A Unified Description of Flame Topologies at Different Turbulent Combustion Regimes Using Computational Singular Perturbation

Efstathios-Al. Tingas; Hong G. Im

A Unified Description of Flame Topologies at Different Turbulent Combustion Regimes Using Computational Singular Perturbation

Efstathios-Al. Tingas
, Hong G. Im

UHI Perth

Producción científica: Abstract › revisión exhaustiva

Resumen

Identifying turbulent flame topologies for unambiguous determination
of key flame quantities is a challenging task for high
Karlovitz number conditions in which different scalar variables
exhibit drastically distinct characteristics. The present study
explores a unified way to characterize the flame topologies
and its important observable quantities by the identification
of representative dynamical features using the computational
singular perturbation (CSP) technique. Various algorithmic tools
of CSP are applied on DNS datasets of turbulent premixed
hydrogen/air flames at different combustion regimes and the
results are compared with conventional flame analysis tools.

Idioma original	English
Estado	Published - may 2019
Evento	Seventeenth International Conference on Numerical Combustion - Aachen, Aachen, Germany Duración: 6 may 2019 → 8 may 2019 Número de conferencia: 17 https://nc19.itv.rwth-aachen.de/

Conference

Conference	Seventeenth International Conference on Numerical Combustion
Título abreviado	ICNC 2019
País/Territorio	Germany
Ciudad	Aachen
Período	6/05/19 → 8/05/19
Dirección de internet	https://nc19.itv.rwth-aachen.de/

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https://nc19.itv.rwth-aachen.de/

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@conference{010aa769707547cdb641661ebd20916f,

title = "A Unified Description of Flame Topologies at Different Turbulent Combustion Regimes Using Computational Singular Perturbation",

abstract = "Identifying turbulent flame topologies for unambiguous determination of key flame quantities is a challenging task for high Karlovitz number conditions in which different scalar variables exhibit drastically distinct characteristics. The present study explores a unified way to characterize the flame topologies and its important observable quantities by the identification of representative dynamical features using the computational singular perturbation (CSP) technique. Various algorithmic tools of CSP are applied on DNS datasets of turbulent premixed hydrogen/air flames at different combustion regimes and the results are compared with conventional flame analysis tools.",

author = "Efstathios-Al. Tingas and Im, \{Hong G.\}",

year = "2019",

month = may,

language = "English",

note = "Seventeenth International Conference on Numerical Combustion, ICNC 2019 ; Conference date: 06-05-2019 Through 08-05-2019",

url = "https://nc19.itv.rwth-aachen.de/",

}

TY - CONF

T1 - A Unified Description of Flame Topologies at Different Turbulent Combustion Regimes Using Computational Singular Perturbation

AU - Tingas, Efstathios-Al.

AU - Im, Hong G.

N1 - Conference code: 17

PY - 2019/5

Y1 - 2019/5

N2 - Identifying turbulent flame topologies for unambiguous determination of key flame quantities is a challenging task for high Karlovitz number conditions in which different scalar variables exhibit drastically distinct characteristics. The present study explores a unified way to characterize the flame topologies and its important observable quantities by the identification of representative dynamical features using the computational singular perturbation (CSP) technique. Various algorithmic tools of CSP are applied on DNS datasets of turbulent premixed hydrogen/air flames at different combustion regimes and the results are compared with conventional flame analysis tools.

AB - Identifying turbulent flame topologies for unambiguous determination of key flame quantities is a challenging task for high Karlovitz number conditions in which different scalar variables exhibit drastically distinct characteristics. The present study explores a unified way to characterize the flame topologies and its important observable quantities by the identification of representative dynamical features using the computational singular perturbation (CSP) technique. Various algorithmic tools of CSP are applied on DNS datasets of turbulent premixed hydrogen/air flames at different combustion regimes and the results are compared with conventional flame analysis tools.

UR - https://nc19.itv.rwth-aachen.de/

M3 - Abstract

T2 - Seventeenth International Conference on Numerical Combustion

Y2 - 6 May 2019 through 8 May 2019

ER -

A Unified Description of Flame Topologies at Different Turbulent Combustion Regimes Using Computational Singular Perturbation

Resumen

Conference

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