FuelCellsWorks

JAKARTA, Indonesia,  — PT CONSISTEL Indonesia, a subsidiary of CONSISTEL Pte Ltd is excited to win one of the largest contracts for supplying Spiro hydrogen fuel cells (”Spiro”) in Asia. CONSISTEL Pte Ltd (”CONSISTEL”) being pioneer of providing telecommunication system integrator services is also providing green and efficient energy solutions to its customers across the Asia Pacific and Middle East. As part of the green movement and adoption of alternative energy sources, PT. Hutchison CP Telecommunications (HCPT) has selected PT CONSISTEL Indonesia as its partner to deploy 200 units of Spiro hydrogen fuel cell in Java, Sumatra and Bali region of Indonesia.

“With global warming issues intensifying, telecommunication providers are adopting green strategy to minimize energy consumption and improve carbon footprint. CONSISTEL foresee significant market potential for Spiro in wireless network deployments worldwide.” Bernard Chan, Group Managing Director of CONSISTEL. “We are committed to support telecom operators in the green initiative and will continue to contribute and provide our services in the best possible way to make this deployment a success. We are confident that telecom operators will benefit significantly from Spiro in terms of the system reliability, modularity design, energy efficiency and environmental friendliness.” Bernard Chan, continued.

The acceptance of CONSISTEL’s Spiro by HCPT in Indonesia is an important milestone for CONSISTEL to broader green energy deployment. The contract is a proof of the system superiority, CONSISTEL’s committed support and close working relationship with its customers.

Eco-friendly policy has become one of the top objectives in current telecom business. Going forward, CONSISTEL is committed to ensuring that its customers receive reliable and robust green backup power solutions. With millions of telecommunication BTS cell sites spread throughout the Asia Pacific region, telecommunication providers are now adopting alternative power sources like hydrogen fuel cells to minimize impact on our environment. The high reliability of Spiro, committed customer service support and field proven technical expertise are the success factors for CONSISTEL to continue its expansion in green energy solution arena in Asia Pacific and Middle East.

About CONSISTEL

CONSISTEL is the leading independent service provider for wireless and mobile network solutions in the wireless telecommunications industry. We offer a complete range of wireless network services and solutions, from green energy solution, software applications, business and technical consultancy to network design, deployment and management. CONSISTEL has a pool of highly qualified professionals and recognized experts located regionally, providing unbiased, best-of-breed solutions across all wireless telecommunications technologies. For more information, please visit http://www.CONSISTEL.com

A year ago, venture capitalists at the firm Kleiner Perkins let slip a few juicy details about their first cleantech investment: quiet fuel cell maker Bloom Energy. Now in an interesting and rare interview with Alison van Diggelen, who produces Fresh Dialogues, Bloom Energy chief executive KR Sridhar has shared a few more tidbits, including the fact that Bloom is targeting the transportation industry in the company’s grand vision.

No the fuel cell won’t be making its way into the vehicles themselves but Sridhar tells van Diggelen that “the ultimate vision” is to have refrigerator-sized Bloom devices powering transportation within a decade. As Sridhar explains: “Our device can either produce the electricity that will charge the car or provide you hydrogen if the transportation becomes a hydrogen based. So we’ve sort of become the gas station for the transportation industry.” That sounds like the devices could provide an off-the-grid form of electric vehicle charging.

It’s yet another massive industry that the 7-year-old company, which is really just getting started on its commercial shipments according to documents associated with its $150 million Series F financing round, is hoping to tackle. The 5-kilowatt Bloom box, which has been in testing for the last few years, involves a fuel cell system that can generate electricity using a range of liquid fuels, such as natural gas or ethanol.

Other interesting points of van Diggelen’s interview include Sridhar’s reality check on how long large scale energy tech projects really take:

This is not a microchip. These are huge devices, they need to be build in very large quantities, and if you take automotive, if you take anything else, its penetration and how long it takes to build the factories, the machines for factories. These things don’t happen over night…It’s going to be slower than what the bits and bites people in Silicon Valley think because it’s not like software that you’re just going to write and then copy 800 times, or a million times over instantly, and distribute.

So if you thought Bloom was taking a long time to deliver its product to market, get ready to wait a whole lot longer for the company to execute on its vision. And on the point of Bloom’s reported pre-money valuation, van Diggelen writes, “Sridhar advised reported figures were not accurate.” To read or listen to the interview (which is just the first part), click here.

ClearEdge Power wants to sell combined heat and power fuel cell units to homes and small businesses. Bigger tax breaks could help.

KDDI has recently shown off a new fuel cell battery that can be refilled with methanol, where it will run for up to 320 hours before requiring another refill. This prototype fuel cell is a type of hybrid device which will be coupled to a lithium ion battery that offers enough juice for surges in use. Unfortunately for the masses, KDDI has no plans to see the technology arrive in the market ASAP – instead, it will take at least a few years to do so. Perhaps in our childrens’ time, they can have handsets that last for weeks on end before requiring a recharge. As for now, we’ll just have to learn to co-exist with numerous chargers whenever we travel.

