Numerical quantification of water saturation, back diffusion, electro-osmotic drag and water generation in polymer electrolyte membrane fuel cells

Khan, Munir; Sundén, Bengt; Yuan, Jinliang

Numerical quantification of water saturation, back diffusion, electro-osmotic drag and water generation in polymer electrolyte membrane fuel cells

Mark

Khan, Munir ^LU ; Sundén, Bengt ^LU and Yuan, Jinliang ^LU (2011) In Journal of Power Sources

Abstract: A 3D unit cell has been simulated numerically using a commercial software

in order to evaluate and quantify various water related phenomena,

i.e., electro-osmotic drag, back diffusion, electro-chemical water generation

and the saturation effects in the porous media. The water saturation

effects were noticed to be more pronounced in the GDL of the cathode

as compared to the catalyst layer due to greater pore dimensions. Also,

a comparison of the water saturation effects were studied at different operating

voltages of 0.7, 0.5 and 0.3 V. In case of 0.7 and 0.5 V, it was

seen that the saturation effects were found to be located in the far region

of the inlet... (More); A 3D unit cell has been simulated numerically using a commercial software

in order to evaluate and quantify various water related phenomena,

i.e., electro-osmotic drag, back diffusion, electro-chemical water generation

and the saturation effects in the porous media. The water saturation

effects were noticed to be more pronounced in the GDL of the cathode

as compared to the catalyst layer due to greater pore dimensions. Also,

a comparison of the water saturation effects were studied at different operating

voltages of 0.7, 0.5 and 0.3 V. In case of 0.7 and 0.5 V, it was

seen that the saturation effects were found to be located in the far region

of the inlet because of the decreasing ability of air to accommodate more

water. But, at the lower voltage of 0.3, the saturation effects started to

appear in the inlet region too due to strong electro-osmotic drag and water

generation due to electro-chemical reactions. The transfer of water from

the cathode via back diffusion also increased accordingly by lowering the

operating voltage. Additionally, the transfer rate of water due to the back

diffusion was observed to be larger than the water addition due to both

the electro-osmotic drag and the electro-chemical generation. (Less)

Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/2205928

author

Khan, Munir ^LU ; Sundén, Bengt ^LU and Yuan, Jinliang ^LU

organization

Heat Transfer

publishing date

2011

type

Contribution to journal

publication status

submitted

subject

Energy Engineering

in

Journal of Power Sources

publisher

Elsevier

ISSN

1873-2755

language

English

LU publication?

yes

id

3359b84d-24d5-4256-bf3c-e90493eb2214 (old id 2205928)

date added to LUP

2016-04-04 14:10:10

date last changed

2019-01-21 11:48:08

@article{3359b84d-24d5-4256-bf3c-e90493eb2214,
  abstract     = {{A 3D unit cell has been simulated numerically using a commercial software<br/><br>
in order to evaluate and quantify various water related phenomena,<br/><br>
i.e., electro-osmotic drag, back diffusion, electro-chemical water generation<br/><br>
and the saturation effects in the porous media. The water saturation<br/><br>
effects were noticed to be more pronounced in the GDL of the cathode<br/><br>
as compared to the catalyst layer due to greater pore dimensions. Also,<br/><br>
a comparison of the water saturation effects were studied at different operating<br/><br>
voltages of 0.7, 0.5 and 0.3 V. In case of 0.7 and 0.5 V, it was<br/><br>
seen that the saturation effects were found to be located in the far region<br/><br>
of the inlet because of the decreasing ability of air to accommodate more<br/><br>
water. But, at the lower voltage of 0.3, the saturation effects started to<br/><br>
appear in the inlet region too due to strong electro-osmotic drag and water<br/><br>
generation due to electro-chemical reactions. The transfer of water from<br/><br>
the cathode via back diffusion also increased accordingly by lowering the<br/><br>
operating voltage. Additionally, the transfer rate of water due to the back<br/><br>
diffusion was observed to be larger than the water addition due to both<br/><br>
the electro-osmotic drag and the electro-chemical generation.}},
  author       = {{Khan, Munir and Sundén, Bengt and Yuan, Jinliang}},
  issn         = {{1873-2755}},
  language     = {{eng}},
  publisher    = {{Elsevier}},
  series       = {{Journal of Power Sources}},
  title        = {{Numerical quantification of water saturation, back diffusion, electro-osmotic drag and water generation in polymer electrolyte membrane fuel cells}},
  year         = {{2011}},
}

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Numerical quantification of water saturation, back diffusion, electro-osmotic drag and water generation in polymer electrolyte membrane fuel cells