论文信息 - Modeling of heat conduction within chamber walls for multidimensional internal combustion engine simulation

Modeling of heat conduction within chamber walls for multidimensional internal combustion engine simulation

A two-dimensional (axisymmetric) transient heat conduction in components computer program (HCC) was successfully developed for predicting engine combustion chamber wall temperatures. The alternating direction explicit (ADE) Saul'yev method, an explicit, unconditionally stable finite difference method, was used in the code. Special treatments for the head gasket and the piston-liner air gap, the piston movement, and a grid transformation for describing the realistic piston bowl shape were designed and utilized. The results were compared with a finite element method and were verified to be accurate for simplified test problems. In addition, the method was applied to realistic problems of heat transfer in an Isuzu engine and a Caterpillar diesel engine, and gave good agreement with available experimental measurements.

Y. Liu | Y. Liu | R. Reitz

[1] Garry J. Tee,et al. Integration of Equations of Parabolic Type by the Method of Nets , 1964 .

[2] J. C. Jaeger,et al. Conduction of Heat in Solids , 1952 .

[3] Rolf D. Reitz,et al. Measurement of the Effect of Injection Rate and Split Injections on Diesel Engine Soot and NOx Emissions , 1994 .

[4] Kazuie Nishiwaki,et al. Internal-combustion engine heat transfer , 1987 .

[5] Rifat Keribar,et al. Cyclical Thermal Phenomena in Engine Combustion Chamber Surfaces , 1985 .

[6] R. Reitz,et al. A temperature wall function formulation for variable-density turbulent flows with application to engine convective heat transfer modeling , 1997 .

[7] John B. Heywood,et al. Internal combustion engine fundamentals , 1988 .

[8] G. E. Myers,et al. Analytical Methods in Conduction Heat Transfer , 1998 .

[9] Rolf D. Reitz,et al. Multidimensional modeling of engine combustion chamber surface temperatures , 1997 .

[10] A. A. Amsden,et al. KIVA-II: A Computer Program for Chemically Reactive Flows with Sprays , 1989 .