[article] 
inTransactions of the ASME . Journal of engineering for gas turbines and power > Vol. 133 N° 7 (Juillet 2011)

Titre :	Nonlinear multiple points gas turbine off-design performance adaptation using a genetic algorithm
Type de document :	texte imprimé
Auteurs :	Y. G. Li, Auteur ; M. F. Abdul Ghafir, Auteur ; L. Wang, Auteur
Année de publication :	2011
Note générale :	Turbines à gaz
Langues :	Anglais (eng)
Mots-clés :	Gas turbines Genetic algorithms Shafts Thermodynamics
Index. décimale :	620.1 Essais des matériaux. Défauts des matériaux. Protection des matériaux
Résumé :	Accurate gas turbine performance models are crucial in many gas turbine performance analysis and gas path diagnostic applications. With current thermodynamic performance modeling techniques, the accuracy of gas turbine performance models at off-design conditions is determined by engine component characteristic maps obtained in rig tests and these maps may not be available to gas turbine users or may not be accurate for individual engines. In this paper, a nonlinear multiple point performance adaptation approach using a genetic algorithm is introduced with the aim to improve the performance prediction accuracy of gas turbine engines at different off-design conditions by calibrating the engine performance models against available test data. Such calibration is carried out with introduced nonlinear map scaling factor functions by “modifying” initially implemented component characteristic maps in the gas turbine thermodynamic performance models. A genetic algorithm is used to search for an optimal set of nonlinear scaling factor functions for the maps via an objective function that measures the difference between the simulated and actual gas path measurements. The developed off-design performance adaptation approach has been applied to a model single spool turbo-shaft aero gas turbine engine and has demonstrated a significant improvement in the performance model accuracy at off-design operating conditions.
DEWEY :	620.1
ISSN :	0742-4795
En ligne :	http://asmedl.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=JETPEZ00013300 [...]

[article] Nonlinear multiple points gas turbine off-design performance adaptation using a genetic algorithm [texte imprimé] / Y. G. Li, Auteur ; M. F. Abdul Ghafir, Auteur ; L. Wang, Auteur . - 2011.
Turbines à gaz
Langues : Anglais (eng)
in Transactions of the ASME . Journal of engineering for gas turbines and power > Vol. 133 N° 7 (Juillet 2011)

Mots-clés :	Gas turbines Genetic algorithms Shafts Thermodynamics
Index. décimale :	620.1 Essais des matériaux. Défauts des matériaux. Protection des matériaux
Résumé :	Accurate gas turbine performance models are crucial in many gas turbine performance analysis and gas path diagnostic applications. With current thermodynamic performance modeling techniques, the accuracy of gas turbine performance models at off-design conditions is determined by engine component characteristic maps obtained in rig tests and these maps may not be available to gas turbine users or may not be accurate for individual engines. In this paper, a nonlinear multiple point performance adaptation approach using a genetic algorithm is introduced with the aim to improve the performance prediction accuracy of gas turbine engines at different off-design conditions by calibrating the engine performance models against available test data. Such calibration is carried out with introduced nonlinear map scaling factor functions by “modifying” initially implemented component characteristic maps in the gas turbine thermodynamic performance models. A genetic algorithm is used to search for an optimal set of nonlinear scaling factor functions for the maps via an objective function that measures the difference between the simulated and actual gas path measurements. The developed off-design performance adaptation approach has been applied to a model single spool turbo-shaft aero gas turbine engine and has demonstrated a significant improvement in the performance model accuracy at off-design operating conditions.
DEWEY :	620.1
ISSN :	0742-4795
En ligne :	http://asmedl.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=JETPEZ00013300 [...]