Climate Analysis

1. Climate Analysis

2. Climate • Most important environmental factor and the first one that should be considered • Can dictate what passive design strategies will be suitable and effective

3. Climate • Dictated by its latitude altitude, and terrain • Influences many aspects of the buildings design • Indoor temp • Predicted energy loads • Factors controlling human thermal comfort

4. Climate • Not and interchangeable term with weather • Climate is the average atmospheric conditions over a long period of time • Weather is the daily temp and atmospheric conditions

5. Climate • Classifications • Köppen-Geiger climate classification system • US climate zones • California climate zones

6. Microclimate • Microclimate • Small area that features different climate characteristics from the overall climate zone it is located in • Typically caused by different topographies, bodies of water, vegetation, site surroundings

7. Temperature • Varies throughout the day and obviously year • Consider for passive heating and cooling design • Two aspects of temperature are dry bulb temp and wet bulb temp

8. Temp

9. Dry bulb • Temperature of the air • Moisture is not considered • Celsius, Fahrenheit, or Kelvin • Reported and referred to as air temperature

10. Wet Bulb • Air temperature • Takes into account cooling potential of evaporation • Measured by exposing a moistened thermometer bulb to air flow (wrap a thermometer in a wet cloth and swing it in the air) • Evaporation of the moisture depends on the humidity of the air

11. Wet bulb • Measured in Celsius, Fahrenheit, or Kelvin • 100% humidity the air is completely saturated • Dry and wet bulb temps will be the same • Any other scenario the wet bulb temp is less than the dry bulb temp, due to evaporative cooling • The larger the difference between dry and wet temps, the drier the air and lower the relative humidity

12. Temp • Sites will obviously vary • Heating will dominate design requirements for most of the year in one • Cooling may dominate the design in another • Temperatures for the site can be seen on a histogram of the temp • Temperature bins

13. Temp charts • Temps are not consistent at the same time of day or year • Robust design • Design for an uncommon circumstance as well as the average

14. Temp charts • Shows the historical averages of monthly highest and lowest dry bulb temps

15. Temp Charts • Extensions show extreme temps only recorded 1% of the time

17. Diurnal Weather Avg • Show daily cycles of temp and radiation on the site • Typically included dry and wet bulb temps, direct solar radiation, diffuse solar radiation as a daily avg for each month • Difference between dry and wet bulb gives a relative humidity indicator • Difference in night and daytime temps (diurnal swing)

18. Diurnal Weather Avg

19. Degree Days • To get a sense of heating/cooling requirements a comfortable temp range should be set (comfort zone) • This can be compared to the building site’s actual temp over time • When the site’s temp is outside the zone it is measured in heating or cooling “degree days”

20. Degree days • If weather is an average of 1 degree warmer than comfortable for 1 day, the building needs 1 “degree day” of cooling • If it is 10 degrees warmer for 1 day then it needs 10 degree days of cool • Helpful to make comparisons between buildings more fair

21. Degree days • Temp past a threshold, multiplied by time

22. Humidity • Can be just as important as temp • Too much can amplify the heat and make it muggy, not enough makes it too dry • Warm air can hold more moisture than the cold air • People don’t perceive the absolute number water molecules in the air(absolute humidity, measured in density) • Perceive relative humidity which is represented as percentage of water vapor in the air

23. Larger the difference is between the dry/wet temps, the drier the air is and the lower the relative humidity

24. Humidity • People generally consider 40-55% relative humidity to be comfortable • Also affects what passive heating/cooling strategies will be effective • Evaporative cooling is much more effective in dry climates • Controlling humidity is actively done by HVAC • Lot of latent heat in water, and de-humidifying the air requires cooling the water (lots of energy)

25. Humidity • Comparing the wet/dry bulb temps can determine humidity • 100% humidity the air is completely saturated • Dry and wet bulb temperature will be the same • All other scenarios the wet bulb is less than the dry bulb temp • Due to evaporative cooling • Larger the difference between dry/wet the drier the air and lower the relative humidity

26. Humidity • Often displayed in psychrometric charts • Like temp it varies throughout the day/year • Robust design requires designing for a range

27. Psychrometric Charts • Complex and difficult to understand • Allows visualization of a tremendous amount of info at once • Temp (wet & dry bulb) • Humidity (relative & absolute) • How comfortable the climate is and what passive/active strategies will be effective

28. Reading the Chart • Help determine what passive strategies to use • Evaporative cooling • Natural ventilation • Night purge ventilation • Direct solar gain plus thermal mass • Overlay human comfort zones on the chart to see how much passive strategies help expand the zone and how much energy you can save

29. Orange too hot • Blue too cold

30. Blue too humid • Yellow too dry

31. To condition air, heat/moisture is added/removed