Advancement in Urban Climate Modelling at Local Scale: Urban Heat Island Mitigation and Building Cooling Demand
Open access
Autor(in)
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Datum
2020-12Typ
- Journal Article
ETH Bibliographie
yes
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Abstract
As cities and their population are subjected to climate change and urban heat islands, it is paramount to have the means to understand the local urban climate and propose mitigation measures, especially at neighbourhood, local and building scales. A framework is presented, where the urban climate is studied by coupling a meteorological model to a building-resolved local urban climate model, and where an urban climate model is coupled to a building energy simulation model. The urban climate model allows for studies at local scale, combining modelling of wind and buoyancy with computational fluid dynamics, radiative exchange and heat and mass transport in porous materials including evaporative cooling at street canyon and neighbourhood scale. This coupled model takes into account the hygrothermal behaviour of porous materials and vegetation subjected to variations of wetting, sun, wind, humidity and temperature. The model is driven by climate predictions from a mesoscale meteorological model including urban parametrisation. Building energy demand, such as cooling demand during heat waves, can be evaluated. This integrated approach not only allows for the design of adapted buildings, but also urban environments that can mitigate the negative effects of future climate change and increased urban heat islands. Mitigation solutions for urban heat island effect and heat waves, including vegetation, evaporative cooling pavements and neighbourhood morphology, are assessed in terms of pedestrian comfort and building (cooling) energy consumption. Mehr anzeigen
Persistenter Link
https://doi.org/10.3929/ethz-b-000456068Publikationsstatus
publishedExterne Links
Zeitschrift / Serie
AtmosphereBand
Seiten / Artikelnummer
Verlag
MDPIThema
Heat wave; Urban heat island; Urban climate; Evaporative cooling; Vegetation; Cooling demandOrganisationseinheit
03806 - Carmeliet, Jan / Carmeliet, Jan
Förderung
169323 - Wind-driven rain impact of urban microclimate: wetting and drying processes in urban environment (SNF)
ETH Bibliographie
yes
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