Berlin, Germany — In the fourth quarter of 2009, Heliocentris will launch the Heliocentris Nexa® 1200, a completely new fuel cell module developed by Heliocentris based on the FCgen 1020 ACS stack from Ballard, with a power output of 1.2 kW.

As a partner of Ballard Power Systems, Heliocentris has sold the Nexa® Power Module around the world for the past five years. Heliocentris has integrated the fuel cell modules in training systems and numerous turnkey projects. For independent integration of the fuel cell module by the customer, Heliocentris also developed matching integration components. More than five years of experience in sales and servicing created the ideal basis for development of a proprietary system.

A new generation of modules

The goal of the Heliocentris development team was to create a follow-up generation for the popular fuel cell module that can not only match the power output of the former system, but also offer significant improvements. “The development of a mere replacement was never a desirable goal for us,” says Klaus Rupprecht, Head of Product Development.

The parasitic power consumption could be reduced by up to 50%, thus significantly increasing the overall system efficiency of the Heliocentris Nexa 1200 as compared with the former model. This was achieved by the concept of atmospheric air supply in combination with the air-cooled stack.

Whilst the old Nexa® Power Module requires a compressor and a fan for the supply of reaction and cooling air, the Heliocentris Nexa 1200 uses a single fan on the back of the system drawing in ambient air for even distribution through the entire system. In addition to improved cooling, this made it possible to eliminate components such as a compressor or cooling water pump, which cause significant parasitic loads.

The system is therefore especially suitable for applications requiring long operating times with a limited hydrogen supply, for example in backup systems for standalone photovoltaic systems or uninterrupted power supply systems.

Optimized for easy integration

The fully integrated Heliocentris Nexa® 1200 contains all system components in a stable plastic housing, which also functions as a component rack and air baffle system. Inadvertent manipulation or short circuits on the stack, which can be caused by falling objects, are not possible. It is not necessary to enclose the system prior to integration. In this respect, the Heliocentris Nexa® 1200 eliminates complex integration processes. “Solely for the purpose of directed dissipation of cooling air, many of our customers have integrated the system from Ballard in a box,” explains Klaus Rupprecht; “with the Heliocentris Nexa® 1200 we have already solved this problem. The air outlet is designed for easy attachment of an exhaust air duct. Draining the water accumulated during the reaction is also facilitated. It evaporates with the cooling air.” It is therefore not necessary to drain the water from the application.

The Heliocentris Nexa® 1200 has a central interface unit on the back. With respect to orientation of the fuel cell module in the application, the system is likewise more flexible. While the system from Ballard could be installed only in upright position, the Heliocentris Nexa® 1200 can be installed vertically, horizontally and over head. The profile rails embedded in the housing enable easy mounting of the system in upright or suspended position. The system is also optimized for integration in 19″ racks.

Fit for the series

For use in series applications the fuel cell module fulfills the requirements of integrators. The system is equipped with an internal safety loop allowing also for integration of external components, such as an external hydrogen warning system, and conforms to the fuel cell standard EN 62282. Simple maintenance tasks, such as changing filters, can even be carried out by the user. An integrated error memory facilitates diagnosis in the event of an outage.

Availability

The Heliocentris Nexa® 1200 will be available in Europe starting the fourth quarter of 2009, initially as a lab system. Markets outside of Europe will be covered by the end of the first quarter of 2010. In addition to the fuel cell module, the product bundle includes a start-up kit for fast and easy system start-up, as well as monitoring software. An optional electronic load can also be purchased from Heliocentris.

Toward the end of the first quarter of 2010 Heliocentris will also offer an Overall System Controller (OSC) for the control of complex energy systems, consisting of several sources and drains, and a DC converter for battery hybridization.

The Mazda RX-8 RE Hydrogen have obtained National Type Approval (NTA) in Norway. This means that the vehicle can be registered for normal road traffic just the same as any other Mazda.

The following conditions apply to the NTA:
·         The approval is valid in a period of 3 years from registration date (return of vehicle to MC)
·         The NTA is valid for “small production series” up to 20 vehicles
·         The driver will be given a special Hydrogen training by Mazda Motor Norway

“Critical moment” as new analysis shows $180bn global market potential

The Carbon Trust is today launching a UK bid for a breakthrough in fuel cell technology, which could open up a global fuel cell market worth over $180 billion by 2050, according to new analysis.

The “Polymer Fuel Cells Challenge” aims to accelerate the commercialisation of breakthrough UK technology that could see the mainstream cost effective (mass) production of fuel cell powered cars and buses, as well as providing electricity and heat in homes and business. These kinds of mass market applications could be saving the UK up to 7 million tonnes of CO2 a year in 2050, equivalent to taking two million of today’s cars off the road.

Launching the initiative, Dr Robert Trezona, Head of Research and Development at the Carbon Trust, said: “Fuel cells have been ten years away from a real breakthrough for the past 20 years. This is a critical moment for UK fuel cell technology as emerging markets combine with technology cost breakthroughs to create a golden opportunity to launch world-beating products onto a massive global market.  Our initiative aims to drive forward the commercialisation of the UK’s unique fuel cell expertise which will play a crucial role in the UK’s Clean Tech Revolution both cutting carbon and creating jobs and economic value.”

