NU-ROOF

1. NU-ROOF CHEMNITZ MEETING – PROJECT UPDATE December 14-15th 2010 D’Appolonia

2. Agenda

3. Current status of the project WP1: concept WP2: research WP3: application guidelines and thermal modeling WP4: knowledge management system WP5: demo WP6: business models WP7: training WP8: management Duration: 36 Months Start: January 2010 End: December 2012

4. Next Steps, roles of the partners BORNER - TNO – STFI – NOTT – NTUA - NANO: concept and research DAPP : thermalanalysis BORNER – LCT – CATI – IFD – IMPRIMA – UNYA – DELL: applicationguidelines DAPP - LCT – CATI – IFD – AMSP – RED: Knowledge management system DAPP - AMSP: business modeling and LCA DELL – IMPRIMA – BORNER – LCT NANOPHOS: demos DAPP – LCT – CATI – IFD – IMPRIMA – UNYA – DELL : business modeling

5. Next Deliverables and key events to agree KEY EVENTS (TO BE AGREED): JANUARY: INTELLECTUAL PROPERTY PROTECTION PLAN FEBRUARY : DISSEMINATION PLAN (1) + KICK OFF OF BUSINESS MODELING (2) MARCH: TWO TECHNICAL MEETINGS (1) KICK OFF OF THE KNOWLEDGE PLATFORM DEVELOPMENT (2) WP2 MEETING AND DEMO PREPARATION APRIL: GUIDELINES AND TRAINING FOR IMPRIMA AND DELLACASA MAY: SUPPLY OF MATERIALS TO IMPRIMA AND DELLACASA

6. RESULTS FROM THERMAL SIMULATIONS (WP3 TASK3.1) SERGIO SEGRETO (DAPP) ANTONIO DE FERRARI (DAPP)

7. Tosimulateimpact on coolingandheatingloads Tocalculatepay back fortheuser Toinput Life Cycle Analysis → esp-r * Simple, fast and easy-to-usesoftware More precisethanmanualcalculationsbased on ASHRAE & ISO13790 and presented in June 2010 Ideal forBuildingsimulations: bigrepositoryofstandardmaterials PCM modulerecentlydeveloped * ESP-r is an integrated energy modelling tool for the simulation of the thermal, visual and acoustic performance of buildings and the energy use and gaseous emissions associated with associated environmental control systems. In undertaking its assessments, the system is equipped to model heat, air, moisture and electrical power flows at user determined resolution. The system is designed for the Unix operating system, with supported implementations for Solaris, Linux (SuSE, Ubuntu, etc.), OSX 10.5 and 10.6. It can also be run on Windows in the Cygwin environment, or it can be run in native Windows (XP Vista). ESP-r has a world-wide development community and its distribution is managed under Subversion source code control. The system is made available at no cost under an Open Sourcelicence. Objectives of Thermal simulation

8. Industrial building, 32mx32mx5m, 15% windows, Palermo climate standard bitumen based membrane, no insulation insulation + standard bitumen based membrane Nuroof concept 1 (reflective membrane), no insulation       insulation + Nuroof concept 1 Nuroof concept 2 insulation + Nuroof concept 2 Nuroof concept 2 insulation + Nuroof concept 2 Thermal simulations: used models EFFECT OF STANDARD INSULATION (5cm) EFFECT OF REFLECTANCE (from IR 0,1 to IR 0,65) EFFECT OF REFLECTANCE AND PCM (0,4KG/M2) EFFECT OF REFLECTANCE AND PCM+ (2KG/M2) roof waterproof membrane (4.5 mm) PS insulation layer (0->50 mm) Vermiculite concrete layer (30 mm) Concrete blocks (100 mm) ceiling

9. Assumptions (1) HVAC Zone control: During working hours (8h-18h weekdays, 8h-13h Saturday) the control maintains the temperature between 20°C and 26°C according to comfort living conditions, for the rest of the hours and during Sunday heating control set point is moved to 13°C to avoid ice formation in pipelines. Internal gains (values from reference study on industrial buildings in California): Occupants: Total horizontal surface of each floor is 1024 m², an average of 36 workers between 8h and 18h. No people in during the weekend. Person working: 125W (65.5W sensible, 65.5W latent) Total: 4500 W Lights: 18W/m², this is 18432W sensible. Lights in the office are off from 18h till 8h of the next morning. During working hours (8h-18h) all lights are on. All lights off during weekends. Equipment: 29000W (20000W sensible, 9000W latent / 0.4 radiant, 0.6 convection) taking into account the presence of laptops, printers, spot welders, ovens, electronic testing equipment, microscopes, air compressors, vacuum pumps, coffee machines, etc. During weekends overall energy consumption is estimated to be 5% of weekdays overall consumption (assumed as stand-by condition), i.e., 1450W (1000W sensible, 450W latent). Air Infiltration/Ventilation: An average infiltration rate of 0.7 air changes per hour throughout the working hours and 0.3 during remaining hours is considered. This implies around 12 changes of the whole volume of air inside the building for weekdays and 7.2 air changes per hour in Sunday. No ventilation included. Note: According to ESP-r all ventilations with atmospheric air are considered as infiltrations.

