Simulation et aide au dimensionnement des chaudières de récupération

Heat recovery steam generators (HRSG) play a very important role in combined cycle (CC) power plants, where steam is generated from a gas turbine exhaust and supplied at the appropriate pressure and temperature to steam turbines for further power generation. The power plants achieve an overall effic...

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Bibliographic Details
Main Author: Dumont, Marie-Noelle
Other Authors: MARECHAL, F
Format: Others
Published: Universite de Liege 2007
Subjects:
Online Access:http://bictel.ulg.ac.be/ETD-db/collection/available/ULgetd-10292007-152507/
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spelling ndltd-BICfB-oai-ETDULg-ULgetd-10292007-1525072013-01-07T15:43:34Z Simulation et aide au dimensionnement des chaudières de récupération Dumont, Marie-Noelle simulation model/modele de simulation Once through boiler/chaudiere a circulation forcee Heat recovery steam generator/chaudiere de recuperation Heat recovery steam generators (HRSG) play a very important role in combined cycle (CC) power plants, where steam is generated from a gas turbine exhaust and supplied at the appropriate pressure and temperature to steam turbines for further power generation. The power plants achieve an overall efficiency above 55% and are ideally suited for combined heat and power generation in utility systems. The performance of energy conversion is improved by reducing exergy losses which implies reducing the temperature difference between the combustion gas and the steam cycle. Thus recent HRSG designs include up to three pressure levels with reheat in the steam cycle for maximum energy recovery and the use of high pressure, high temperature superheater and reheater in CC plants. Super critical boilers are also conceivable. Since HRSG performance has a large impact on the overall efficiency of the CC power plant, an accurate simulation of the performance of the HRSG is necessary. We present a steady state HRSG model to support design and rating simulations of vertical units. The simulation model, called FELVAL, divides the boiler in its rows. The row model can also be divided several times following the tube length, to better estimate the fumes temperature distribution across the hot gas path. Another model, called SUFVAL, carries out the design as well as the automatic generation of the FELVAL units and all the needed connections. The log mean temperature difference (LMTD) method and the effectiveness-NTU (ε -NTU) method are alternatively used to compute the overall heat transferred in each part of the HRSG. The problem of convergence of boiler models with more than one row in parallel is discussed. Good initialisation of the different variables is crucial to obtain convergence. The models are tested on 2 references HRSG. The first one is an assisted circulation boiler that operates at 3 subcritical pressure levels. The second is a once through boiler able to operate above the critical pressure of water. These new models were introduced into a commercial software of data reconciliation (VALI of Belsim sa) already used by the engineering and design departments of a HRSG manufacturer. They thus have a general-purpose package enabling them to make design, data reconciliation and simulation with the same software. Moreover, the use of FELVAL model will enable them to simulate any type of boiler and to obtain informations on the change of the temperatures inside the heat exchangers. This information is crucial for well monitoring closely the operation of a boiler, and better understanding its behaviour. This knowledge improvement allows to limit the overdesign and the safety margins and to reduce the investment costs. MARECHAL, F FRERE, M FRAIKIN, Ch. MATHIEU, Philippe NGENDAKUMANA, Philippe HEYEN, Georges CRINE, Michel HOGGE, Michel GERMAIN, Albert Universite de Liege 2007-09-13 text application/pdf http://bictel.ulg.ac.be/ETD-db/collection/available/ULgetd-10292007-152507/ http://bictel.ulg.ac.be/ETD-db/collection/available/ULgetd-10292007-152507/ unrestricted Je certifie avoir complété et signé le contrat BICTEL/e remis par le gestionnaire facultaire.
collection NDLTD
format Others
sources NDLTD
topic simulation model/modele de simulation
Once through boiler/chaudiere a circulation forcee
Heat recovery steam generator/chaudiere de recuperation
spellingShingle simulation model/modele de simulation
Once through boiler/chaudiere a circulation forcee
Heat recovery steam generator/chaudiere de recuperation
Dumont, Marie-Noelle
Simulation et aide au dimensionnement des chaudières de récupération
description Heat recovery steam generators (HRSG) play a very important role in combined cycle (CC) power plants, where steam is generated from a gas turbine exhaust and supplied at the appropriate pressure and temperature to steam turbines for further power generation. The power plants achieve an overall efficiency above 55% and are ideally suited for combined heat and power generation in utility systems. The performance of energy conversion is improved by reducing exergy losses which implies reducing the temperature difference between the combustion gas and the steam cycle. Thus recent HRSG designs include up to three pressure levels with reheat in the steam cycle for maximum energy recovery and the use of high pressure, high temperature superheater and reheater in CC plants. Super critical boilers are also conceivable. Since HRSG performance has a large impact on the overall efficiency of the CC power plant, an accurate simulation of the performance of the HRSG is necessary. We present a steady state HRSG model to support design and rating simulations of vertical units. The simulation model, called FELVAL, divides the boiler in its rows. The row model can also be divided several times following the tube length, to better estimate the fumes temperature distribution across the hot gas path. Another model, called SUFVAL, carries out the design as well as the automatic generation of the FELVAL units and all the needed connections. The log mean temperature difference (LMTD) method and the effectiveness-NTU (ε -NTU) method are alternatively used to compute the overall heat transferred in each part of the HRSG. The problem of convergence of boiler models with more than one row in parallel is discussed. Good initialisation of the different variables is crucial to obtain convergence. The models are tested on 2 references HRSG. The first one is an assisted circulation boiler that operates at 3 subcritical pressure levels. The second is a once through boiler able to operate above the critical pressure of water. These new models were introduced into a commercial software of data reconciliation (VALI of Belsim sa) already used by the engineering and design departments of a HRSG manufacturer. They thus have a general-purpose package enabling them to make design, data reconciliation and simulation with the same software. Moreover, the use of FELVAL model will enable them to simulate any type of boiler and to obtain informations on the change of the temperatures inside the heat exchangers. This information is crucial for well monitoring closely the operation of a boiler, and better understanding its behaviour. This knowledge improvement allows to limit the overdesign and the safety margins and to reduce the investment costs.
author2 MARECHAL, F
author_facet MARECHAL, F
Dumont, Marie-Noelle
author Dumont, Marie-Noelle
author_sort Dumont, Marie-Noelle
title Simulation et aide au dimensionnement des chaudières de récupération
title_short Simulation et aide au dimensionnement des chaudières de récupération
title_full Simulation et aide au dimensionnement des chaudières de récupération
title_fullStr Simulation et aide au dimensionnement des chaudières de récupération
title_full_unstemmed Simulation et aide au dimensionnement des chaudières de récupération
title_sort simulation et aide au dimensionnement des chaudières de récupération
publisher Universite de Liege
publishDate 2007
url http://bictel.ulg.ac.be/ETD-db/collection/available/ULgetd-10292007-152507/
work_keys_str_mv AT dumontmarienoelle simulationetaideaudimensionnementdeschaudieresderecuperation
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