced by local renewable energies. Requeriment 2: C FE 25kWh/m2y FE consumption yearly (heating, cooling, ventillation and lighting) per conditioned area Requeriment 3: Indoor air quality guaranteed (CO 2 1 ppm) and temperature above 28ºC 4 hours yearly during occupancy National factors for conversion in energy and CO 2 have been taken into account (data 214). Methodology in energy simulations: Steps considered: First step: 3 proposals (variant A, B and C) in envelope renovation: from less insulated to more insulated Second step: 2 proposals for each variant: Renovation in lighting gsystem Renovation in lighting system, heating and DHW system + installation of PV system+use of natural ventilation Renovation in lighting system, heating and DHW system + installation of PV system+use of mechanical ventilation without heat recovery Renovation in lighting system, heating and DHW system + installation of PV system+use of mechanical ventilation with heat recovery
11 11 First step: 3 proposals (variant A, B and C) in envelope renovation: from less insulated to more insulated. Variant A Variant B Variant C Step 1 Uwindows and exterior doors Solar protection Interior Curtains Replacement of existing single glazing for: Variant A: low e double glazing, 16mm(air) and wooden frame (with thermal break). Ug=1.6 Uf= Variant B: low e double glazing, 16mm(argon) and wooden frame (with thermal break). Ug=1.3 Uf= 2.2 Variant C: low e double glazing, 16mm(argon) and wooden frame. Ug=1.3 Uf= 2.2 Uroof Variant A: 3cm roof tiles with cool material coating and 4cm EPS attached Variant B: 3cm roof tiles with cool material coating and 7cm EPS attached Variant C 3cm roof tiles with cool material coating and 14cm EPS attached Uwall Variant A: External wall insulation 5cm EPS & plaster with cool coating Variant B: External wall insulation 8cm EPS & plaster with cool coating Variant C: External wall insulation 13cm EPS & plaster with cool coating Ugroundfloor current
12 12 Second step: 3 proposals for each variant A, B and C: Step 2.1: Renovation of heating and DHW system + installation of PV system + use of natural ventilation Step 2.2: Renovation of heating and DHW system + installation of PV system + use of mechanical ventilation without heat recovery Step 23:Renovation 2.3: of heating and DHW system + installation of PV system +useofmechanical ventilation with heat recovery Step 2.1 Natural lventilation Windows open sceanrio (,8 8 m3/sec/person) / Heating system Condensing boilers Cooling system no cooling system PV system 448m 2 PV panels Step 2.2 Mechanical Ventilation Heating system Cooling system PV system Ventilation systems without heat recovery (control when occupancy) 6.5 l/s person Condensing boilers no cooling system 67m 2 PV panels Step 2.3 Mechanical Ventilation Heating system Cooling system PV system Ventilation systems without heat recovery (control when occupancy) 6.5 l/s person, 7% heat recovery Condensing boilers no cooling system 496m 2 PV panels
13 13 Italian Regulation:
14 14 VARIANT A FINAL ENERGY: kwh/m Total ZEMedS Heating, cooling & ventilation Lighting 5 ZEMedS requirements (heating, cooling, vent. & lighting) National Regulation step 1 & step 2.1 step 1 & step 2.2 step 1 & step 2.3 step 1 & step 2.1 : 66 kwh/m² in final energy e Lighting; 5 Ventilatio n; Cooling; Heating; 62 step 1 & step 2.2 : 15 kwh/m² in final energy Lighting; 5 Heating; 1 Ventilatio n; Cooling; step 1 & step 2.3 : 75 kwh/m² in final energy Lighting; 5 Heating; 7 Ventilatio n; Cooling; PRIMARY ENERGY: Primary energy of existing building kwhpe/m².y 2 (heating, lighting, i DHW, appliances) data from bills ng Existing buildi step 1 step 1 & ste ep 2.1 step 1 & ste ep 2.2 step 1 & ste ep 2.3 Primary energy for non renewable energy consumption kwhpe/m².y (heating, ventilation, lighting and DHW) (data from simulation) Primary Energy predicted by RES kwh/m2 y covering heating, vent., lighting, DHW (data from simulation)
15 15 FINAL ENERGY: VARIANT B 25 2 kwh/m2 Total ZEMedS Heating, cooling & ventilation Lighting 5 ZEMedS requirements (heating, cooling, vent. & lighting) National Regulation step 1 & step 2.1 step 1 & step 2.2 step 1 & step 2.3 step 1 & step 2.1 : 65 kwh/m² in final energy Lighting; 5 Ventilatio n; Heating; 6Cooling; step 1 & step 2.2 : 14 kwh/m² in final energy Lighting; 5 Heating; 99 Ventilatio n; Cooling; step 1 & step 2.3 : 74 kwh/m² in final energy Lighting; 5 Heating; 69 Ventilatio n; Cooling; PRIMARY ENERGY: Primary energy of existing building kwhpe/m².y 2 (heating, lighting, DHW, appliances) data from bills Primary energy for non renewable energy consumption kwhpe/m².y (heating, ventilation, 5 lighting and DHW) (data from simulation) 1 15 Existing buildin ng step 1 ep step 1 & ste 2.1 ep step 1 & ste 2.2 ep step 1 & ste 2.3 Primary Energy predicted by RES kwh/m2 y covering heating, vent., lighting, DHW (data from simulation)
16 FINAL ENERGY: VARIANT C 25 2 kwh/m2 Total ZEMedS Heating, cooling & ventilation Lighting 5 ZEMedS requirements (heating, cooling, vent. & lighting) National Regulation step 1 & step 2.1 step 1 & step 2.2 step 1 & step 2.3 step 1 & step 2.1 : 64 kwh/m² in final energy Lighting; 5 Ventilatio n; Heating; Cooling; 59 step 1 & step 2.2 : 14 kwh/m² in final energy Lighting; 5 Ventilatio n; Heating; 99 Cooling; step 1 & step 2.3 : 73 kwh/m² in final energy Lighting; 5 Heating; 68 Ventilatio n; Cooling; PRIMARY ENERGY: Primary energy of existing building kwhpe/m².y 2 (heating, lighting, DHW, appliances) data from bills Primary energy for non renewable energy consumption kwhpe/m².y (heating, ventilation, lighting and DHW) (data from simulation) Existing building step 1 step 1 & step 2.1 step 1 & step 2.2 step 1 & step 2.3 Primary Energy predicted by RES kwh/m2 y covering heating, vent., lighting, DHW (data from simulation)
