1 / 39

Modeling Building Thermal Response to HVAC Zoning

Modeling Building Thermal Response to HVAC Zoning. Virginia Smith Tamim Sookoor Kamin Whitehouse April 16, 2012 CONET Workshop (CPS Week). Homes are ~30% vacant. * National Academy of Science, 2006. Homes are ~30% vacant. Smart Thermostat: 28% savings --Sensys 2010. Homes are

kalin
Télécharger la présentation

Modeling Building Thermal Response to HVAC Zoning

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Modeling Building Thermal Response to HVAC Zoning • Virginia Smith • Tamim Sookoor • Kamin Whitehouse • April 16, 2012 • CONET Workshop (CPS Week)

  2. Homes are • ~30% vacant * National Academy of Science, 2006

  3. Homes are • ~30% vacant • Smart Thermostat: 28% savings • --Sensys 2010

  4. Homes are • ~50% used • when occupied • Ongoing work: • Occupancy-driven • Zoning

  5. Homes are • ~50% used • when occupied • Ongoing work: • Occupancy-driven • Zoning

  6. Outline • Zoning Overview • Coordination Approach • Results

  7. Outline • Zoning Overview • Coordination Approach • Results

  8. “Snap-in” Zoning Retrofit

  9. “Snap-in” Zoning Retrofit • Low cost • DIY: no configuration • Focus on forced air • Other systems are similar

  10. Snap-in Zoning • Zoned Heat • K sensors • K heaters • K sensors • One heater • Central Heat • One sensor • One heater • K+1 Control Signals Q: When the system turns on: Which damper configuration will achieve the desired temperature distribution?

  11. Outline • Zoning Overview • Coordination Approach • Results

  12. Weather: • Has a large effect on temperature • Is not fully observable • Rarely repeats • Q: Can we learn the effect of dampers on temperature sensors without knowing the weather?

  13. T D

  14. When OFF: Train a dTk/dt =aT + ßD

  15. When ON: Use a; Train ß dTk/dt =aT + ßD

  16. Outline • Zoning Overview • Coordination Approach • Results

  17. Experimental Approach • Deployed zoning in a 7-room house • 7 sets of dampers • 12 thermostats • Controlled based on occupancy • 21 days of data

  18. T Time

  19. Conclusions • “Snap-in” Zoning • Cheap, easy, & energy saving • Coordination btwn objects is needed • Learning is complicated by weather • ON/OFF separates weather/system

  20. Credits & Questions Ginger Smith Tamim Sookoor Kamin Whitehouse

More Related