The initiative aims to deliver the critical reduction in fuel cell system costs that must be achieved to make mass market deployment a reality. New Carbon Trust analysis shows that if substantial cuts can be achieved, the global market could be worth over $26bn in 2020 and over $180bn in 2050. The UK share of this market could be $1bn in 2020 rising to $19bn in 2050.

David Hart, Head of Fuel Cell and Hydrogen Research, Centre for Energy Policy and Technology, Imperial College, said: “For many years fuel cell and hydrogen technologies have been expected to become a cornerstone of a low-carbon, more efficient energy system, but the cost, durability and performance of current fuel cell systems remain unattractive in most applications. The Polymer Fuel Cells Challenge is an exciting opportunity to address these issues with a fresh perspective and co-ordinated approach to make polymer fuel cells an everyday commercial reality.”

Celia Greaves, Fuel Cells UK, said: “We warmly welcome the Carbon Trust’s new Polymer Fuel Cells Challenge. The UK is home to a number of world class fuel cell companies and research centres, and substantive IP has already been created in this area. Initiatives such as this from the Carbon Trust are vital to strengthening the UK’s position and ensuring that the UK is innovative and remains competitive in this growing global industry.”

Current fuel cell system costs are still too high by a factor of at least ten for widespread uses. These costs could be brought down in the future through volume production, but projections show that even then, with today’s technology, costs would remain too high by 30-40% for most markets. The Polymer Fuel Cells Challenge will aim to support those breakthroughs that will allow high-volume costs to come down by 35%, making fuel cell systems attractive for mass markets.

Fuel cells efficiently convert the chemical energy contained in a fuel directly into electricity – they produce electricity like a battery but are fuelled like an engine or a boiler. Fuel cells are already marketed around the world, with sales growing at over 60% a year – they are used to power forklift trucks, mobile phone masts or provide power in camper vans. However, they currently remain too expensive to be more widespread.

By 2030, polymer fuel cells worldwide could be saving every year more CO2 than the UK will emit.

The £8 million Polymer Fuel Cell Challenge will be split into two phases.  A call for proposals opening today (carbontrust.co.uk/fuelcells) will lead to the selection of up to three novel ideas, offering up to £1m per project to further develop and prove them. If one of these demonstrates its potential for lower-cost fuel cell systems, the Carbon Trust will then co-invest up to £5m in the technology to develop it commercially.

Fuel cells in the UK

The UK is one of the leading fuel cell research hubs in the world, drawing on the country’s strong materials science and chemistry research base as well as recent novel ideas from outside the fuel cell community.  Examples of this technology transfer are the adaptation of a water filtration membrane to make fuel cells, or the use of plastic materials originally developed for contact lenses.

Polymer fuel cells

Of the several different types of fuel cell, polymer fuel cells (also known as PEM fuel cells) are the most commonly-used.  They are based around a plastic, or polymer, membrane which carries the ions that move electrical charge inside the fuel cell.  Polymer fuel cells are light weight, powerful and increasingly durable, but are currently expensive.  The Carbon Trust is focussing on polymer fuel cells for three reasons: (i) they can be used in many different products, including all the applications with a strong prospect for carbon savings (cars, buses, combined heat and power); (ii) the horizontal structure of the polymer fuel cell supply chain allows the development of new businesses to market component technologies rather than requiring the development of completely new systems; and (iii) there is capacity and appetite from the UK research and industry community to deliver breakthrough polymer fuel cell technologies, which the Carbon Trust has confirmed with extensive recent engagement.

The Carbon Trust

• The Carbon Trust is an independent company set up in 2001 by Government in response to the threat of climate change, to accelerate the move to a low carbon economy by working with organisations to reduce carbon emissions and develop commercial low carbon technologies.
• We cut carbon emissions now by giving business and the public sector expert advice, finance and certification to help them reduce their carbon footprint and to stimulate demand for low carbon products and services.
• Through our work, we’ve already helped save over 23 million tonnes of carbon, delivering costs savings of around £1.4 billion. We aim to help our customers cut a further 17MtCO2 and save another £1 billion in the next three years.
• In the past year, the Carbon Trust has supported 30,000 customers, saving companies up to £227 million in direct costs and cutting up to 2 million tonnes of carbon dioxide from their annual emissions.
• We cut future carbon emissions by developing new low carbon technologies. We are helping the UK become a global hub for low carbon innovation. We do this through funding and managing projects, investing and collaborating on low carbon technologies and by identifying market barriers and practical ways to overcome them. Our work on commercialising new technologies will  deliver savings of up to 23 million tonnes of carbon a year by 2050.
• The Carbon Trust is also undertaking world leading projects on offshore wind, algae and advanced solar power.

IDAHO FALLS — Hydrogen researchers at the U.S. Department of Energy’s Idaho National Laboratory have reached another milestone on the road to reducing carbon emissions and protecting the nation against the effects of peaking world oil production.

