Thermally Conductive and Shape‐Stabilized Polyethylene Glycol/Carbon Foam Phase‐Change Composites for Thermal Energy Storage

Lin, Fuchang; Zhang, Weiyi; Shi, Tengteng; Lv, Zhenfei; Min, Xin; Fang, Minghao; Wu, Xiaowen; Liu, Yangai; Huang, Zhaohui

doi:10.1002/slct.201904489

Cited by 17 publications

(2 citation statements)

References 38 publications

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“…11 To obtain SPCMs, in addition to the microcapsule method, it is also an effective way to use the microscopic pore structure of the framework support material to realize the encapsulation of phase change materials. 12 Current research in this field mainly focuses on the use of biomass carbon materials, 13 inorganic nonmetals, 14 montmorillonite, 15 delignified wood, 12 diatomaceous earth, 16 carbon foam, 17 radial mesoporous silica sphere, 18 etc. as framework support materials.…”

Section: ■ Introductionmentioning

confidence: 99%

Design and Construction of Photochromic and Antileakage Reinforced Wood-Based Cellulose Microframework/Hexadecanol-Coconut Oil Composite Phase Change Material

2021

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The development of high-performance shape-stable phase change material composites (SPCMs) with high phase change enthalpy and high conversion efficiency, especially with good photochromic properties, is essential for thermal energy storage. Here, we report that one type of SPCMs with both photochromic and phase change energy storage is obtained by incorporating organic binary composite PCMs (hexadecanol/coconut oil, H/C) and photochromic phosphotungstic acid (PA) into Ochroma pyramidale wood-based cellulose microframe (DOW) through simple vacuum impregnation. When the ratio of hexadecanol to coconut oil is 3:7 and the ratio of phosphotungstic acid to N,N-dimethylacetamide is 4:13.6, the SPCM composite material (DOW-H3C7-4PA) represents a high phase transition enthalpy of 163.7 J/g and an appropriate phase transition temperature of 42.55 °C that can be applied to the environmental temperature adjustment of high-temperature areas (>40 °C) mentioned in this paper, in addition to the excellent thermal stability and photochromic stability; for example, even after 100 thermal cycles and UV radiation cycles, its phase transition enthalpy remains almost unchanged. The DOW-H3C7-4PA composite material also shows good shape stability and leakage resistance. In addition, the high photothermal conversion efficiency (65.71%) of DOW-H3C7-4PA is considered to be a promising candidate for photothermal energy storage applications. Therefore, the manufactured SPCMs (DOW-H3C7-4PA) have high latent heat, good melting/freezing cycle reliability, high photochromic stability, and remarkable light-to-heat energy conversion ability, making them show broad application prospects in energy conversion and storage devices.

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Section: ■ Introductionmentioning

confidence: 99%

Design and Construction of Photochromic and Antileakage Reinforced Wood-Based Cellulose Microframework/Hexadecanol-Coconut Oil Composite Phase Change Material

2021

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“…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. Such porous carbon materials play pivotal roles in various fields due to their three‐dimensional structures with distinguished properties, such as high porosity, low density, and high thermal conductivity, etc .…”

Section: Introductionmentioning

confidence: 99%

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

Zou

Shen

2020

ChemistrySelect

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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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Light- and electro-driven phase change materials derived from activated porous biochar nanosheets and encapsulated polyethylene glycol

Zhang,

Zheng,

et al. 2024

Colloids and Surfaces A: Physicochemical and Engineering Aspect

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Thermally Conductive and Shape‐Stabilized Polyethylene Glycol/Carbon Foam Phase‐Change Composites for Thermal Energy Storage

Cited by 17 publications

References 38 publications

Design and Construction of Photochromic and Antileakage Reinforced Wood-Based Cellulose Microframework/Hexadecanol-Coconut Oil Composite Phase Change Material

Design and Construction of Photochromic and Antileakage Reinforced Wood-Based Cellulose Microframework/Hexadecanol-Coconut Oil Composite Phase Change Material

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

Light- and electro-driven phase change materials derived from activated porous biochar nanosheets and encapsulated polyethylene glycol

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