Abstract
Adequate visibility through the automobile windshield is of paramount practical significance, most often at very low temperatures when ice tends to form on the windshield screen. But the numerical simulation of the defrost process is a challenging task because phase change is involved. In this study numerical solution was computed by a finite volume computational fluid dynamics (CFD) program and experimental investigations were performed to validate the numerical results. It was found that the airflow produced by the defrost nozzle is highly nonuniform in nature and does not cover the whole windshield area. The nonuniformity also severely affected the heating temperature pattern on the windshield. The windshield temperature reached a maximum in the vicinity of the defroster nozzle in the lower part of the windshield and ranged from 9∼31°C over a period of 30 min, which caused the frost to melt on the windshield. The melting time was under 10 minutes, which satisfied the NHTSA standard. The numerical predictions were in close agreement with the experimental results. Thus, CFD can be a very useful design tool for an automobile HVAC system.
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References
Anon (2007). SC/Tetra User’s Guide, Version 7, Software Cradle Co., Ltd. September.
Abdul Nour, B. S. (1998). Numerical simulation of vehicle defroster flow field. SAE Paper No. 980285.
Aroussi, A. and Hassan, A. (2003). Vehicls side-window defrosting and demisting process. 1st European Automotive CFD Conf..
Aroussi, A., Hassan, A. and Morsi, Y. S. (2003). Numerical simulation of the airflow over and heat transfer through a vehicle windshield defrosting and demisting system. Heat and Mass Transfer, 39, 401–405.
Brewster, R. A., Frik, S. and Werner, F. (1997). Computational analysis of automotive windshield de-icing with comparison to test data. SAE Paper No. 971833, London & New York.
Carignano, M. and Pipppione, E. (1990). Optimisation of windscreen defrosting for industrial vehicle via computer assisted thermographic analysis. SAE Paper No. 905237.
Dugand, M. M. and Vitali, D. F. (1990). Vehicle internal thermo-fluid dynamics; Experimental and numerical evaluation. SAE Paper No. 9052335.
Park, W. G., Park, M. S. and Jang, K. L. (2006). Flow and temperature analysis within automobile cabin by discgarged hot air from defrost nozzle. Int. J. Automotive Technology 7,2, 139–143.
Kader, M. F., Youn, Y. M., Jun, Y. D. and Lee, K. B. (2009). Characterization of the HVAC performance with defroster grillers and instrument panel registers. Int. J. Automotive Technology 10,3, 305–312.
Lee, J. G., Jiang, Y., Przekwas, J. and Sioshansi, M. (1994). Validation of computational vehicle windshield de-icing process. SAE Paper No. 940600.
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Kang, S.J., Kader, M.F., Jun, Y.D. et al. Automobile defrosting system analysis through a full-scale model. Int.J Automot. Technol. 12, 39–44 (2011). https://doi.org/10.1007/s12239-011-0005-0
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DOI: https://doi.org/10.1007/s12239-011-0005-0