Stephen Herring, laboratory fellow and technical director of the INL High Temperature Electrolysis team, today announced that the latest fuel cell modification has set a new mark in endurance. The group’s Integrated Laboratory Scale experiment has now operated continuously for 2,583 hours at higher efficiencies than previously attained.

“I’m very much encouraged that it will be able to operate for longer periods of time,” said Herring. “It means that this research is closer to commercial viability.”

The commercial viability that Herring spoke about is likely different than what many may think of when they hear about hydrogen and fuel cells. Instead of working to create vehicles that use pure hydrogen as fuel, Herring and his team are focused on another application.

Currently, “gasoline and diesel fuel actually have a lot of hydrogen that has been added to them, and that’s one thing many people don’t recognize,” said Herring. “Next to a refinery, there’s often a plant that’s making hydrogen used for upgrading.”

If that hydrogen can be produced more efficiently, by decreasing the amount of electricity required by the electrolysis process that separates hydrogen from oxygen in water, there’s the potential for large savings.

Perhaps even more motivating is that multiple government, corporate and other organizations have published reports pointing to severe world economic consequences when world oil production peaks sometime in the near future. Those same reports identify that one of the key parts of a solution is being able to upgrade lower quality petroleum, from sources like oil sands in Canada, into transportation-grade fuels.

“The production of liquid fuels, such as gasoline or diesel, is the primary use of this hydrogen.  Refining poor-quality crude oils, upgrading the tar-like Canadian oil sands and removing sulfur from petroleum already require large amounts of hydrogen,” said Herring.

By adding a special coating to the cells used in the latest test, the team achieved more than double the lifetime of previous cells and will immediately begin analysis of the experiment to try to improve the design further.

“It has been a lot of work by a number of people here, particularly Lisa Moore-McAteer, Keith Condie, Carl Stoots and Jim O’Brien,” said Herring. “They’ve really worked hard in putting this all together over the last five or six years and then keeping it running, that’s always a real challenge.”

INL is one of the DOE’s 10 multiprogram national laboratories. The laboratory performs work in each of the strategic goal areas of DOE: energy, national security, science and environment. INL is the nation’s leading center for nuclear energy research and development. Day-to-day management and operation of the laboratory is the responsibility of Battelle Energy Alliance.

3M to Provide Membrane Electrode Assemblies for Product Used by Tata

Loughborough–Following the recent opening of the Aerotec Fuel Cell Test Centre in Hamburg, clean power systems company, Intelligent Energy, announced today that it has provided leading aircraft manufacturer Airbus with a multi-functional fuel cell auxiliary power unit (APU) aimed at on-board power and other loads in future commercial airliners.

In front of Intelligent Energy's fuel cell APU, Dr. Gerald Weber, Managing Director of Operations AIRBUS GmbH (right) formally opens the Aerotec Fuel Cell Test Centre with the Centre's Managing Director, Rainer Feddersen

In August 2009, Dr. Gerald Weber, Managing Director of Operations AIRBUS GmbH formally opened the Aerotec Fuel Cell Test Centre which was set up to test fuel cell systems for use on-board commercial aircraft. The opening ceremony featured an Intelligent Energy fuel cell system designed for multi-functional on-board power supply in commercial airliners.

Fuel cells are highly efficient devices, which could provide power for various applications in the aircraft cabin, thereby relieving the drain on the main engines. They will reduce carbon dioxide production in the air and on the ground at airports, thus making a significant contribution to emissions reduction.

Intelligent Energy CEO, Henri Winand said “The advantage of incorporating hydrogen fuel cell technology into aviation is multi-faceted and part of the movement towards “more electric aircraft”. Not only do fuel cells reduce emissions and decrease fuel consumption but as we move to a lower carbon economy, the airlines can diversify their fuel supply base, becoming less exposed to volatility in fuel prices.”

The clean APU is designed around Intelligent Energy’s common core fuel cell systems already utilised in motive programmes such as Intelligent Energy’s fuel cell hybrid London taxi and in distributed power work with Scottish and Southern Energy plc.  Henri Winand added “Intelligent Energy operates a focused, working capital efficient “design once, deploy many times” market development approach for our power systems, which allows our customers operating in different market segments to benefit from commercialisation in other non competing markets”.

Airbus has already been investigating how hydrogen fuel cells can provide power for aircraft and has previously tested a hydrogen and oxygen-based fuel cell system on board their A320 test aircraft. The fuel cell system powers the aircraft’s back-up hydraulic and electric power systems, as well as operating the ailerons.

In February 2008, using a similar type of power system, Intelligent Energy first demonstrated its aviation credentials when it provided the system to Boeing which powered the World’s first manned fuel cell aircraft.

