Computational analysis on thermal performance and coolant flow of an air-cooled polymer electrolyte membrane fuel cell / Wan Ahmad Najmi Wan Mohamed and Rahim Atan

Polymer Electrolyte Membrane (PEM) fuel cells are electrochemical power generators that converts the energy potential of a hydrogen-based fuel into electricity with water and heat as the major by-products. The sensitivity of the solid polymer membrane to temperature requires that thermal management...

Full description

Bibliographic Details
Main Authors: Wan Mohamed, Wan Ahmad Najmi, Atan, Rahim
Format: Article
Language:English
Published: UiTM Press 2010
Subjects:
Online Access:https://ir.uitm.edu.my/id/eprint/13730/1/AJ_WAN%20AHMAD%20NAJMI%20WAN%20MOHAMED%20JME%2010.pdf
_version_ 1825734149713952768
author Wan Mohamed, Wan Ahmad Najmi
Atan, Rahim
author_facet Wan Mohamed, Wan Ahmad Najmi
Atan, Rahim
author_sort Wan Mohamed, Wan Ahmad Najmi
collection UITM
description Polymer Electrolyte Membrane (PEM) fuel cells are electrochemical power generators that converts the energy potential of a hydrogen-based fuel into electricity with water and heat as the major by-products. The sensitivity of the solid polymer membrane to temperature requires that thermal management of a PEM fuel cell stack operates efficiently to maintain the temperature at the optimal level. Air cooling is normally applied for industrial PEM fuel cells of up to 2 kW power output. A computational investigation on the effective micro cooling channel geometries was conducted in order to enhance the practical capability of air cooling for a 3 kW stack power output with a reduced conversion efficiency of 30%. Plate and stack assembly simulation cases of a single channel and 40 cooling channel configurations using Computational Fluid Dynamics (CFD) were conducted with constant heat generation. The cooling performance was evaluated based on the boundary heat transfer and shows 100% effectiveness when subjected to airflows with a minimum Reynolds number of 200. The temperature distribution of the stack showed significant temperature gradients exists across the stack where multiple cooling channels provided a reduced gradient, approximately 50% less compared to the single channel. The coolant flow characteristics were also analyzed and an average velocity rise factor (AVRF) was introduced. Validation of the CFD simulation results was performed analytically and the simulation methodology reliability was found satisfactory by comparing the results of single plate simulations to the stack simulations
first_indexed 2024-03-06T01:27:27Z
format Article
id oai:ir.uitm.edu.my:13730
institution Universiti Teknologi MARA
language English
last_indexed 2024-03-06T01:27:27Z
publishDate 2010
publisher UiTM Press
record_format dspace
spelling oai:ir.uitm.edu.my:137302016-07-25T03:11:26Z https://ir.uitm.edu.my/id/eprint/13730/ Computational analysis on thermal performance and coolant flow of an air-cooled polymer electrolyte membrane fuel cell / Wan Ahmad Najmi Wan Mohamed and Rahim Atan jmeche Wan Mohamed, Wan Ahmad Najmi Atan, Rahim Electrolytes, electrolyte solutions Polymers and polymer manufacture Polymer Electrolyte Membrane (PEM) fuel cells are electrochemical power generators that converts the energy potential of a hydrogen-based fuel into electricity with water and heat as the major by-products. The sensitivity of the solid polymer membrane to temperature requires that thermal management of a PEM fuel cell stack operates efficiently to maintain the temperature at the optimal level. Air cooling is normally applied for industrial PEM fuel cells of up to 2 kW power output. A computational investigation on the effective micro cooling channel geometries was conducted in order to enhance the practical capability of air cooling for a 3 kW stack power output with a reduced conversion efficiency of 30%. Plate and stack assembly simulation cases of a single channel and 40 cooling channel configurations using Computational Fluid Dynamics (CFD) were conducted with constant heat generation. The cooling performance was evaluated based on the boundary heat transfer and shows 100% effectiveness when subjected to airflows with a minimum Reynolds number of 200. The temperature distribution of the stack showed significant temperature gradients exists across the stack where multiple cooling channels provided a reduced gradient, approximately 50% less compared to the single channel. The coolant flow characteristics were also analyzed and an average velocity rise factor (AVRF) was introduced. Validation of the CFD simulation results was performed analytically and the simulation methodology reliability was found satisfactory by comparing the results of single plate simulations to the stack simulations UiTM Press 2010 Article PeerReviewed text en https://ir.uitm.edu.my/id/eprint/13730/1/AJ_WAN%20AHMAD%20NAJMI%20WAN%20MOHAMED%20JME%2010.pdf Computational analysis on thermal performance and coolant flow of an air-cooled polymer electrolyte membrane fuel cell / Wan Ahmad Najmi Wan Mohamed and Rahim Atan. (2010) Journal of Mechanical Engineering (JMechE) <https://ir.uitm.edu.my/view/publication/Journal_of_Mechanical_Engineering_=28JMechE=29/>, 7 (2). pp. 15-36. ISSN 1823-5514 ; 2550-164X https://jmeche.uitm.edu.my/
spellingShingle Electrolytes, electrolyte solutions
Polymers and polymer manufacture
Wan Mohamed, Wan Ahmad Najmi
Atan, Rahim
Computational analysis on thermal performance and coolant flow of an air-cooled polymer electrolyte membrane fuel cell / Wan Ahmad Najmi Wan Mohamed and Rahim Atan
title Computational analysis on thermal performance and coolant flow of an air-cooled polymer electrolyte membrane fuel cell / Wan Ahmad Najmi Wan Mohamed and Rahim Atan
title_full Computational analysis on thermal performance and coolant flow of an air-cooled polymer electrolyte membrane fuel cell / Wan Ahmad Najmi Wan Mohamed and Rahim Atan
title_fullStr Computational analysis on thermal performance and coolant flow of an air-cooled polymer electrolyte membrane fuel cell / Wan Ahmad Najmi Wan Mohamed and Rahim Atan
title_full_unstemmed Computational analysis on thermal performance and coolant flow of an air-cooled polymer electrolyte membrane fuel cell / Wan Ahmad Najmi Wan Mohamed and Rahim Atan
title_short Computational analysis on thermal performance and coolant flow of an air-cooled polymer electrolyte membrane fuel cell / Wan Ahmad Najmi Wan Mohamed and Rahim Atan
title_sort computational analysis on thermal performance and coolant flow of an air cooled polymer electrolyte membrane fuel cell wan ahmad najmi wan mohamed and rahim atan
topic Electrolytes, electrolyte solutions
Polymers and polymer manufacture
url https://ir.uitm.edu.my/id/eprint/13730/1/AJ_WAN%20AHMAD%20NAJMI%20WAN%20MOHAMED%20JME%2010.pdf
work_keys_str_mv AT wanmohamedwanahmadnajmi computationalanalysisonthermalperformanceandcoolantflowofanaircooledpolymerelectrolytemembranefuelcellwanahmadnajmiwanmohamedandrahimatan
AT atanrahim computationalanalysisonthermalperformanceandcoolantflowofanaircooledpolymerelectrolytemembranefuelcellwanahmadnajmiwanmohamedandrahimatan