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Thermodynamic and Thermochemical Aspects of Combustion in Premixed Charge Engines Revisited
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Abstract
In principle, the thermodynamic and thermochemical processes evolve with time, irrespectively of their spatial orientation. They are, therefore, specified in terms of ordinary differential equations with respect to time as the only independent variable. This feature is well reflected in the literature by the so-called zero-dimensional models. Current demands of technological progress impose much stricter requirements upon the precision of such calculations than ever before. A methodology for catering to them is presented. Its application is illustrated by the performance analysis of a Renault engine, operated at full and part loads, with particular emphasis placed upon the formation of major combustion-generated pollutants, NOx and CO, in a premixed-charge engine.
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Gavillet, G., Maxson, J., and Oppenheim, A., "Thermodynamic and Thermochemical Aspects of Combustion in Premixed Charge Engines Revisited," SAE Technical Paper 930432, 1993, https://doi.org/10.4271/930432.Also In
References
- Obert, E. F. Internal Combustion Engines and Air Pollution xiii 740 Harper and Row, Publishers New York 1973
- Heywood, J. B. Internal Combustion Engine FundamentalS xxix 930 McGraw-Hill Book Company 1988
- Benson, R. A. The Thermodynamics and Gas Dynamics of internal-Combustion Engines Horlockand J. H. Winterbone D. E. I 582 Clarendon Press Oxford 1982 Horlock J. H. Winterbone D. E. The Thermodynamics and Gas Dynamics of Internal-Combustion Engines 583 1237 Clarendon Press Oxford 1986
- Rassweiler, G. M. Withrow, L. “Motion Pictures of Engine Flames Correlated with Pressure Cards,” SAE Landmark Reprint Paper 80031 20 1980 SAE Trans. 83 185 204 1938
- Lavoie, G. A. Heywood, J. B. Keck, J. C. “Experimental and Theoretical investigation of Nitric Oxide Formation in internal Combustion Engines,” Combustion Science and Technology 1 313 326 1970
- Blizard, N. C. Keck, J. C. “Experimental and Theoretical Investigation of Turbulent Burning Model for internal Combustion Engines,” SAE Paper 740191 18 1974
- Heywood, J. B. Higgins, J. M. Watts, P. A. Tabaczynski, R. J. “Development and Use of a Cycle Simulation to Predict S. I. Engine Efficiency and NO x Emissions,” SAE Paper 790291 1979
- Hiraki, H. Rife, J. M. “Performance and NO x Model of a Direct Injection Stratified Charge Engine SAE Paper 800050 21 1980
- Chun, K. M. Heywood, J. B. “Estimating Heat-Release and Mass-of-Mixture Burned from Spark-Ignition Engine Pressure Data,” Combust. Sci. and Tech. 54 133 143 1987
- Blumberg, P. N. Kummer, J. T. “Prediction of Nitric Oxide Emissions from Spark Ignited Engines: An Analysis of Methods of Control,” Combustion Science and Technology 4 73 95 1971
- Blumberg, P. N. Lavoie, G. A. Tabaczynski, R. J. “Phenomenological Models for Reciprocating internal Combustion Engines,” Progress in Combustion and Energy Science 5 123 167 1979
- Shayler, P. J. Wiseman, M. W. Ma, T. “Improving the Determination of Mass Fraction Burnt,” SAE Paper 900351 8 1990
- Heywood, J. B. “Engine Combustion Modeling - An Overview,” Combustion Modeling in Reciprocating Engines Mattavi J. N. Amann C. A. 1 38 Plenum Publishing Corp. New York 1980
- Myers, P. “The Art of Choosing a Model,” SAE Paper 850341 Engine Combustion Analysis: New Approaches 1 14 SAE Warrendale, PA. 1985
- Primus, R J. Wong, V. W. “Performance and Combustion Modeling of Heterogeneous Charge Engines,” SAE Paper 850343 Engine Combustion Analysis: New Approaches 15 25 SAE Warrendale, PA. 1985
- Borman, G. Nishiwaki, K. “Internal-Combustion Engine Heat Transfer,” Prog, in Energy and Combustion Sci. 13 1 1 46 1987
- Krieger, R. B. Borman, G. L. “The Computation of Apparent Heat Release for internal Combustion Engines,” ASME 66-WA/DGP-4 16 1966
- Flynn, P. Mizusawa, M. Uyehara, O. A. Myers, P. S. “An Experimental Determination of the Instantaneous Potential Radiant Heat Transfer Within an Operating Diesel Engine,” SAE Paper 720022