About Intelligent Energy
Intelligent Energy is a clean power systems company, with a range of leading fuel cell and hydrogen generation technologies. The company is focused on the provision of cleaner power and low carbon technologies. Intelligent Energy partners with leading companies globally, in the transportation, oil and gas, aerospace, defence, distributed generation and portable power markets. Current partners and customers include Scottish & Southern Energy plc with whom the company has formed a joint venture to commercialise fuel cell combined heat and power (CHP) systems, and The Suzuki Motor Corporation. Intelligent Energy’s successes in recent years include the development of the world’s first hydrogen fuel cell motorbike and supplying the fuel cell system to Boeing which powered the world’s first manned fuel cell aircraft.

We are pleased to inform you that Suzuki will have a major presence at the Tokyo Motor Show 2009, which will be held at the Makuhari Messe International Convention Complex in Chiba City from 21 October to 4 November 2009. It will be organized by the Japan Automobile Manufacturers Association.

At the 2009 Tokyo Motor Show, the Suzuki booth will bring together automobiles, motorcycles, power-assisted bicycles, and electric wheelchairs under an overall theme of “small cars for a big future”. As well as showing Suzuki products, it will highlight the company’s future-oriented initiatives. Visitors will see how Suzuki’s automaking spirit and technologies realize exciting lifestyle possibilities.

* SX4-FCV (Fuel-Cell Vehicle)

The SX4-FCV combines a General Motors-produced high-performance fuel cell with a Suzuki-developed high-pressure (70MPa) hydrogen tank and a light, compact capacitor, which promotes driving performance by recovering energy during brake application and using it to reduce fuel-cell loading during acceleration. With a view to commercializing the SX4-FCV, Suzuki is testing it on public roads with government approval and using the resulting data in ongoing development.

* MIO (Fuel-Cell-Powered Electric Wheelchair)

Suzuki’s MIO electric wheelchair is powered by a direct-methanol fuel cell rather than by a conventional lead-acid battery. The methanol solution is held in a cartridge-type bottle that’s easy to replace with a full spare one, so the user gains extra freedom and doesn’t need to worry about running out of fuel on the road. Suzuki began joint trials of the MIO with the Shizuoka prefectural government in November 2008 with a view to enhancing its reliability ready for commercialization.

* Burgman Fuel-Cell Scooter

Having stunned the motorcycling world with the Crosscage fuel-cell bike at the 2007 Tokyo Motor Show, Suzuki applied the technologies to a more practical and accessible form of two-wheel transportation: a scooter. The result is the Burgman Fuel-Cell Scooter. The fuel cell is air-cooled and concomitantly light, compact, and structurally simple. A 70MPa hydrogen tank (the highest-pressure tank used on a bike thus far) allows a usable riding range. And the tank is mounted within a robust frame for safety.

Lewis Center, OH –NexTech Materials, Ltd. announces its selection for a U.S. Department of Energy Phase I SBIR Award on “Manufacturing Analysis of SOFC Interconnect Coating Processes.” In this effort, NexTech’s Commercial Services Division will perform a techno-economic analysis of oxide coating processes for the metallic interconnects of solid oxide fuel cell (SOFC) stacks, leveraging proprietary materials and process technology.

NexTech, which has developed several interconnect coating processes, will evaluate these methods independently and in collaboration with SOFC developers, to determine which are best suited to large-scale manufacturing. Interconnect coatings are essential for long-term stable operation of SOFCs, providing protection against corrosion by process gases and seal materials, while maintaining electrical contact between cells in the stack. The coatings must be stable for 5,000 to 40,000 hours to meet the demands of mobile and stationary applications. Future activities will focus on removing technical barriers to scale-up, performing coating trials on production-intent equipment and interconnects, and demonstrating interconnect performance in collaboration with SOFC developers in the DOE SECA program and other manufacturers world-wide.

Mr. Bill Dawson, NexTech’s CEO, stated, “This award highlights the technical strength of our Commercial Services business. Our team’s design-neutrality, coupled with NexTech’s vertical integration from raw materials to volume-manufactured components is unique in our markets. We are thrilled to have this award–it will allow NexTech to continue to offer clients access to market-leading materials and process technology.”

Dr. Matthew Seabaugh, Director of Commercial Services, commented “This award marks an important milestone in NexTech’s Commercial Services growth. The technical and economic analysis outlined in this program will allow us to provide even better solutions to our customers. It will allow us to build on our track record of innovation and of providing value-added solutions to developers of all sizes.”

About NexTech Materials

NexTech’s vision is to be a global leader in the development and manufacturing of innovative products for energy and environmental markets. NexTech is a leading developer and supplier of materials, components and services for the fuel cell industry and is dedicated to reducing the manufacturing and operating costs of fuel cells and other electrochemical devices. NexTech’s customers are located in over 35 countries and include leading researchers, developers and manufacturers throughout the world. NexTech Materials, Ltd. was founded as a privately held company in 1994 and has grown into one of Ohio’s leading technology companies. NexTech recently expanded its manufacturing and R&D facilities located in Lewis Center Ohio. NexTech has many products in the pipeline including fuel cell stacks for military and residential power applications, sensors for gas detection and control systems, catalysts for energy conversion systems, and membranes for gas separation devices. www.nextechmaterials.com

Researchers created material under enormous pressures by squeezing samples between two diamonds. (Photo courtesy Wendy Mao, SIMES.)

