Turbulent flame propagation and combustion in spark ignition engines

Beretta, Gian Paolo; Rashidi, M. Al; Keck, James C.

doi:10.1016/0010-2180(83)90135-9

Cited by 156 publications

(75 citation statements)

References 22 publications

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“…It should be noted that this ratio remains nearly constant over most of the combustion event and this is a useful property because it simplifies the analysis [59].…”

Section: Turbulent Burning Velocitiesmentioning

confidence: 99%

Characterisation of flame development with ethanol, butanol, iso-octane, gasoline and methane in a direct-injection spark-ignition engine

Aleiferis

Serras-Pereira

Richardson

2013

Fuel

136

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“…It should be noted that this ratio remains nearly constant over most of the combustion event and this is a useful property because it simplifies the analysis [59].…”

Section: Turbulent Burning Velocitiesmentioning

confidence: 99%

Characterisation of flame development with ethanol, butanol, iso-octane, gasoline and methane in a direct-injection spark-ignition engine

Aleiferis

Serras-Pereira

Richardson

2013

Fuel

136

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“…The ratio between unburned to burned gas density is approximately constant throughout the combustion and close to a value of 4 and the mass fraction burned x b can be calculated according to Beretta et al (1983). The gas densities were obtained by Morley (2005) for the in-cylinder conditions at stoichiometric spark timing (4.8 bar, 550 K) and a ratio of  u / b =4.7 was calculated.…”

Section: A2 Mfb From Flame Imaging and Thermodynamic Analysismentioning

confidence: 95%

Insights into Stoichiometric and Lean Combustion Phenomena of Gasoline–Butanol, Gasoline–Ethanol, Iso-Octane–Butanol, and Iso-Octane–Ethanol Blends in an Optical Spark-Ignition Engine

Aleiferis

Behringer

OudeNijeweme

et al. 2017

Combustion Science and Technology

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“…In previous engine research images of flames in cylinders showed a significant enflamed volume, but the pressure measurements were not accurate or sensitive enough to indicate the evolving flame kernels [21,15]. Therefore, optical investigation of combustion is preferred to pressure tracing at the early combustion stages.…”

Section: Visualisation Of Initial Flame Kernel Growth In Si Enginesmentioning

confidence: 99%

“…The first two stages are of high importance in terms of in-cylinder pressure development [12][13][14][15][16]. These four stages are influenced by: spark energy and duration [17]; spark plug design and orientation [18]; in-cylinder flow field [19]; cyclic cylinder charging [20]; in-cylinder composition [21]; and other related factors. A detailed literature survey on the effects of these parameters on the four stages of combustion appeared in [12].…”

Section: Flame Structure and Propagationmentioning

confidence: 99%

“…Generally, previous studies have assumed that the propagation of the spark-initiated oxidation is isotropic, i.e. spherical flame propagation [15,16,18,21,25,28,29,39,38,[30][31][32][33][34][35][36]. Only a few studies mentioned different flame-front geometries [14,15,30,39] and looked into implications arising from the assumption that the flame front surface had a spherical geometry.…”

Section: Visualisation Of Initial Flame Kernel Growth In Si Enginesmentioning

confidence: 99%

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Assessment of elliptic flame front propagation characteristics of iso-octane, gasoline, M85 and E85 in an optical engine

Ihracska

Korakianitis

Ruiz

et al. 2014

Combustion and Flame

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a b s t r a c tPremixed fuel-air flame propagation is investigated in a single-cylinder, spark-ignited, four-stroke optical test engine using high-speed imaging. Circles and ellipses are fitted onto image projections of visible light emitted by the flames. The images are subsequently analysed to statistically evaluate: flame area; flame speed; centroid; perimeter; and various flame-shape descriptors. Results are presented for gasoline, isooctane, E85 and M85. The experiments were conducted at stoichiometric conditions for each fuel, at two engine speeds of 1200 rpm (rpm) and 1500 rpm, which are at 40% and 50% of rated engine speed. Furthermore, different fuel and speed sets were investigated under two compression ratios (CR: 5.00 and 8.14). Statistical tools were used to analyse the large number of data obtained, and it was found that flame speed distribution showed agreement with the normal distribution. Comparison of results assuming spherical and non-isotropic propagation of flames indicate non-isotropic flame propagation should be considered for the description of in-cylinder processes with higher accuracy. The high temporal resolution of the sequence of images allowed observation of the spark-ignition delay process. The results indicate that gasoline and isooctane have somewhat similar flame propagation behaviour. Additional differences between these fuels and E85 and M85 were also recorded and identified.

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Turbulent flame propagation and combustion in spark ignition engines

Cited by 156 publications

References 22 publications

Characterisation of flame development with ethanol, butanol, iso-octane, gasoline and methane in a direct-injection spark-ignition engine

Characterisation of flame development with ethanol, butanol, iso-octane, gasoline and methane in a direct-injection spark-ignition engine

Insights into Stoichiometric and Lean Combustion Phenomena of Gasoline–Butanol, Gasoline–Ethanol, Iso-Octane–Butanol, and Iso-Octane–Ethanol Blends in an Optical Spark-Ignition Engine

Assessment of elliptic flame front propagation characteristics of iso-octane, gasoline, M85 and E85 in an optical engine

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