Optimizing cascade refrigeration systems with low GWP refrigerants for Low-Temperature Applications: A thermodynamic analysis

IF 7.1 Q1 ENERGY & FUELS

Energy Conversion and Management-X Pub Date : 2024-09-21 DOI:10.1016/j.ecmx.2024.100722

Md. Miraj Arefin, Dipayan Mondal , Md. Ashraful Islam

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引用次数: 0

Abstract

This study offers a comprehensive thermodynamic analysis of a cascade refrigeration system conducted for low-temperature applications, focusing on the use of low-GWP and zero-ODP refrigerants to improve efficiency and sustainability. The target of this study is to explore the performance of the system using a combination of refrigerants: low-temperature cycle refrigerants such as R744, while high-temperature cycle refrigerants such as R717, R1234yf, R1234ze(E), R1336mzz(E), and R1336mzz(Z), respectively. The ECS model incorporating in REFPROP 10.0a tool was utilized to extract the data through coding for analysis. The assessment of this system involves the examination of various parameters such as its coefficient of performance, total compressor workload, total exergy, and exergy efficiency across various operational conditions. The results are compared with and without superheated and subcooled conditions to understand the impact of these parameters on the system performance. The system with R744 in the low-temperature cycle and R717, R1234yf, R1234ze(E), R1336mzz(E), and R1336mzz(Z) in the high-temperature cycle provides a higher COP and lower total compressor work compared to the conventional cascade refrigeration system. In optimal CRS, the R744-R717 pair attains the highest COP of 2.05 at the lowest possible compressor work from 9.53 to 4.87 kW than other refrigerants pair while evaporator temperature shifting from −55 °C to −20 °C. The exergy efficiency of R744/R717 is found at 26.47 % at an evaporator temperature of −55 °C, but it extends to a peak of 51.73 % at −20 °C. The study also shows that the superheating and sub-cooling of the refrigerants have a significant impact on the performance of the cascade refrigeration system. Superheating and sub-cooling at 10 °C, improves the COP of the system by reducing the compressor work and increasing the heat transfer efficiency. The research offers valuable insights into the system’s thermodynamic performance when employing low GWP refrigerants in low-temperature applications. These findings have the potential to guide the design and optimization of cascade refrigeration systems over the range of low-temperature applications.

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为低温应用优化使用低全球升温潜能值制冷剂的级联制冷系统：热力学分析

本研究对低温应用中的级联制冷系统进行了全面的热力学分析，重点是使用低全球升温潜能值和零臭氧消耗潜能值制冷剂来提高效率和可持续性。本研究的目标是探索使用制冷剂组合的系统性能：低温循环制冷剂，如 R744；高温循环制冷剂，如 R717、R1234yf、R1234ze(E)、R1336mzz(E) 和 R1336mzz(Z)。利用 REFPROP 10.0a 工具中的 ECS 模型，通过编码提取数据进行分析。对该系统的评估包括对各种参数的检查，如性能系数、压缩机总工作量、总放能和各种运行条件下的放能效率。比较了过热和过冷条件下的结果，以了解这些参数对系统性能的影响。与传统的级联制冷系统相比，在低温循环中使用 R744，在高温循环中使用 R717、R1234yf、R1234ze(E)、R1336mzz(E) 和 R1336mzz(Z) 的系统具有更高的 COP 和更低的压缩机总功。在最佳 CRS 中，与其他制冷剂相比，R744-R717 制冷剂对的 COP 最高，达到 2.05，压缩机功耗最低，从 9.53 kW 降至 4.87 kW，而蒸发器温度从 -55 °C 降至 -20 °C。在蒸发器温度为-55 °C时，R744/R717的能效为26.47%，但在-20 °C时，能效达到51.73%的峰值。研究还表明，制冷剂的过热和过冷对级联制冷系统的性能有重大影响。过热和过冷温度为 10 °C，通过减少压缩机功和提高传热效率，提高了系统的 COP。这项研究为在低温应用中使用低全球升温潜能值制冷剂时系统的热力学性能提供了宝贵的见解。这些发现有可能为低温应用范围内的级联制冷系统的设计和优化提供指导。

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来源期刊

Energy Conversion and Management-X Multiple-

CiteScore

8.80

自引率

3.20%

发文量

180

审稿时长

58 days

期刊介绍： Energy Conversion and Management: X is the open access extension of the reputable journal Energy Conversion and Management, serving as a platform for interdisciplinary research on a wide array of critical energy subjects. The journal is dedicated to publishing original contributions and in-depth technical review articles that present groundbreaking research on topics spanning energy generation, utilization, conversion, storage, transmission, conservation, management, and sustainability. The scope of Energy Conversion and Management: X encompasses various forms of energy, including mechanical, thermal, nuclear, chemical, electromagnetic, magnetic, and electric energy. It addresses all known energy resources, highlighting both conventional sources like fossil fuels and nuclear power, as well as renewable resources such as solar, biomass, hydro, wind, geothermal, and ocean energy.