Experimental evaluation of energy storage and hydration of lauric acid/expanded vermiculite composite phase change cementitious materials

Experimental evaluation of energy storage and hydration of lauric acid/expanded vermiculite composite phase change cementitious materials

Incorporating phase change material (PCMs) into concrete to functionalize concrete for energy storage, due to their high latent heat, has been demonstrated as an effective strategy for improving building energy efficiency. This study aims to synthesize a shape-stabilized composite phase change mater...

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Bibliographic Details
Main Authors: Yong Wen, Peifeng Tian, Xuemei Di, Kaiming Pan, Huijing Wu
Format: Article
Language:English
Published: Elsevier 2024-12-01
Series:Case Studies in Construction Materials
Subjects:
Phase change materials
Non-contact resistivity
Thermal energy storage
Heat of hydration
Cracks
Online Access:http://www.sciencedirect.com/science/article/pii/S2214509524011021
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Summary:Incorporating phase change material (PCMs) into concrete to functionalize concrete for energy storage, due to their high latent heat, has been demonstrated as an effective strategy for improving building energy efficiency. This study aims to synthesize a shape-stabilized composite phase change material (PCMs) to explore its potential in mitigating early thermal cracking in concrete. To reduce the risk of leakage, vacuum impregnation was employed to load lauric acid (LA) between layers of expanded vermiculite (EV) treated at different firing temperatures. The structural composition and thermal storage performance of the LA/EV composite PCMs (LA/EV-PCMs) were systematically evaluated using various characterization techniques to assess stability and efficiency. The synthesized PCMs exhibits excellent thermal storage capacity (183.8 J/g), a low melting point (31.1 °C), and thermal conductivity 1.43 times higher than that of EV alone. For the first time, the influence of LA/EV-PCMs on the cement hydration process and heat of hydration was studied using non-contact resistivity and adiabatic heating experiments. The results indicated that the PCMs delayed the peak hydration temperature, with the maximum difference in hydration temperature reaching 11.6 °C. Additionally, the set-hardening phase of the cement was accelerated by 8.97 % and 7.96 % due to pore filling by the LA/EV-PCMs. These findings offer innovative insights into the design of energy-efficient concrete and the prevention of early cracking caused by temperature variations.
ISSN:2214-5095

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