The transition-piece of a gas turbine engine is subjected to high thermal loads as it collects high temperature combustion products from the gas generator to a turbine. This generally produces high thermal stress levels in the casing of the transition piece, strongly limiting its life expectations and making it one of the most critical components of the entire engine. The reliable prediction of such thermal loads is hence a crucial aspect to increase the transition-piece life span and to assure safe operations. The present study aims to investigate the aerothermal behavior of a gas turbine engine transition-piece and in particular to evaluate working temperatures of the casing in relation to the flow and heat transfer situation inside and outside the transition-piece. Typical operating conditions are considered to determine the amount of heat transfer from the gas to the casing by means of computational fluid dynamics (CFD). Both conjugate approach and wall fixed temperature have been considered to compute the heat transfer coefficient (HTC), and more in general, the transition-piece thermal loads. Finally a discussion on the most convenient HTC expression is provided.
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June 2015
Research-Article
Thermofluid Dynamic Analysis of a Gas Turbine Transition-Piece
Riccardo Da Soghe,
e-mail: riccardo.dasoghe@ergonresearch.it
Riccardo Da Soghe
1
Ergon Research s.r.l.
,via Panciatichi 92
,Florence 50139
, Italy
e-mail: riccardo.dasoghe@ergonresearch.it
1Corresponding author.
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Cosimo Bianchini,
Cosimo Bianchini
Ergon Research s.r.l.
,via Panciatichi 92
,Florence 50139
, Italy
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Antonio Andreini,
Antonio Andreini
DIEF—Department of Industrial Engineering Florence,
University of Florence
,via di Santa Marta 3
,Firenze (FI) 50139
, Italy
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Lorenzo Mazzei,
Lorenzo Mazzei
DIEF—Department of Industrial Engineering Florence,
University of Florence
,via di Santa Marta 3
,Firenze (FI) 50139
, Italy
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Giovanni Riccio,
Giovanni Riccio
GE Oil and Gas,
University of Florence
,via Matteucci 2
,Florence 50127
, Italy
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Alessandro Marini,
Alessandro Marini
GE Oil and Gas,
University of Florence
,via Matteucci 2
,Florence 50127
, Italy
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Alessandro Ciani
Alessandro Ciani
GE Oil and Gas,
University of Florence
,via Matteucci 2
,Florence 50127
, Italy
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Riccardo Da Soghe
Ergon Research s.r.l.
,via Panciatichi 92
,Florence 50139
, Italy
e-mail: riccardo.dasoghe@ergonresearch.it
Cosimo Bianchini
Ergon Research s.r.l.
,via Panciatichi 92
,Florence 50139
, Italy
Antonio Andreini
DIEF—Department of Industrial Engineering Florence,
University of Florence
,via di Santa Marta 3
,Firenze (FI) 50139
, Italy
Lorenzo Mazzei
DIEF—Department of Industrial Engineering Florence,
University of Florence
,via di Santa Marta 3
,Firenze (FI) 50139
, Italy
Giovanni Riccio
GE Oil and Gas,
University of Florence
,via Matteucci 2
,Florence 50127
, Italy
Alessandro Marini
GE Oil and Gas,
University of Florence
,via Matteucci 2
,Florence 50127
, Italy
Alessandro Ciani
GE Oil and Gas,
University of Florence
,via Matteucci 2
,Florence 50127
, Italy
1Corresponding author.
Contributed by the Turbomachinery Committee of ASME for publication in the JOURNAL OF ENGINEERING FOR GAS TURBINES AND POWER. Manuscript received August 6, 2014; final manuscript received October 7, 2014; published online December 9, 2014. Editor: David Wisler.
J. Eng. Gas Turbines Power. Jun 2015, 137(6): 062602 (9 pages)
Published Online: June 1, 2015
Article history
Received:
August 6, 2014
Revision Received:
October 7, 2014
Online:
December 9, 2014
Citation
Da Soghe, R., Bianchini, C., Andreini, A., Mazzei, L., Riccio, G., Marini, A., and Ciani, A. (June 1, 2015). "Thermofluid Dynamic Analysis of a Gas Turbine Transition-Piece." ASME. J. Eng. Gas Turbines Power. June 2015; 137(6): 062602. https://doi.org/10.1115/1.4028869
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