17 17 Global cost and paybacks for the renovation scenarios: Calculations based on: Average yearly increase in gas price*: 3.9 % (data from 23 to 214) Average yearly increase in electricity price**: 2.5 % (data from 23 to 214) Overall cost of gas: 65,22 /year (VAT included) Overall cost of electricity: 8,148 /year (VAT included) Considered an overall maintenance cost of the renovation scenarios (yearly percentage of the total cost of the renewals) in.5% (envelope measures), 2% (heating systems and PV) Replacement assumed in lighting (15 2 years lifetime) Average inflation considered in 1.8% (from 1 years average data) Overall maintenance yearly percentage of total cost of investment. All construction costs (prices at 214) in renovation scenarios include assembling, disassembling and daily amortization of scaffold are included. Sources for cost data are gathered from using of existing cost database which have been derived from market based data gathering, evaluating of recent projects, and analyzing of standard offers of construction companies. *Source: ** Source:
18 18 Paybacks for the renovation implemented in steps (every 4 years): Expected savings in Expected savings in Overall cost of gas Overall cost of electricity Investment Overall maintenan ce Cost of replacemen Payback gas electrcicity /year /year in cost /year t in Items to be replaced (years) step 1 var A (windows & ext. doors & walls & roofs) 54% % step 1 var B (windows & ext. doors & walls & roofs) 56% % step 1 var C (windows & ext. doors & walls & roofs) 57% % step 2.1 boiler + nat. vent. + PV gas boiler (15 years)/inversors 9% 33% system (var A) PV 39 step boiler + nat. vent. + PV gas boiler (15 years)/inversors 8% 33% system (var B) PV 39 step 2.1 boiler + nat. vent. + PV gas boiler (15 years)/inversors 6% 33% system (var C) PV 4 step 2.2 boiler + mechanical vent. + gas boiler (15 years)/inversors 43% 33% PV system (var A) PV >5 step boiler + mechanical vent. + gas boiler (15 years)/inversors 46% 33% PV system (var B) PV >5 step 2.2 boiler + mechanical vent. + gas boiler (15 years)/inversors 51% 33% PV system (var C) PV >5 step 2.3 boiler + MVHR + PV system gas boiler (15 years)/inversors 3% 33% (var A) PV >5 step boiler + MVHR + PV system gas boiler (15 years)/inversors 4% 33% (var B) PV >5 step 2.3 boiler + MVHR + PV system (var C) 7% 33% gas boiler (15 years)/inversors PV >5 Ttl Total payback in all variants is > 5 years, except for variants with natural ventilation. Overall maintenance yearly percentage of the total cost of the investment. All construction costs (prices at 214) in the renovation scenarios include assembling, disassembling and daily amortization of scaffold are included in wall insulation costs. VAT included.
19 19 Paybacks for the renovation implemented in steps (every 4 years): Values in m2 conditioned area Expected savings in gas Expected savings in electrcicity Overall cost of gas /year m2 Overall cost of electricity Investment /year m2 in /m2 Overall maintenanc e cost /year m2 Cost of replacemen t in /m2 Items to be replaced step 1 var A( (windows & ext. doors & walls & roofs) 54% % step 1 var B (windows & ext. doors & walls & roofs) 56% % step 1 var C (windows & ext. doors & walls & roofs) 57% % step boiler + nat. vent. +PV 9% 33% system (var A) step 2.1 boiler + nat. vent. + PV 8% 33% system (var B) step 2.1 boiler + nat. vent. + PV 6% 33% system (var C) step boiler + mechanical vent. 43% 33% PV system (var A) step 2.2 boiler + mechanical vent. 46% 33% PV system (var B) step 2.2 boiler + mechanical vent. 51% 33% PV system (var C) step boiler + MVHR + PV 3% 33% system (var A) step 2.3 boiler + MVHR + PV 4% 33% system (var B) step 2.3 boiler + MVHR + PV 7% 33% system (var C) Total payback in all variants is > 5 years, except for variants with natural ventilation. Overall maintenance yearly percentage of the total cost of the investment. All construction costs (prices at 214) in the renovation scenarios include assembling, disassembling and daily amortization of scaffold are included in wall insulation costs. VAT included. Payback (years) >5 >5 >5 >5 >5 >5
20 2 In graphics, global cost of step 1: Global costs en /m² Existing building step 1 var A (windows & ext. doors & walls & roofs) step 1 var B (windows & ext. doors & walls & roofs) step 1 var C (windows & ext. doors & walls & roofs) Confort Maintenance costs /m2 year Energy price (electricity) /m2 year Energy price (diesel) /m2 year Cost of replacement /m2 Investment /m2 Confort (numbers of hours > 28ºC) Number of hours of overheating over 28ºC for renovated buildings are expected to be zero.
21 21 In graphics, global cost of step 2.1: Global costs en /m² Existing building step 2.1 boiler + nat. vent. + PV system (var A) step 2.1 boiler + nat. vent. + PV system (var B) step 2.1 boiler + nat. vent. + PV system (var C) Comfort Maintenance costs /m2 year Energy price (electricity) /m2 year Energy price (diesel) /m2 year Cost of replacement /m2 Investment /m2 Comfort (numbers of hours > 28ºC) Number of hours of overheating over 28ºC for renovated buildings are expected to be zero. The replacement of the gas boilers have been considered in the cost of replacement of the existing building. There is no information of the costs in maintenance concerning the existing building.
22 22 In graphics, global cost of step 2.2: Global costs en /m² Existing building step 2.2 boiler + mechanical vent. + PV system (var A) step 2.2 boiler + mechanical vent. + PV system (var B) step 2.2 boiler + mechanical vent. + PV system (var C) t Comfort Maintenance costs /m2 year Energy price (electricity) /m2 year Energy price (diesel) /m2 year Cost of replacement /m2 Investment /m2 Confort (numbers of hours > 28ºC) Number of hours of overheating over 28ºC for renovated buildings are expected to be zero. The replacement of the gas boilers have been considered in the cost of replacement of the existing building. There is no information of the costs in maintenance concerning the existing building.
