Cementitious composites integrated phase change materials for passive buildings: An overview

Yang, Haibin; Xu, Ziqing; Cui, Hongzhi; Bao, Xiaohua; Tang, Waiching; Sang, Guochen; Chen, Xiangsheng

Title: Cementitious composites integrated phase change materials for passive buildings: An overview
Creator: Yang, Haibin; Xu, Ziqing; Cui, Hongzhi; Bao, Xiaohua; Tang, Waiching; Sang, Guochen; Chen, Xiangsheng
Relation: Construction and Building Materials Vol. 361, no. 129635
Publisher Link: http://dx.doi.org/10.1016/j.conbuildmat.2022.129635
Publisher: Elsevier BV
Resource Type: journal article
Date: 2022
Description: Phase change materials (PCMs) have attracted considerable attention as potential energy storage media for improving the energy storage densities of building envelopes. Therefore, researchers have committed to introducing PCMs into cementitious materials to develop structural–functional integrated thermal energy storage cementitious materials (TESCMs). Nevertheless, TESCMs have not been widely applied in large-scale engineering and remain in a trial or test stage. This review provides an overview of TESCMs for passive buildings to keep researchers abreast of the latest research trends and technological advances. Among the different types of PCMs, inorganic PCMs with low cost and high thermal conductivity have the most potential for application in buildings; however, their supercooling and phase separation must be addressed before use. Vacuum impregnation and micro-encapsulated and macro-encapsulated techniques are the main methods to encapsulate PCMs for preparing shape-stabilized PCMs (SSPCMs) and preventing PCM leakage from TESCMs. The inclusion of SSPCMs was found to have a negative effect on the workability, mechanical strength, and thermal conductivity of cementitious materials. However, thermal energy storage buildings (TESBs) composed of TESCMs can regulate the indoor temperature within the thermal comfort range, significantly decreasing energy consumption. This is because the effectiveness of TESBs depends highly on such factors as PCM dosages, climatic conditions, and the phase change temperature of PCMs; thus, a multi-objective optimization design is required to design TESB layouts.
Subject: phase change materials; cementitious materials; shape-stabilized phase change materials; thermal storage cementitious materials; thermo-regulated performance; payback period
Identifier: http://hdl.handle.net/1959.13/1485074
Identifier: uon:51484
Identifier: ISSN:0950-0618
Language: eng
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