1 / 30

Department of Architecture The University of Hong Kong

Department of Architecture The University of Hong Kong. Building Design for Cold Climates. Sam C M Hui, Mar 2001. Contents. Climate Basics Cold Climates Response to Climate Human Factors. Climatic zones in the world. Climate Classifications. Cold climates. Temperate climates.

garan
Download Presentation

Department of Architecture The University of Hong Kong

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. Department of ArchitectureThe University of Hong Kong Building Design for Cold Climates Sam C M Hui, Mar 2001

  2. Contents • Climate Basics • Cold Climates • Response to Climate • Human Factors

  3. Climatic zones in the world

  4. Climate Classifications Cold climates Temperate climates Hot-dry climates Warm-humid climates

  5. Climate Basics • Cold climates • lack of heat (under-heating) • Temperature climates • seasonal variation between under-heating and over-heating • Hot-dry (arid) climates • overheating, dry • Warm-humid climates • overheating, humid

  6. Climate Basics • Climatic elements • Temperature • Humidity • Air movement (wind speed and direction) • Precipitation (rain, hail, snow, dew) • Cloud cover • Sunshine duration • Solar radiation

  7. Major climatic elements of Hong Kong

  8. Cold Climates • Polar climates require special attention • Assume temperate climates • e.g. Canada, UK, New Zealand, Northern China • Severe winters, with snow and strong icy winds • Major considerations • Max. summer temperatures • Min. winter temperatures • Annual rainfall and humidity (dry or wet) • Sky conditions (cloudy or clear)

  9. Cold Climates • Design principles • Minimal surface-to-volume ratio • Insulation of all external surfaces is very important • Small windows and openings, preferably double-glazed • Annual solar gains through windows are generally less that associated heat losses • Use of exposed internal thermal mass • Lightweight insulated structures are quick to heat up but also quick to cool, • Heavyweight structures are slow to heat up and cool down.

  10. Cold climate (example) - protection from wind, cold, snow drift and snow load - design for minimum heat loss

  11. Temperature climate (example) • protection from rain, snow, cold winds, moderate summer • heat & moderate winter cold • minimize heat loss, maximize isolation in winter; consider • summer shading and ventilation

  12. Tokyo, January 1998

  13. How could I respond to cold climate? • Main criteria: • built form • orientations • wall area • window area • thermal insulation • thermal mass * Face House, Kyoto, Japan

  14. Response to Climate Climate-responsive building (Tokyo Gas Earth Port, Japan)

  15. General climate control strategies

  16. Response to Climate • Building envelope - outer shell of a building that determines external thermal forces • exterior walls • exterior windows • roofs • underground slab and foundation • doors open to outdoor

  17. Response to Climate • Major factors determining envelope heat flow: • temperature differential, T • area of exposed building surfaces, A • heat transmission properties, like U-value • thermal storage capacity • Effect of thermal mass • delay heat transfer and store heat • important for intermittently heated spaces

  18. Response to Climate Selection and design of window system

  19. Effective use of solar energy } Active solar Passive solar {

  20. Human Factors Heat conduction and convection Solar heat and radiation Evaporative heat loss Wind chill

  21. Human Factors Thermal comfort & design conditions ASHRAE comfort envelope

  22. Local thermal discomfort Asymmetric thermal radiation Draft Vertical air temp. diff. Warm or cold floor

  23. Draft - undesired local cooling of human body caused by air movement

  24. Asymmetric thermal radiation in a space

  25. Vertical air temperature difference - the temperature gradient may cause local warm discomfort at the head and/or cold discomfort at the feet

  26. Warm or cold floor - direct contact between the feet and the floor causes discomfort; flooring material is important to avoid this problem

  27. References • Climatic Design of Buildings - An Overview • http://arch.hku.hk/~cmhui/teach/65156-7.htm • Climatic Design • http://fridge.arch.uwa.edu.au/topics/thermal/climate/design.html • Climate Classification • http://fridge.arch.uwa.edu.au/topics/thermal/climate/classification.html

  28. References • Hutcheon, N. B. and Handegord, G. O.P., 1983. Building Science for a Cold Climate, National Research Council of Canada, Toronto. [690.0911 H9] • Lstiburek, J. W., 2000. Builder’s Guide to Cold Climates: Details for Design and Construction, Taunton Press, Newtown, Conn. [693.8 L925 b] • Markus, T. A. and Morris, E. N., 1980. Buildings, Climate, and Energy, Pitman, London. [697 M34] • Watson, D. and Lab, K., 1983. Climatic Design: Energy-efficient Building Principles and Practices, McGraw-Hill, New York, 1983. [697.9 W3]

  29. Further questions: Web: http://arch.hku.hk/research/BEER Email: cmhui@hku.hk

More Related