Transactions of the Korean Society of Automotive Engineers (한국자동차공학회논문집)

The Korean Society of Automotive Engineers (한국자동차공학회)
권호 표지
DOI QR코드

DOI QR Code

Experimental Study of the Effect on Cabin Thermal Comfort for Cold Storage Systems in Vehicles

축냉 시스템이 차 실내 열 쾌적성에 미치는 영향에 관한 실험적 연구

  • Lee, Daewoong (Research Division, Halla-Visteon Climate Control Corp.)
  • 이대웅 (한라비스테온공조 연구본부)
  • Received : 2014.12.26
  • Accepted : 2015.04.13
  • Published : 2015.07.01
Download PDF
⟨ Previous Next ⟩

Abstract

This paper presents the experimental study of cabin thermal comfort using a cold storage heat exchanger in a vehicle air-conditioning system. Recent vehicle-applied ISG functions for fuel economy and emission, but when vehicles stop, compressors in the air-conditioning system stop, and the cabin temperature sharply increases, making passengers feel thermal discomfort. This study conducts thermal comfort evaluation in the vehicle, which is applied to a cold storage system for the climate control wind tunnel test and the vehicle fleet road test with various airflow volume rates and ambient temperatures blowing to the cold storage heat exchanger. The experimental results, in the cold storage system, air discharge temperature is $3.1-4.2^{\circ}C$ lower than current air-conditioning system when the compressor stops and provides cold air for at least 38 extra seconds. In addition, the blowing airflow volume to the cold storage heat exchanger with various ambient temperature was examined for the control logic of the cold storage system, and in the results, the airflow volume rate is dominant over the outside temperature. For this study, a cold storage system is economically useful to keep the cabin at a thermally comfortable level during the short period when the engine stops in ISG vehicles.

Keywords

References

  1. J. Kim, K. Oh, J. Lee and H. Kim, "Analysis of Fuel Economy for a 42-volt ISG Vehicle Using Performance Simulator," Transactions of KSAE, Vol.13, No.3, pp.1-9, 2005.
  2. K. Okuda, Y. Komatsu, S. Aoki, T. Fujiwara and Y. Nakahara, "Research of Low Tension ISG Belt-riven System for Idling Stop System," IPC 13, pp.238-243, 2005.
  3. G. Guyonvarch, R. Haller and L. Lepetit, "A Comparison between Climate Control Systems Providing Thermal Comfort during Vehicle Stops," SAE 2003-01-1073, 2003.
  4. J. Bailey, P. Pilato, F. Wicks and R. Wilk, "Modeling and Assessment of Ice Storage for Air Conditioning," SAE 1999-012719, 1999.
  5. K. S. Lee, H. J. Kim, C. I. Baek, Y. K. Song, C. S. Han and D. J. Kim, "Numerical Analysis on the Performance for Automobile Heat Storage System Using Phase Change Material," Transactions of KSAE, Vol.4, No.3, pp.187-198, 1996.
  6. K. B. Kim, B. H. Moon, K. W. Choi and K. H. Lee, "Automotive Engine Cooling Using a Phase Change Material," Transactions of KSAE, Vol.21, No.3, pp.24-29, 2013.
  7. M. Eisele, Y. Hwang and R. Radermacher, "Utilization of Ice Storage in Secondary Loop Automotive Air-conditioning Systems," SAE 2013-01-0235, 2013.
  8. T. Craig, J. O. Brien, D. Polisoto and N. Wolfe, "Integrated Air Conditioning Evaporator with Phase Change Material for Thermal Storage," SAE 10AARS-002, 2010.
  9. D. Lee, D. Keon, S. Chung, C. Jeong and Y. Wang, "Performance Investigation of Cold Storage Heat-exchanger or Vehicle Applied ISG," KSAE Annual Conference Proceedings, pp.485-492, 2014.

Cited by

  1. Numerical analysis and experimental study on the performance optimization of cold storage heat exchanger integrated with evaporator vol.18, pp.3, 2017, https://doi.org/10.1007/s12239-017-0038-0