On the Rate of Heat Release for High-Boost, Low-Temperature Combustion Schemes: Accounting for Compressibility Effects

“…The model assumes a mixture of ideal gases, so compressibility effects are currently not considered. These have been shown to be important at certain conditions relevant to high pressure, low temperature combustion [63]. The properties routines allow for multi-component fuels, such as gasoline surrogates, Primary Reference Fuels (PRF) and gasoline-ethanol blends, and includes some of the most commonly used fuels.…”

Section: Appendix a Supporting Methods In Ace-hramentioning

confidence: 99%

Enhanced heat release analysis for advanced multi-mode combustion engine experiments

et al. 2014

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“…The heat denoted Q Loss comprises three distinct components: Q IC, which represents the heat loss from incomplete combustion of fuel within the engine cylinder; Q CR, which denotes the heat loss from crevices; and Q BL , which signifies the heat loss from a combustible mixture blow-by to the crankcase (Equation ( 3)). As this analysis aims to eliminate the total heat released and concentrate on the net heat, these losses can be neglected as stated by Goldsborough, Nande and Ihsan et al [3][4][5], respectively.…”

Section: Introductionmentioning

confidence: 99%

Thermodynamic Analysis of the Combustion Process in Hydrogen-Fueled Engines with EGR

Szwaja,

Piotrowski,

Szwaja

et al. 2024

Energies

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This article presents a novel approach to the analysis of heat release in a hydrogen-fueled internal combustion spark-ignition engine with exhaust gas recirculation (EGR). It also discusses aspects of thermodynamic analysis common to modeling and empirical analysis. This new approach concerns a novel method of calculating the specific heat ratio (cp/cv) and takes into account the reduction in the number of moles during combustion, which is characteristic of hydrogen combustion. This reduction in the number of moles was designated as a molar contraction. This is particularly crucial when calculating the average temperature during combustion. Subsequently, the outcomes of experimental tests, including the heat-release rate, the initial combustion phase (denoted CA0-10) and the main combustion phase (CA10-90), are presented. Furthermore, the impact of exhaust gas recirculation on the combustion process in the engine is also discussed. The efficacy of the proposed measures was validated by analyzing the heat-release rate and calculating the mean combustion temperature in the engine. The application of EGR in the range 0-40% resulted in a notable prolongation of both the initial and main combustion phases, which consequently influenced the mean combustion temperature.

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On the Rate of Heat Release for High-Boost, Low-Temperature Combustion Schemes: Accounting for Compressibility Effects

Cited by 4 publications

References 58 publications

Fuel and diluent property effects during wet compression of a fuel aerosol under RCM conditions

Fuel and diluent property effects during wet compression of a fuel aerosol under RCM conditions

Enhanced heat release analysis for advanced multi-mode combustion engine experiments

Thermodynamic Analysis of the Combustion Process in Hydrogen-Fueled Engines with EGR

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