Abstract A novel composite bipolar plate for a polymer electrolyte fuel cell has been prepared by a bulk-moulding compound (BMC) process. The electrical resistance of the composite material decreases from 20 000 to 5.8 mΩ as the graphite content is increased from 60 to 80 wt.%. Meanwhile, the electrical resistance of composite increases from 6.5 to 25.2 mΩ as the graphite size is decreased from 1000 to 177 μm to less than 53 μm. The thermal decomposition of 5% weight loss of composite bipolar plate is higher than 250 °C. The oxygen permeability of the composite bipolar plate is 5.82×10 −8 (cm 3 /cm 2 s) when the graphite content is 75 wt.%, and increases from 6.76×10 −8 to 3.28×10 −5 (cm 3 /cm 2 s) as the graphite size is longer or smaller than 75 wt.%. The flexibility of the plate decreases with increasing graphite content. The flexural strength of the plate decreases with decrease in graphite size from 31.25 MPa (1000–177 μm) to 15.96 MPa (53 μm). The flexural modulus decreases with decrease of graphite size from 6923 MPa (1000–177 μm) to 4585 MPa (53 μm). The corrosion currents for plates containing different graphite contents and graphite sizes are all less than 10 −7 A cm −2 . The composite bipolar plates with different graphite contents and graphite sizes meet UL-94V-0 tests, and the limiting oxygen contents are higher than 50. Testing show that composite bipolar plates with optimum composition are very similar to that of the graphite bipolar plate.
[1]
J. Wind,et al.
Metallic bipolar plates for PEM fuel cells
,
2002
.
[2]
A. Hagiwara.
FUEL CELL SYSTEMS
,
2022
.
[3]
P. Adcock,et al.
Stainless steel as a bipolar plate material for solid polymer fuel cells
,
2000
.
[4]
R. Hornung,et al.
Bipolar plate materials development using Fe-based alloys for solid polymer fuel cells
,
1998
.
[5]
James Larminie,et al.
Fuel Cell Systems Explained
,
2000
.
[6]
Frank A. de Bruijn,et al.
Stainless steel for cost-competitive bipolar plates in PEMFCs
,
2000
.