LES Simulation of a Model Gas-Turbine Lean Combustor: Impact of Coherent Flow Structures on the Temperature Field and Concentration of CO and NO

Leonid M. Chikishev; Dmitriy K. Sharaborin; Aleksei S. Lobasov; Artem A. Dekterev; Roman V. Tolstoguzov; Vladimir M. Dulin; Dmitriy M. Markovich

doi:10.3390/en15124362

LES Simulation of a Model Gas-Turbine Lean Combustor: Impact of Coherent Flow Structures on the Temperature Field and Concentration of CO and NO

Leonid M. Chikishev, Dmitriy K. Sharaborin, Aleksei S. Lobasov, Artem A. Dekterev, Roman V. Tolstoguzov, Vladimir M. Dulin, Dmitriy M. Markovich

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Abstract

The present paper reports on the numerical simulation of flow dynamics in a model gas-turbine combustor by large eddy simulation in order to evaluate the effect of coherent flow structures on the local fluctuations of gas temperature and local concentrations of NO and CO. The simulations were performed for a generic swirler, based on the design by Turbomeca, for a Reynolds number of 15,000 at normal and elevated inlet temperature and pressure (up to 500 K and 3.4 atm). The simulation data were validated based on the velocity measurements by stereoscopic particle image velocimetry. In order to reveal coherent flow structures, the velocity snapshots were processed by the proper orthogonal method. The temporal coefficients of the decomposition were used to evaluate the conditional sampled spatial distributions of the temperature and species concentration. It is shown that the coherent fluctuations of temperature can locally reach up to 200 K with the fluctuations of NO up to 20%. Thus, the results demonstrate that coherent flow structures in a lean swirl combustor can sufficiently contribute to NOx emission.

Original language	English
Article number	4362
Journal	Energies
Volume	15
Issue number	12
DOIs	https://doi.org/10.3390/en15124362
Publication status	Published - 1 Jun 2022

Keywords

elevated pressure
gas-turbine combustor
large eddy simulation
lean methane flame
NOx emission
particle image velocimetry
proper orthogonal decomposition

OECD FOS+WOS

2.07 ENVIRONMENTAL ENGINEERING
1.07 OTHER NATURAL SCIENCES
2.02 ELECTRICAL ENG, ELECTRONIC ENG

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10.3390/en15124362

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@article{2e0cd93bef97476eb678c7df4e589295,

title = "LES Simulation of a Model Gas-Turbine Lean Combustor: Impact of Coherent Flow Structures on the Temperature Field and Concentration of CO and NO",

abstract = "The present paper reports on the numerical simulation of flow dynamics in a model gas-turbine combustor by large eddy simulation in order to evaluate the effect of coherent flow structures on the local fluctuations of gas temperature and local concentrations of NO and CO. The simulations were performed for a generic swirler, based on the design by Turbomeca, for a Reynolds number of 15,000 at normal and elevated inlet temperature and pressure (up to 500 K and 3.4 atm). The simulation data were validated based on the velocity measurements by stereoscopic particle image velocimetry. In order to reveal coherent flow structures, the velocity snapshots were processed by the proper orthogonal method. The temporal coefficients of the decomposition were used to evaluate the conditional sampled spatial distributions of the temperature and species concentration. It is shown that the coherent fluctuations of temperature can locally reach up to 200 K with the fluctuations of NO up to 20%. Thus, the results demonstrate that coherent flow structures in a lean swirl combustor can sufficiently contribute to NOx emission.",

keywords = "elevated pressure, gas-turbine combustor, large eddy simulation, lean methane flame, NOx emission, particle image velocimetry, proper orthogonal decomposition",

author = "Chikishev, {Leonid M.} and Sharaborin, {Dmitriy K.} and Lobasov, {Aleksei S.} and Dekterev, {Artem A.} and Tolstoguzov, {Roman V.} and Dulin, {Vladimir M.} and Markovich, {Dmitriy M.}",

note = "Funding Information: Funding: Research was supported by the Ministry of Science and Higher Education of Russia, agreement No. 075-15-2020-806. Publisher Copyright: {\textcopyright} 2022 by the authors. Licensee MDPI, Basel, Switzerland.",

year = "2022",

month = jun,

day = "1",

doi = "10.3390/en15124362",

language = "English",

volume = "15",

journal = "Energies",

issn = "1996-1073",

publisher = "MDPI AG",

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TY - JOUR

T1 - LES Simulation of a Model Gas-Turbine Lean Combustor: Impact of Coherent Flow Structures on the Temperature Field and Concentration of CO and NO

AU - Chikishev, Leonid M.

AU - Sharaborin, Dmitriy K.

AU - Lobasov, Aleksei S.

AU - Dekterev, Artem A.

AU - Tolstoguzov, Roman V.

AU - Dulin, Vladimir M.

AU - Markovich, Dmitriy M.

N1 - Funding Information: Funding: Research was supported by the Ministry of Science and Higher Education of Russia, agreement No. 075-15-2020-806. Publisher Copyright: © 2022 by the authors. Licensee MDPI, Basel, Switzerland.

PY - 2022/6/1

Y1 - 2022/6/1

N2 - The present paper reports on the numerical simulation of flow dynamics in a model gas-turbine combustor by large eddy simulation in order to evaluate the effect of coherent flow structures on the local fluctuations of gas temperature and local concentrations of NO and CO. The simulations were performed for a generic swirler, based on the design by Turbomeca, for a Reynolds number of 15,000 at normal and elevated inlet temperature and pressure (up to 500 K and 3.4 atm). The simulation data were validated based on the velocity measurements by stereoscopic particle image velocimetry. In order to reveal coherent flow structures, the velocity snapshots were processed by the proper orthogonal method. The temporal coefficients of the decomposition were used to evaluate the conditional sampled spatial distributions of the temperature and species concentration. It is shown that the coherent fluctuations of temperature can locally reach up to 200 K with the fluctuations of NO up to 20%. Thus, the results demonstrate that coherent flow structures in a lean swirl combustor can sufficiently contribute to NOx emission.

AB - The present paper reports on the numerical simulation of flow dynamics in a model gas-turbine combustor by large eddy simulation in order to evaluate the effect of coherent flow structures on the local fluctuations of gas temperature and local concentrations of NO and CO. The simulations were performed for a generic swirler, based on the design by Turbomeca, for a Reynolds number of 15,000 at normal and elevated inlet temperature and pressure (up to 500 K and 3.4 atm). The simulation data were validated based on the velocity measurements by stereoscopic particle image velocimetry. In order to reveal coherent flow structures, the velocity snapshots were processed by the proper orthogonal method. The temporal coefficients of the decomposition were used to evaluate the conditional sampled spatial distributions of the temperature and species concentration. It is shown that the coherent fluctuations of temperature can locally reach up to 200 K with the fluctuations of NO up to 20%. Thus, the results demonstrate that coherent flow structures in a lean swirl combustor can sufficiently contribute to NOx emission.

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KW - gas-turbine combustor

KW - large eddy simulation

KW - lean methane flame

KW - NOx emission

KW - particle image velocimetry

KW - proper orthogonal decomposition

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LES Simulation of a Model Gas-Turbine Lean Combustor: Impact of Coherent Flow Structures on the Temperature Field and Concentration of CO and NO

Abstract

Keywords

OECD FOS+WOS

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