Design, Simulation and Control of a 100 MW-Class Solid Oxide Fuel Cell Gas Turbine Hybrid System

A 100 MW-class planar solid oxide fuel cell, synchronous gas turbine hybrid system has been designed, modeled and controlled. The system is built of 70 functional fuel cell modules each containing 10 fuel cell stacks, a blower to recirculate depleted cathode air, a depleted fuel oxidizer and a cathode inlet air recuperator with bypass. The recuperator bypass serves to control the cathode inlet air temperature while the variable speed cathode blower recirculates air to control the cathode air inlet temperature. This allows for excellent fuel cell thermal management without independent control of the gas turbine, which at this scale will most likely be a synchronous generator. In concept the demonstrated modular design makes it possible to vary the number of cells controlled by each fuel valve, power electronics module, and recirculation blower, so that actuators can adjust to variations in the hundreds of thousands of fuel cells contained within the 100 megawatt hybrid system for improved control and reliability. In addition, the modular design makes it possible to take individual fuel cell modules offline for maintenance while the overall system continues to operate. Parametric steady state design analyses conducted on the system reveal that the overall fuel-to-electricity conversion efficiency of the current system increases with increased cathode exhaust recirculation. To evaluate and demonstrate the conceptualized design, the fully integrated system was modeled dynamically in Matlab–Simulink®. Simple proportional feedback with steady state feed-forward controls for power tracking, thermal management, and stable gas turbine operation were developed for the system. Simulations of the fully controlled system indicate that the system has a high efficiency over a large range of operating conditions, decent transient load following capability, fuel and ambient temperature disturbance rejection as well as the capability to operate with a varying number of fuel cell modules. The efforts here build upon prior work and combine the efforts of system design, system operation, component performance characterization and control to demonstrate hybrid transient capability in large-scale coal synthesis gas-based applications through simulation. Furthermore, the use of a modular fuel cell system design, the use of blower recirculation, and the need for integrated system controls are verified.Copyright © 2008 by ASME

[1]  Alberto Traverso,et al.  Control System for Solid Oxide Fuel Cell Hybrid Systems , 2005 .

[2]  J. P. Strakey,et al.  U.S. DOE fossil energy fuel cells program , 2006 .

[3]  Rory A. Roberts,et al.  Dynamic Simulation of Carbonate Fuel Cell-Gas Turbine Hybrid Systems , 2004 .

[4]  G. S. Samuelsen,et al.  Power and temperature control of fluctuating biomass gas fueled solid oxide fuel cell and micro gas turbine hybrid system , 2006 .

[5]  J. P. Strakey,et al.  The U.S. Department of Energy, Office of Fossil Energy Stationary Fuel Cell Program , 2005 .

[6]  Jack Brouwer,et al.  Dynamic simulation of carbonate fuel cell-gas turbine hybrid systems , 2006 .

[7]  Mark C. Williams,et al.  U.S. distributed generation fuel cell program , 2004 .

[8]  Loredana Magistri,et al.  Ejector performance influence on a solid oxide fuel cell anodic recirculation system , 2004 .

[9]  Ashok Rao,et al.  Sensitivity analysis of a Vision 21 coal based zero emission power plant , 2006 .

[10]  Fabian Mueller,et al.  On control concepts to prevent fuel starvation in solid oxide fuel cells , 2008 .

[11]  Rory A. Roberts,et al.  Control Design for a Bottoming Solid Oxide Fuel Cell Gas Turbine Hybrid System , 2006 .

[12]  V. Antonucci,et al.  Micro-modelling of solid oxide fuel cell electrodes , 1998 .

[13]  Jack Brouwer,et al.  Control design of an atmospheric solid oxide fuel cell/gas turbine hybrid system: Variable versus fixed speed gas turbine operation , 2006 .

[14]  Y. Tian,et al.  Modelling for part-load operation of solid oxide fuel cell–gas turbine hybrid power plant , 2003 .

[15]  Fabian Mueller,et al.  Dynamic Simulation of an Integrated Solid Oxide Fuel Cell System Including Current-Based Fuel Flow Control , 2005 .

[16]  Rory A. Roberts,et al.  Dynamic Simulation of a Pressurized 220kW Solid Oxide Fuel-Cell–Gas-Turbine Hybrid System: Modeled Performance Compared to Measured Results , 2006 .

[17]  Jack Brouwer,et al.  Dynamic Simulation of a Stationary PEM Fuel Cell System , 2006 .

[18]  Fabian Mueller,et al.  Linear Quadratic Regulator for a Bottoming Solid Oxide Fuel Cell Gas Turbine Hybrid System , 2009 .

[19]  Y. Inui,et al.  Analytical investigation on cell temperature control method of planar solid oxide fuel cell , 2006 .

[20]  A. Nakajo,et al.  Modeling of thermal stresses and probability of survival of tubular SOFC , 2006 .

[21]  Jack Brouwer,et al.  Quasi-three dimensional dynamic model of a proton exchange membrane fuel cell for system and controls development , 2007 .

[22]  Miriam Kemm,et al.  Steady state and transient thermal stress analysis in planar solid oxide fuel cells , 2005 .

[23]  G. S. Samuelsen,et al.  A thermodynamic analysis of tubular solid oxide fuel cell based hybrid systems , 2003 .

[24]  Norman F. Bessette,et al.  Modeling and simulation for solid oxide fuel cell power system , 1994 .

[25]  F. Jurado,et al.  Adaptive control of a fuel cell-microturbine hybrid power plant , 2002, IEEE Power Engineering Society Summer Meeting,.

[26]  David Tucker,et al.  Characterization of Air Flow Management and Control in a Fuel Cell Turbine Hybrid Power System Using Hardware Simulation , 2005 .

[27]  S. Bhattacharya,et al.  Combination of thermochemical recuperative coal gasification cycle and fuel cell for power generation , 2005 .

[28]  J. P. Strakey,et al.  Solid oxide fuel cell technology development in the U.S. , 2006 .

[29]  Fabian Mueller,et al.  Synergistic integration of a gas turbine and solid oxide fuel cell for improved transient capability , 2008 .

[30]  Alberto Traverso,et al.  Influence of the anodic recirculation transient behaviour on the SOFC hybrid system performance , 2005 .

[31]  Bjarne A. Foss,et al.  Modeling and control of a SOFC-GT-based autonomous power system , 2007 .

[32]  Paola Costamagna,et al.  Design and part-load performance of a hybrid system based on a solid oxide fuel cell reactor and a micro gas turbine , 2001 .

[33]  I. Celik,et al.  A numerical study of cell-to-cell variations in a SOFC stack , 2004 .

[34]  Atsushi Tsutsumi,et al.  Energy recuperation in solid oxide fuel cell (SOFC) and gas turbine (GT) combined system , 2003 .

[35]  Rory A. Roberts A dynamic fuel cell-gas turbine hybrid simulation methodology to establish control strategies and an improved balance of plant , 2005 .

[36]  Comas Haynes,et al.  Simulating process settings for unslaved SOFC response to increases in load demand , 2002 .

[37]  Jun Li,et al.  Cycle analysis of an integrated solid oxide fuel cell and recuperative gas turbine with an air reheating system , 2007 .

[38]  Faryar Jabbari,et al.  Analysis of a molten carbonate fuel cell: Numerical modeling and experimental validation , 2006 .

[39]  Lars Imsland,et al.  Control strategy for a solid oxide fuel cell and gas turbine hybrid system , 2006 .

[40]  Faryar Jabbari,et al.  Novel solid oxide fuel cell system controller for rapid load following , 2007 .