Development and evaluation of a building energy model integrated in the TEB scheme
The use of air-conditioning systems is expected to increase as a consequence of global-scale and urban-scale climate warming. In order to represent future scenarios of urban climate and building energy consumption, the Town Energy Balance (TEB) scheme must be improved. This paper presents a new buil...
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doaj-d5097f180ec243c2b61eacb86931675b2020-11-24T23:01:01ZengCopernicus PublicationsGeoscientific Model Development1991-959X1991-96032012-03-015243344810.5194/gmd-5-433-2012Development and evaluation of a building energy model integrated in the TEB schemeB. BuenoG. PigeonL. K. NorfordK. ZiboucheC. MarchadierThe use of air-conditioning systems is expected to increase as a consequence of global-scale and urban-scale climate warming. In order to represent future scenarios of urban climate and building energy consumption, the Town Energy Balance (TEB) scheme must be improved. This paper presents a new building energy model (BEM) that has been integrated in the TEB scheme. BEM-TEB makes it possible to represent the energy effects of buildings and building systems on the urban climate and to estimate the building energy consumption at city scale (~10 km) with a resolution of a neighbourhood (~100 m). The physical and geometric definition of buildings in BEM has been intentionally kept as simple as possible, while maintaining the required features of a comprehensive building energy model. The model considers a single thermal zone, where the thermal inertia of building materials associated with multiple levels is represented by a generic thermal mass. The model accounts for heat gains due to transmitted solar radiation, heat conduction through the enclosure, infiltration, ventilation, and internal heat gains. BEM allows for previously unavailable sophistication in the modelling of air-conditioning systems. It accounts for the dependence of the system capacity and efficiency on indoor and outdoor air temperatures and solves the dehumidification of the air passing through the system. Furthermore, BEM includes specific models for passive systems, such as window shadowing devices and natural ventilation. BEM has satisfactorily passed different evaluation processes, including testing its modelling assumptions, verifying that the chosen equations are solved correctly, and validating the model with field data.http://www.geosci-model-dev.net/5/433/2012/gmd-5-433-2012.pdf |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
B. Bueno G. Pigeon L. K. Norford K. Zibouche C. Marchadier |
spellingShingle |
B. Bueno G. Pigeon L. K. Norford K. Zibouche C. Marchadier Development and evaluation of a building energy model integrated in the TEB scheme Geoscientific Model Development |
author_facet |
B. Bueno G. Pigeon L. K. Norford K. Zibouche C. Marchadier |
author_sort |
B. Bueno |
title |
Development and evaluation of a building energy model integrated in the TEB scheme |
title_short |
Development and evaluation of a building energy model integrated in the TEB scheme |
title_full |
Development and evaluation of a building energy model integrated in the TEB scheme |
title_fullStr |
Development and evaluation of a building energy model integrated in the TEB scheme |
title_full_unstemmed |
Development and evaluation of a building energy model integrated in the TEB scheme |
title_sort |
development and evaluation of a building energy model integrated in the teb scheme |
publisher |
Copernicus Publications |
series |
Geoscientific Model Development |
issn |
1991-959X 1991-9603 |
publishDate |
2012-03-01 |
description |
The use of air-conditioning systems is expected to increase as a consequence of global-scale and urban-scale climate warming. In order to represent future scenarios of urban climate and building energy consumption, the Town Energy Balance (TEB) scheme must be improved. This paper presents a new building energy model (BEM) that has been integrated in the TEB scheme. BEM-TEB makes it possible to represent the energy effects of buildings and building systems on the urban climate and to estimate the building energy consumption at city scale (~10 km) with a resolution of a neighbourhood (~100 m). The physical and geometric definition of buildings in BEM has been intentionally kept as simple as possible, while maintaining the required features of a comprehensive building energy model. The model considers a single thermal zone, where the thermal inertia of building materials associated with multiple levels is represented by a generic thermal mass. The model accounts for heat gains due to transmitted solar radiation, heat conduction through the enclosure, infiltration, ventilation, and internal heat gains. BEM allows for previously unavailable sophistication in the modelling of air-conditioning systems. It accounts for the dependence of the system capacity and efficiency on indoor and outdoor air temperatures and solves the dehumidification of the air passing through the system. Furthermore, BEM includes specific models for passive systems, such as window shadowing devices and natural ventilation. BEM has satisfactorily passed different evaluation processes, including testing its modelling assumptions, verifying that the chosen equations are solved correctly, and validating the model with field data. |
url |
http://www.geosci-model-dev.net/5/433/2012/gmd-5-433-2012.pdf |
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