SAE Technical Paper Series 1963
DOI: 10.4271/630076
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A Digital Computer Simulation for Spark-Ignited Engine Cycles

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Cited by 37 publications
(10 citation statements)
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“…A modification to two-zone (burned-gas, unburned-gas) models (Patterson and Van Wylen, 1963;Krieger and Borman, 1966) of the combustion event is useful in the context of end-gas knock: specifically, a distinct initial thermodynamic state (at Downloaded by [Michigan State University] at 03:24 08 February 2015 ignition) and (more importantly) a distinct polytropic-law exponent (for subsequent evolution of the thermodynamic state) characterize the final portion of the charge to undergo chemical conversion. Thus, for analytic purposes, the unburned charge at time zero is split into so-called "bulk" unburned gas and unburned end gas, each part being spatially uniform and temporally evolving, but the two parts being in general at different thermodynamic states at all times.…”
Section: Three-zone Treatment Of the Combustion Event 2a Preliminariesmentioning
confidence: 99%
“…A modification to two-zone (burned-gas, unburned-gas) models (Patterson and Van Wylen, 1963;Krieger and Borman, 1966) of the combustion event is useful in the context of end-gas knock: specifically, a distinct initial thermodynamic state (at Downloaded by [Michigan State University] at 03:24 08 February 2015 ignition) and (more importantly) a distinct polytropic-law exponent (for subsequent evolution of the thermodynamic state) characterize the final portion of the charge to undergo chemical conversion. Thus, for analytic purposes, the unburned charge at time zero is split into so-called "bulk" unburned gas and unburned end gas, each part being spatially uniform and temporally evolving, but the two parts being in general at different thermodynamic states at all times.…”
Section: Three-zone Treatment Of the Combustion Event 2a Preliminariesmentioning
confidence: 99%
“…Because specifically for combustion and, in general, chemically reactive systems, second law analysis allows the calculation of reaction irreversibility, i.e., the amount of fuel exergy which is destroyed during the irreversible chemical reaction and cannot be converted to work due to entropy increase, something that is not evident from simple first law analysis. A pioneering work on second law analysis of internal combustion engines was reported by Patterson and Van Wylen [6]. They described an early version of thermodynamic cycle simulation for SI engines in which they included the determination of entropy values.…”
Section: Introductionmentioning
confidence: 99%
“…However, a number of maior assumptions are often made in order to simplify the equations and obtain simple analytical solutions (cf., e.g., Krieger and Borman, 1966;Lavoie, Heywood, and Keck, 1970;Harrington, 1975;Danieli, Keck, and Heywood, 1977;McCuiston, Lavoie, and Kauffman, 1977). When accuracy is a requirement, then numerical techniques are adopted (cf., e.g., Patterson and Van Wylen, 1964;Tabaczynski, Ferguson, and Radhakrishnan, 1977).…”
Section: Introductionmentioning
confidence: 99%