An experimental and detailed chemical kinetic modeling study of hydrogen and syngas mixture oxidation at elevated pressures

An experimental and detailed chemical kinetic modeling study of hydrogen and syngas mixture oxidation at elevated pressures

The oxidation of syngas mixtures was investigated experimentally and simulated with an updated chemical kinetic model. Ignition delay times for H2/CO/O2/N2/Ar mixtures have been measured using two rapid compression machines and shock tubes at pressures from 1 to 70bar, over a temperature range of 91...

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Veröffentlicht in:Combustion and flame 2013-06, Vol.160 (6), p.995-1011
Hauptverfasser: Kéromnès, Alan, Metcalfe, Wayne K., Heufer, Karl A., Donohoe, Nicola, Das, Apurba K., Sung, Chih-Jen, Herzler, Jürgen, Naumann, Clemens, Griebel, Peter, Mathieu, Olivier, Krejci, Michael C., Petersen, Eric L., Pitz, William J., Curran, Henry J.
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30 DIRECT ENERGY CONVERSION
Applied sciences
Carbon monoxide
Combustion. Flame
Delay
Elevated
Energy
Energy. Thermal use of fuels
Engineering Sciences
Equivalence ratio
Exact sciences and technology
Flame speed
Hydrogen
Ignition
Ignition delay times
INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY
Kinetic mechanism
Miscellaneous
Rate constants
Reaction kinetics
Syngas
Theoretical studies. Data and constants. Metering
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container_end_page 1011
container_issue 6
container_start_page 995
container_title Combustion and flame
container_volume 160
creator Kéromnès, Alan
Metcalfe, Wayne K.
Heufer, Karl A.
Donohoe, Nicola
Das, Apurba K.
Sung, Chih-Jen
Herzler, Jürgen
Naumann, Clemens
Griebel, Peter
Mathieu, Olivier
Krejci, Michael C.
Petersen, Eric L.
Pitz, William J.
Curran, Henry J.
description The oxidation of syngas mixtures was investigated experimentally and simulated with an updated chemical kinetic model. Ignition delay times for H2/CO/O2/N2/Ar mixtures have been measured using two rapid compression machines and shock tubes at pressures from 1 to 70bar, over a temperature range of 914–2220K and at equivalence ratios from 0.1 to 4.0. Results show a strong dependence of ignition times on temperature and pressure at the end of the compression; ignition delays decrease with increasing temperature, pressure, and equivalence ratio. The reactivity of the syngas mixtures was found to be governed by hydrogen chemistry for CO concentrations lower than 50% in the fuel mixture. For higher CO concentrations, an inhibiting effect of CO was observed. Flame speeds were measured in helium for syngas mixtures with a high CO content and at elevated pressures of 5 and 10atm using the spherically expanding flame method. A detailed chemical kinetic mechanism for hydrogen and H2/CO (syngas) mixtures has been updated, rate constants have been adjusted to reflect new experimental information obtained at high pressures and new rate constant values recently published in the literature. Experimental results for ignition delay times and flame speeds have been compared with predictions using our newly revised chemical kinetic mechanism, and good agreement was observed. In the mechanism validation, particular emphasis is placed on predicting experimental data at high pressures (up to 70bar) and intermediate- to high-temperature conditions, particularly important for applications in internal combustion engines and gas turbines. The reaction sequence H2+HO˙2↔H˙+H2O2 followed by H2O2(+M)↔O˙H+O˙H(+M) was found to play a key role in hydrogen ignition under high-pressure and intermediate-temperature conditions. The rate constant for H2+HO˙2 showed strong sensitivity to high-pressure ignition times and has considerable uncertainty, based on literature values. A rate constant for this reaction is recommended based on available literature values and on our mechanism validation.
doi_str_mv 10.1016/j.combustflame.2013.01.001