23 23 In graphics, global cost of step 2.3: Global costs en /m² Existing building step 2.3 boiler + MVHR + PV system (var A) step 2.3 boiler + MVHR step 2.3 boiler + MVHR + PV system (var B) + PV system (var C) Confort Maintenance costs /m2 year Energy price (electricity) /m2 year Energy price (diesel) /m2 year Cost of replacement /m2 Investment t / /m2 Confort (numbers of hours > 28ºC) Number of hours of overheating over 28ºC for renovated buildings are expected to be zero. The replacement of the gas boilers have been considered in the cost of replacement of the existing building. There is no information of the costs in maintenance concerning the existing building.
24 24 Paybacks for the renovation implemented all at once (step 1 + steps 2): Expected Expected Overall cost Overall cost Overall maintenanc Cost of savings in savings in of gas of electricity Investment e replacement gas electrcicity /year /year in cost /year in Items to be replaced step 1+ step 2.1 (var A) 58% 33% step 1+ step 2.1 (var B) 59% 33% step 1+ step 2.1 (var C) 6% 33% Payback (years) step 1+ step (var A) 35% 33% step 1+ step 2.2 (var B) 35% 33% step 1+ step 2.2 (var C) 36% 33% step 1+ step 2.3 (var A) 53% 33% step 1+ step 2.3 (var B) 54% 33% step 1+ step 2.3 (var C) 54% 33% Total paybacks in variants with natural ventilation is expected in years. Total paybacks in variants with mechanical ventilation is expected in years. Total paybacks in variants with mechanical ventilation with heat recovery is expected in years. Overall maintenance yearly percentage of the total cost of the investment. All construction costs (prices at 214) in the renovation scenarios include assembling, disassembling and daily amortization of scaffold are included in wall insulation costs. VAT included.
25 25 Paybacks for the renovation implemented all at once (step 1 + steps 2): Values in m2 conditioned area Expected savings in gas Expected savings in electrcicity Overall cost of gas /m2 year Overall cost of electricity /m2 year Investment in /m2 Overall maintenanc e cost /m2 year Cost of replacement in /m2 step 1+ step 2.1 (var A) 58% 33% 9,1 1, step 1+ step 2.1 (var B) 59% 33% 8,8 1, step 1+ step 2.1 (var C) 6% 33% 8,7 1, step 1+ step 2.2 (var A) 35% 33% 14,2 1, step 1+ step 2.2 (var B) 35% 33% 14, 1, step 1+ step 2.2 (var C) 36% 33% 14, 1, step 1+ step 2.3 (var A) 53% 33% 1,2 1, step 1+ step 2.3 (var B) 54% 33% 1, 1, step 1+ step 2.3 (var C) 54% 33% 9,99 1, Items to be replaced Payback (years) Total paybacks in variants with natural ventilation is expected in years. Total paybacks in variants with mechanical ventilation is expected in years. Total paybacks in variants with mechanical ventilation with heat recovery is expected in years. Overall maintenance yearly percentage of the total cost of the investment. All construction costs (prices at 214) in the renovation scenarios include assembling, disassembling and daily amortization of scaffold are included in wall insulation costs. VAT included.
26 26 In graphics, global cost of renovation all at once for step 1+ step 2.1: Glob bal costs en /m m² Existing building step 1+ step 2.1 (var A) step 1+ step 2.1 (var B) step 1+ step 2.1 (var C) Confort Maintenance costs /m2 year Energy price (electricity) /m2 year Energy price (diesel) /m2 year Cost of replacement /m2 Investment /m2 Confort (numbers of hours > 28ºC) Number of hours of overheating over 28ºC for renovated buildings are expected to be zero. The replacement of the gas boilers have been considered in the cost of replacement of the existing building. There is no information of the costs in maintenance concerning the existing building.
27 27 In graphics, global cost of renovation all at once for step 1+ step 2.2: Gl lobal costs en / /m² Existing building step 1+ step 2.2 (var A) step 1+ step 2.2 (var B) step 1+ step 2.2 (var C) Confort Maintenance costs /m2 year Energy price (electricity) /m2 year Energy price (diesel) /m2 year Cost of replacement /m2 Investment /m2 Confort (numbers of hours > 28ºC) Number of hours of overheating over 28ºC for renovated buildings are expected to be zero. The replacement of the gas boilers have been considered in the cost of replacement of the existing building. There is no information of the costs in maintenance concerning the existing building.
28 28 In graphics, global cost of renovation all at once for step 1+ step 2.1: Glob bal costs en /m m² Existing building step 1+ step 2.1 (var A) step 1+ step 2.1 (var B) step 1+ step 2.1 (var C) Confort Maintenance costs /m2 year Energy price (electricity) /m2 year Energy price (diesel) /m2 year Cost of replacement /m2 Investment /m2 Confort (numbers of hours > 28ºC) Number of hours of overheating over 28ºC for renovated buildings are expected to be zero. The replacement of the gas boilers have been considered in the cost of replacement of the existing building. There is no information of the costs in maintenance concerning the existing building.
