Enhanced thermal conductivity in phase change composites via cu nanoparticle-decorated anisotropic carbon rolls
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Updated Time:2024-05-18 11:32:29
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Oral Presentation
Abstract
Phase change materials (PCMs) face scalability challenges for industrial use due to problems such as phase transition leakage, less-than-ideal thermal conductivity, and limited photothermal absorption. Our study addresses these issues by developing sophisticated phase change composites (PCCs) reinforced with Cu nanoparticle-laden porous carbon rolls. These rolls, formed from cotton cloth, serve as a matrix for embedding Cu nanoparticles, which significantly enhance interfacial thermal conductivity. The synthesis of these PCCs involves a vacuum impregnation technique using paraffin wax as the PCM core, resulting in a composite with enhanced thermal conductivity and robust structural integrity. This novel approach boosts anisotropic thermal conductivity to 3.4 W/(m·K) along the axial direction and 2 W/(m·K) radially. These PCCs demonstrate superior solar-thermal-electric energy conversion capabilities, making them promising candidates for applications in solar energy harvesting, thermal energy storage, and effective thermal regulation systems.
Keywords
Phase change composites; Cu nanoparticles; Anisotropic carbon rolls; Thermal conductivity; Solar-thermal-electric energy conversion
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