Researchers at the Stanford Institute for Materials and Energy Science, a joint institute of DOE’s SLAC National Accelerator Laboratory and Stanford University, have produced a hydrogen-rich alloy that could provide insight into the properties of metallic hydrogen. The work is a step toward materials with revolutionary implications for energy science, enabling lossless power transmission, next-generation particle accelerators and even magnetic levitation.

Metallic hydrogen is a state of hydrogen predicted to form under ultra-high pressure. If achieved, it could function as a room-temperature superconductor—a material capable of conducting electricity with no resistance at temperatures above 0 degrees Celsius. But because the pressure required to make metallic hydrogen is so enormous—much greater the pressure experienced by materials in the center of the earth—researchers have had little luck in producing it.

To better understand how metallic hydrogen behaves, researchers are becoming increasingly interested in hydrogen-rich compounds that might have properties similar to those seen in pure hydrogen, but at more accessible pressures. One of the most promising candidates is called silane, which contains an atom of silicon bound to four atoms of hydrogen. The goal for the SIMES group was to study the properties of alloys composed of hydrogen and silane together.

The group found that the alloys solidified at much lower pressures than would be required for hydrogen alone, with the hydrogen-rich alloy forming a solid containing more than 99 percent hydrogen. They also discovered that even though the amount of silane in the hydrogen-rich sample was minimal, it had a dramatic effect on hydrogen-hydrogen interactions.

According to Shibing Wang, a SIMES graduate student and the lead author on the paper, the finding is significant because it could contribute to a better understanding of the properties of atoms in hydrogen alloys, which are commonly used in hydrogen storage and could have implications for hydrogen fuel storage.

Frankfurt– Carmakers around the world are trying to come up with a workable hydrogen fuel source which will help solve one of the major problems facing electrically-driven cars, namely the limited range they offer. Lithium-ion batteries are the power pack of choice but these tend to run down quickly, with the result that most electric cars cannot travel for long distances between recharges. A hydrogen-powered car using a fuel cell to convert chemical into electrical energy is seen as a viable alternative.

Germany’s Daimler has put its faith in the new technology and the company has successfully operated a fleet of hydrogen fuel-cell-driven buses in Hamburg for the past three years. From 2015 it intends to team up with other concerns such as Shell or gas manufacturer Linde to set up a countrywide network of hydrogen refuelling stations.

Automotive researchers admit that the road to a hydrogen-powered future is not without obstacles. The production and storage of the ethereal gas can cause headaches, said Ulrich Hoepfner of the Institute for Energy and Environmental Research in Heidelberg.

Hydrogen must first of all be obtained from water using a process of electrolysis which consumes large quantities of energy. The hydrogen enters the fuel cell which operates very much like a battery, producing electricity directly from the electrochemical reaction between the hydrogen and oxygen in the air. This energy needs to be stored in batteries and the transfer leads to a larger loss of electricity than if a battery was charged up by being simply plugged into the mains electricity supply.

“You have to use up three times as much energy,” said Hoepfner. If the energy used to make hydrogen comes from a conventional coal-fired power station the advantage of using the futuristic fuel are quickly cancelled out. The car industry is aware of the problems but solutions are at hand.

“Looked at from today’s point of view hydrogen has the potential to replace fossil fuels such as petrol and diesel,” said the German Automobile Federation in a brochure at the recent Frankfurt IAA car show.

At the same time, producing hydrogen only makes sense if this can be done with regenerative energy sources.

Storage is another bugbear. Hydrogen is a very volatile substance which is easily dispersed. “Hydrogen seeps out everywhere,” said Hoepfner. It has to be kept under high pressure or in liquid form. In order to liquidise hydrogen it must be cooled to minus 250 degrees celsius.

This devours energy and large tanks are need to store the hydrogen. “The whole storage issue is tricky,” said Maximilian Prager who carries out research into combustion engines at the technical university in Munich. The necessary equipment uses a lot of energy too since it has to neutralise the considerable temperature variations. Pressure storage is cheaper.

Prager played down the potential security risks of tanks containing the highly-combustible substance: “My personal view is that hydrogen is no more dangerous than petrol, since it dissipates very quickly.”The fuel cell method favoured by Daimler, by which hydrogen reacts with oxygen, does not represent the last word on the subject.

Rivals BMW in Munich have pinned their hopes on burning hydrogen in a conventional combustion engine and have been experimenting with the technology for two decades. “Hydrogen-power can be realised more quickly using a conventional engine which has the advantage of being able to operate even with mildly contaminated hydrogen,” said Prager. Such engines have also been shown to cope better with power peaks such as periods of hard acceleration on the motorway.

Dr. Gerardine Botte watches a hydrogen fuel cell run in her lab at the Stocker Center at Ohio University.

Driving home from a seminar on fuel cell technology, Gerardine Botte was struck with a notion.

Her idea was based on water electrolysis, a process used to produce hydrogen energy from water. Botte, an associate professor of chemical and biomolecular engineering in the Russ College of Engineering and Technology, took the concept to the next level: Instead of clean water, what if it were possible to use wastewater?