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A detailed chemical kinetic mechanism for hydrogen and H2/CO (syngas) mixtures has been updated, rate constants have been adjusted to reflect new experimental information obtained at high pressures and new rate constant values recently published in the literature. Experimental results for ignition delay times and flame speeds have been compared with predictions using our newly revised chemical kinetic mechanism, and good agreement was observed. In the mechanism validation, particular emphasis is placed on predicting experimental data at high pressures (up to 70bar) and intermediate- to high-temperature conditions, particularly important for applications in internal combustion engines and gas turbines. The reaction sequence H2+HO˙2↔H˙+H2O2 followed by H2O2(+M)↔O˙H+O˙H(+M) was found to play a key role in hydrogen ignition under high-pressure and intermediate-temperature conditions. 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Thermal use of fuels</subject><subject>Engineering Sciences</subject><subject>Equivalence ratio</subject><subject>Exact sciences and technology</subject><subject>Flame speed</subject><subject>Hydrogen</subject><subject>Ignition</subject><subject>Ignition delay times</subject><subject>INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY</subject><subject>Kinetic mechanism</subject><subject>Miscellaneous</subject><subject>Rate constants</subject><subject>Reaction kinetics</subject><subject>Syngas</subject><subject>Theoretical studies. Data and constants. 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Ignition delay times for H2/CO/O2/N2/Ar mixtures have been measured using two rapid compression machines and shock tubes at pressures from 1 to 70bar, over a temperature range of 914–2220K and at equivalence ratios from 0.1 to 4.0. Results show a strong dependence of ignition times on temperature and pressure at the end of the compression; ignition delays decrease with increasing temperature, pressure, and equivalence ratio. The reactivity of the syngas mixtures was found to be governed by hydrogen chemistry for CO concentrations lower than 50% in the fuel mixture. For higher CO concentrations, an inhibiting effect of CO was observed. Flame speeds were measured in helium for syngas mixtures with a high CO content and at elevated pressures of 5 and 10atm using the spherically expanding flame method. A detailed chemical kinetic mechanism for hydrogen and H2/CO (syngas) mixtures has been updated, rate constants have been adjusted to reflect new experimental information obtained at high pressures and new rate constant values recently published in the literature. Experimental results for ignition delay times and flame speeds have been compared with predictions using our newly revised chemical kinetic mechanism, and good agreement was observed. In the mechanism validation, particular emphasis is placed on predicting experimental data at high pressures (up to 70bar) and intermediate- to high-temperature conditions, particularly important for applications in internal combustion engines and gas turbines. The reaction sequence H2+HO˙2↔H˙+H2O2 followed by H2O2(+M)↔O˙H+O˙H(+M) was found to play a key role in hydrogen ignition under high-pressure and intermediate-temperature conditions. The rate constant for H2+HO˙2 showed strong sensitivity to high-pressure ignition times and has considerable uncertainty, based on literature values. A rate constant for this reaction is recommended based on available literature values and on our mechanism validation.</abstract><cop>Amsterdam</cop><pub>Elsevier Inc</pub><doi>10.1016/j.combustflame.2013.01.001</doi><tpages>17</tpages><orcidid>https://orcid.org/0000-0002-5457-0223</orcidid><orcidid>https://orcid.org/0000-0003-2046-8076</orcidid><oa>free_for_read</oa></addata></record>
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source Elsevier ScienceDirect Journals
subjects 30 DIRECT ENERGY CONVERSION
Applied sciences
Carbon monoxide
Combustion. Flame
Delay
Elevated
Energy
Energy. Thermal use of fuels
Engineering Sciences
Equivalence ratio
Exact sciences and technology
Flame speed
Hydrogen
Ignition
Ignition delay times
INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY
Kinetic mechanism
Miscellaneous
Rate constants
Reaction kinetics
Syngas
Theoretical studies. Data and constants. Metering
title An experimental and detailed chemical kinetic modeling study of hydrogen and syngas mixture oxidation at elevated pressures
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