Optimization Strategies for the Envelope of Student Dormitories in Hot Summer and Cold Winter Regions: Multi-Criteria Assessment Method

Energy consumption in student dormitories, key living and study spaces, is a major concern for institutions and communities. This paper proposes a multi-objective optimization model to address the issue of incomplete single-dimensional analysis in existing research. Firstly, optimization was conduct...

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Veröffentlicht in:	Sustainability 2024-07, Vol.16 (14), p.6172
Hauptverfasser:	Xie, Fangyuan, Wu, Yi, Wang, Xinqi, Zhou, Xiling
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Sprache:	eng
Schlagworte:	Alloys Analysis Case studies China Cold Decision-making Design Dormitories Emissions (Pollution) Energy conservation Energy consumption Energy efficiency Energy industry Methods
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creator	Xie, Fangyuan Wu, Yi Wang, Xinqi Zhou, Xiling
description	Energy consumption in student dormitories, key living and study spaces, is a major concern for institutions and communities. This paper proposes a multi-objective optimization model to address the issue of incomplete single-dimensional analysis in existing research. Firstly, optimization was conducted separately for the external walls, windows, and roof to study different parts of the building envelope. Secondly, a student dormitory in a hot summer and cold winter region was used for a comprehensive optimization analysis. The study compared energy consumption, carbon emissions, and costs with the original building, showing a 31.79% reduction in energy savings (ESR), while carbon emission savings (CESR) and cost savings (CSR) increased by 57.18% and 15.58%. This study highlights the importance of selecting appropriate window configurations for sustainability. Optimized thermally broken Low-E glass windows save 5.6% in annual energy consumption compared to aluminum alloy double-glazed windows, with only a 0.03% increase in energy consumption and a 4.49% rise in costs. Long-term, optimized windows provide greater positive feedback for energy efficiency. This case study offers insights for retrofitting buildings with good wall performance but poor window performance and emphasizes the comprehensive decision-making authority of designers and policymakers in sustainable renovations.
doi_str_mv	10.3390/su16146172
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subjects	Alloys Analysis Case studies China Cold Decision-making Design Dormitories Emissions (Pollution) Energy conservation Energy consumption Energy efficiency Energy industry Methods
title	Optimization Strategies for the Envelope of Student Dormitories in Hot Summer and Cold Winter Regions: Multi-Criteria Assessment Method
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