Multi-criteria thermal resilience certification scheme for indoor built environments during heat waves

[en] With climate change, the indoor built environment is expected to influence the occupant's safety and wellbeing significantly. A novel multi-criteria thermal resilience certification scheme for indoor built environments during extreme heat events is proposed in this paper. The certification scheme considers overheating, thermal comfort, heat stress, and hygrothermal discomfort in built environments. These criteria are quantified using key performance indicators like indoor overheating degree, hours of exceedance, wet-bulb globe temperature, and heat index, respectively. This scheme is developed based on existing best practices like standards, rating systems, and literature. The scheme is implemented on a benchmark building energy performance model for detached post-World War II dwellings in Belgium as a case study using weather data measured from the City of Brussels. The indoor overheating in the reference dwelling is assessed with a static threshold of 27 °C for the bedrooms and adaptive thresholds for other areas. The analysis found that the building performance is within the defined threshold levels throughout the heat wave duration for all criteria. Therefore, the reference dwelling got a maximum attainable score of four points and is rated five-star for thermal resilience during heat waves. The proposed certification scheme is intended as a standardized framework and highlights the need for further revisions in building performance policies and guidelines.

Research Center/Unit :

Sustainable Building Design Lab

Disciplines :

Architecture

Author, co-author :

Amaripadath, Deepak ; Université de Liège - ULiège > Urban and Environmental Engineering

Mirzaei, Parham

Attia, Shady ; Université de Liège - ULiège > Urban and Environmental Engineering

Language :

English

Title :

Multi-criteria thermal resilience certification scheme for indoor built environments during heat waves

Publication date :

01 August 2024

Journal title :

Energy and Built Environment

eISSN :

2666-1233

Publisher :

Elsevier, Oxford, United Kingdom

Peer reviewed :

Peer Reviewed verified by ORBi

Development Goals :

11. Sustainable cities and communities

Additional URL :

https://www.sciencedirect.com/science/article/pii/S2666123324000618?via%3Dihub

Name of the research project :

SurChauffe

Funders :

SPW - Service Public de Wallonie

Funding number :

BEWARE2

Available on ORBi :

since 11 May 2024

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76 (11 by ULiège)

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Bibliography

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