Effect of CO2 Dilution on the Laminar Burning Velocities of Premixed Methane/Air Flames at Elevated Temperature

Duva, Berk Can; Chance, Lauren Elizabeth; Toulson, Elisa

doi:10.1115/1.4044641

Cited by 14 publications

(5 citation statements)

References 38 publications

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“…The chemical, or kinetic, effect occurs when there is an alteration in reaction kinetics . For instance, CO 2 participates in the reaction CO 2 + H = CO + OH according to a detailed sensitivity analysis . It competes for H radicals with the chain-branching reaction H + O 2 = O + OH and, by doing so, impedes the isooctane/air combustion.…”

Section: Resultsmentioning

confidence: 99%

“…49 For instance, CO 2 participates in the reaction CO 2 + H = CO + OH according to a detailed sensitivity analysis. 51 It competes for H radicals with the chain-branching reaction H + O 2 = O + OH and, by doing so, impedes the isooctane/air combustion. This last reaction is important as it is the dominant reaction that produces reactive radicals, which in part control the laminar flame speed.…”

Section: Resultsmentioning

confidence: 99%

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Experimental and Numerical Investigation of the CO₂ Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures

2019

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The exhaust gas recirculation effect on the laminar burning velocity (S L ) and flame stability of CO 2 -diluted isooctane/air and high/low research octane number (RON) gasoline/air mixtures was investigated by studying spherically expanding flames at a constant pressure of 1 bar and 373−473 K. Measurements were carried out in a constant volume combustion vessel. The experimental setup and methodology were validated by comparing the isooctane results with the existing literature. The results of measurements showed that flame speeds of commercial gasolines do not vary significantly with RON whereas S L values of isooctane flames are consistently slower than those of gasoline. A temperature increase of 100 K (373−473 K) yielded 51−56, 50−54, and 48−51% increases in laminar burning velocities for the high RON gasoline, low RON gasoline, and isooctane, respectively. Investigation of burned gas Markstein lengths (L b ) revealed that the flame stability of the three fuels deteriorates considerably with increasing equivalence ratio; however, the burned gas Markstein lengths were not significantly affected by the 100 K increase in initial temperature. Similar to the laminar burning velocity, the burned gas Markstein lengths of the high and low RON gasoline flames were very close, but the isooctane/air flames had slightly higher burned gas Markstein lengths. The CO 2 addition at 473 K yielded 41−46, 42−44, and 46−49% decreases in laminar burning velocities for the high RON gasoline, low RON gasoline, and isooctane, respectively, due to a combination of dilution, thermaldiffusion, and chemical effects. The chemical effect had a minor contribution of 23−25% on the decrease in the laminar burning velocity at lean and stoichiometric conditions, and its impact dropped to only 15% for rich mixtures. The addition of CO 2 also postponed the initiation of cellular formation by increasing the L b values of the three fuels. Numerical analysis was performed with the CHEMKIN software [Kee et al. PREMIX: A Fortran Program for Modeling Steady Laminar One-Dimensional Premixed Flames; Reaction Design: 1985] using the chemical mechanisms of Chaos et al. [Int.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Experimental and Numerical Investigation of the CO₂ Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures

2019

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“…For the current work, a comprehensive set of experimental data including IDT, LFS, and species profile measurements was collected. For CH 4 , 1418 shock tube IDT data from refs and − , 1278 LFS measurements from refs and − , and 200 species profile measurements from refs , , and in jet-stirred reactor (JSR) were collected. Among the experimental data, 204 IDT and 522 LFS measurements were diluted in CO 2 and hence are relevant to oxyfuel combustion.…”

Section: Experimental Datamentioning

confidence: 99%

An Optimized Methane Reaction Model for Oxyfuel Combustion

et al. 2023

Energy Fuels

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Pressurized oxyfuel combustion technology is a potential solution for reducing greenhouse gas emissions by carbon capture and storage while burning hydrocarbon fuels. Numerous experiments on CH4 ignition delay times and laminar flame propagation velocities at high pressures and CO2 atmosphere dilution have been reported, contributing to the improvement of current CH4 combustion kinetic models. However, existing mainstream models produce significantly larger prediction errors for syngas ignition delay time data, especially under oxyfuel combustion conditions. Motivated by the observation, an optimized CH4 model was developed based on a comprehensive set of experimental data, including 2205 ignition delay time, 3344 laminar flame speed, and 200 species profile measurements and balanced the predicted performance of the syngas. A novel sampling strategy was developed and embedded in the optimization algorithm to improve the computational efficiency. The optimized rate constants fall reasonably within the estimated uncertainty range. Prediction performance of the optimized model was evaluated and compared to four well-established models. The optimized model showed considerably improved results, providing a better balance between the prediction of ignition delay time and laminar flame speed data. The kinetic reasons for the improved performance were examined and discussed.

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“…Laminar burning velocity is defined as the speed of a steady, one-dimensional adiabatic laminar flame (Duva et al, 2020). It is the speed at which a flame will propagate through a homogeneous mixture of unburned reactants under adiabatic conditions.…”

Section: Natural Gas Compositionmentioning

confidence: 99%

Achieving Net-Zero CO2 Emissions from Indirect Co-combustion of Biomass and Natural Gas with Carbon Capture using a Novel Amine Blend

et al. 2023

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Effect of CO2 Dilution on the Laminar Burning Velocities of Premixed Methane/Air Flames at Elevated Temperature

Cited by 14 publications

References 38 publications

Experimental and Numerical Investigation of the CO₂ Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures

Experimental and Numerical Investigation of the CO₂ Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures

An Optimized Methane Reaction Model for Oxyfuel Combustion

Achieving Net-Zero CO2 Emissions from Indirect Co-combustion of Biomass and Natural Gas with Carbon Capture using a Novel Amine Blend

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Effect of CO2 Dilution on the Laminar Burning Velocities of Premixed Methane/Air Flames at Elevated Temperature

Cited by 14 publications

References 38 publications

Experimental and Numerical Investigation of the CO2 Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures

Experimental and Numerical Investigation of the CO2 Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures

An Optimized Methane Reaction Model for Oxyfuel Combustion

Achieving Net-Zero CO2 Emissions from Indirect Co-combustion of Biomass and Natural Gas with Carbon Capture using a Novel Amine Blend

Contact Info

Product

Resources

About

Experimental and Numerical Investigation of the CO₂ Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures

Experimental and Numerical Investigation of the CO₂ Dilution Effect on Laminar Burning Velocities and Burned Gas Markstein Lengths of High/Low RON Gasolines and Isooctane Flames at Elevated Temperatures