To effectively remove liquid water in the channel, the effect of partial blockage in the fuel cell channel on the droplet transport process was investigated by the volume of fluid model (VOF) method, and the effects of blockage block shape parameters, droplet size and gas diffusion layer (GDL) surface wettability on the twophase transport characteristics in the channel were explored. The results show that the presence of block affects the droplet transport in the channel. The introduction of block can increase the droplet shear force in the y direction, which increases the droplet transport rate and facilitates the removal of liquid water from the GDL surface. As the blocking ratio and longitudinal ratio increase, the pressure drop in the channel is increased, and the droplet transport rate is accelerated. With the increasing of droplet diameter and contact angle of GDL surface, the droplet transport rate is increased. When the droplet diameter is 0.8 cm with the GDL surface contact angle of 150°, the droplet transport rate in the channel is fast.
Key words
proton exchange membrane fuel cell /
water management /
partially blocked channel /
VOF method /
droplet transport
{{custom_keyword}} /
{{custom_sec.title}}
{{custom_sec.title}}
{{custom_sec.content}}
References
[1]张恒,陈涛,刘士华,等.PEMFC微流道内液滴运动的数值分析[J].电源技术,2018,42(12):1841-1845.
ZHANG H, CHEN T, LIU S H, et al. Numerical analysis of droplet moved in microchannel of proton exchange membrane fuel cell[J]. Chinese Journal of Power Sources, 2018,42(12):1841-1845.(in Chinese)
[2]GUO Q Y, QIN Y Z. Numerical investigation of water droplet removal characteristics in novel block channels of PEMFC using dynamic wettability model[J]. International Journal of Hydrogen Energy, 2021,46(74):36890-36902.
[3]JAZMI R, MOHAMMADZADEH K, KHALEGHI H, et al. Numerical investigation of water droplet behavior in anode channel of a PEM fuel cell with partial blockage[J]. Archive of Applied Mechanics, 2020,91(4):1391-1406.
[4]LI Z J, WANG S B, LI W W, et al. Droplet dynamics in a proton exchange membrane fuel cell flow field design with 3D geometry[J]. International Journal of Hydrogen Energy, 2021,46(31):16693-16707.
[5]LEI H, HUANG H Z, LI C, et al. Numerical simulation of water droplet transport characteristics in cathode channel of proton exchange membrane fuel cell with tapered slope structures[J]. International Journal of Hydrogen Energy, 2020,45(53):29331-29344.
[6]ANYANWU I S, HOU Y Z, XI F Q, et al. Comparative analysis of twophase flow in sinusoidal channel of different geometric configurations with application to PEMFC[J]. International Journal of Hydrogen Energy, 2019,44(26):13807-13819.
[7]XU Y F, PENG L F, YI P Y, et al. Numerical investigation of liquid water dynamics in wavelike gas channels of PEMFCs[J]. International Journal of Energy Research, 2019,43(3):1191-1202.
[8]DANG D K, ZHOU B. Liquid water transport in PEMFC cathode with symmetrical biomimetic flow field design based on Murray′s law[J]. International Journal of Hydrogen Energy, 2021,46(40):21059-21074.
[9]QIN Y Z, LI X G, JIAO K, et al. Effective removal and transport of water in a PEM fuel cell flow channel having a hydrophilic plate[J]. Applied Energy, 2014,113(13):116-126.
[10]徐城杰,张广升,刘洪潭,等. PEM燃料电池内部水传递的数值模拟[J]. 工程热物理学报,2010(9):1504-1507.
XU C J, ZHANG G S, LIU H T, et al. Modelling of water transport in PEM fuel cell[J]. Journal of Engineering Thermophysics, 2010(9):1504-1507.(in Chinese)
{{custom_fnGroup.title_en}}
Footnotes
{{custom_fn.content}}
PDF(10133 KB)
({{custom_author.role_en}}), {{javascript:window.custom_author_en_index++;}}
