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H2 from Multiple Fuels & Polymeric Membrane Separation

So much is going on in hydrogen these days, but one still wonders whether truly novel developments will ultimately be the key to making H2 an economic and practical part of the energy system. H2fuel, a small technology development company in Chicago, has two important innovations that may be examples the kinds of breakthroughs that are needed.

1. Fuel Processor — Simpler cheaper integrated autothermal reformer system–sulfur tolerant

2. Polymeric Membrane — A unique new membrane that removes CO2 and H2S, by a chemical mass transport, not physical separation, while reducing CO.

H2fuel is jointly owned by Avista Labs(70%) and Unitel Fuel Technologies (30%). H2fuel is looking for investors. A business plan is available.

Contacts:
Lee Camara, Unitel, ehc.unitel@usa.net 847-297-2265
Mike Davis, Avista Labs, mdavis@avistalabs.com 509-228-6685

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Here are some technical details, adapted from a 4-page summary the company has prepared, complete with color graphics. (download – password required):
http://www.ufto.com/clients-only/H2fuel.doc.

Fuel Processor

A couple of years ago, H2fuel took over funding of work at Argonne on an autothermal reformer (ATR), and introduced new sulfur-tolerant catalysts. A key goal was to process any number of standard (sulfur bearing) fuels in the same device. The system now promises low cost, simple operation, ease of manufacture, rapid cycling (load following), and ease of manufacture.

Sulfur-tolerant water gas shift (WGS) catalysts have been qualified for both medium temperature and low temperature applications. One of the most significant breakthroughs is the elimination of the zinc oxide bed, thus allowing the H2S produced in this processor to go right through the reactor without any deleterious effects. The H2S is continuously removed by a new subsystem downstream (see below).

The CO produced in the fuel processor, ~1%, depending on the fuel, acts as a PEM fuel cell poison because it affects the anode electrocatalyst. H2fuel has developed a unique method for reducing the CO level to below 10 ppm, thus eliminating this problem.

H2fuel’s new hydrogen processor, with its sulfur-tolerant autothermal and water gas shift catalysts, and without the need for a zinc oxide bed, has been tested continuously for over 2500 hours with natural gas containing ~20 ppm sulfur compounds. During this period, it has successfully completed several load-following tests and maintained an output gas composition (dry basis) of 45% H2, 15% CO2, 1% CO, 0.4% CH4, balance N2. This reactor continues to be tested; however, the fuel is being changed to regular gasoline, and later to fuel grade ethanol.

Polymeric Membrane

On a separate front, under the auspices of a R&D program originally started at the University of Kentucky, and now being continued at Ohio State University, H2fuel has a controlling position in the IP developing polymeric membrane products and support devices to facilitate the removal of H2S and CO2 from the reformate product streams. The key component of this membrane separator is a surface layer that reacts with H2S and CO2, but not with H2 and CO. The membrane transports the reaction products from one side of the membrane to the other by mass transport. The H2S and CO2 desorb on the other side and are swept away. The H2 and CO don’t react with the membrane and are retained on the reformate side. A second membrane stage incorporates a catalyst to deplete the remaining CO in the reformate to less than 10 ppm.

This membrane technology can be used as well to clean up H2 from other production processes. Some major fuel cell companies have made clear their interest once higher temperature operation of the membrane is accomplished.

CO, CO2 Removal from reformate H2

This press release will be released on Wednesday. It follows an earlier one from Avista that contained some errors. The company, H2fuel, is a spinoff from Unitel and is co-owned by Avista Labs. Unitel is a small technology development company in Chicago with several other developments that we’re tracking for UFTO.

I visited Unitel/H2fuel in Chicago recently, and heard a detailed account of this technology under an NDA. They’ve given me permission to pass the press release along to UFTO, so please hold onto it at least til Thursday.

There is an investment opportunity here.

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H2FUEL NEWS

For Immediate Release, October 31, 2001

Media Contacts: Serge Randhava, H2fuel, 847-297-2265

H2fuel Membrane Program Technical Update

October 31, 2001: In providing additional details about its proposed fuel cell hydrogen membrane program, H2fuel confirmed that the membrane is being tailored to work at temperatures up to 350C, levels that are normally associated with the water gas shift reaction. In a press release issued earlier this month, the company had announced that it had awarded a R&D contract to the University of Kentucky to synthesize, characterize and test a family of chemical transport membranes that can efficiently and selectively remove oxides of carbon from a gas mixture.

The primary objective of the H2fuel membrane program is to eliminate carbon dioxide and carbon monoxide from a reformate gas stream, thereby increasing its hydrogen content and greatly reducing the overall cost of producing pure hydrogen for fuel cell applications.

H2fuel’s membrane module is being configured as a dual-role device. To begin with, all the carbon dioxide in the gas stream will be stripped out of the gas mixture. Simultaneously, the carbon monoxide that is present will be converted into carbon dioxide by means of an integrated water gas shift reaction step, following which this coproduced carbon dioxide will also be transferred out by the membrane. For all practical purposes, the H2fuel membrane module will serve to get rid of all the carbon in the gas before it goes to the fuel cell.

The H2fuel membrane is not a conventional permeation platform. Rather, it will use a polymeric membrane that operates at close to atmospheric pressure, and incorporates a unique chemical transport mechanism for attaching and detaching the carbon dioxide molecule.

“Our membrane program is based upon a simple wish list,” notes Serge Randhava, President of H2fuel. “First, we want to get rid of the carbon dioxide leaving our primary fuel processor. Second, we want to convert any carbon monoxide in the gas stream into carbon dioxide, and also affect the parallel removal of this secondary compound. At the end of the faucet, we want an enriched fuel cell hydrogen stream that is totally free of all oxides of carbon,” he adds.

H2fuel is jointly owned by Avista Labs, Inc., a wholly owned subsidiary of Spokane-based Avista Corp. (NYSE: AVA) and Unitel Fuel Technologies, LLC, Mt. Prospect, IL.