- Woschni, G. “A Universally Applicable Equation for the instantaneous Heat Transfer Coefficient in the internal Combustion Engine,” SAE Paper 670931 SAE Transactions 76 3065 3083 1968
- Annand, W. J. D. “Heat Transfer in the Cylinders of Reciprocating internal Combustion Engines,” Proceedings of the Institution of Mechanical Engineers 177 36 973 996 1963
- Annand, W. J. D. Ma, T. H. “Instantaneous Heat Transfer Rates to the Cylinder Wall Surface of a Small Compression-Ignition Engine,” Proceedings of the institution of Mechanical Engineers 185 976 987 1970
- Maxson, J. A. Ezekoye, O. A. Hensinger, D. M. Greif, R. Oppenheim, A. K. “Heat Transfer from Combustion in an Enclosure,” Twenty-Fourth Symposium (International) on Combustion Sydney, Australia 1992
- Meintjes, K. “A User's Guide for the GM Engine-Simulation Program,” GM Research Publication GMR-5758 17 1987
- Morel, T. Keribar Blumberg, P. N. “A New Approach to integrating Engine Performance and Component Design Analysis Through Simulation,” SAE 880131 24 1988
- Morel, T. Flemming, M. F. LaPointe, L. A. “Characterization of Manifold Dynamics in the Chrysler 2.2 S.I. Engine by Measurements and Simulation,” SAE 900679 12 1990
- Reynolds, W. C. “Engine Simulation Program,” Department of Mechanical Engineering, Stanford University 8 1987
- Amsden, A. A. O'Rourke, P. J. Butler, T. D. “KIVA-II: A Computer Program for Chemically Reactive Flows with Sprays,” Los Alamos National Laboratory Report LA-11560-MS vi 158 1989
- Oppenheim, A. K. Beltramo, J. Faris, D. W. Maxson, J. A. Hom, K. Stewart, H. E. “Combustion by Pulsed Jet Plumes - Key to Controlled Combustion Engines,” SAE Paper 890153 10 1989
- Maxson, J. A. Oppenheim, A. K. “Pulsed Jet Combustion - Key to a Refinement of the Stratified Charge Concept,” Twenty-Third Symposium (International) on Combustion The Combustion institute Pittsburgh, Pa. 1041 1046 1991
- Maxson, J. A. Hensinger, D. M. Hom, K. Oppenheim, A. K. “Performance of Multiple Stream Pulsed Jet Combustion Systems,” SAE Paper 910565 9 1991
- Hensinger, D. M. Maxson, J. A. Hom, K. Oppenheim, A. K. “Jet Plume injection and Combustion,” SAE Paper 920414 10 1992
- Reynolds, W.C. “STANJAN - interactive Computer Programs for Chemical Equilibrium Analysis,” Department of Mechanical Engineering. Stanford University 46 1981
- Kee, R. J. Rupley, F.M. Miller, J. A. “CHEMKIN-II: A Fortran Chemical Kinetics Package for the Analysis of Gas-Phase Chemical Kinetics,” Sandia Report SAND89-8009 127 1989
- Hindmarsh, A. L. “ODEPACK. A Systematized Collection of ODE Solvers,” Scientific Computing Stephens R. F. IMAC Transactions on Scientific Comput 55 64 North Holland Amsterdam 1983
- Gear, C. W. Numerical initial Value Problems for Ordinary Differential Equations xvii 253 Prentice-Hall 1971
- Guirguis, R. H. Oppenheim, A. K. Karasalo, I. Creighton, J. R. “Thermochemistry of Methane Ignition,” Combustion in Reactive Systems, Progress in Astronautics and Aeronautics AIAA New York 76 134 153 1981
- Oppenheim, A. K. “Dynamic Features of Combustion,” Phil. Trans. R. Soc. Lond. A315 471 508 1985
- Griffiths, J. F. “Thermokinetic interactions in Simple Gaseous Reactions,” Ann. Rev. Phys. Chem. 36 77 104 1985
- Maas, U. Pope, S. B. “Simplifying Chemical Kinetics: intrinsic Low-Dimensional Manifolds in Composition Space,” Combustion and Flame 88 239 264 1992
- Maas, U. Pope, S. B. “Implementation of Simplified Chemical Kinetics Based on intrinsic Low-Dimensional Manifolds,” Twenty-Fourth Symposium (International) on Combustion The Combustion institute Pittsburgh, PA.
- Oppenheim, A. K. Maxson, J. A. “Thermodynamics of Combustion in an Enclosure,” Progress in Astronautics and Aeronautics American institute of Aeronautics and Astronautics New York
- Flamm, L. Mache, H. “Combustion of an Explosive Gas Mixture within a Closed Vessel,” Berichte, Wien Akad. Wissenschaften 26 9 ff 1917
- Lewis, B. von Elbe, G. Combustion, Flames and Explosion of Gase S, (esp. Chapter V, 15, Combustion Waves in Closed Vessels 381 395 Third xxiv 739 Academic Press, Inc. Orlando, Florida 1987
- Zeldovich, Ya. B. Barenblatt, G. I. Librovich, V. B. Makhviladze, G. M. The Mathematical Theory of Combustion and Explosions 478 1980 Combustion in Closed Vessels, The Mache Effect 470 487 McNeill D. H. Consultants Bureau New York and London xxi 597 1985