铜纳米粒子导热增强固-液相变储能材料的性能

使用聚乙烯吡咯烷酮（PVP）和聚乙二醇（PEG）作为钝化剂对铜纳米颗粒进行原位包覆制备了PVP/PEG/Cu复合纳米粒子（CuNP），将其作为导热增强剂引入到PEG中制备了CuNP/PEG固-液相变储能材料（PCMs），并通过FTIR、XRD、DSC以及TGA等表征了CuNP/PEG固-液PCMs的结构及热性能。利用纳米粒子表面的PVP与PEG之间的氢键和空间位阻效应，以及PVP对铜核的保护作用，赋予了铜纳米粒子在PCMs中优异的分散稳定性。结果表明，CuNP的引入能够显著提高复合相变储能材料的导热能力，并能够作为晶核加速材料的结晶行为。当纳米粒子的质量分数为5%时，CuNP/PEG固-液PCMs的相变焓值为157.0 J/g，体系的储热速率、放热速率和结晶速率与纯PEG相比分别提高了34.09%、31.45%和53.33%。

Properties of solid-liquid phase change materials based on copper nanoaggregates with enhanced thermal conductivity for storing thermal energy

polyvinylpyrrolidone (PVP) and polyethylene glycol (PEG) were used as passivators to prepare PVP/PEG/Cu composite nanoaggregates (CuNP) by in-situ coating copper nanoparticles. Then, CuNP, as a thermal conductivity enhancer, were introduced into the phase change system to prepare CuNP/PEG solid-liquid phase change materials (CuNP/PEG PCMs). FT-IR, XRD, DSC and TGA were used to investigate the interaction and thermal properties of the PCMs. The physical interaction between the PVP coated on the nanoaggregate and the working material PEG, and the protective effect of PVP ensured that the PCMs exhibit stable performance, good thermal cycle stability and service life. The results showed that the introduction of CuNP significantly improved the thermal conductivity of the PCMs and accelerated the crystallization of the working material as a crystal nucleus. When the mass fraction of CuNP was 5%, the phase change enthalpy of the solid-liquid PCMs was 157.0 J/g, and the material also exhibited strong thermal stability under 370°C. The heat accumulation rate, heat release rate, and crystallization rate were increased 34.09%, 31.45%, and 55.33%, respectively, when comparing with the pure PEG.