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27/09/2014- Sustainable Places– Nice PAGE 1 Matthieu COSNIER - Daniel QUENARD Direction Energie Environnement CSTB Grenoble NZEB & EV for Energy Positive.

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Presentation on theme: "27/09/2014- Sustainable Places– Nice PAGE 1 Matthieu COSNIER - Daniel QUENARD Direction Energie Environnement CSTB Grenoble NZEB & EV for Energy Positive."— Presentation transcript:

1 27/09/2014- Sustainable Places– Nice PAGE 1 Matthieu COSNIER - Daniel QUENARD Direction Energie Environnement CSTB Grenoble NZEB & EV for Energy Positive Communities ADEME POLINOTEN Project : CEA, IFPEN, DAUPHINE,CSTB Sustainable Places 01/10/2014 NZEB : Nearly Zero Energy Building EV : Electric Vehicle

2  Context  Simulation  Results  Prospective  Conclusion CONTENT

3 CO2 EMISSION - FRANCE Transportation + Buildings : 47 % GHG – 70 % Energy CONTEXT

4 CO2 EMISSION - HOUSEHOLD 2 : HOUSING 3 : FOOD 1 :TRANSPORTATION Source : GREEN INSIDE – IPSOS - 2011 TRANSPORTATION HOUSING FOOD TRANSPORTATION HOUSING FOOD CARBON FOOTPRINT HOUSEHOLD PERSON

5 … the household’s “energy burden” 1 : THERMAL REGULATION Heating, Cooling, DHW, Ventilation, Lighting & Pumps & Fans 50 kWh-PE/m².year 2 : APPLIANCES & ICT 2700 kWh/year 70 kWh-PE/m².year (Source ADEME) 4 : EMBODIED ENERGY Building only 50 kWh-PE/m².year (50 years) Missing ENR Appliances & ICT Transportation ICEEV Consumption7l/100km150Wh/km 70kWh/100km15kWh/100km km/an14000 Consumption9800 kWh/year2600 kWh/year 6708 kWh-PE/year 3 : MOBILITY ICE : 9800 kWh/year EV : 2600 kWh/year EV : 6700 kWh-PE/year ICE : 98 kWh/m².y. (100 m²) EV : 67 kWh-PE/m².y. (100 m²) Source : PLAN BATIMENT GRENELLE -LA GARANTIE DE PERFORMANCE ENERGETIQUE Heating DHW

6 Household’s Energy Expenditures (2006) Total : 27381 €/year Energy : 2300 €/year 2006 : 8,4 % (fuel poverty : 10%) 4,8 % Housing 3,6 % Transportation FOOD ENERGY Source : INSEE

7 … the TECHNOLOGIES to meet the NEEDS Source : Cardonnel REN HOME ? ICE & BOILER Since 1850 Resource Depletion Climate Change Pollution & Health Impact MOBILITY & COMFORT

8 PAGE 8 PV and plug-in station at home PV and plug-in station at work PV and plug-in station at home & work  2 Climates: North and South of France  2 Commuting distances: 50 km and 16 km Where are the cars ? Source : Projet KLEBER - Strasbourg Source – GM-SAE France 18 Millions of Single Houses = 18 Millions of Charging Points ? HOME WORK CHARGING POINT STREET

9 3 scenario HOMEWORK Every Day Travel : 50 km Round Trip - 16 km Round Trip + 100 km WE Charge at Night : 10pm-8am EV Battery used from 6pm-10pm Charge 10am-12am at Work :14pm-17h30pm SIMULATION

10 Hypothesis & Scenario PAGE 10 PV & Climate o 140 Wc/m² o Whole system efficiency : 86 %  Two cities - Data from METEONORM o Trappes : 973 Wh/Wc o Carpentras : 1320 Wh/Wc  PV surface at work : 13 m 2  PV surface at home : from 24m 2 à 47 m 2 EV Battery  25 kWh  EV consumption : 200 Wh/km  230 V 16 A - Power =3700 W Electricity Consumption at Home  Data from Annex 42 de l’EA o Measured in UK 2003 et 2005 o Household (65 m², 2 Childs) o Electricity Consumption : 3028 kWh/year  Electricity Profiles : 1 year, every 5 minutes  Simulation : 1 year  Heating and DHW are not taken into account as they do not used electricity as energy source Commuting & Travel (WE) Scenario Two Average distances : 16 km & 50 km AR At home : 6 pm – 8 am At work : 8h30 am – 5h30 pm Travel : ½ hour WE : 50 km/day – 2 am -5 am EV battery used as energy source : 6 pm – 10 pm At home : grid charge : 10h am -8h pm At work : grid charge : 10 pm -12 & 2 am- 5h30 am

