Simulation of multi fluid gas turbines
This work focuses on two main subjects: first, the development and validation of a robust generic performance code for industrial gas turbines (GTSI) and, second, the study of an innovative carbon dioxide/argon semi-closed cycle burning low calorific gas coming from coal gasification. GTSI will be a...
Main Author: | |
---|---|
Other Authors: | |
Language: | en |
Published: |
Cranfield University
2009
|
Online Access: | http://hdl.handle.net/1826/3537 |
id |
ndltd-CRANFIELD1-oai-dspace.lib.cranfield.ac.uk-1826-3537 |
---|---|
record_format |
oai_dc |
spelling |
ndltd-CRANFIELD1-oai-dspace.lib.cranfield.ac.uk-1826-35372013-04-19T15:25:18ZSimulation of multi fluid gas turbinesUlizar Alvarez., J. I.This work focuses on two main subjects: first, the development and validation of a robust generic performance code for industrial gas turbines (GTSI) and, second, the study of an innovative carbon dioxide/argon semi-closed cycle burning low calorific gas coming from coal gasification. GTSI will be able to simulate open, closed and semi-closed cycles at design and off-design conditions. A comprehensive thermodynamic study of the properties of the most common working fluids has been carried out, introducing the results in GTSI for a wide range of temperatures and pressures, being easy to add other gases. To make the code very general, in addition to gas turbines conventional components, such as inlet, compressor,, intercooler, regenerator, combustor, turbine and exhaust system, GTSI can model evaporative intercooler, steam injection and reheat. The possibility of variable geometry was introduced in the compressor, steam injector and turbine modules. Given the high temperatures in modem and future turbines, a detailed cooling system modeling has been developed, being able to predict cooling flow requirements according to different technology levels. The control of the complete power plant has also been considered in detail, allowing the user to select among different options. The code incorporates a simple steam turbine bottoming cycle for a preliminary analysis of the combined cycle arrangement. In addition to the conventional off-design simulations it is possible to carry out studies involving engine deterioration and modification, or substitution, of components. A validation process was carried out using different gas turbine arrangements. The result has been satisfactory, although additional configurations should be examined when more data is available. As a direct application of GTSI, the conceptual design of the carbon dioxide/argon semi-closed cycle was conducted. Several key performance factors were considered in this study, such as the working fluid composition, the gas turbine arrangement and the cooling technology. Other main parameters were selected according to the state-of-the-art technology. Advanced concepts such as cryogenic precooling and turbine stator internal cooling, together with improved component efficiencies and higher temperatures were contemplated for a mid-long term future design. The results obtained for the conventional cycles have not been very promising, with slightly better values for the advanced cycles. Five of the most interesting cycles were selected for off-design studies, evaluating the part-power behaviour, the variable geometry requirement, etc. To complete the investigation, the starting sequence of one of them was performed. Also, considering the possibility of using existing turbomachinery, designed for air, in a semi-closed cycle pilot plant, the operation of several gas turbine configurations was analysed.Cranfield UniversityPilidis, Pericles2009-08-04T11:23:12Z2009-08-04T11:23:12Z1998-01Thesis or dissertationDoctoralPhDhttp://hdl.handle.net/1826/3537en |
collection |
NDLTD |
language |
en |
sources |
NDLTD |
description |
This work focuses on two main subjects: first, the development and validation
of a robust generic performance code for industrial gas turbines (GTSI) and, second,
the study of an innovative carbon dioxide/argon semi-closed cycle burning low
calorific gas coming from coal gasification. GTSI will be able to simulate open,
closed and semi-closed cycles at design and off-design conditions.
A comprehensive thermodynamic study of the properties of the most common
working fluids has been carried out, introducing the results in GTSI for a wide range
of temperatures and pressures, being easy to add other gases.
To make the code very general, in addition to gas turbines conventional
components, such as inlet, compressor,, intercooler, regenerator, combustor, turbine
and exhaust system, GTSI can model evaporative intercooler, steam injection and
reheat. The possibility of variable geometry was introduced in the compressor, steam
injector and turbine modules. Given the high temperatures in modem and future
turbines, a detailed cooling system modeling has been developed, being able to
predict cooling flow requirements according to different technology levels. The
control of the complete power plant has also been considered in detail, allowing the
user to select among different options. The code incorporates a simple steam turbine
bottoming cycle for a preliminary analysis of the combined cycle arrangement. In
addition to the conventional off-design simulations it is possible to carry out studies
involving engine deterioration and modification, or substitution, of components.
A validation process was carried out using different gas turbine arrangements.
The result has been satisfactory, although additional configurations should be
examined when more data is available.
As a direct application of GTSI, the conceptual design of the carbon
dioxide/argon semi-closed cycle was conducted. Several key performance factors
were considered in this study, such as the working fluid composition, the gas turbine
arrangement and the cooling technology. Other main parameters were selected
according to the state-of-the-art technology. Advanced concepts such as cryogenic
precooling and turbine stator internal cooling, together with improved component
efficiencies and higher temperatures were contemplated for a mid-long term future
design. The results obtained for the conventional cycles have not been very
promising, with slightly better values for the advanced cycles. Five of the most
interesting cycles were selected for off-design studies, evaluating the part-power
behaviour, the variable geometry requirement, etc. To complete the investigation, the
starting sequence of one of them was performed. Also, considering the possibility of
using existing turbomachinery, designed for air, in a semi-closed cycle pilot plant, the
operation of several gas turbine configurations was analysed. |
author2 |
Pilidis, Pericles |
author_facet |
Pilidis, Pericles Ulizar Alvarez., J. I. |
author |
Ulizar Alvarez., J. I. |
spellingShingle |
Ulizar Alvarez., J. I. Simulation of multi fluid gas turbines |
author_sort |
Ulizar Alvarez., J. I. |
title |
Simulation of multi fluid gas turbines |
title_short |
Simulation of multi fluid gas turbines |
title_full |
Simulation of multi fluid gas turbines |
title_fullStr |
Simulation of multi fluid gas turbines |
title_full_unstemmed |
Simulation of multi fluid gas turbines |
title_sort |
simulation of multi fluid gas turbines |
publisher |
Cranfield University |
publishDate |
2009 |
url |
http://hdl.handle.net/1826/3537 |
work_keys_str_mv |
AT ulizaralvarezji simulationofmultifluidgasturbines |
_version_ |
1716581414481166336 |