The effects of gravitational force on the orientation-dependent performance of portable proton exchange membrane (PEM) fuel cell using serpentine flow channels were investigated by the measurement and analysis of polarization curves. Whether the removal of produced water in the cathode flow channel is resisted or assisted by the gravity depends on the orientation variation, flow direction, and flow channel distribution of a fuel cell. This gravity will then affect the fuel cell performance, especially for fuel cells operating at a high current density. The results show that a fuel cell with perpendicular flow channel distribution and cathode gas flow in vertical direction requires a longer distance of pushing liquid droplets against gravity to remove the produced water, which is difficult to expel the produced water from the flow channels, and the performance reduction is obviously in high current density. A fuel cell operating in a normal position achieves higher performance than one operating in a horizontal position, except the cathode gas flow in vertical direction and feed from lower inlet. Furthermore, for a fuel cell operating in a horizontal position with anode below the membrane, gravitational force transports the water to the anode and blocks the fuel channel in the gas diffusion layer. This leads a fuel cell operating in high current densities with the cathode below the membrane performs better than one with the cathode above the membrane. Therefore, to reduce the effects of gravity on the orientation-dependent performance, a fuel cell with parallel flow channel distribution and feeding the cathode gas from the upper inlet port is recommended in this study.

1.
Kundu
,
A.
,
Jang
,
J. H.
,
Gil
,
J. H.
,
Jung
,
C. R.
,
Lee
,
H. R.
,
Kim
,
S. -H.
,
Ku
,
B.
, and
Oh
,
Y. S.
, 2007, “
Micro-Fuel Cells—Current Development and Applications
,”
J. Power Sources
0378-7753,
170
, pp.
67
78
.
2.
Li
,
X.
, 2006,
Principles of Fuel Cells
,
Taylor & Francis
,
London
, Chap. 7.
3.
Benziger
,
J.
,
Chia
,
J. E.
,
Kimball
,
E.
, and
Kevrekidis
,
I. G.
, 2007, “
Reaction Dynamics in a Parallel Flow Channel PEM Fuel Cell
,”
J. Electrochem. Soc.
0013-4651,
154
(
8
), pp.
B835
B844
.
4.
Kimball
,
E.
,
Whitaker
,
T.
,
Kevrekidis
,
Y. G.
, and
Benziger
,
J. B.
, 2008, “
Drops, Slugs, and Flooding in Polymer Electrolyte Membrane Fuel cells
,”
AIChE J.
0001-1541,
54
(
5
), pp.
1313
1332
.
6.
Chen
,
S. -H.
, and
Wu
,
Y. -H.
, 2008, “
Experimental Study of the Gravity Effect on PEMFC Performance
,”
J. Shenyang Jianzhu University
,
24
, pp.
1075
1079
.
7.
Quan
,
P.
,
Zhou
,
B.
,
Sobiesiak
,
A.
, and
Liu
,
Z. -S.
, 2005, “
Water Behavior in Serpentine Micro-Channel for Proton Exchange Membrane Fuel Cell Cathode
,”
J. Power Sources
0378-7753,
152
, pp.
131
145
.
8.
Li
,
P. -W.
,
Schaefer
,
L.
,
Wang
,
Q. -M.
,
Zhang
,
T.
, and
Chyu
,
M. K.
, 2003, “
Multi-Gas Transportation and Electrochemical Performance of a Polymer Electrolyte Fuel Cell With Complex Flow Channels
,”
J. Power Sources
0378-7753,
115
, pp.
90
100
.
9.
Cha
,
S. W.
,
O’Hayre
,
R.
,
Park
,
Y. -I.
, and
Prinz
,
F. B.
, 2006, “
Electrochemical Impedance Investigation of Flooding in Micro-Flow Channels for Proton Exchange Membrane Fuel Cells
,”
J. Power Sources
0378-7753,
161
, pp.
138
142
.
10.
Shah
,
K.
,
Shin
,
W. C.
, and
Besser
,
R. S.
, 2004, “
A PDMS Micro Exchange Membrane Fuel Cell by Conventional and Non-Conventional Micro-Fabrication Techniques
,”
Sens. Actuators B
0925-4005,
97
, pp.
157
167
.
11.
Kim
,
J. -Y.
,
Kwon
,
O. J.
, and
Hwang
,
S. -M.
, 2006, “
Development of a Miniaturized Polymer Electrolyte Membrane Fuel Cell With Silicon Separators
,”
J. Power Sources
0378-7753,
161
, pp.
432
436
.
12.
Yu
,
J.
,
Cheng
,
P.
,
Ma
,
Z.
, and
Yi
,
B.
, 2003, “
Fabrication of Miniature Silicon Wafer Fuel Cells With Improved Performance
,”
J. Power Sources
0378-7753,
124
, pp.
40
46
.
You do not currently have access to this content.