You need JavaScript to view this
ETDEWEB   /       /    A model predicting transient responses of proton exchange membrane fuel cells

A model predicting transient responses of proton exchange membrane fuel cells

Journal Article:

SAVE / SHARE

XML RIS EndNote CSV/Excel JSON

Abstract

Steady-state behaviour is very common and in some cases is considered as the normal operating standard. Unsteady-state behaviour, however, is becoming more of an issue, especially for the transportation applications of fuel cells where the operating conditions will normally change with time. For example, system start-up, system shut-down, and large changes in the power level may be accompanied by changes in the stack temperature, as well as changes in the reactant gas concentrations at the electrode surface. Therefore, both mass and heat transfer transient features must be incorporated into an electrochemical model to form an overall model predicting transient responses by the stack. A thermal model for a Ballard Mark V 35-cell 5 kW PEM fuel cell stack has been developed by performing mass and energy balances on the stack. The thermal characterization of the stack included determining the changes in the sensible heat of the anode, cathode, and water circulation streams, the theoretical energy release due to the reaction, the electrical energy produced by the fuel cell, and the heat loss from the surface of the stack. This thermal model was coupled to a previously-developed electrochemical model linking the power produced by the stack and the stack temperature to  More>>
Authors:
Amphlett, J C; [1]  Mann, R F; [1]  Peppley, B A; [1]  Roberge, P R; [1]  Rodrigues, A [1] 
  1. Royal Military Coll. of Canada, Kingston, ON (Canada)
Publication Date:
Jul 01, 1996
DOI:
https://doi.org/10.1016/S0378-7753(96)02360-9
Product Type:
Journal Article
Report Number:
CONF-9509158-
Reference Number:
SCA: 300502; PA: CHF-97:0G3405; EDB-97:040527; SN: 97001749363
Resource Relation:
Journal Name: Journal of Power Sources; Journal Volume: 61; Journal Issue: 1-2; Conference: 4. Grove fuel cell symposium - opportunities, progress and challenges, London (United Kingdom), 19-22 Sep 1995; Other Information: PBD: Jul-Aug 1996
Subject:
30 DIRECT ENERGY CONVERSION; TRANSIENTS; MATHEMATICAL MODELS; FUEL CELLS; PERFORMANCE; MEMBRANES; PROTONS; HEAT LOSSES
OSTI ID:
440420
Country of Origin:
Switzerland
Language:
English
Other Identifying Numbers:
Journal ID: JPSODZ; ISSN 0378-7753; TRN: CH97G3405
Submitting Site:
CHF
Size:
pp. 183-188
Announcement Date:
Mar 14, 1997

Journal Article:

SAVE / SHARE

XML RIS EndNote CSV/Excel JSON

Citation Formats

Amphlett, J C, Mann, R F, Peppley, B A, Roberge, P R, and Rodrigues, A. A model predicting transient responses of proton exchange membrane fuel cells. Switzerland: N. p., 1996. Web. doi:10.1016/S0378-7753(96)02360-9.
Amphlett, J C, Mann, R F, Peppley, B A, Roberge, P R, & Rodrigues, A. A model predicting transient responses of proton exchange membrane fuel cells. Switzerland. https://doi.org/10.1016/S0378-7753(96)02360-9
Amphlett, J C, Mann, R F, Peppley, B A, Roberge, P R, and Rodrigues, A. 1996. "A model predicting transient responses of proton exchange membrane fuel cells." Switzerland. https://doi.org/10.1016/S0378-7753(96)02360-9.
@misc{etde_440420,
title = {A model predicting transient responses of proton exchange membrane fuel cells}
 author = {Amphlett, J C, Mann, R F, Peppley, B A, Roberge, P R, and Rodrigues, A}
 abstractNote = {Steady-state behaviour is very common and in some cases is considered as the normal operating standard. Unsteady-state behaviour, however, is becoming more of an issue, especially for the transportation applications of fuel cells where the operating conditions will normally change with time. For example, system start-up, system shut-down, and large changes in the power level may be accompanied by changes in the stack temperature, as well as changes in the reactant gas concentrations at the electrode surface. Therefore, both mass and heat transfer transient features must be incorporated into an electrochemical model to form an overall model predicting transient responses by the stack. A thermal model for a Ballard Mark V 35-cell 5 kW PEM fuel cell stack has been developed by performing mass and energy balances on the stack. The thermal characterization of the stack included determining the changes in the sensible heat of the anode, cathode, and water circulation streams, the theoretical energy release due to the reaction, the electrical energy produced by the fuel cell, and the heat loss from the surface of the stack. This thermal model was coupled to a previously-developed electrochemical model linking the power produced by the stack and the stack temperature to the amount and method of heat removal from the stack. This electrochemical model calculates the power output of a PEM fuel cell stack through the prediction of the cell voltage as a complex function of operating current, stack temperature, hydrogen and oxygen gas flowrates and partial pressures. Initially, a steady-state overall dynamic model (electrochemical model coupled with the thermal model) was developed. This was then transformed into a transient model which predicts fuel cell performance in terms of cell voltage output and heat losses as a function of time due to various changes imposed on the system. (orig./MM)}
 doi = {10.1016/S0378-7753(96)02360-9}
 journal = []
 issue = {1-2}
 volume = {61}
 journal type = {AC}
 place = {Switzerland}
 year = {1996}
 month = {Jul}
 }