29 29 Current situation: gas electricity consumption (kwh) Ratio (kwh/m2) consumption (kwh) Ratio (kwh/m2) Real (bills) Simulation (Open studio+energyplus) Results of nzeb renovation under ZEMedS goals: Renovation implemented with energy efficiency measures in result 1 result 2 result 3 envelope + ventilation with natural ventilation + heating system (condensing boiler)+ PV system covering (heating, lighting, ventilation) envelope + ventilation with mechanical ventilation + heating system (condensing boiler)+ PV system covering (heating, lighting, ventilation) envelope + ventilation with mechanical ventilation with heat recovery + heating system (condensing boiler)+ PV system covering (heating, lighting, ventilation) Energy balance in PE (kwh/m2 y) (heating, cooling, vent., Var A / / /42 DHW & lighting) and RES production (kwh and kwh/m2 Var B / / /42 conditioned area) (ZEMedS requirement 1) (simulations) Var C / / /41 Energy result in FE (kwh/m2 y) (heating, cooling, vent. & Var A lighting) per conditioned area (ZEMedS requirement 2) Var B (simulations) Var C Goal of (ZEMedS requirement 3) natural ventilation by opening windows (no indoor quality guaranteed) predicted temperatures above 28ºC in less than 4 hours/year indoor quality guaranteed by mechanical ventilation predicted temperatures above 28ºC in less than 4 hours/year indoor quality guaranteed by mechanical ventilation predicted temperatures above 28ºC in less than 4 hours/year Paybacks (years) step by step implementation >5 (except for natural ventilation) Paybacks (years) all at once implementation
ZEMedS: Case studies
ZEMedS: Case studies Case study: ANTONIO SALVETTI Primary School, Colle di Val d'elsa, Italy The sole responsibility for the content of this publication lies with the authors. It does not necessarily reflect
More informationZEMedS ds: Case studies
ZEMedS: Case studies Case study: Don Milani Primary School, San Miniato, Italy The sole responsibility for the content of this publication lies with the authors. It does not necessarily reflect the opinion
More informationZEM ds : Case studies
ZEMedS: Case studies Case study: Salamanque Group school, Montpellier, France The sole responsibility for the content of this publication lies with the authors. It does not necessarily reflect the opinion
More informationZEMedS: Implementation
ZEMedS: Implementation Implementation Case: El Calamot, Gavà, Catalonia (Spain) General data 3 Name of the School Type of school El Calamot High School High School Number of students Owner 1000 public
More informationZEMedS: Implementation
ZEMedS: Implementation Implementation Case: Pere Borrell, Puigcerdà, Catalonia (Spain) General data 3 Name of the School Type of school Pere Borrell High School High School Number of students Owner 487
More informationImp ementation Case:
ZEMedS: Implementation Implementation Case: ITIS Merloni, Fabriano, Italy General data 3 Name of the School Type of school ITIS MERLONI High School High School Number of students Owner 398 public Location
More informationImp ementation Case:
ZEMedS: Implementation Implementation Case: IIS Vanvitelli Angelini, Ancona, Italy General data IIS Vanvitelli Angelini High School, Municipality of Ancona (AN), Italy 3 Name of the School Type of school
More informationImp ementation Case:
ZEMedS: Implementation Implementation Case: IPSSART Varnelli, Cingoli, Italy General data 3 Name of the School Type of school IPSSART Cingoli High School High School Number of students Owner 724 public
More informationImp ementation Case:
ZEMedS: Implementation Implementation Case: IPCT Bonifazi, Recanati, Italy General data 3 Name of the School Type of school IPCT Recanati High School High School Number of students Owner 277 public Location
More informationEXECUTIVE SUMMARY: Best practices and lists of technologies to refurbish buildings & Proposed packages of measures
EXECUTIVE SUMMARY: Best practices and lists of technologies to refurbish buildings & Proposed packages of measures Authors: Zoltan Magyar, Gabor Nemeth & Jeno Kontra BME RePublic_ZEB 2016 Executive summary:
More informationSchool Tito Maccio Plauto Cesena (IT)
School Tito Maccio Plauto Cesena (IT) 1. INTRODUCTION PROJECT SUMMARY - Major renovation of a primary school, built in the 60s - 440 students, 50 employees - 20 classes (about 22 students) - Area: 6.420
More informationEuroPHit. Outlines for training modules for designer
EuroPHit Outlines for training modules for designer Zeno Bastian Passive House Institute Darmstadt, Germany www.europhit.eu The EuroPHit Project With the EnerPHit Standard as the goal and Passive House
More information2000 Antwerp, terraced house
2000 Antwerp, terraced house 1. INTRODUCTION PROJECT SUMMARY - First phase energy renovation: 1999 - Second phase energy renovation: 2007 SPECIAL FEATURES - Two phased energy renovation - The owners stayed
More informationDanish national plans for Nearly Zero Energy Buildings
Danish national plans for Nearly Zero Energy Buildings ENERGY SEMINAR IN ESPOO 5 NOVEMBER 2014 KIRSTEN ENGELUND THOMSEN DANISH BUILDING RESEARCH INSTITUTE, SBi AALBORG UNIVERSITY COPENHAGEN Agenda Political
More informationHealthy Buildings 2017 Europe July 2-5, 2017, Lublin, Poland
Healthy Buildings 217 Europe July 2-5, 217, Lublin, Poland Paper ID 89 ISBN: 978-83-7947-232-1 THERMAL RETROFIT OF A RESIDENTIAL BUILDING IN ROMANIA TO REACH LOW-CONSUMPTION ENERGY TARGETS Andrei DAMIAN
More informationThe BIG Energy Upgrade Energy Innovation for Retrofitting Deprived Community Housing in the UK
The BIG Energy Upgrade Energy Innovation for Retrofitting Deprived Community Housing in the UK Dr. Hasim Altan Lecturer in Sustainable Environmental Design Director of BEAU Research Centre, School of Architecture
More informationBuilt examples and project certification. Zeno Bastian, Passive House Institute
Built examples and project certification Zeno Bastian, Passive House Institute Passive House Standard for Retrofits? Photo Passive House Institute Shape Graphic Passive House Institute Thermal Bridges
More informationProject Description. Projected build start date 15 Aug 2011 Projected date of occupation 19 Dec Existing external wall construction
http://lowenergybuildings.org.uk Project name Redlands Project summary Deep retrofit of 1955 brick house in Devon based on EnerPHit standard. House had old gas boiler, double glazing, cavity wall insulation
More informationEnergy efficiency of buildings from Europe to Slovakia
Energy efficiency of buildings from Europe to Slovakia Prof. Dušan Petráš, PhD. Slovak University of Technology Faculty of Civil Engineering Department of Building Services mail.: dusan.petras@stuba.sk
More informationD3.9_Overall Refurbishment Plan DRAFT CS03. Hotel Restaurant Valcanover
D3.9_Overall Refurbishment Plan DRAFT CS03 Hotel Restaurant Valcanover INTELLIGENT ENERGY EUROPE II Energy efficiency and renewable energy in buildings IEE/12/070 EuroPHit [Improving the energy performance
More informationEnergy Audit of two Apartment Buildings in Cagliari using Energy Simulation
