Synthesis and Characterization of Solid-State Phase Change Material Microcapsules for Thermal Management Applications

Journal of nanotechnology in engineering and medicine Pub Date : 2013-11-01 DOI:10.1115/1.4026970

F. Cao, Jing Ye, Bao Yang

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引用次数: 15

Abstract

Polyalcohols such as neopentyl glycol (NPG) undergo solid-state crystal transformations that absorb/release sufficient latent heat. These solid-solid phase change materials (PCM) can be used in practical thermal management applications without concerns about liquid leakage and thermal expansion during phase transition. In this paper, microcapsules of NPG encapsulated in silica shell were successfully synthesized with the use of the emulsion technique. The size of the microcapsules was in the range of 0.2–4 μm, and the thickness of the silica shell was about 30 nm. It was found that the endothermic event of the phase change behavior of these NPG-silica microcapsules was initiated at around 39 °C and the latent heat was about 96.0 J/g. A large supercooling of about 43.3 °C was observed in the pure NPG particles without shell. The supercooling of the NPG microcapsules can be reduced to about 14 °C due to the heterogeneous nucleation sites provided by the silica shell. These NPG microcapsules were added into heat transfer fluid PAO to enhance its heat capacity. The effective heat capacity of the fluids can be increased by 56% by adding 20 wt. % NPG-silica microcapsules.Copyright © 2013 by ASME

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热管理用固态相变材料微胶囊的合成与表征

多醇如新戊二醇(NPG)经历固态晶体转变，吸收/释放足够的潜热。这些固-固相变材料(PCM)可用于实际的热管理应用，而无需担心相变过程中的液体泄漏和热膨胀。本文采用乳化法制备了以二氧化硅为包覆层的NPG微胶囊。微胶囊的尺寸在0.2 ~ 4 μm之间，硅壳的厚度约为30 nm。结果表明，npg -二氧化硅微胶囊相变行为的吸热事件发生在39℃左右，潜热约为96.0 J/g。在无壳的纯NPG颗粒中观察到约43.3°C的大过冷。由于二氧化硅外壳提供的非均相成核位点，NPG微胶囊的过冷度可降低至约14℃。将这些NPG微胶囊加入到传热流体PAO中，以提高其热容量。添加20 wt. % npg -二氧化硅微胶囊可使流体的有效热容提高56%。ASME版权所有©2013

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Journal of nanotechnology in engineering and medicine

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