Shape‐Stabilized PCMs@Foam‐Based Porous Polymers for Thermal Energy Storage

Liu, Zhihong; Wu, Wei; Liu, Bo; Wang, Liang

doi:10.1002/slct.201900781

Cited by 3 publications

(2 citation statements)

References 43 publications

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“…The composites achieved a considerably high latent heat of 150.6 J g −1 with no leakage out. However, the thermal conductivity of the composites was not reported . In the past few years, porous carbon materials, including carbon nanotubes aerogel, graphene aerogel, carbon foam, and biomass‐derived porous carbon materials, were applied to comprehensively modifying the thermal conductivity together with preventing the leakage.…”

Section: Introductionmentioning

confidence: 99%

Introduction of Phase Change Material into Sustainable Carbon Materials for Enhanced Shape Stability and Thermal Conductivity

Zou

Shen

2020

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New sustainable carbon materials were synthesized from a low‐price and eco‐friendly carrot via hydrothermal reaction and carbonization approach. Afterwards, palmitic acid (PA) was impregnated into the carrot‐derived carbon material (CCM) to prepare PA@CCM composites through vacuum impregnation method. The thermal properties and shape stability of PA@CCM composites were evaluated by differential scanning calorimetry (DSC), thermal conductivity and thermal cycling tests. Owing to the special hybrid microstructure of the CCMs, the loading ratio of PA in PA@CCM composites could reach up to 85.3 % with the latent heat of 166.4 J g−1. More importantly, the PA@CCM composites show negligible leakage above the melting point of PA, exhibiting excellent shape stability. Compared with pristine PA, the thermal conductivity of PA@CCM composites could greatly enhanced by 145.5 %. Thus, PA@CCM composites can be considered as a promising candidate for thermal energy storage applications.

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Section: Introductionmentioning

confidence: 99%

Introduction of Phase Change Material into Sustainable Carbon Materials for Enhanced Shape Stability and Thermal Conductivity

Zou

Shen

2020

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“…Herein, for the first time, we summarized the advanced applications of polymers in multifunctional SSPCMs, such as shape memory, hydrophobicity, and wearable devices. This review aims to gain an in‐depth understanding of polymers as supporting materials to encapsulate PCMs, and at the same time endow PCMs with more intelligent applications [65–68] . We hope that the in‐depth study of polymers and multifunctional SSPCMs can provide better guidance for the design of multifunctional SSPCMs.…”

Section: Introductionmentioning

confidence: 99%

Recent Advances in Polymer‐Containing Multifunctional Phase‐Change Materials

et al. 2021

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Phase‐change materials (PCMs) play a key role in thermal energy storage owing to their high‐energy storage density and small temperature fluctuation during the phase‐transition stage. Polymers, either as a supporting material to prevent liquid leakage during the phase‐change process or used with specific target, have been widely recognized in the fabrication of PCM composites. In the meantime, due to the continued demand for variety of PCMs, a single thermal energy storage function seems to be insufficient to meet these needs. Thanks to the good compatibility with PCMs and the structural adjustable properties of polymers, they have been broadly used as the second component in the multifunctional PCMs composite. In this Review, strategies for multifunctional PCMs supported by polymers and their potential energy applications, such as thermal energy harvesting and storage, shape memory, wearable devices, self‐cleaning, and other forms of applications, are summarized comprehensively. The future research directions and challenges of multifunctional PCMs with polymers are also discussed.

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