Prediction of mean radical concentrations in lean hydrogen-air turbulent flames at different Karlovitz numbers adopting a newly extended flamelet-based presumed PDF

Prediction of mean radical concentrations in lean hydrogen-air turbulent flames at different Karlovitz numbers adopting a newly extended flamelet-based presumed PDF

A recent analysis (Lipatnikov et al., 2020) of complex-chemistry direct numerical simulation (DNS) data obtained from lean hydrogen-air flames associated with corrugated-flame (case A), thin-reaction-zone (case B), and broken-reaction-zone (case C) regimes of turbulent burning has shown that the fla...

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Veröffentlicht in:Combustion and flame 2021-04, Vol.226, p.248-259
Hauptverfasser: Lipatnikov, A.N., Sabelnikov, V.A., Hernández-Pérez, F.E., Song, W., Im, Hong G.
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Sprache:eng
Schlagworte:
Aerodynamics
Combustion
Complex chemistry
Computational fluid dynamics
Direct numerical simulation
DNS
Engineering Sciences
Fluid flow
Mathematical models
Modeling
Physics
Premixed turbulent combustion
Presumed PDF
Probability density functions
Radical concentrations
Turbulent flames
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container_start_page 248
container_title Combustion and flame
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creator Lipatnikov, A.N.
Sabelnikov, V.A.
Hernández-Pérez, F.E.
Song, W.
Im, Hong G.
description A recent analysis (Lipatnikov et al., 2020) of complex-chemistry direct numerical simulation (DNS) data obtained from lean hydrogen-air flames associated with corrugated-flame (case A), thin-reaction-zone (case B), and broken-reaction-zone (case C) regimes of turbulent burning has shown that the flamelet concept (i) can predict mean concentrations of various species in those flames if the probability density function (PDF) for the fuel-based combustion progress variable c is extracted from the DNS data, but (ii) poorly performs for the mean rate W¯c of product creation. These results suggest applying the concept to evaluation of mean species concentration (but not the mean rate) in combination with another closure relation for W¯c whose predictive capabilities are better. This proposal is developed in the present paper whose focus is placed on studying a new flamelet-based presumed PDF P(c) for predictions of mean concentration of radicals in engineering computational fluid dynamics (CFD) applications. Analysis of the DNS data shows that (i) the flamelet PDF performs well at intermediate values of c in cases A and B, but should be truncated at small and large c, (ii) modeling P(c) in the radical recombination zone (i.e., at large c) is of importance for predicting mean concentrations of H,O, and OH. Accordingly, the flamelet PDF is truncated and combined with a uniform P(c) at large c. Moreover, the mean rate W¯c extracted from the DNS data is used to calibrate the PDF (the rate is considered to be given by another model). Assessment of the approach against the DNS data shows that it well predicts mean density, temperature, and concentrations of reactants, product, and the aforementioned radicals in cases A and B. In case C, the approach performs worse for OandOH at large c¯ and moderately underestimates the mean concentration of H in the entire flame brush.
doi_str_mv 10.1016/j.combustflame.2020.12.009
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These results suggest applying the concept to evaluation of mean species concentration (but not the mean rate) in combination with another closure relation for W¯c whose predictive capabilities are better. This proposal is developed in the present paper whose focus is placed on studying a new flamelet-based presumed PDF P(c) for predictions of mean concentration of radicals in engineering computational fluid dynamics (CFD) applications. Analysis of the DNS data shows that (i) the flamelet PDF performs well at intermediate values of c in cases A and B, but should be truncated at small and large c, (ii) modeling P(c) in the radical recombination zone (i.e., at large c) is of importance for predicting mean concentrations of H,O, and OH. Accordingly, the flamelet PDF is truncated and combined with a uniform P(c) at large c. Moreover, the mean rate W¯c extracted from the DNS data is used to calibrate the PDF (the rate is considered to be given by another model). Assessment of the approach against the DNS data shows that it well predicts mean density, temperature, and concentrations of reactants, product, and the aforementioned radicals in cases A and B. 