A two-dimensional dynamic model was created for a Siemens Westinghouse type tubular solid oxide fuel cell (SOFC). This SOFC model was integrated with simulation modules for other system components (e.g., reformer, combustion chamber, and dissipater) to comprise a system model that can simulate an integrated 25kw SOFC system located at the University of California, Irvine. A comparison of steady-state model results to data suggests that the integrated model can well predict actual system power performance to within 3%, and temperature to within 5%. In addition, the model predictions well characterize observed voltage and temperature transients that are representative of tubular SOFC system performance. The characteristic voltage transient due to changes in SOFC hydrogen concentration has a time scale that is shown to be on the order of seconds while the characteristic temperature transient is on the order of hours. Voltage transients due to hydrogen concentration change are investigated in detail. Particularly, the results reinforce the importance of maintaining fuel utilization during transient operation. The model is shown to be a useful tool for investigating the impacts of component response characteristics on overall system dynamic performance. Current-based flow control (CBFC), a control strategy of changing the fuel flow rate in proportion to the fuel cell current is tested and shown to be highly effective. The results further demonstrate the impact of fuel flow delay that may result from slow dynamic responses of control valves, and that such flow delays impose major limitations on the system transient response capability.

1.
Jurado
,
F.
,
Valverde
,
M.
, and
Cano
,
A.
, 2004, “
Effect of a SOFC Plant on Distribution System Stability
,”
J. Power Sources
0378-7753,
129
, pp.
170
179
.
2.
Nickens
,
A.
,
Cervi
,
M.
,
Abens
,
S.
, and
Hoffman
,
D.
, 2004, “
US Navy Ship Service Fuel Cell Program
,”
Fuel Cell Seminar
, San Antonio, Texas.
3.
Stevenson
,
J. W.
,
Khaleel
,
D. L.
,
King
,
G. L.
, and
McVay
,
P. S.
, 2004, “
Solid Oxide Fuel Cell Development Activities at Pacific Northwest National Laboratory
,”
Fuel Cell Seminar
, San Antonio, Texas.
4.
Eelman
,
S.
, and
Poza
,
I. P.
, 2004, “
Fuel Cell APU’s in Commercial Aircraft-An Assessment of SOFC and PEMFC Concepts
,”
24th International Congress of the Aeronautical Sciences
, Yokohama, Japan.
5.
Randall
,
S. G.
,
Liese
,
E.
,
Riveria
,
J. G.
,
Jabbari
,
F.
, and
Brouwer
,
B.
, 2000, “
Development of Dynamic Modeling Tools For Solid Oxide and Molten Carbonate Hybrid Fuel Cell Gas Turbine Systems
,”
International Gas Turbine and Aeroengine Congress and Exhibition
,
Munich Germany
, May 8–10, ASME Paper No. 2000-GT-0554.
6.
Peters
,
D.
,
Freeh
,
L.
,
Kopasakis
,
G.
, and
Steffens
,
C.
, 2004, “
Fuel Cell System Modeling and Analysis at the NASA Glenn Research Center
,”
Fuel Cell Seminar
, San Antonio, Texas.
7.
Haynes
,
C.
, 2004, “
An Investigation to Resolve the Interaction Between SOFC Module, PES, and Balance-of-Plant During Transient Conditions
,”
Fuel Cell Seminar
, San Antonio, Texas.
8.
Lim
,
D. S.
,
Brouwer
,
J.
,
Neylon
,
M. K.
,
Fleckner
,
K. M.
,
Finalyson
,
B. A.
, and
Loffler
,
D. G.
, 2004, “
Novel Integrated Use of Femlab and Simulink to Understand the Dynamics of an SOFC/ Reformer System for Aeronautical Applications
,”
Fuel Cell Seminar
, San Antonio, Texas.
9.
Roberts
,
R. A.
,
Brouwer
,
J.
, and
Samuelsen
,
G. S.
, 2004, “
Dynamic Simulation of a Solid Oxide Fuel Cell/Gas Turbine Hybrid and Comparison to Data
,”
Fuel Cell Seminar
, San Antonio, Texas.
10.
Dicks
,
A. L.
, and
Martin
,
P. A.
, 1998, “
A Fuel Cell Balance of Plant Test Facility
,”
J. Power Sources
0378-7753,
71
, pp.
321
327
.
11.
Yi
,
Y.
,
Brouwer
,
J.
,
Rao
,
A. D.
, and
Samuelsen
,
G. S.
, 2004, “
Fuel Flexibility Study of an Integrated 25kW SOFC Reformer System
,”
Fuel Cell Seminar
, San Antonio, Texas.
12.
Casanova
,
A.
, 1998, “
A consortium Approach to Commercialized Westinghouse Solid Oxide Fuel Cell Technology
,”
J. Power Sources
0378-7753,
71
, pp.
65
70
.
13.
Burt
,
A. C.
,
Celik
,
I. B.
,
Gemmen
,
R. S.
, and
Smirnov
,
A. V.
, 2004, “
A Numerical Study of Cell to Cell Variation in a SOFC Stack
,”
J. Power Sources
0378-7753,
126
, pp.
76
87
.
14.
Campanari
,
S.
, and
Iora
,
P.
, 2004, “
Definition and Sensitivity Analysis of a Finite Volume SOFC Model for a Tubular Cell Geometry
,”
J. Power Sources
0378-7753,
132
, pp.
113
126
.
15.
Andrew
,
M. R.
, 1966, “
Kinetic Effects-Part 2
,”
An Introduction to Fuel Cells
,
K. R.
Williams
, ed.,
Elsevier Publishing Company
, New York, Chap. 4.
16.
Srinivasan
,
S.
,
Omourtag
,
A. V.
,
Parthasrathy
,
A.
,
Manko
,
D. J.
, and
Appleby
,
A. J.
, 1991, “
High Energy Efficiency and High Power Density Proton Exchange Membrane Fuel Cells-Electrode Kinetics and Mass Transport
,”
J. Polym. Sci., Polym. Symp.
0360-8905,
36
, pp.
299
320
.
17.
Bessette
,
N. F.
, 1994, “
Modeling and Simulation for Solid Oxide Fuel Cell Power Systems
,” Ph.D. thesis, Georgia Institute of Technology, Atlanta.
18.
Incropera
,
F. P.
, and
Dewitt
,
D. P.
, 2002,
Fundamental of Heat and Mass Transfer
,
Wiley
, New York.
19.
Gabor
,
J. D.
, and
Botterill
,
J. S. M.
, 1985, “
Heat Transfer in Fluidized and Packed Beds
,”
Handbook of Heat Transfer Applications
, 2nd ed.
W. M.
Rohsenoe
, et al.
, eds.,
McGraw-Hill
, New York.
20.
Xu
,
J.
, and
Froment
,
G. F.
, 1989, “
Methane Steam Reformation, Methanation and Water-Gas Shift: I. Intrinsic Kinetics
,”
AIChE J.
0001-1541,
35
(
1
), pp.
88
96
.
21.
Xu
,
J.
, and
Froment
,
G. F.
, 1989, “
Methane Steam Reforming: Diffusional Limitations and Reactor Simulation
,”
AIChE J.
0001-1541,
35
(
1
), pp.
97
103
.
22.
Gemmen
,
R.
,
Liese
,
E.
,
Rivera
,
J.
,
Jabbari
,
F.
, and
Brouwer
,
J.
, 2000, Development of Dynamic Modeling Tools for Solid Oxide and Molten Carbonate Fuel Cell Gas Turbine Systems, ASME Paper Number 2000-GT-554, May.
You do not currently have access to this content.