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Heat Transfer Studies in an Adiabatic Diesel Engine
Technical Paper
912502
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English
Abstract
Numerical calculation based on finite element method are carried out to calculate the temperature field in an adiabatic diesel engine piston having diameter. 127 mm and made of aluminum alloy. The engine cylinder wall have the coated externally by a thin layer of very high grade ceramic insulating material. The isothermic distribution in the piston body and the heat flow rates to the cooling media at different loads have been depicted for both cases with and without insulation coating. The paper first reviews the current state of development of ‘adiabatic’ diesel engine in Europe, U.S.A and the Japan. This review section is followed by a brief description of the common element of hostile features, then comes the experimental program on thermally insulated components for single cylinder engine in the research center of Tabriz and finally by a theoretical section dealing with the performance potential of composed engine schemes based on ‘adiabatic’ engine operation.
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Citation
Khoshravan, E., "Heat Transfer Studies in an Adiabatic Diesel Engine," SAE Technical Paper 912502, 1991.Also In
References
- Wallace, F.J. Kao, T.K. Tarabad, M. Alexander, W.D. Cole, A. Thermally insulated diesel engines Proc.Instn. Mech. Engrs 1984
- Kawamura, H. Development of ceramic engine parts for heat insulated engine Proc. of Intl. Conference on auto technology 1990
- Kamo, R. Cycles and performance studies for advanced diesel engines Conference on ceramics for high performance applications Newport, RI Mar. 1977
- Kamo, R. Bryzik, W. Adiabatic turbocompound engine performance prediction SAE Congress Detroit 1978 780066
- Kamo, R. Bryzik, W. Ceramics - TARADCOM adiabatic turbocompound engine program SAE Congress Detroit 1981
- Bryzik, W. Kamo, R. TACOM - CUMMINS adiabatic engine program SAE Congress Detroit Feb. 1983 830314
- Marmach, M. Servent, D. Hanink, R.H.J. Murray, M.J. Swain, M.V. Toughend PSZ Ceramics - their role as advanced engine components SAE Congress Detroit Feb. 1983 830318
- Valland, H. Wyspiansky, G.K. A theoretical analysis of thermal barriers in diesel engine cylinders Norwegian Marine Research 1982 Nov. 2
- Wallace, F.J. Way, R.J.B. Vollmert H. Effect of partial suppression of heat loss to coolant on the high output diesel engine cycle SAE Milwukee Sept. 1979 790823
- Wallace, F.J. Kao, T.K. Alexander, W.A. Cole, A.C. Tarabad, M. Thermal barrier pistons and their effect on the performance of compound diesel engine cycles SAE Detroit Mar. 1983 830312
- Wallace, F.J. The differential compound engine Proc. Instn. Mech. Engrs 1973 187 548
- Chen, S.K. Lin, R. A review of engine advanced cycle and Rankine bottoming cycle and their loss evaluations SAE Congress Detroit Feb. 1983 830124
- Suzuki, T. An observation of combustion phenomenon on heat insulated turbo - charged and inter cooled D.I. diesel engine SAE, paper 861187
- Onishi, S. Kato, S. Direct injection stratified charge engine by impingement of fuel jet (OSKA) - performance and combustion characteristics SAE, paper 900609
- Kamimoto, T. Bae, M. High combustion temperature for the reduction of particulate in diesel engine SAE, paper 880423
- Kawamura, H. Study of construction and tribology in heat insulated ceramic engine SAE, paper 900624
- Kawamura, H. Ceramics materials for an automotive engine 1989
- Khoshravan, E. Heat transfer studies in an I.C.E. piston Proc. of the Intl. Conference on auto technology 1990