Comprehensive improvement of energy efficiency and indoor environmental quality for university library atrium—A multi-objective fast optimization framework

Comprehensive improvement of energy efficiency and indoor environmental quality for university library atrium—A multi-objective fast optimization framework

Low-carbon, energy-saving, and health have become a common trend for the whole of mankind. However, how to balance the relationship between energy-saving and healthy indoor environment is a key issue for sustainable building development. This paper extracted the prototypical form of university libra...

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Bibliographic Details
Main Authors: Shen Xu, Yongzhong Chen, Jianlin Liu, Jian Kang, JinFeng Gao, Yuchen Qin, Wenjun Tan, Gaomei Li
Format: Article
Language:English
Published: KeAi Communications Co., Ltd. 2025-04-01
Series:Frontiers of Architectural Research
Subjects:
University library atrium
Spatial morphology
Building energy efficiency
Indoor environmental quality
Machine learning
Multi-objective optimization
Online Access:http://www.sciencedirect.com/science/article/pii/S2095263524001365
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Summary:Low-carbon, energy-saving, and health have become a common trend for the whole of mankind. However, how to balance the relationship between energy-saving and healthy indoor environment is a key issue for sustainable building development. This paper extracted the prototypical form of university library atrium based on 44 library cases in Wuhan. A methodology verified with measured data for evaluating building performance was constructed, and the synergistic influence of spatial morphology parameters on the building energy efficiency (BEE) and indoor environmental quality (IEQ) was analyzed. Finally, a multi-objective fast optimization framework coupled with machine learning algorithms was used to achieve the optimal design of university library atrium. The results showed that the parameters that influence the building energy consumption, indoor thermal comfort, daylighting performance most were the height-to-width ratio, the skylight solar heat gain coefficient, and the sidewall window-to-wall ratio, respectively. The machine learning models predicted performance 400 times faster than traditional performance simulations. And compared with the worst-performance scheme, the maximum optimization rate of building energy consumption, indoor thermal comfort, daylighting performance was 29.46%, 10.46%, and 65.56%, respectively. The multi-objective fast optimization framework could provide guidance for policy makers and architects to performance-based design in the early design stages of university library atrium.
ISSN:2095-2635

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