High-performance multimode elastocaloric cooling system

Suxin Qian; David Catalini; Jan Muehlbauer; Boyang Liu; Het Mevada; Huilong Hou; Yunho Hwang; Reinhard Radermacher; Ichiro Takeuchi

doi:10.1126/SCIENCE.ADG7043

High-performance multimode elastocaloric cooling system

Suxin Qian
, David Catalini
, Jan Muehlbauer
, Boyang Liu
, Het Mevada
, Huilong Hou
, Yunho Hwang
, Reinhard Radermacher
, Ichiro Takeuchi

School of Energy and Power Engineering

University of Maryland, College Park
Beihang University
Tianmushan Laboratory (Zhejiang Provincial Laboratory for Aviation)

Research output: Contribution to journal › Article › peer-review

177 Scopus citations

Abstract

Developing zero–global warming potential refrigerants has emerged as one area that helps address global climate change concerns. Various high-efficiency caloric cooling techniques meet this goal, but scaling them up to technologically meaningful performance remains challenging. We have developed an elastocaloric cooling system with a maximum cooling power of 260 watts and a maximum temperature span of 22.5 kelvin. These values are among the highest reported for any caloric cooling system. Its key feature is the compression of fatigue-resistant elastocaloric nitinol (NiTi) tubes configured in a versatile multimode heat exchange architecture, which allows the harnessing of both high delivered cooling power and large temperature spans. Our system shows that elastocaloric cooling, which only emerged 8 years ago, is a promising direction for commercializing caloric cooling.

Original language	English
Pages (from-to)	722-727
Number of pages	6
Journal	Science
Volume	380
Issue number	6646
DOIs	https://doi.org/10.1126/SCIENCE.ADG7043
State	Published - 19 May 2023

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This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1126/SCIENCE.ADG7043

Cite this

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title = "High-performance multimode elastocaloric cooling system",

abstract = "Developing zero–global warming potential refrigerants has emerged as one area that helps address global climate change concerns. Various high-efficiency caloric cooling techniques meet this goal, but scaling them up to technologically meaningful performance remains challenging. We have developed an elastocaloric cooling system with a maximum cooling power of 260 watts and a maximum temperature span of 22.5 kelvin. These values are among the highest reported for any caloric cooling system. Its key feature is the compression of fatigue-resistant elastocaloric nitinol (NiTi) tubes configured in a versatile multimode heat exchange architecture, which allows the harnessing of both high delivered cooling power and large temperature spans. Our system shows that elastocaloric cooling, which only emerged 8 years ago, is a promising direction for commercializing caloric cooling.",

author = "Suxin Qian and David Catalini and Jan Muehlbauer and Boyang Liu and Het Mevada and Huilong Hou and Yunho Hwang and Reinhard Radermacher and Ichiro Takeuchi",

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T1 - High-performance multimode elastocaloric cooling system

AU - Qian, Suxin

AU - Catalini, David

AU - Muehlbauer, Jan

AU - Liu, Boyang

AU - Mevada, Het

AU - Hou, Huilong

AU - Hwang, Yunho

AU - Radermacher, Reinhard

AU - Takeuchi, Ichiro

PY - 2023/5/19

Y1 - 2023/5/19

N2 - Developing zero–global warming potential refrigerants has emerged as one area that helps address global climate change concerns. Various high-efficiency caloric cooling techniques meet this goal, but scaling them up to technologically meaningful performance remains challenging. We have developed an elastocaloric cooling system with a maximum cooling power of 260 watts and a maximum temperature span of 22.5 kelvin. These values are among the highest reported for any caloric cooling system. Its key feature is the compression of fatigue-resistant elastocaloric nitinol (NiTi) tubes configured in a versatile multimode heat exchange architecture, which allows the harnessing of both high delivered cooling power and large temperature spans. Our system shows that elastocaloric cooling, which only emerged 8 years ago, is a promising direction for commercializing caloric cooling.

AB - Developing zero–global warming potential refrigerants has emerged as one area that helps address global climate change concerns. Various high-efficiency caloric cooling techniques meet this goal, but scaling them up to technologically meaningful performance remains challenging. We have developed an elastocaloric cooling system with a maximum cooling power of 260 watts and a maximum temperature span of 22.5 kelvin. These values are among the highest reported for any caloric cooling system. Its key feature is the compression of fatigue-resistant elastocaloric nitinol (NiTi) tubes configured in a versatile multimode heat exchange architecture, which allows the harnessing of both high delivered cooling power and large temperature spans. Our system shows that elastocaloric cooling, which only emerged 8 years ago, is a promising direction for commercializing caloric cooling.

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JO - Science

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ER -

High-performance multimode elastocaloric cooling system

Abstract

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