Energy Audit of two Apartment Buildings in Cagliari using Energy Simulation Graduation Thesis by Carla Vargiu and Luisa Zedda, Master in Green Building and Energy Efficiency This thesis focuses on the
More informationBuilding Typology Brochure England September 2014
Building Typology Brochure England September 2014 Disclaimer The sole responsibility for the content of this publication lies with the authors. It does not necessarily reflect the opinion of the European
More informationAttic conversion in Innsbruck AT
Attic conversion in Innsbruck AT PROJECT SUMMARY An attic conversion of a historic building in Innsbruck built in 1882. The two new levels are built of connected wooden boxes. Complies with Austrian low
More informationPHPP Report. Beattie Passive Inchkeith Drive
PHPP Report Beattie Passive Inchkeith Drive 1. Introduction Passive House is the world-leading building standard in energy-efficient construction. It is comfortable, affordable and ecological at the same
More informationAvailable online at ScienceDirect. Energy Procedia 48 (2014 )
Available online at www.sciencedirect.com ScienceDirect Energy Procedia 48 (2014 ) 1482 1492 Energy saving technology screening within the EU-project School of the Future Ove C. Mørck a, *, Anton J. Paulsen
More informationProject name Gentoo Retrofit Bid 1 Project summary Refurbishment of 2no. Semi Detached houses using Passivhaus principles
http://lowenergybuildings.org.uk Project name Gentoo Retrofit Bid 1 Project summary Refurbishment of 2no. Semi Detached houses using Passivhaus principles Project Description Projected build start date
More informationCost optimality and nzeb target in the renovation of Portuguese building stock. Rainha Dona Leonor neighborhood case study
Chapter 1 - Nearly Zero Energy Buildings Cost optimality and nzeb target in the renovation of Portuguese building stock. Rainha Dona Leonor neighborhood case study Manuela Almeida University of Minho,
More informationKoniklecová 4, Brno-Nový Lískovec
Koniklecová 4, Brno-Nový Lískovec Project summary Energy concept: Renovation to low-energy / passive house standard Background for the renovation reasons: Intention for the renovation: Overall modernization
More informationINNOVATIVE METHODS TO ENCOURAGE BUILDING ENERGY EFFICIENCY IN FRANCE Francis Allard LaSIE, University of La Rochelle/CNRS
Rakennusten energiaseminaari Finlandia-talossa 8.10.2015 INNOVATIVE METHODS TO ENCOURAGE BUILDING ENERGY EFFICIENCY IN FRANCE Francis Allard LaSIE, University of La Rochelle/CNRS francis.allard@univ-lr.fr
More informationAM-55, AM-56) B U I L D I N G P A R T N E R S H I P S F O R E N E R G Y S E C U R I T Y
Nearly zero-energy building and components of the DIRECTIVE on energy performance of buildings 2010/31/EU Albin Zsebik, PhD, CEM Improving university curricula in the areas of a) energy efficiency in the
More informationOSU Cascades Net Zero Campus. Recommendations
OSU Cascades Net Zero Campus Recommendations February 20, 2017 Viable Net Zero Options Building Energy Efficiency Better 30% better than code Best 50% better than code Electrical energy Photovoltaic energy
More informationTowards nzeb buildings: a historical building case study
Towards nzeb buildings: a historical building case study The recast of EU Directive 2010/31 introduced the concept of (nearly) zero energy building (NZEB). In Italy this challenge is remarkable: existing
More informationModeling and Simulation of Energy Use and Indoor Thermal Environment of Highly-Insulated Buildings
Modeling and Simulation of Energy Use and Indoor Thermal Environment of Highly-Insulated Buildings Laurent Georges Energy and Process Engineering Department, Norwegian University of Science and Technology
More informationProject name SOLAR HOUSE 80/50 Project summary
http://lowenergybuildings.org.uk Project name SOLAR HOUSE 80/50 Project summary Project Description Projected build start date 01 Mar 2010 Projected date of occupation 19 Jul 2010 Project stage Under construction
More informationUpgrading the energy performance of residential buildings in Cyprus
Upgrading the energy performance of residential buildings in Cyprus Energy Services, Barriers & Opportunities Gazzada Schianno, Varese, Italy 18-19 October 2017 Savvas Vlachos / Director Member of Cyprus
More informationProject Description. Projected build start date Projected date of occupation. Dungannon, County Tyrone, Northern Ireland
http://lowenergybuildings.org.uk Project name Lisnahull Project summary The terrace of 5 two storey houses have been developed as the first certified social housing project in Ireland for Oaklee Homes
More informationNear zero energy building with steel solutions case study. Jyrki Kesti, Technology Director, Ruukki Construction
Near zero energy building with steel solutions case study, Technology Director, Ruukki Construction SSAB & Ruukki SSAB Special Steels SSAB Europe SSAB Americas Global steel and service partner in value-added
More informationResults from the Application of the Maltese Energy Performance Rating of Dwellings in Malta EPRDM Software to a New Block of Apartments
Results from the Application of the Maltese Energy Performance Rating of Dwellings in Malta EPRDM Software to a New Block of Apartments Charles Yousif Institute for University of Malta with Celia Pérez
More informationPilot project: DUTH Student residences, Komotini, Greece. Detailed technical and financial action plans for each individual building block
MED Programme Priority-Objective 2-2: Promotion and renewable energy and improvement of energy efficiency Contract n. IS-MED10-029 Pilot project: DUTH Student residences, Komotini, Greece Detailed technical
More information71 kwh/(m²a) Project Documentation. 1 Abstract. Single family house in Bellbrae, Victoria, Australia. 1.1 Data of building. Year of construction
Project Documentation 1 Abstract Single family house in Bellbrae, Victoria, Australia 1.1 Data of building Year of construction U-value external wall 2015 Space heating 0.220 W/(m²K) 16 kwh/(m²a) U-value
More informationHouse Pillon Year of construction (2008), Caldaro (IT)
Energy production by RES (kwh/(m2*year) Operational success story GENERAL INFORMATIONS Owner: Architect: Design office: Use: Heated surface*: Gross volume*: 600,52m 3 Built in: 2008/09 Cost (only construction)
More informationDefining a Fabric Energy Efficiency Standard for zero carbon homes
Defining a Fabric Energy Efficiency Standard for zero carbon homes Appendix D Cost analysis The views and recommendations within this report are those of the Task Group and do not necessarily reflect the
More informationMinimum Energy Consumption 84% energy heating savings*
3 HOUSE DESIGNS OF 140m² A modern concept for energy efficiency ENERGY EFFICIENCY AND ENVIRONMENTAL QUALITY Minimum Energy Consumption 84% energy heating savings* * According to a home fulfilling thermal
More informationEDEM detail description part 1: inputs and outputs
EDEM detailed description: Part 1 - inputs and outputs. Summary EDEM is a flexible approach to mapping the possible building carbon and energy performance universe in terms of a matrix of simulation models.