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These results suggest applying the concept to evaluation of mean species concentration (but not the mean rate) in combination with another closure relation for W¯c whose predictive capabilities are better. This proposal is developed in the present paper whose focus is placed on studying a new flamelet-based presumed PDF P(c) for predictions of mean concentration of radicals in engineering computational fluid dynamics (CFD) applications. Analysis of the DNS data shows that (i) the flamelet PDF performs well at intermediate values of c in cases A and B, but should be truncated at small and large c, (ii) modeling P(c) in the radical recombination zone (i.e., at large c) is of importance for predicting mean concentrations of H,O, and OH. Accordingly, the flamelet PDF is truncated and combined with a uniform P(c) at large c. Moreover, the mean rate W¯c extracted from the DNS data is used to calibrate the PDF (the rate is considered to be given by another model). Assessment of the approach against the DNS data shows that it well predicts mean density, temperature, and concentrations of reactants, product, and the aforementioned radicals in cases A and B. In case C, the approach performs worse for OandOH at large c¯ and moderately underestimates the mean concentration of H in the entire flame brush.</description><subject>Aerodynamics</subject><subject>Combustion</subject><subject>Complex chemistry</subject><subject>Computational fluid dynamics</subject><subject>Direct numerical simulation</subject><subject>DNS</subject><subject>Engineering Sciences</subject><subject>Fluid flow</subject><subject>Mathematical models</subject><subject>Modeling</subject><subject>Physics</subject><subject>Premixed turbulent combustion</subject><subject>Presumed PDF</subject><subject>Probability density functions</subject><subject>Radical concentrations</subject><subject>Turbulent flames</subject><issn>0010-2180</issn><issn>1556-2921</issn><issn>1556-2921</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2021</creationdate><recordtype>article</recordtype><recordid>eNqNUsmO1DAQjRBINAP_YMGJQ3q8xEma22gWZkRLjAScLS_labcSu7GdHprv4UNxCEJw42RXvUVV9quq1wSvCSbt-X6tw6imlO0gR1hTTAtA1xhvnlQrwnlb0w0lT6sVxgTXlPT4efUipT3GuGsYW1U_7iMYp7MLHgWLRpAeRVk6ckA6eA0-RzmjCTmPhhnenUwMD-Br6SLKU1TTUFjo1wQJyYyMsxbi3Psg4xCOLn9HfhoVxAKbcMjOPyCJPDwOJwTfMngDZtEPkGslUykPEdI0lsv91c3L6pmVQ4JXv8-z6svN9efL23r78f3d5cW21pw0uW45WDCAZbcBCZoxBqAtpRYzjK1khOONUh3upNUWrOWM9Npw3JIGMCvlWfVp8U2PcJiUOEQ3yngSQTpRxgEZ9U7onRzGsopIIHSn2qbtQHCurGiMbcQGNBHMWqKogr4sVlzfLq5F-I_l7cVWzD3MeM97wo6kcN8s3EMMXydIWezDFH1ZWlBOaUObtp9Z7xaWjiGlCPaPLcFizoXYi79zIeZcCEJFyUURXy1iKC95dBBF0g7KTxsXQWdhgvsfm5_Ej82V</recordid><startdate>20210401</startdate><enddate>20210401</enddate><creator>Lipatnikov, A.N.</creator><creator>Sabelnikov, V.A.</creator><creator>Hernández-Pérez, F.E.</creator><creator>Song, W.</creator><creator>Im, Hong G.</creator><general>Elsevier Inc</general><general>Elsevier BV</general><general>Elsevier</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TB</scope><scope>8FD</scope><scope>FR3</scope><scope>H8D</scope><scope>L7M</scope><scope>1XC</scope><scope>VOOES</scope><scope>ADTPV</scope><scope>AOWAS</scope><scope>F1S</scope><orcidid>https://orcid.org/0000-0001-5682-4947</orcidid></search><sort><creationdate>20210401</creationdate><title>Prediction of mean radical concentrations in lean hydrogen-air turbulent flames at different Karlovitz numbers adopting a newly extended flamelet-based presumed PDF</title><author>Lipatnikov, A.N. ; 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These results suggest applying the concept to evaluation of mean species concentration (but not the mean rate) in combination with another closure relation for W¯c whose predictive capabilities are better. This proposal is developed in the present paper whose focus is placed on studying a new flamelet-based presumed PDF P(c) for predictions of mean concentration of radicals in engineering computational fluid dynamics (CFD) applications. Analysis of the DNS data shows that (i) the flamelet PDF performs well at intermediate values of c in cases A and B, but should be truncated at small and large c, (ii) modeling P(c) in the radical recombination zone (i.e., at large c) is of importance for predicting mean concentrations of H,O, and OH. Accordingly, the flamelet PDF is truncated and combined with a uniform P(c) at large c. Moreover, the mean rate W¯c extracted from the DNS data is used to calibrate the PDF (the rate is considered to be given by another model). Assessment of the approach against the DNS data shows that it well predicts mean density, temperature, and concentrations of reactants, product, and the aforementioned radicals in cases A and B. In case C, the approach performs worse for OandOH at large c¯ and moderately underestimates the mean concentration of H in the entire flame brush.</abstract><cop>New York</cop><pub>Elsevier Inc</pub><doi>10.1016/j.combustflame.2020.12.009</doi><tpages>12</tpages><orcidid>https://orcid.org/0000-0001-5682-4947</orcidid><oa>free_for_read</oa></addata></record>
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subjects Aerodynamics
Combustion
Complex chemistry
Computational fluid dynamics
Direct numerical simulation
DNS
Engineering Sciences
Fluid flow
Mathematical models
Modeling
Physics
Premixed turbulent combustion
Presumed PDF
Probability density functions
Radical concentrations
Turbulent flames
title Prediction of mean radical concentrations in lean hydrogen-air turbulent flames at different Karlovitz numbers adopting a newly extended flamelet-based presumed PDF
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