使用 R1234ze(氢氟烯烃)作为制冷剂的热泵空调性能

IF 1 Q3 ENGINEERING, MULTIDISCIPLINARY
Subhash Kumar, V. Raibhole, Himadri Majumder
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引用次数: 0

摘要

研究表明,制冷剂 R1234ze (E) 和 R1234ze (Z) 以其较低的全球升温潜能值而著称,很可能成为住宅和商用热泵空调的主要选择。该研究通过实验、热力学和数值分析对 R1234ze (Z) 的热力学特性进行了评估。该研究通过探索各种制冷剂(包括 R227ea、R114、R236fa、R134a、R1234ze (Z) 和 R245fa)作为满足不断变化的行业需求的潜在候选制冷剂,满足了含氟温室气体法规的要求,并与《巴黎协定》的目标保持一致。分析表明,在热泵应用中,R1234ze (Z) 的性能优于其他工作流体,在冷凝温度比临界温度低 22 K 时,其理论性能系数 (COP) 达到最优。然而,由于压降较大,特别是在容积容量不足的情况下,实际 COP 会出现偏差。一个重要发现是,压力降低的很大一部分原因是为了减少不可逆损失,估计冷凝温度为 70-75°C,强调了压力与性能之间的复杂关系。研究表明,与传统空调系统相比,R1234ze(Z)更适合高温应用。在一项平行评估中,对 R245fa 性能系数的初步计算评估了新型制冷工业布置的可靠性。热泵技术的测试结果表明,R1234ze(Z)在 90°C 的升温温度和 45 K 的温差条件下可实现高达 3.60 的性能系数。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Performance of Heat Pump Air Conditioning with R1234ze (HFO) as a Refrigerant
The study shows that refrigerants R1234ze (E) and R1234ze (Z), known for their low global warming potential, are likely to become primary choices in heat pump air conditioning for residential and commercial use. The research evaluates the thermodynamic properties of R1234ze (Z) using experimental, thermodynamic, and numerical analyses. It addresses F-gas regulation requirements and aligns with the Paris Agreement goals by exploring various refrigerants, including R227ea, R114, R236fa, R134a, R1234ze (Z), and R245fa, as potential candidates for evolving industry needs. The analysis indicates that R1234ze (Z) outperforms other working fluids in heat pump applications, with an optimized theoretical coefficient of performance (COP) at a condensation temperature 22 K lower than critical temperatures. However, actual COP deviates due to a significant pressure drop, especially with inadequate volumetric capacity. A key finding is that a substantial portion of the pressure reduction is attributed to mitigating irreversible losses, estimated at a condensation temperature of 70–75°C, emphasizing the complex relationship between pressure and performance. The study suggests that R1234ze (Z) is more suitable for high-temperature applications than traditional air conditioning systems. In a parallel assessment, the initial calculation of the coefficient of performance for R245fa evaluates the reliability of a new refrigeration industry arrangement. Test results for heat pump technology reveal that R1234ze (Z) achieves an impressive COP of up to 3.60 at a buildup temperature of 90°C with a temperature differential of 45 K. This positions R1234ze (Z) as a suitable choice for heat pump applications prioritizing simplicity in system design.
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来源期刊
Journal of Optimization
Journal of Optimization ENGINEERING, MULTIDISCIPLINARY-
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