A Computational Model for the Study of Gas Turbine Combustor Dynamics

D. M. Costura; P. B. Lawless; S. H. Fankel

Source: Journal of Engineering for Gas Turbines and Power:;1999:;volume( 121 ):;issue: 002::page 243

Author:

D. M. Costura

P. B. Lawless

S. H. Fankel

DOI: 10.1115/1.2817112

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: A dynamic combustor model is developed for inclusion into a one-dimensional full gas turbine engine simulation code. A flux-difference splitting algorithm is used to numerically integrate the quasi-one-dimensional Euler equations, supplemented with species mass conservation equations. The combustion model involves a single-step, global finite-rate chemistry scheme with a temperature-dependent activation energy. Source terms are used to account for mass bleed and mass injection, with additional capabilities to handle momentum and energy sources and sinks. Numerical results for cold and reacting flow for a can-type gas turbine combustor are presented. Comparisons with experimental data from this combustor are also made.

keyword(s): Dynamics (Mechanics) , Combustion chambers , Gas turbines , Equations , Chemistry , Algorithms , Momentum , Flow (Dynamics) , Temperature , Combustion AND Simulation ,

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A Computational Model for the Study of Gas Turbine Combustor Dynamics

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Journal of Engineering for Gas Turbines and Power

contributor author	D. M. Costura
contributor author	P. B. Lawless
contributor author	S. H. Fankel
date accessioned	2017-05-08T23:59:37Z
date available	2017-05-08T23:59:37Z
date copyright	April, 1999
date issued	1999
identifier issn	1528-8919
identifier other	JETPEZ-26788#243_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/122147
description abstract	A dynamic combustor model is developed for inclusion into a one-dimensional full gas turbine engine simulation code. A flux-difference splitting algorithm is used to numerically integrate the quasi-one-dimensional Euler equations, supplemented with species mass conservation equations. The combustion model involves a single-step, global finite-rate chemistry scheme with a temperature-dependent activation energy. Source terms are used to account for mass bleed and mass injection, with additional capabilities to handle momentum and energy sources and sinks. Numerical results for cold and reacting flow for a can-type gas turbine combustor are presented. Comparisons with experimental data from this combustor are also made.
publisher	The American Society of Mechanical Engineers (ASME)
title	A Computational Model for the Study of Gas Turbine Combustor Dynamics
type	Journal Paper
journal volume	121
journal issue	2
journal title	Journal of Engineering for Gas Turbines and Power
identifier doi	10.1115/1.2817112
journal fristpage	243
journal lastpage	248
identifier eissn	0742-4795
keywords	Dynamics (Mechanics)
keywords	Combustion chambers
keywords	Gas turbines
keywords	Equations
keywords	Chemistry
keywords	Algorithms
keywords	Momentum
keywords	Flow (Dynamics)
keywords	Temperature
keywords	Combustion AND Simulation
tree	Journal of Engineering for Gas Turbines and Power:;1999:;volume( 121 ):;issue: 002
contenttype	Fulltext

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