Energy-saving potential of intermittent heating system: Influence of composite phase change wall and optimization strategy

Energy-saving potential of intermittent heating system: Influence of composite phase change wall and optimization strategy

In the Yangtze River zone of China, the heating operation in buildings is mainly part-time and part-space, which could affect the indoor thermal comfort while making the thermal process of building envelope different. This paper proposed to integrate phase change material (PCM) to building walls to...

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Bibliographic Details
Published in:Energy exploration & exploitation Vol. 39; no. 1; pp. 426 - 443
Main Authors: Li, Yanru, Long, Enshen, Zhang, Lili, Dong, Xiangyu, Wang, Suo
Format: Journal Article
Language:English
Published: London, England SAGE Publications 01-01-2021
Sage Publications Ltd
SAGE Publishing
Subjects:
Air temperature
Building envelopes
Buildings
Construction materials
Energy conservation
Energy consumption
Heat transfer
Heating
Indoor environments
Optimization
Phase change materials
Thermal comfort
Thermal environments
Intermittent heating
indoor thermal environment
phase change material
optimal strategy
energy-saving
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Summary:In the Yangtze River zone of China, the heating operation in buildings is mainly part-time and part-space, which could affect the indoor thermal comfort while making the thermal process of building envelope different. This paper proposed to integrate phase change material (PCM) to building walls to increase the indoor thermal comfort and attenuate the temperature fluctuations during intermittent heating. The aim of this study is to investigate the influence of this kind of composite phase change wall (composite-PCW) on the indoor thermal environment and energy consumption of intermittent heating, and further develop an optimization strategy of intermittent heating operation by using EnergyPlus simulation. Results show that the indoor air temperature of the building with the composite-PCW was 2–3°C higher than the building with the reference wall (normal foamed concrete wall) during the heating-off process. Moreover, the indoor air temperature was higher than 18°C and the mean radiation temperature was above 20°C in the first 1 h after stopping heating. Under the optimized operation condition of turning off the heating device 1 h in advance, the heat release process of the composite-PCW to the indoor environment could maintain the indoor thermal environment within the comfortable range effectively. The composite-PCW could decrease 4.74% of the yearly heating energy consumption compared with the reference wall. The optimization described can provide useful information and guidance for the energy saving of intermittently heated buildings.
ISSN:0144-5987
2048-4054
DOI:10.1177/0144598720969217