复合定形相变材料的封装及应用研究新进展

Research progress in encapsulation and application of shape-stabilized composite phase-change materials

  • 摘要: 有机相变材料具有热存储密度高、自身温度和体积变化小、腐蚀性小和化学性质稳定等优点,能有效提升不可再生能源的利用率,是一种绿色节能环保材料,在新能源开发和热能储存领域起着至关重要的作用。然而,有机相变储能材料普遍存在相变过程中熔融泄漏和热导率低的问题,严重制约了相变材料的实际应用。因此,相变材料的封装定形和导热强化成为近年来的研究热点。本文针对有机相变材料普遍存在的泄漏和热导率低问题,综述了有机相变材料的封装技术和导热强化技术的基本方法及最新研究成果,并总结了复合相变储能材料的能量转换机理,浅谈了复合定形相变储能材料在建筑节能、太阳能和电子设备等领域的应用情况。最后,对未来复合定形相变储能材料发展的研究重点和方向进行了展望。

     

    Abstract: Currently, energy demand and consumption problems have become a focus issue due to rapid economic growth, environmental pollution, and energy shortages. Hence, new technologies must be explored and developed for the recovery of wasted energy or to harness solar energy. Thermal energy storage will not only improve energy utilization efficiency and store wasted heat; it will also ease the problem of energy supply and demand. Thermal energy storage is considered to be one of the most efficient approaches for the sustainable control and utilization of energy. Organic phase-change energy storage as a strategy for thermal energy storage has attracted widespread attention in recent years by virtues of its high latent storage capacity, suitable phase-change temperature, chemical and thermal stability, non-toxicity, and nearly absent supercooling properties. However, the leakage problem and low conductivity of organic phase-change materials during the phase-change process hinder their practical application. Leakage can cause serious environmental damage and reduce thermal energy storage. Low thermal conductivity can result in a large temperature gradient and insensitivity to temperature changes, thereby reducing the heat transfer efficiency of phase-change materials. To solve the above issues, various encapsulation techniques have been developed and substances with high thermal conductivity have become a research hotspot. In this work, we summarized three main approaches—porous absorption, microencapsulation, and electrospinning—to prepare shape-stabilized phase-change materials. For porous absorption, we identified some widely available, low-cost renewable materials that can be used as support material for fabricating composite phase-change materials, such as biomass-derived wood, winter melon, potatoes, and cotton. In addition, the energy conversion mechanism of composite phase-change materials was discussed. The applications of phase-change materials in solar absorption refrigeration systems, solar energy systems, energy storage systems for buildings, passive thermal management of batteries, cold storage, and photovoltaic electricity generation were summarized. Lastly, future research directions on composite phase-change energy storage materials were also proposed.

     

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