Kalkidan Mekonnen Meshesha, David Newport, Gomez-Hernandez, J., Alan Odonovan, Ronan Grimes
Abstract: The increasing need for energy-efficient and sustainable high-temperature heat pump systems (HTHPs) has led to extensive research into working fluids with optimal thermodynamic performance. Among various refrigerants, carbon dioxide is a promising candidate due to its favourable effects on the environment, good thermophysical properties, and economic feasibility. However, its low critical temperature and high operating pressure pose significant challenges on efficiency of the system. One of the methods to explore the use of CO₂ as a refrigerant is to mix it with other hydrocarbons and form zeotropic refrigerant mixtures. Thus, the present study investigates the performance of CO₂-based zeotropic refrigerant mixtures with six hydrocarbons. Key performance indicators, including coefficient of performance (COP), sink outlet temperature, pressure ratio, and Lorenz efficiency were evaluated for the selected mixtures at different source inlet temperatures. The results indicated that at a source inlet temperature of 90°C, a CO₂/butane mixture delivers a sink outlet temperature of 147.3°C with a COP of 5.73, making it a strong candidate for temperature < 140°C. Additionally, CO₂/butane exhibits the lowest pressure ratio and highest Lorenz efficiency of 77.7% at 90°C source inlet temperature, exhibits reduced compressor workload and improving overall efficiency. For high-temperature applications exceeding 150°C, CO₂/acetone emerges as the most suitable mixture. At the maximum source inlet temperature, it achieves a sink outlet temperature of 188.76°C with a highest COP of 6.41 among all tested mixtures. Those findings highlight the potential of CO₂-based zeotropic mixtures to enhance HTHPs performance by reducing exergy destruction and improving heat exchanger thermal matching without the need for complex system modifications.
Keywords: Temperature glide, Hydrocarbons, Lorenz efficiency, zeotropic mixture, heat pump.
Date Published: December 24, 2025 DOI: 10.11159/jffhmt.2025.049
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