11 Scenario PAGE 11 Ref. km site PVPV at HomePV at Work PV Surface at Home PV Surface at Work Total PV Surface 1a50TH6,72 kWc0 kWc47,6 m 2 0 m 2 47,6 m 2 1b50TW3,68 kWc1,92 kWc26,1 m 2 13,6 m 2 39,7 m 2 1c50THW6,72 kWc1,92 kWc47,6 m 2 13,6 m 2 61,2 m 2 1d50CH4,96 kWc0 kWc35,1 m 2 0 m 2 35,1 m 2 1e50CW2,72 kWc1,92 kWc19,3 m 2 13,6 m 2 32,9 m 2 1f50CHW4,96 kWc1,92 kWc35,1 m 2 13,6 m 2 48,8 m 2 2a16TH4,64 kWc0 kWc32,9 m 2 0 m 2 32,9 m 2 2b16TW3,68 kWc1,92 kWc26,1 m 2 13,6 m 2 39,7 m 2 2c16THW4,64 kWc1,92 kWc32,9 m 2 13,6 m 2 46,5 m 2 2d16CH3,36 kWc0 kWc23,8 m 2 0 m 2 23,8 m 2 2e16CW2,72 kWc1,92 kWc19,3 m 2 13,6 m 2 32,9 m 2 2f16CHW3,36 kWc1,92 kWc23,8 m 2 13,6 m 2 37,4 m 2 Case Studies T : Trappes (North) – C : Carpentras (South) H : Home – W : Work

12 TRNSYS software PAGE 12

13 PAGE 13 PV and plug-in station at home PV and plug-in station at work PV and plug-in station at home & work  2 Climates: North and South of France  2 Commuting distances: 50 km and 16 km Priorities HOMEWORK

14 Consumption/Production Profile (at home) SOC EV battery MAY SOC EV Battery Battery Charging Consumption - Grid PV Home to Work Work to Home

15 PAGE 15 Trappes 50km - PV- At Home At homeAt work PV surface at home PV surface at work Total PV Surface 6,72 kWc0 kWc47,6 m 2 0 m 2 47,6 m 2 RESULTS LOAD

16 PAGE 16 Trappes 50km PV-At Work At homeAt work PV surface at home PV surface at work Total PV Surface 3,68 kWc1,92 kWc26,1 m 2 13,6 m 2 39,7 m 2 LOAD

17 Capteurs Solaires / Batteries PAGE 17 Trappes 50km PV- H+W At homeAt work PV surface at home PV surface at work Total PV Surface 6,72 kWc1,92 kWc47,6 m 2 13,6 m 2 61,2 m 2 LOAD

18 Capteurs Solaires / Batteries PAGE 18 Carpentras 16km PV- H+W At homeAt work PV surface at home PV surface at work Total PV Surface 3,36 kWc1,92 kWc23,8 m 2 13,6 m 2 37,4 m 2 LOAD

19 PAGE 19 Trappes 50km PVHomeWorkH+W At home 7238 kWh3964 kWh7238 kWh At work 0 kWh1985 kWh To the grid 4964 kWh3512 kWh5921 kWh Use of PV To the H grid Use EV H Use To the H grid To the W grid EV W EV H EV W

20 PAGE 20 Trappes 50 km PVHomeWorkH+W Cons.3028 kWh Grid1133 kWh1848 kWh1130 kWh EV521 kWh0 kWh524 kWh Electricity sources for Appliances H Grid H PV EV

21 Sommaire PAGE 21 Trappes 50km PVHomeWorkH+W Cons.3345 kWh2735 kWh3351 kWh Grid2446 kWh1479 kWh1424 kWh EV Source H Grid W Grid H Grid H PV W PV H PV W PV

22 Sommaire PAGE 22 Carpentras 16km PVHomeWorkH+W Cons.1424 kWh869 kWh1511 kWh Grid643 kWh0 kWh65 kWh EV Source H Grid H PV W PV H PV W PV

23 PAGE 23 Building Autonomy EV Solar Charging Trappes 50kmTrappes 16km Carpentras 50kmCarpentras 16km % time EV Solar Charging% time Building Autonomy HOME WORK H + W HOME WORK H + W HOME WORK H + W HOME WORK H + W

24 Urban Density Newman & Kenworthy Curb CITIES 50% of world population (60% in 2030) 75% of energy consumption 75% of GHG 60 % of water consumption Around 1% of the planet surface Source : SIEMENS PROSPECTIVE OIL CONSUMPTION GJ DENSITY capita per hectare US ASIA EUROPE AUSTRALIA

25 « Fossil Resource's » Model “solar” Model DENSITY hab./hectare ENERGY CONSUMPTION MJ/hab.an 1 kWh = 3,6 MJ … Energy Transition ? Newman-Kenworthy Curb NZEB + VE ICE + Boilers Source : Dense cities in 2050: the energy option? R. Ménard – ECEEE - 2011

26 Limitations / questions  One car, one home, one building …  Heating & DHW don’t take into account …  V2G, V2H, V2B ?  Battery cycling, cost ?  Consumption model for travelling ?  Charging point location ?  “energy gardening” & “grid discretion” ?  …

27 PAGE 27 CONCLUSION California Building Code Incentives in US & Canada

28 Thank you Questions ? 1912 Source : Hermes

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