A conceptual design of a thermal switch capacitor in a magnetocaloric device: experimental characterization of properties and simulations of operating characteristics
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引用次数: 0
Abstract
The quest for better performance from magnetocaloric devices has led to the development of thermal control devices, such as thermal switches, thermal diodes, and thermal capacitors. These devices are capable of controlling the intensity and direction of the heat flowing between the magnetocaloric material and the heat source or heat sink, and therefore have the potential to simultaneously improve the power density and energy efficiency of magnetocaloric systems. We have developed a new type of thermal control device, i.e., a silicon mechanical thermal switch capacitor ( TSC). In this paper we first review recently developed thermal switches based on micro-electromechanical systems and present the operation and structure of our new TSC. Then, the results of the parametric experimental study on the thermal contact resistance, as one of the most important parameters affecting the thermal performance of the device, are presented. These experimental data were later used in a numerical model for a magnetocaloric device with a thermal switch-capacitor. The results of the study show that for a single embodiment, a maximum cooling power density of 970 W m−2 (510 W kgmcm −1) could be achieved for a zero-temperature span and an operating frequency of 5 Hz. However, a larger temperature span could be achieved by cascading multiple magnetocaloric elements with TSCs. We have shown that the compact TSC can be used in caloric devices, even with small temperature variations, and can be used in a variety of practical applications requiring thermal regulation.
对磁热器件更好性能的追求导致了热控制器件的发展,如热开关、热二极管和热电容器。这些装置能够控制在磁热材料与热源或散热器之间流动的热量的强度和方向,因此具有同时提高磁热系统的功率密度和能量效率的潜力。我们开发了一种新型的热控制装置,即硅机械热开关电容器(TSC)。在本文中,我们首先回顾了最近开发的基于微机电系统的热开关,并介绍了我们新的TSC的操作和结构。然后,给出了影响器件热性能的最重要参数之一热接触电阻的参数实验研究结果。这些实验数据后来被用于具有热开关电容器的磁热器件的数值模型中。研究结果表明,对于单个实施例,在零温度范围和5 Hz的工作频率下,可以实现970 W m−2(510 W kgmcm−1)的最大冷却功率密度。然而,通过将多个磁热元件与TSC级联可以实现更大的温度跨度。我们已经证明,即使温度变化很小,紧凑型TSC也可以用于热量设备,并且可以用于需要热调节的各种实际应用。
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.