Bioinspired roll-to-roll solar-thermal energy harvesting within form-stable flexible composite phase change materials

Bioinspired roll-to-roll solar-thermal energy harvesting within form-stable flexible composite phase change materials

Converting solar energy into storable thermal energy within organic phase change materials has emerged as a promising way to overcome solar intermittency and continuously harness solar-thermal energy for many heating-related applications. The low thermal conductivity and leakage issue of the phase c...

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Veröffentlicht in:Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2020-10, Vol.8 (4), p.297-2978
Hauptverfasser: Chang, Chao, Nie, Xiao, Li, Xiaoxiang, Tao, Peng, Fu, Benwei, Wang, Zhongyong, Xu, Jiale, Ye, Qinxian, Zhang, Jingyi, Song, Chengyi, Shang, Wen, Deng, Tao
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Sprache:eng
Schlagworte:
Biomimetics
Charging
Composite materials
Diffusion rate
Energy harvesting
Energy storage
Phase change materials
Solar energy
Solar energy conversion
Solar radiation
Thermal conductivity
Thermal energy
Thermoregulation
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container_end_page 2978
container_issue 4
container_start_page 297
container_title Journal of materials chemistry. A, Materials for energy and sustainability
container_volume 8
creator Chang, Chao
Nie, Xiao
Li, Xiaoxiang
Tao, Peng
Fu, Benwei
Wang, Zhongyong
Xu, Jiale
Ye, Qinxian
Zhang, Jingyi
Song, Chengyi
Shang, Wen
Deng, Tao
description Converting solar energy into storable thermal energy within organic phase change materials has emerged as a promising way to overcome solar intermittency and continuously harness solar-thermal energy for many heating-related applications. The low thermal conductivity and leakage issue of the phase change materials, however, limit scalable solar-thermal energy storage and their practical applications. Inspired by the dynamic thermoregulation behavior of butterfly wings, here we demonstrate rapid roll-to-roll solar-thermal energy harvesting within flexible form-stable composite phase change materials. Instead of static charging the bulk materials, the thin composite sheets are exposed to solar radiation for rapid charging while being continuously rolled. Due to shortened heat-diffusion distance and rollability of the composites, it achieves fast uniform solar-thermal energy storage within the bulk storage media. The flexibility of charged composites also enables broad tuning of the discharging behavior, and offers the possibility to explore wearable thermotherapy and other flexible solar-thermal applications. Roll-to-roll charging of flexible composite phase change materials enables fast solar-thermal energy harvesting within bulk storage media.
doi_str_mv 10.1039/d0ta07289c
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source Royal Society Of Chemistry Journals 2008-
subjects Biomimetics
Charging
Composite materials
Diffusion rate
Energy harvesting
Energy storage
Phase change materials
Solar energy
Solar energy conversion
Solar radiation
Thermal conductivity
Thermal energy
Thermoregulation
title Bioinspired roll-to-roll solar-thermal energy harvesting within form-stable flexible composite phase change materials
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