Laminar burning velocities of hydrogen–air mixtures from closed vessel gas explosions

Dahoe, A.E.

doi:10.1016/j.jlp.2005.03.007

Cited by 240 publications

(87 citation statements)

References 41 publications

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“…S22-S41. 3.5. Laminar burning velocity and flame structure of H 2 mixtures Figures 7 and 8 show the laminar burning velocity of H 2 + air mixtures at 1 atm [7,8,[130][131][132][133][134][135][136][137][138][139][140][141][142][143][144][145][146] at room and elevated temperatures, respectively. It can be seen that both the current model and the previous version [6] agree well with the most recent experimental data in a wide range of equivalence ratios except very lean and very rich flames.…”

Section: Ignition Delaysmentioning

confidence: 99%

The effect of temperature on the adiabatic burning velocities of diluted hydrogen flames: A kinetic study using an updated mechanism

Алексеев

Christensen

Konnov

2015

Combustion and Flame

126

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Section: Ignition Delaysmentioning

confidence: 99%

The effect of temperature on the adiabatic burning velocities of diluted hydrogen flames: A kinetic study using an updated mechanism

Алексеев

Christensen

Konnov

2015

Combustion and Flame

126

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“…In the modified version, an empirical laminar burning velocity correlation is added so that the laminar burning velocity can be calculated as a function of the temperature, the pressure, and the unburned gas composition. The correlation is fit to data compiled by Dahoe at difference hydrogen/air ratios for the unburned gas [6], as shown by Fig. 2.…”

Section: Changes To Laminar Burning Velocitymentioning

confidence: 99%

Benchmarking of Improved DPAC Transient Deflagration Analysis Code

Laurinat

Hensel

2017

Journal of Pressure Vessel Technology

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The transient deflagration code DPAC (Deflagration Pressure Analysis Code) has been upgraded for use in modeling hydrogen deflagration transients. The upgraded code is benchmarked using data from vented hydrogen deflagration tests conducted at the HYDRO-SC Test Facility at the University of Pisa. DPAC originally was written to calculate peak deflagration pressures for deflagrations in radioactive waste storage tanks and process facilities at the Savannah River Site. Upgrades include the addition of a laminar flame speed correlation for hydrogen deflagrations and a mechanistic model for turbulent flame propagation, incorporation of inertial effects during venting, and inclusion of the effect of water vapor condensation on vessel walls. In addition, DPAC has been coupled with CEA, a NASA combustion chemistry code. The deflagration tests are modeled as end-to-end deflagrations. The improved DPAC code successfully predicts both the peak pressures during the deflagration tests and the times at which the pressure peaks.

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“…Then the laminar burning velocity increases as equivalence ratio increases until it reaches a maximum value at the stoichiometric mixture. On the rich side, the laminar burning velocity begins to decrease until it reaches a minimum value as the higher flammability limit is approached [6,9,12,30,31].…”

Section: Effect Of Equivalence Ratiomentioning

confidence: 99%

Jojoba methyl ester as a diesel fuel substitute: Preparation and characterization

Radwan

Ismail

Elfeky

et al. 2007

Applied Thermal Engineering

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Laminar burning velocities of hydrogen–air mixtures from closed vessel gas explosions

Cited by 240 publications

References 41 publications

The effect of temperature on the adiabatic burning velocities of diluted hydrogen flames: A kinetic study using an updated mechanism

The effect of temperature on the adiabatic burning velocities of diluted hydrogen flames: A kinetic study using an updated mechanism

Benchmarking of Improved DPAC Transient Deflagration Analysis Code

Jojoba methyl ester as a diesel fuel substitute: Preparation and characterization

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