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Fuel Cell News
August 30, 2005
Proton Exchange Membrane Fuel Cells - Conversion
Of Hydrocarbon
Source: Azom.Com
Fuel Processors
In order to use hydrocarbon fuels in proton-exchange-membrane (PEM) fuel
cell systems, fuel (e.g., gasoline or natural gas) must first be converted
into a hydrogen-rich gas with little or no carbon monoxide (CO). Fuel
processors based on multiple catalytic stages are being developed for
this application.
Synthesis Gas Conversion
In the first stage the hydrocarbon fuel is converted (reformed) to a synthesis
gas (hydrogen and carbon monoxide) with a CO content of about 10-15 mol%.
Water Gas Shift (WGS) Reaction
The second stage is the water gas shift (WGS) reaction, which converts
carbon monoxide to carbon dioxide while increasing the hydrogen content
(CO + H2O " CO2+ H2). This reaction is generally performed in the
temperature range of 250 to 400°C.
After the WGS stage, the CO content in the gas is between 0.5 and 1 mol%.
Clean Up Stage
The final CO clean-up stage in a fuel processor involves either preferential
oxidation of CO to CO2 by addition of air or collection of hydrogen using
a hydrogen permeable membrane.
In traditional WGS fuel processors the reaction is carried out with two
catalytic stages: relatively inactive iron-chrome catalysts running at
higher temperatures in the first and active but temperature-limited copper-based
catalysts in the second.
Pyrophoric Copper Based Catalysts
A critical issue is that copper-based catalysts are pyrophoric and must
be protected from air and condensed water during start-up and shut-down
of the fuel processor. No single catalyst material has been available
that provides the desired attributes of high activity and stability over
the entire temperature range of interest - until now!
Water Gas Shift Catalysts
Our WGS catalysts, based on nano-particle ceria-based mixed oxide supports
with highly dispersed precious metals, provide a technically viable and
cost-effective alternative for WGS catalysts used in fuel processors.
Our catalysts are highly active above 250°C and are non-pyrophoric.
Furthermore, these catalysts can be washcoated onto monolithic (honeycomb
or foamed ceramic) supports so that small size can be maintained and precious
metal utilization maximized.
Applications
· Monolithic WGS reactors for PEM fuel cell systems
· Micro-channel WGS reactors for PEM fuel cell systems
· WGS membrane reactors for PEM fuel cell systems
Benefits
· Pt/ceria catalysts are non-pyrophoric and provide high activity
at temperatures above 250ºC (see Figures 1 and 2) for excellent start
up, operating and shut down performance
· Pt/ceria catalysts can be regenerated by annealing in air (see
Figure 3) for long life cycles
· Catalysts can be deposited onto monoliths, using low-cost, high-volume
methods that are well established for automotive catalytic converters
(see Figure 5)
· Less than six grams of precious metal will be required for a
WGS monolith sized for a 50-kilowatt fuel processor based upon kinetics
models (see Figure 6).
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