Urban microclimate and its impact on building performance: A case study of San Francisco

• Published in: Urban climate Vol. 38; no. C; p. 100871
• Main Authors: Hong, Tianzhen, Xu, Yujie, Sun, Kaiyu, Zhang, Wanni, Luo, Xuan, Hooper, Barry
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 01.07.2021; Elsevier
• Subjects: Building energy use; Building performance; Building simulation; CityBES; Climate resilience; Urban microclimate; Building performance; Urban microclimate; Building simulation; CityBES; Climate resilience; Building energy use
• ISSN: 2212-0955; 2212-0955
• DOI: 10.1016/j.uclim.2021.100871

Urban microclimate exerts an increasing influence on urban buildings, energy, and sustainability. This study uses 10-year measured hourly weather data at 27 sites in San Francisco, California, to (1) analyze and visualize the urban microclimate patterns and urban heat island effect; (2) simulate annual energy use and peak electricity demand of typical large office buildings and large hotels to investigate the influence of urban microclimate on building performance; (3) simulate indoor air temperature of a single-family house without air-conditioning during the record three-day heatwave of 2017, to quantify the divergence of climate resilience due to urban microclimate effect. Results show significant microclimate effects in San Francisco with up to 11 °C outdoor air temperature difference between the coastal and downtown areas on September 1, 2017, during the record three-day heatwave. The simulated energy results of the prototype large office and large hotel buildings using the 2017 weather data show over 100% difference in annual heating energy use and 65% difference in annual cooling energy use across different stations; as well as up to 30% difference in peak cooling electricity demand. The impacts on annual site or source energy use are minimal (less than 5%) as cooling and heating in a mild climate are a relatively small portion of overall building energy use in San Francisco. Results also show the microclimate effects influence indoor air temperature of unconditioned homes by up to 5 °C. Newer buildings and homes are much less affected by microclimate effects due to more stringent performance requirements of the building envelope and energy systems. These findings inform that San Francisco microclimate variations should be considered in urban energy planning, building energy codes and standards, as well as heat resilience policymaking. •10-year measured hourly weather data at 27 local stations in San Francisco are used.•San Francisco shows significant microclimate variations, especially during heat waves.•Large differences in simulated annual heating and cooling energy use of commercial buildings.•Unconditioned houses show 5 °C difference in indoor air temperature due to microclimate effect.•CityBES provides a visualization of urban microclimate.