Miniature-scale elastocaloric cooling by rubber-based foils

IF 7 3区 材料科学 Q1 ENERGY & FUELS Journal of Physics-Energy Pub Date : 2023-11-28 DOI:10.1088/2515-7655/ad0cff
Carina Ludwig, Jan Leutner, Oswald Prucker, Jürgen Rühe, Manfred Kohl
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Abstract

We report on the design and characterization of a demonstrator device for miniature-scale elastocaloric (eC) cooling using a series of natural rubber (NR) foil specimens of 9 × 26.5 mm2 lateral size and thicknesses in the range of 290–900 μm. NR has the potential to meet the various challenges associated with eC cooling, as it exhibits a large adiabatic temperature change in the order of 20 K and high fatigue resistance under dynamic load, while loading forces are low. Owing to the large surface-to-volume ratio of rubber-based foils, heat transfer to heat sink and source elements is accomplished by mechanical contact enabling compact designs. Two actuators are implemented to control the performance in loading direction independent from the performance of mechanical contacting. The study of operation parameters is complemented by lumped-element modeling to understand the cycle frequency-dependent dynamics of heat transfer and resulting cooling capacity. The single-stage device operates in the strain range of 300%–700% and exhibits a temperature span up to 4.1 K, while the specific cooling power reaches 1.1 Wg−1 and the absolute cooling power 123 mW. The performance metrics show a pronounced dependence on foil thickness and heat transfer coefficient indicating a path toward future device optimization.
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利用橡胶箔进行微型规模弹性冷却
我们报告了利用一系列横向尺寸为 9 × 26.5 mm2、厚度为 290-900 μm 的天然橡胶 (NR) 箔试样设计和表征微型规模弹性冷却 (eC) 演示装置的情况。NR 具有应对与 eC 冷却相关的各种挑战的潜力,因为它表现出 20 K 量级的较大绝热温度变化,在动态负载下具有较高的抗疲劳性,同时负载力较低。由于橡胶箔的表面体积比很大,因此通过机械接触实现了散热器和热源元件之间的热传递,从而实现了紧凑型设计。采用两个致动器来控制加载方向上的性能,与机械接触的性能无关。在研究运行参数的同时,还进行了块状元件建模,以了解热传递和由此产生的冷却能力的循环频率动态。单级装置的工作应变范围为 300%-700%,温度跨度高达 4.1 K,比冷却功率达到 1.1 Wg-1,绝对冷却功率为 123 mW。性能指标显示出对薄膜厚度和传热系数的明显依赖性,这为未来的器件优化指明了方向。
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来源期刊
CiteScore
10.90
自引率
1.40%
发文量
58
期刊介绍: The Journal of Physics-Energy is an interdisciplinary and fully open-access publication dedicated to setting the agenda for the identification and dissemination of the most exciting and significant advancements in all realms of energy-related research. Committed to the principles of open science, JPhys Energy is designed to maximize the exchange of knowledge between both established and emerging communities, thereby fostering a collaborative and inclusive environment for the advancement of energy research.
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