10. Assumptions (2) External wall (UNI TS 11300-1) Ground floor commercial building Door (http://www.ocmflex.com/it/index.shtml) Double glazed windows (http://www.double-glazing-uk.co.uk/U_values.asp)

11. Assumptions (3) Waterproof top layer + white paint (acrylic paint VIVECRYL) Material: Polyester (STFI) Thickness: 0,5 mm (STFI) Conductivity: 0.15 W/(m*K) (STFI - NTUA) Density: 100 g/m2 textile+ 100 g/m2 paint (STFI- NTUA) Specific heat: 1200 J/(kg*K) polyester + 3000 J/(kg*K) water-based paint (total value evaluated by weighting each specific heat value on weight) (STFI - NTUA) Absorptivity: 0.25 (STFI - NTUA) we have chosen this value as the lowest from the NTUA experimental set Functional layer with PCM in a polymer emulsion Material: Polyester (STFI- TNO) Thickness: 4 mm (STFI– TNO) Conductivity: 0.25 W/(m*K) at 25°C when PCM is solid, 0.14 W/(m*K) at 40°C when PCM is liquid (TNO) Density: 200 g/m2 textile + 0,4 kg/m2 PCM (TNO) corresponding to 80% impregnation Specific heat: 1200 J/(kg*K) polyester + 29700 J/KgK estimated from one DSC measurement Melting/crystallization temperature: 28°C (TNO) PCM Latent heat:  100 J/g (TNO)

12. Thermal Analysis Results First july (averaged 5 years) in Palermo PCM 2kg PCM 0,4kg/m2

13. Industrial building, 32mx32mx5m, 15% windows, Palermo climate, standard bitumen based membrane, no insulation insulation + standard bitumen based membrane Nuroof concept 1 (reflective membrane), no insulation       insulation + Nuroof concept 1 Nuroof concept 2 insulation + Nuroof concept 2 Nuroof concept 2 Thermal simulations: energy loads for HVAC EFFECT OF STANDARD INSULATION:--5,2% Sensible heating 1307 kWh Sensible cooling -63203 kW Sensible heating 309 kWh Sensible cooling -60845 kWh EFFECT OF REFLECTANCE -23% -14% Sensible heating 2015 kWh Sensible cooling -47458 kWh Sensible heating 430 kWh Sensible cooling -54808 kWh EFFECT OF REFLECTANCE AND PCM (0,4KG/M2) --- - 23% -14% Sensible heating 1928 kWh Sensible cooling -47723 kWh Sensible heating 427 kWh Sensible cooling -54840 kWh EFFECT OF REFLECTANCE AND PCM+ (2KG/M2) -23% Sensible heating 1925 kWh Sensible cooling -47697 kWh roof waterproof membrane (4.5 mm) PS insulation layer (0->50 mm) Vermiculite concrete layer (30 mm) Concrete blocks (100 mm) ceiling

14. Thermal Analysis Conclusions and Next Steps • Conclusions do not significantlydifferfrommanualcalculationsbased on ASHRAE & ISO13790: • PCM do not have a significantimpact. Onlyvery large quantities (>2 kg) have a significantimpact on surfacetemperatureandsmall on energysavings • Standard insulation do not providesignificantadvantages („hat“ effect)e • Reflectiveroofaloneisthe ideal solution in warm andtemperateclimateslike southern europe: itgets a significantenergysaving (upto 23% withtheminimum IR valuefrom NTUA preliminarytests)

15. PARALLEL MEETINGS

16. Technical meeting 1: role of associatons and smes for training, application guidelines, demo PARTICIPANTS (coordinator IFD) LCT, CAT, IFD, AMSP,IMPRIMA,UNYA,DELL,RED POINTS FOR DISCUSSION (if ok for you ) Do you have special requirements for the knowledge base? Do you have special requirements for the application guidelines? Are the associations interested on preliminary internal tests for application? What do we want to test on demos: application guidelines or energy saving measurements? Do you want to include self adhesive in the application guidelines? Dissemination plan EXPECTED OUTPUT TO DISCUSS AT THE COMMON SESSION: Final agreement on the above points (where possible) Planning of next activities Objectives of the Technical Meetings • Technical meeting 2 nuroof membrane technical development • PARTICIPANTS (coordinator DAPP) DAPP, NOTT, BORNER,STFI, NTUA,TNO POINTS FOR DISCUSSION (if ok foryou) • Common decisionabout PCM useandimpacts on conceptandfutureresearcheffortsforbothscenarios • Questionsfrom STFI (material, fieldtest) • Questionsfrom NTUA (useofslates, arginotec in top coat, ageingtest, useofwhitepaint) • Questionsfrom TNO and NOTT • Questionsfrom BORNER EXPECTED OUTPUT TO DISCUSS AT THE COMMON SESSION: • Final agreement on theabovepoints (wherepossible) • Planningofnextactivities

17. Objectives of the Technical Meetings • Technical meeting 2 nuroof membrane technical development • PARTICIPANTS (coordinator DAPP) DAPP, NOTT, BORNER,STFI, NTUA,TNO POINTS FOR DISCUSSION • 1) Need to find a coating expert andsupplier(waterproof acrylatebasedispersion) • NTUA -> setuptherequestforoffer (technicalpart) • NANO and NTUA -> draftlistofsuppliers • DAPP -> requestforofferanddecision on suppliers (MID JANUARY) • 2) Concept 2 • NTUA and DAPP-> setup a testingprotocol • STFI provideswith textile -> TNO -> BORNER -> NTUA -> final decision on pcms (APRIL) EXPECTED OUTPUT TO DISCUSS AT THE COMMON SESSION: • Final agreement on theabovepoints (wherepossible) • Planningofnextactivities