More informationRetrofit of an historical building toward NZEB
Available online at www.sciencedirect.com ScienceDirect Energy Procedia 00 (2015) 000 000 www.elsevier.com/locate/procedia 6th International Building Physics Conference, IBPC 2015 Retrofit of an historical
More informationUlvøya, Oslo, Norway. One Stop Shop Demonstration Project 1. OVERVIEW
Ulvøya, Oslo, Norway 1. OVERVIEW PROJECT SUMMARY - Year of construction: 1958 - Renovation: 2012 - Building typology: Semi-detached house SPECIAL FEATURE - Exterior insulation - Windows replacement - Balanced
More informationPassive House Object Documentation
Passive House Object Documentation 3 stores, 9 units multifamily building in Lonato, Brescia, Italy Project team Architecture: Arch. Angiolino Imperadori Structures and tech. services: Ing. Giovanni Ziletti
More informationBPE Case study of Pippin Close and Barnlea Close
BPE Case study of Pippin Close and Barnlea Close Building Performance Evaluation conference 14 th July 2015 Woking Professor Rajat Gupta and Mariam Kapsali Low Carbon Building Group, Oxford Institute for
More informationCALCULATIONS OF COST-OPTIMAL LEVELS OF ENERGY PERFORMANCE REQUIREMENTS FOR RENOVATED BUILDINGS AND BUILDING ELEMENTS: A LATVIAN CASE
Green design and sustainable architecture CALCULATIONS OF COST-OPTIMAL LEVELS OF ENERGY PERFORMANCE REQUIREMENTS FOR RENOVATED BUILDINGS AND BUILDING ELEMENTS: A LATVIAN CASE Dr. phys. Staņislavs Gendelis
More information5 social row houses (Wachtebeke)
5 social row houses (Wachtebeke) 1. OVERVIEW PROJECT SUMMARY - Year of construction: 1971 - Renovation: 2012 - Building typology: Social housing SPECIAL FEATURE - Demolition of facade brick & adding 30
More informationENERGY IN BUILDINGS AND COMMUNITIES PROGRAMME EXPERIENCES FROM ANNEX 61 DEEP REFURBISHMENT CASE STUDIES ENERGY
INVESTING INTO ENERGY EFFICIENCY PROJECTS: WHY AND HOW? ENERGY IN BUILDINGS AND COMMUNITIES PROGRAMME ENERGY EXPERIENCES FROM ANNEX 61 DEEP REFURBISHMENT CASE STUDIES Energy consultants, Denmark CASE STUDIES
More informationNZEB: The new challenge of HVAC Manufacturers. ASTRO Tower (Archi Urbain)
NZEB: The new challenge of HVAC Manufacturers ASTRO Tower (Archi Urbain) Who are we? 35 production sites units compressors refrigerants chillers Who are we? Daughter company (100%) of Daikin Europe Specialised
More informationRefurbishment challenges of nzeb
UNIVERSITY OF MINHO SCHOOL OF ENGINEERING CIVIL ENGINEERING DEPARTMENT Refurbishment challenges of nzeb Cost optimal building renovation with zero energy target Manuela Almeida University of Minho 29 September
More informationPassive houses for the Northern climate
Passive houses for the Northern climate Jyri Nieminen Customer Manager VTT Technical Research Centre of Finland Finland Jyri.Nieminen@vtt.fi Jouko Knuutinen Regional Director TA Yhtymä Finland Jouko.Knuutinen@TA.fi
More informationEfficiency house. Building description
Efficiency house Building description Building use Primary school Construction year 1968 Completion of improving the energy efficiency 04/2011 Living space 1162 m² Numbers of stories 1 Features Address
More information> Performance requirements: Part L UK vs Energiesprong vs Passivhaus.
> Performance requirements: Part L UK vs Energiesprong vs Passivhaus. Introduction The purpose of this paper is to highlight and compare the difference in performance requirements between UK Building Regulations
More informationThe Effects of Set-Points and Dead-Bands of the HVAC System on the Energy Consumption and Occupant Thermal Comfort
The Effects of Set-Points and Dead-Bands of the HVAC System on the Energy Consumption and Occupant Thermal Comfort Ongun Berk Kazanci, Bjarne W. Olesen 1 1 International Center for Indoor Environment and
More informationBuilding Concepts for a mid-century energy-neutral society
ECN-M--6-15 SET26-5 th International Conference on Sustainable Energy Technologies. Vicenza, Italy Page 1 of 8 Building Concepts for a mid-century energy-neutral society I.J. Opstelten, E.J. Bakker, B.J.
