Study on expansion methods of the DC flow for transferring the temperature-distributed refrigeration power

IF 3.5 2区工程技术 Q1 ENGINEERING, MECHANICAL

International Journal of Refrigeration-revue Internationale Du Froid Pub Date : 2025-04-18 DOI:10.1016/j.ijrefrig.2025.04.017

Qiang Cao , Pengcheng Wang , Zhiping Wang , Yuji Chen , Lichun Ge , Peng Li , Qinyu Zhao , Bo Wang , Zhihua Gan

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引用次数: 0

Abstract

The temperature-distributed refrigeration power in the regenerator is effectively transferred by extracting the inner direct-current (DC) flow from the regenerator. The transfer efficiency is improved by up to 1–2 times compared with traditional transfer methods because there is no radial thermal resistance in the regenerator during the transfer process. However, the specific heat capacity between the DC flow and the gas to be liquefied is usually mismatched due to the difference in pressure or working fluid, resulting in heat exchange loss. In this paper, we propose the expansion methods of the DC flow. The refrigeration power at the cold end of the refrigerator is increased by the expansion methods due to the liquefaction of the DC flow. Meanwhile, the distribution of specific heat capacity in the DC flow is altered, which generally enhances its availability. For the case study of ⁴He, the availability of the expanded DC flow is improved by around 40 % after expansion. The specific heat capacity between the DC flow and the gas to be liquefied becomes better matched, and the theoretical helium liquefaction rate is improved by approximately 25 %. In addition, the figure of merit (FOM) for liquefaction is enhanced by about 20 %, which includes the compression work of the expanded DC flow returning to the original refrigerator, form a closed cycle. This research enriches the study of the temperature-distributed regenerative refrigeration method and provides a reference for improving the transfer efficiency of the temperature-distributed refrigeration power and the liquefaction rate of cryogenic gases.

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温度分布制冷功率直流流扩展方法研究

通过抽取蓄热器内部的直流电，有效地传递了蓄热器内温度分布的制冷功率。由于蓄热器在传递过程中不存在径向热阻，因此与传统的传递方式相比，传递效率提高了1-2倍。但由于压力或工质的差异，直流流与待液化气体之间的比热容往往不匹配，造成换热损失。在本文中，我们提出了直流流的展开方法。由于直流流的液化作用，采用膨胀方式增加了制冷机冷端制冷功率。同时，改变了直流流中比热容的分布，提高了直流流的可用性。以4He为例，扩展后的直流流的可用性提高了约40%。直流流与待液化气体的比热容匹配较好，理论氦液化率提高约25%。此外，液化的功值（FOM）提高了约20%，其中包括膨胀直流流返回原始制冷机的压缩功，形成封闭循环。本研究丰富了温度分布蓄热式制冷方式的研究，为提高温度分布制冷功率的传递效率和低温气体的液化速率提供了参考。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Refrigeration-revue Internationale Du Froid 工程技术-工程：机械

CiteScore

7.30

自引率

12.80%

发文量

363

审稿时长

3.7 months

期刊介绍： The International Journal of Refrigeration is published for the International Institute of Refrigeration (IIR) by Elsevier. It is essential reading for all those wishing to keep abreast of research and industrial news in refrigeration, air conditioning and associated fields. This is particularly important in these times of rapid introduction of alternative refrigerants and the emergence of new technology. The journal has published special issues on alternative refrigerants and novel topics in the field of boiling, condensation, heat pumps, food refrigeration, carbon dioxide, ammonia, hydrocarbons, magnetic refrigeration at room temperature, sorptive cooling, phase change materials and slurries, ejector technology, compressors, and solar cooling. As well as original research papers the International Journal of Refrigeration also includes review articles, papers presented at IIR conferences, short reports and letters describing preliminary results and experimental details, and letters to the Editor on recent areas of discussion and controversy. Other features include forthcoming events, conference reports and book reviews. Papers are published in either English or French with the IIR news section in both languages.