Evaluating long-term thermal and chemical stability and leaching potential of low-temperature phase change materials in concrete slabs exposed to outdoor environmental conditions

IF 3.4 3区 工程技术 Q2 CONSTRUCTION & BUILDING TECHNOLOGY Materials and Structures Pub Date : 2024-12-18 DOI:10.1617/s11527-024-02545-1
Robin Deb, Mohammad Irfan Iqbal, Yaghoob Farnam
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Abstract

This study examined the potential of using phase change material (PCM)-integrated concrete slabs for long-term thermal-responsive applications in an outdoor environment condition. The objectives were to: (i) evaluate long-term thermal response, snow melting and freeze–thaw reduction efficiency of PCM integrated concrete slabs, (ii) characterize the chemical stability of PCM in cement matrix, and (ii) assess the possibility of PCM leaching into the cement matrix and subgrade soil of the slabs. The experimental program included: (i) outdoor experimentation using large-scale field concrete slabs, (ii) guarded calorimetric (LGCC) tests of cut-bar concrete specimens, (iii) Fourier transform infrared (FTIR) spectroscopic characterization of PCM in mortar and subgrade soil specimens, and (iv) low-temperature differential scanning calorimetric (LT-DSC) tests to assess and quantify the amount of PCM contamination in subgrade soil. Results presented varying degrees of effectiveness after three years of environmental exposure: Micro-encapsulated PCM (MPCM) concrete exhibited considerable success (i.e., ~ 50%) in snow melting while PCM infused in lightweight aggregates (PCM-LWA) concrete failed to provide substantial snow-melting; moreover, both PCM-LWA and MPCM slabs showed diminished resistance to freeze–thaw (F-T) cycles compared to the first-year winter cycle data. Factors contributing to efficiency loss are found to be shell degradation of microcapsules, potential leaching of PCM into subgrade soil (i.e., between 0.2 to 0.3% wt. concentration), and effects of warm temperatures influencing the degree of evaporation, as evidenced with LGCC, FTIR and LT-DSC results. Strategies to enhance efficiency and stability include improved encapsulation techniques, and vascularization methods.

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评估暴露在室外环境条件下的混凝土板中低温相变材料的长期热稳定性、化学稳定性和浸出潜力
本研究考察了在室外环境条件下将相变材料(PCM)集成混凝土板用于长期热响应应用的潜力。目标是(i) 评估 PCM 集成混凝土板的长期热响应、融雪和冻融减少效率;(ii) 确定水泥基质中 PCM 的化学稳定性;以及 (ii) 评估 PCM 沥入板的水泥基质和基层土壤的可能性。实验计划包括(i) 使用大尺度现场混凝土板进行室外实验,(ii) 对切条混凝土试样进行防护量热测试 (LGCC),(iii) 对砂浆和基层土壤试样中的 PCM 进行傅立叶变换红外光谱定性,以及 (iv) 进行低温差扫描量热测试,以评估和量化基层土壤中的 PCM 污染量。经过三年的环境暴露后,结果显示了不同程度的有效性:微胶囊 PCM(MPCM)混凝土在融雪方面取得了相当大的成功(即约 50%),而注入轻集料的 PCM(PCM-LWA)混凝土则未能提供实质性的融雪效果;此外,与第一年冬季循环数据相比,PCM-LWA 和 MPCM 板对冻融循环的抵抗力都有所下降。如 LGCC、傅立叶变换红外光谱和 LT-DSC 结果所示,导致效率降低的因素包括微胶囊的外壳降解、PCM 可能沥滤到路基土壤中(即 0.2% 至 0.3% 重量浓度)以及影响蒸发程度的低温效应。提高效率和稳定性的策略包括改进封装技术和血管化方法。
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来源期刊
Materials and Structures
Materials and Structures 工程技术-材料科学:综合
CiteScore
6.40
自引率
7.90%
发文量
222
审稿时长
5.9 months
期刊介绍: Materials and Structures, the flagship publication of the International Union of Laboratories and Experts in Construction Materials, Systems and Structures (RILEM), provides a unique international and interdisciplinary forum for new research findings on the performance of construction materials. A leader in cutting-edge research, the journal is dedicated to the publication of high quality papers examining the fundamental properties of building materials, their characterization and processing techniques, modeling, standardization of test methods, and the application of research results in building and civil engineering. Materials and Structures also publishes comprehensive reports prepared by the RILEM’s technical committees.
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