Your search keyword '"Liu, Cichong"' showing total 2 results

1. Leakage analysis and concentration distribution of flammable refrigerant R290 in the automobile air conditioner system.

Author

Zhang, Yun, Liu, Cichong, Wang, Tianying, Pan, Leyan, Li, Wanyong, Shi, Junye, and Chen, Jiangping

Subjects

*LEAKAGE, *FLAMMABLE limits, *WIND speed, *GAS distribution, *AUTOMOBILES, *AIR conditioning

Abstract

• The leak pressure, leak hole size and wind speed are the three major parameters that affect R290 distribution. • Increasing the hole size and decreasing the wind speed will raise the maximum R290 concentration and the duration time. • A lower pressure indicates that the concentration rises slower but a maintained longer time. • Evaporator leakage is the most risky situation of the R290 MAC system. • The highest concentration and the duration time can be both significantly reduced by the SL system. The natural refrigerant R290 has been gradually investigated as an alternative refrigerant of R134a in the automobile air conditioning (MAC) systems at present. As an A3 class refrigerant, the application of R290 is associated with the greatest challenge of its flammable and explosive characteristics. This paper aimed to describe the distribution of R290 gas under different leakage conditions through experiments in the engine compartment and the passenger compartment. Our results showed that, evaporator leakage was the most risky situation of the system. In this case, R290 gas leaked to the passenger compartment, as a result, the R290 concentration in the environment was above the lower flammable limit (LFL). In the case of leakage in the engine compartment, the leak pressure, leak hole size, and wind speed were recognized as the three main parameters affecting R290 distribution. Moreover, increasing the hole size and decreasing the wind speed would raise the maximum R290 concentration as well as the duration in which the R290 gas concentration was above the LFL level. Additionally, a lower pressure suggested that the R290 concentration rose slower but it was maintained for a longer time above the LFL than that under high pressure situation. [ABSTRACT FROM AUTHOR]

Published

2020

2. Performance improvements evaluation of an automobile air conditioning system using CO2-propane mixture as a refrigerant.

Author

Yu, Binbin, Wang, Dandong, Liu, Cichong, Jiang, Fuzheng, Shi, Junye, and Chen, Jiangping

Subjects

*AIR conditioning, *AUTOMOBILES, *CARBON dioxide, *PERFORMANCE evaluation, *PROPANE, *GAS mixtures, *REFRIGERANTS

Abstract

The main purpose of this work is to enhance the energy efficiency of CO 2 automobile air conditioning system. Theoretical analysis demonstrated that the mixture of CO 2 and propane can improve its performance, thus, experiments have been carried out to see effects of various CO 2 -propane mass fractions of 100/0, 90/10, 80/20, 70/30, 60/40, 50/50 on the system performance at different ambient temperatures and gas cooler frontal air velocities. Experimental results show similar trends with those from the theoretical results. It has been shown that under the same compressor speed, system COP reaches highest at 60% of CO 2 mass fraction, which is 29.4% higher than pure CO 2 system and even achieves equal level of the R134a system, the optimum pressure and discharge temperature are reduced up to a maximum of 40% and 47   °C during the research range. Furthermore, comparison was carried out under the same cooling capacity by adjusting compressor speed for different mass fraction of CO 2 , results demonstrate that the use of CO 2 -propane mixtures yields a maximum COP rise of 22%even when cooling capacity is kept constant. A new optimum high pressure control algorithm for the transcritical CO 2 -propane mixture cycle has been developed based on the experimental data within a deviation of 5%. [ABSTRACT FROM AUTHOR]

Published

2018