More informationBUILDING REGULATIONS PART L 2011 PROVISIONS & COSTS (STANDARD 3-BED SEMI-D, CIRCA 120 SQM)
BUILDING REGULATIONS PART L 2011 PROVISIONS & COSTS (STANDARD 3-BED SEMI-D, CIRCA 120 SQM) NOV 2012 OVERALL PRIMARY ENERGY, CO 2 & RENEWABLES TGD L 2005-2013 2005 2007/8 2011 2013? CO 2 % 100% 69% 46%
More informationProject Description. Projected build start date 01 May 2010 Projected date of occupation 01 Nov Belfast, County Antrim, Northern Ireland
http://lowenergybuildings.org.uk Project name Eco-Energy Retrofit, Grove Housing Association, Belfast Project summary The mid terrace solid wall house built in 1896, is located in North Belfast and owned
More informationStudy of the energy performance of a retrofitting office
Study of the energy performance of a retrofitting office Paolo Valdiserri CIRI Edilizia Costruzioni, Università di Bologna paolo.valdiserri@unibo.it Abstract Building retrofitting is the most feasible
More informationEXAMPLES ON DEEP RENOVATION IN PUBLIC BUILDINGS
EXAMPLES ON DEEP RENOVATION IN PUBLIC BUILDINGS PALERMO 28 FEBRUARY 2017 CERTUS WORKSHOP COST EFFICIENT OPTIONS AND FINANCING MECHANISMS FOR NEARLY ZERO ENERGY RENOVATION OF EXISTING BUILDINGS STOCK KIRSTEN
More informationAdaption of the passive house concept in northern Sweden - a case study of performance
Passivhus Norden 2013 Adaption of the passive house concept in northern Sweden - a case study of performance Itai Danielski, The Department of Ecotechnology and Sustainable Building Engineering, Mid Sweden
More informationVerified net Zero Energy Building with air source heat pumps for SME
Verified net Zero Energy Building with air source heat pumps for SME Field measurements were conducted on a net zero energy building designed for small to medium enterprises (SMEs). Energy flow and comfort
More informationHomesol Passive House Design Process
Homesol Passive House Design Process Passive Houses are residential, commercial and institutional buildings in which a comfortable temperature can be achieved year round with a 75% 85% reduction in energy
More informationSingle family semi-detached four-bedroom home in London, England
Passivhaus Project Documentation Hiley Road Retrofit Passivhaus, London, UK Abstract Single family semi-detached four-bedroom home in London, England Building data Year of Construction 2016 0.076 Space
More informationBuilding Performance Evaluation
BUILDING PERFORMANCE EVALUATION CASE STUDY ONE BRIGHTON One Planet Living Zero carbon (renewable heat, on and off-site renewable electricity) Mechanical ventilation with heat recovery, communal heating,
More informationMethodology, Calculations and Results
1 BEEM-UP Building Energy Efficiency for Massive market Uptake: Methodology, Calculations and Results Ulrich Baum, LUWOGE consult GmbH, Holger Wallbaum, Chalmers University of Technology, Friedrich Reuter,
More informationEngineers Ireland Cork Region CPD lecture series
Engineers Ireland Cork Region CPD lecture series NZEB and Emerging Legislation & SEAI s Deep Retrofit Pilot Programme Orla Coyle NZEB Programme Manager Conor Hanniffy Deep Retrofit Pilot Programme Manager
More informationBUILDING ENERGY SYSTEMS
BUILDING ENERGY SYSTEMS Week 6 7LYM30 Building performance and energy systems simulation Building District Regional 2 Other challenges» Real challenge: existing buildings» Building + system building =
More informationLow energy buildings
Low energy buildings the basis for realizing the strategy for independency of fossil fuels in 2050 NSB 2011 Tampere 2011-05-31 Professor Svend Svendsen Department of Civil Engineering Technical University
More informationSOLAR XXI: A Portuguese Office Building towards Net Zero-Energy Building
SOLAR XXI: A Portuguese Office Building towards Net Zero-Energy Building Helder Gonçalves PhD, Director of the Energy Laboratory, National Energy and Geology Laboratory, Portugal email: helder.goncalves@lneg.pt
More informationBuilding Technology Research in Architectural Practice: Lessons Learned from Implementations of Energy-Efficient Advanced Building Technologies
Building Technology Research in Architectural Practice: Lessons Learned from Implementations of Energy-Efficient Advanced Building Technologies Ajla Aksamija and Abul Abdullah, Perkins+Will ABSTRACT This
More informationActive solar heating system with concrete plate heating analysed with dynamical thermal simulations
Active solar heating system with concrete plate heating analysed with dynamical thermal simulations Dr. D. Pahud SUPSI DCT Laboratory of Energy, Ecology and Economy, phone + 41 91 935 13 53, fax + 41 91
More informationSOLAR PHOTOVOLTAIC ENERGY
SOLAR PHOTOVOLTAIC ENERGY THE PHOTOVOLTAIC TECHNOLOGY PRODUCES CLEAN ELECTRICITY FROM SOLAR ENERGY 126 m 2 of photovoltaic modules are installed that generate about 12,000 kwh electricity per year, equivalent
More informationPASSIVHAUS Designed for you to enjoy maximum comfort with minimum energy.
PASSIVHAUS Designed for you to enjoy maximum comfort with minimum energy. + Energy efficiency + Savings +Comfort WHAT IS PASSIVHAUS? The Passivhaus (Passive House) standard is the most stringent international
More informationBruck an der Mur. Project summary. Energy concept: Background for the renovation reasons
Bruck an der Mur Project summary Energy concept: Background for the renovation reasons The aim of this project was to gather information and experiences of the pilot project and the research, so that those
More informationResidential buildings retrofit: the role of solar technologies
Residential buildings retrofit: the role of solar technologies Chiara Dipasquale 1, Roberto Fedrizzi 1 and Alessandro Bellini 1 1 Institute for Renewable Energy, Eurac Research, Bolzano (Italy) Abstract
More informationFinancing Energy Efficiency in Malta and Italy
Financing Energy Efficiency in Malta and Italy Westin Dragonara Resort, St Julians, Malta 22 November 2018 Overview of Energy Performance of the Maltese Housing Stock Prof. Vincent Buhagiar Department
More informationCCHVAC REHVA Workshop in CLIMA nzeb experiences in South Europe and Mediterranean Climate
CCHVAC REHVA Workshop in CLIMA 2019 nzeb experiences in South Europe and Mediterranean Climate Stefano P. Corgnati Aalborg - 2016 Mediterranean climate North Europe South Europe - Control of thermal loads
More informationProject Description. Projected build start date 01 Mar 2010 Projected date of occupation 01 Aug Energy target.
