Additively Manufactured High-Performance Elastocaloric Materials with Long Fatigue Life

SMST 2022: Extended Abstracts from the International Conference on Shape Memory and Superelastic Technologies Pub Date : 2022-05-16 DOI:10.31399/asm.cp.smst2022p0034

Huilong Hou, E. Şimşek, Tao Ma, N. Johnson, Suxin Qian, Cheikh Cissé, Drew Stasak, Naila M. Al Hasan, Lin Zhou, Y. Hwang, R. Radermacher, V. Levitas, M. Kramer, M. Asle Zaeem, A. Stebner, R. Ott, Jun Cui, I. Takeuchi

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Abstract

Elastocaloric cooling, which exploits superelastic transitions of shape memory alloys to pump heat, has recently emerged as a frontrunner in alternative cooling technologies. Despite its intrinsic high efficiency, elastocaloric materials exhibit hysteresis associated with input work, a common attribute of caloric cooling materials. In this study, the authors created a Ni-Ti-based elastocaloric material by additive manufacturing nanocomposite materials using a laser directed-energy- deposition system. The material exhibited exceptional stability and unusual operational efficiency derived from the unique and intricate nanocomposite structures made by additive manufacturing. This demonstration shows the potential for using additive manufacturing to optimize caloric cooling by providing a highly desirable topology flexibility into materials components that serve as both refrigerants and heat exchangers.

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增材制造的长疲劳寿命高性能弹热材料

弹性热冷却，利用形状记忆合金的超弹性转变来泵送热量，最近成为替代冷却技术的领跑者。尽管其固有的高效率，弹性热材料表现出与输入功相关的滞后，这是热冷却材料的共同属性。在本研究中，作者利用激光定向能量沉积系统，通过增材制造纳米复合材料，制备了一种镍钛基弹性热材料。这种材料表现出了优异的稳定性和不同寻常的操作效率，这源于其独特而复杂的纳米复合材料结构。该演示展示了使用增材制造优化热冷却的潜力，通过为既可以作为制冷剂又可以作为热交换器的材料组件提供高度理想的拓扑灵活性。

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SMST 2022: Extended Abstracts from the International Conference on Shape Memory and Superelastic Technologies

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