Low-temperature ignition behavior of iso-octane

Mansfield, Andrew B.; Wooldridge, Margaret S.; Di, Haisheng; He, Xin

doi:10.1016/j.fuel.2014.08.019

Cited by 51 publications

(12 citation statements)

References 18 publications

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“…Weak ignition and associated front propagation behavior at NTC conditions have recently been studied (Yoo et al, 2011;Gupta et al, 2013;Kim et al, 2014;Mansfield et al, 2015). Further work is needed in order to validate the proposed regime diagram and ignition criterion for …”

Section: The Regime Diagram and Discussionmentioning

confidence: 99%

A Regime Diagram for Autoignition of Homogeneous Reactant Mixtures with Turbulent Velocity and Temperature Fluctuations

Pal

Wooldridge

et al. 2015

Combustion Science and Technology

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Section: The Regime Diagram and Discussionmentioning

confidence: 99%

A Regime Diagram for Autoignition of Homogeneous Reactant Mixtures with Turbulent Velocity and Temperature Fluctuations

Pal

Wooldridge

et al. 2015

Combustion Science and Technology

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“…S6 of the Supplementary material. Several pressure traces at lower temperatures (i.e., longer ignition delay times) exhibited significant pre-ignition pressure rise that may be caused by inhomogeneous ignition [81,82].…”

Section: -4 Kaust Hpstmentioning

confidence: 99%

A comprehensive iso-octane combustion model with improved thermochemistry and chemical kinetics

Atef

Kukkadapu

Mohamed

et al. 2017

Combustion and Flame

174

181

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iso-Octane (2,2,4-trimethylpentane) is a primary reference fuel and an important component of gasoline fuels. Moreover, it is a key component used in surrogates to study the ignition and burning characteristics of gasoline fuels. This paper presents an updated chemical kinetic model for iso-octane combustion. Specifically, the thermodynamic data and reaction kinetics of isooctane have been reassessed based on new thermodynamic group values and recently evaluated

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“…A recent experimental study using iso-octane confirms consistent behaviour [36]. Extension of the Zel'dovich-Sankaran criterion to predict weak versus strong ignition regimes in turbulent conditions has been proposed with a scaling analysis by Im et al [22], and validation by multi-dimensional simulations is underway.…”

Section: Effects Of Local Hot Spotsmentioning

confidence: 75%

A computational study of syngas auto-ignition characteristics at high-pressure and low-temperature conditions with thermal inhomogeneities

Pal

Mansfield

Arias

et al. 2015

Combustion Theory and Modelling

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A computational study was conducted to investigate the characteristics of auto-ignition in a syngas mixture at high-pressure and low-temperature conditions in the presence of thermal inhomogeneities. Highly resolved one-dimensional numerical simulations incorporating detailed chemistry and transport were performed. The temperature inhomogeneities were represented by a global sinusoidal temperature profile and a local Gaussian temperature spike (hot spot). Reaction front speed and front Damköhler number analyses were employed to characterise the propagating ignition front. In the presence of a global temperature gradient, the ignition behaviour shifted from spontaneous propagation (strong) to deflagrative (weak), as the initial mean temperature of the reactant mixture was lowered. A predictive Zel'dovich-Sankaran criterion to determine the transition from strong to weak ignition was validated for different parametric sets. At sufficiently low temperatures, the strong ignition regime was recovered due to faster passive scalar dissipation of the imposed thermal fluctuations relative to the reaction timescale, which was quantified by the mixing Damköhler number. In the presence of local hot spots, only deflagrative fronts were observed. However, the fraction of the reactant mixture consumed by the propagating front was found to increase as the initial mean temperature was lowered, thereby leading to more enhanced compression-heating of the end-gas. Passive scalar mixing was not found to be important for the hot spot cases considered. The parametric study confirmed that the relative magnitude of the Sankaran number translates accurately to the quantitative strength of the deflagration front in the overall ignition advancement.

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Low-temperature ignition behavior of iso-octane

Cited by 51 publications

References 18 publications

A Regime Diagram for Autoignition of Homogeneous Reactant Mixtures with Turbulent Velocity and Temperature Fluctuations

A Regime Diagram for Autoignition of Homogeneous Reactant Mixtures with Turbulent Velocity and Temperature Fluctuations

A comprehensive iso-octane combustion model with improved thermochemistry and chemical kinetics

A computational study of syngas auto-ignition characteristics at high-pressure and low-temperature conditions with thermal inhomogeneities

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