http://lowenergybuildings.org.uk Project name Larch House, Ebbw Vale, Wales Project summary The Larch House, designed by bere:architects, is the UKs first zero carbon (code 6), low cost, Certified Passivhaus,
More informationROW - Albertslund, DK
PROJECT SUMMARY Renovation and additional insulation of roof, facades and floor. New bay windows, bathrooms, kitchens and interior surfaces. Designed per Danish low energy class 2 (63,3 kwh/m² a for a
More informationProject Description. Projected build start date 24 Dec 2004 Projected date of occupation. Energy target. Existing external wall construction
http://lowenergybuildings.org.uk Project name Withy Cottage Project summary Timber Frame & Straw Bale self build with thermal bridge free construction (other than door and window frames). Simple flat raft
More informationPowerhouse the unique and the ingenious Powerhouse Kjørbo facts and figures Powerhouse economy and motivation Q & A
Powerhouse the unique and the ingenious Powerhouse Kjørbo facts and figures Powerhouse economy and motivation Q & A ASPLAN VIAK AS: ARCHITECTURE AND CONSULTING COMPANY Approx. 900 employees with expertise
More informationKindergarten Vejtoften, Høje-Taastrup, Denmark
FAIR ON PASSIVE CONSTRUCTION AND RENOVATION WORKSHOP IEA SHC TASK 47, RETROFIT OF NON-RESIDENTIAL BUILDINGS: AN INTERNATIONAL EXPERT VIEW ON EXEMPLARY PROJECTS Brussels, 7 September 2012 Kindergarten Vejtoften,
More informationScienceDirect ENERGY EFFICIENT REFURBISHMENT TOWARDS NEARLY ZERO ENERGY HOUSES, FOR THE MEDITERRANEAN REGION
Available online at www.sciencedirect.com ScienceDirect Energy Procedia 83 (2015 ) 533 543 7th International Conference on Sustainability in Energy and Buildings ENERGY EFFICIENT REFURBISHMENT TOWARDS
More informationOPEN COMPETITION Energy Design of High Performance Buildings Organised by EC-JRC and ESRU
OPEN COMPETITION Energy Design of High Performance Buildings Organised by EC-JRC and ESRU Target group: under-graduate, postdoc, PhD students and researchers level SUMMARY The objective is to assess for
More informationProject name Fulford Passivhaus, York Project summary New-build singe-family detached house for individual clients. Certified as Passivhaus Plus.
http://lowenergybuildings.org.uk Project name Fulford Passivhaus, York Project summary New-build singe-family detached house for individual clients. Certified as Passivhaus Plus. Project Description Projected
More informationDeep thermomodernization of three residential buildings in Kryvyi Rih, Ukraine
Deep thermomodernization of three residential buildings in Kryvyi Rih, Ukraine Kamil Różycki 1,* 1 Warsaw University of Technology, Division of Refrigeration and Energy in Buildings, Nowowiejska 21/25,
More informationProject Description. Projected build start date 12 Apr 2010 Projected date of occupation 28 Feb
http://lowenergybuildings.org.uk Project name PassivHaus Retrofit - Octavia Housing Project summary PassivHaus retrofit of a three storey solid brick Victorian terraced house in a conservation area. Produce
More informationOFFICE BUILDINGS IN DIFFERENT CLIMATE ZONES FROM ROMANIA - COMPARATIVE STUDY ON ENERGY EFFICIENCY INDICATORS
Bulletin of the Transilvania University of Braşov Vol. 10 (59) Special Issue No. 1-2017 Series I: Engineering Sciences OFFICE BUILDINGS IN DIFFERENT CLIMATE ZONES FROM ROMANIA - COMPARATIVE STUDY ON ENERGY
More informationResidential New Construction Passive House The Nordeast Nest Case Study Tim Eian, Dipl.-Ing., Certified Passive House Planner & Consultant
Residential New Construction Passive House The Nordeast Nest Case Study Tim Eian, Dipl.-Ing., Certified Passive House Planner & Consultant In accordance with the Department of Labor and Industry s statute
More informationIEA. Retrofit of the Library Building of the University of Bremen
IEA Energy Conservation in Buildings and Community Systems, Annex 36 Case studies overview Retrofit of the Library Building of the University of Bremen 1 Photo Figure 1: Left: Entrance area of the Bremen
More informationSingle family low energy house, Herselt, Belgium
PROJECT SUMMARY Retrofit of a century old land-house into a single family low energy house. SPECIAL FEATURES House meets Universal Design criteria. ARCHITECT S. Corten OWNER Verbruggen-Jennes Single family
More informationThe Importance of Slab Edge & Balcony Thermal Bridges
Date RDH Building Engineering Ltd. September 24, 2013 The Importance of Edge & Balcony Thermal Bridges Report # 3: Energy Consumption and Cost Savings of Thermal Breaks Prepared by The Importance of Edge
More informationProject Description. Projected build start date Projected date of occupation. Existing external wall construction.
http://lowenergybuildings.org.uk Project name Admirals Hard Project summary FINALIST of the UK Passivhaus Awards 2015 - Situated on the Stonehouse peninsula, by the banks of the River Tamar, Number 3 Admirals
More informationPrimary School Retrofit Project
Primary School Retrofit Project Final Design Proposal Ian Black DIT D12124703 Passiv Haus Design Criteria PHI ENERPHIT CRITERIA EnerPHit Certification based on the requirement for heating demand Heating
More informationPotential of ventilative cooling in German residential buildings
Potential of ventilative cooling in German residential buildings QUALICHeCK-Webinar, 2016-12-01 Auf Wissen bauen Fraunhofer IBP Introduction Background Highly insulated buildings with almost completely
More informationSingle family house in Herselt BE
Single family house in Herselt BE PROJECT SUMMARY Retrofit of a century old countryhouse into a low energy house. SPECIAL FEATURES House meets Universal Design criteria. ARCHITECT S. Corten OWNER Verbruggen-Jennes
More informationDienstleistung. Certification as "Quality Approved Passive House" Criteria for Residential-Use Passive Houses
Passiv Haus Institut Passivhaus Dienstleistung GmbH Dr. Wolfgang Feist Rheinstr. 44/46 Rheinstr. 44/46 D-64283 Darmstadt D-64283 Darmstadt www.passiv.de www.passivhaus-info.de Certification as "Quality
More information