基于R744和R134a制冷循环的热力学研究

2020 3rd International Conference on Computing, Mathematics and Engineering Technologies (iCoMET) Pub Date : 2020-01-01 DOI:10.1109/iCoMET48670.2020.9074121

F. Akhtar, M. Sultan

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引用次数: 0

摘要

本文对R134a和CO2/R744制冷剂的制冷循环和压缩机的工作进行了研究。相对的论证已经特别创建了小冷却能力和蒸发温度的设计。利用压缩机工作性能的精确数值模拟微型机对R134a和R744压缩机样机进行了数值校核。为了验证单级蒸汽压缩制冷机组的热力和流体动力学特性，开发并应用了详细的数值模拟。热力学研究的数值结果显示了令人满意的一致性，而相对全局值表明在相同的工作条件下相似的效率。对比R744和R134a作为制冷剂，在- 17.7℃下吸热，60℃下排热。R744需要更高的压力，导致压缩机温度更高，性能系数更低。热力学计算用REFPROP软件完成。

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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Thermodynamic investigation of R744 and R134a based refrigeration cycle

The present work is an investigation of refrigerating cycles and the compressors work for R134a and CO2/R744 refrigerants. Relative demonstration conferred has been peculiarly created design for small cooling capacities and an evaporation temperature. An accurate numerical feigning miniature for compressors work performance has been used to numerically collate both R134a and R744 based compressor prototypes. To validate the detailed numerical simulation of the thermal and fluid dynamic behavior of single stage vapor compression refrigerating unit has been developed and utilized. The numerical outcomes obtained from the thermodynamic investigation reveals a satisfactory agreement, while the relative global values indicate resembling efficiencies under the identical working conditions. Compare is made between R744 and R134a as a refrigerant to pick up heat at −17.7°C and reject at 60°C. R744 requires significantly higher pressures and results in higher temperature from compressor and have lower coefficient of performance. Thermodynamic calculations are done with REFPROP software.

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2020 3rd International Conference on Computing, Mathematics and Engineering Technologies (iCoMET)

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