“You could remove the ammonia from wastewater, convert it to hydrogen energy, and it would be better, because you’d be remediating and producing clean energy,” says Botte.

What resulted was a first-of-its-kind fuel cell technology, known as the “ammonia electrolytic cell,” that allows hydrogen to be produced on demand. It’s an efficient and environmentally sound process; compared to water electrolysis, ammonia electrolysis consumes 95 percent less energy and produces more hydrogen.

The ammonia itself comes from a renewable supply. Botte estimates more than 5 million tons of ammonia enter the waste stream as human and animal urine each year in the United States.

If it seems like an unlikely fuel source, Botte will do her best to convince you otherwise. “I think ammonia is our future fuel,” she says. “It’s green, renewable, and we know how to transport it and work with it.”

Since its inception, Botte’s idea of ammonia electrolysis has blossomed into several projects. At Ohio University, she enlists the help of five graduate students who each cover specific branches of ammonia electrolysis research, including potential automobile and residential applications.

In November, Botte’s Electrochemical Engineering Research Laboratory received a $2.23 million federal grant to adapt the concept for military use. Under the “Silent Camp Initiative,” she’ll work with the U.S. Army Engineer Research and Development Center’s Construction, Engineering Research Laboratory to provide backup power for training facilities and soldier camps at night.

The system could cut long-term costs for fuel and decrease susceptibility to attacks against fuel supply lines.

If successful, there could be promising potential for the commercialization of the ammonia electrolytic cell.

Botte takes pride in the fact that the cell had its beginnings at Ohio University. “It was born here and is unique to this university,” she says.

Premier Gordon Campbell helped to welcome ‘Bus 1’, the first of BC Transit’s fleet of 20 hydrogen fuel cell buses. The fleet begins operation in Whistler next month.

Premier Gordon Campbell and Minister of International Trade and Minister for the Asia-Pacific Gateway Stockwell Day celebrated the arrival of the first bus of what will become the world’s largest single hydrogen fuel cell bus fleet today in Vancouver.

“The arrival of “Bus 1” of the hydrogen fuel cell bus is a major step forward as we work to build a Hydrogen Highway that stretches from Whistler to Victoria and beyond,” said Premier Campbell.  “This fleet will reduce greenhouse gas emissions by 1,800 tonnes per year in B.C. and – when the world comes to our province in 2010 – it will showcase British Columbia’s expertise in cutting-edge hydrogen and fuel cell technology to the world.”

“Our government is proud that our country’s first hydrogen fuel cell bus is being unveiled today, to be used during the 2010 Olympics,” said Minister Day.  “By investing in the development of green buses and refueling stations, we are creating jobs today and also ensuring that British Columbia is a world leader in hydrogen fuel cell technology.”

The 20 hydrogen fuel cell buses will be in operation as part of the BC Transit fleet in Whistler during the 2010 Olympic and Paralympic Winter Games and beyond.  It will be the world’s largest hydrogen fuel cell bus fleet operating in a single location.

“The introduction of this new bus represents a major milestone for BC Transit. Not only is it the first hydrogen bus, but it’s also the thousandth bus within our fleet,” said BC Transit president and CEO Manuel Achadinha. “This bus, along with the other 19, represents our ongoing commitment to investing in greener technologies.”

Total funding for the hydrogen fuel cell bus project, covering capital and operating costs to March 2014, is $89.5 million.  $45 million is from the Government of Canada and $44.5 million is from the Province and BC Transit.

The development of a hydrogen bus fleet is part of B.C.’s commitment to fuel cell technologies and the Hydrogen Highway as part of the overall plan to cut greenhouse gas emissions by 33 per cent by 2020. The Hydrogen Highway is a government-industry initiative seeking to accelerate the demonstration and commercialization of hydrogen and fuel cell technologies from British Columbia to California. For more information on the Hydrogen Highway, go to: www.hydrogenhighway.ca

The new buses produce no smog-creating emissions and no greenhouse gases at the tailpipe.  Hydrogen is combined with oxygen in the fuel cell to electrochemically produce electricity.  Heat and water are the only by-products.  Operating 20 fuel cell buses over one year will eliminate more than 1800 tonnes of greenhouse gas emissions, compared to a diesel fleet of the same number of buses.

By 2020, the $14 billion Provincial Transit Plan will reduce greenhouse gas emissions by 4.7 million tonnes cumulatively and double transit ridership to more than 400 million trips per year.

The modified Toshiba T002 handset

The latest prototype cell phone based on a direct methanol fuel cell (DMFC) made its debut on Tuesday at the Ceatec show in Japan.

The modified Toshiba T002 handset is being shown by Japanese carrier KDDI as a research and development device and shows some improvements in technology based on previous prototypes, but there’s still no word on when a phone based on the technology will be available.

DMFCs produce electricity from a reaction between methanol, water and air. The only by-products are a small amount of water vapor and carbon dioxide, so DMFCs are often seen as a greener source of energy than traditional batteries.

In the prototype mobile phone, the fuel-cell unit also includes a lithium ion battery. The battery is needed to cope with the spikes in power demand from the mobile phone between times when it sits idle and when it’s used to make a call or browse the web. The fuel cell is best suited to supplying a constant amount of power so the battery acts as a buffer to ensure the mobile phone works smoothly.

That combination gives the phone an overall life, on a single charge of methanol, of about 320 hours. That’s about three days longer than the commercial T002 phone can manage.

But the biggest advantage of DFMC isn’t the longer battery life but that it can be refilled in seconds with a squirt of methanol rather than having to wait an hour or two for the battery to be recharged.

For now, the addition of a fuel cell means the phone’s thickness is about twice that of the equivalent commercial version of the phone. But at 22 millimetres this latest version is about half the thickness of a prototype shown several years ago and KDDI said it continues to work towards a thinner handset.

The phone is based on a fuel cell developed by Toshiba.

Toshiba has been promising a commercial battery charger based on the same fuel-cell technology for several months but has yet to announce a commercial product. Two months ago, the company’s new president said it would be launched by the end of September but that deadline passed a few days ago without anymore information on the device.

The charger will be a portable device that can be used to charge the batteries in portable gadgets such as mobile phones, music players and portable game devices instead of plugging them into an electrical outlet.

VANCOUVER–Ballard Power Systems (TSX: BLD; NASDAQ: BLDP) congratulates BC Transit, the Province of British Columbia, the Government of Canada, and its consortium partners on the introduction of the first bus in BC Transit’s fleet of 20 hydrogen fuel cell buses. Representatives from Ballard were on site as Premier Gordon Campbell unveiled “Bus 1″ on Friday, October 3, 2009 in Vancouver. BC Transit’s fleet will become the largest single deployment of zero-emission fuel cell buses worldwide and it is powered by Ballard’s heavy-duty fuel cell module, the FCvelocity(TM)-HD6.

“All of us at Ballard are proud of to be partners in helping BC lead the way in adopting new technologies that support sustainable practices and reduce greenhouse gas emissions,” said John Sheridan, Ballard’s President and Chief Executive Officer. “The BC Transit fuel cell bus fleet is an important proof point for the level of robustness and durability offered by Ballard clean energy products – not only in buses but also in material handling and stationary power.”

Fuel cell buses are zero-emission vehicles, with no greenhouse gases, particulates, or harmful emissions released during operation. Water is the only byproduct. BC Transit’s fleet of fuel cell buses is expected to reduce greenhouse gas emissions by around 1,800 tonnes per year in British Columbia.

Ballard’s FCvelocity(TM)-HD6 is ideal for integration into bus applications. It is designed to be a plug-and-play solution for any fuel cell or hybrid fuel cell bus platform and to be robust and durable in harsh motive conditions. The BC Transit fleet is the first that incorporates Ballard’s heavy-duty fuel cell module into a hybrid fuel cell/battery architecture with an electric drive, which enables higher vehicle efficiency and improved fuel cell durability.

BC Transit’s fleet of fuel cell buses will operate in revenue service in the Resort Municipality of Whistler, British Columbia during the 2010 Olympic and Paralympic Winter Games and beyond.

About Ballard Power Systems

Ballard Power Systems (TSX: BLD; NASDAQ: BLDP) is recognized as a world leader in the design, development, manufacture and sale of clean energy fuel cell products. Ballard’s mission is to accelerate fuel cell product adoption. To learn more about what Ballard is doing with Power to Change the World(R), visit www.ballard.com.

Berlin, Germany–Heliocentris Fuel Cells AG, a leading system integrator for fuel cells, announces its acquisition of a major order for the delivery of an autonomous power supply solution for the University of Applied Sciences Wildau in Germany. The complete solution will be used to supply energy to selected applications in a building and shall serve as a link between training and applied research. The project has a total volume of nearly half a million Euros.

The complete solution is a hybrid energy storage system consisting of a battery, fuel cell, electrolyser and adapted power electronics that can store solar or wind-generated power to be generated in the building. This allows for a self-sufficient total solution regardless of solar radiation or wind availability. In addition to the integration of four of the just launched Heliocentris Nexa 1200 fuel cell systems, one of the key aspects of the project is the development of hardware and software for energy management. The energy management delivered by Heliocentris will manage and optimise all energy flows within the system to ensure maximum availability of energy. It is planned to further optimise the energy management jointly with the customer during the test phase of the solution.

Dr. Henrik Colell, CEO, commented: “We are proud to be able to realise such a completely integrated solution for a customer and therefore consider ourselves very much in line with the trend of offering intelligent storage solutions for renewable energies. Heliocentris’ expertise in hydrogen and fuel cells, as well as in providing management solutions for more complex energy systems will come to fruition in this project.”

Thomas Lehne, Chancellor of the University of Applied Sciences Wildau: “The Department Physics Engineering is one of the leading of our strongly research oriented University. We have the expectation that the cooperation with Heliocentris will not be limited to the pure power supply technology but will lead to new impulses also in the field of energy management of renewable energies.”

EHS System Being Developed to Separate Pure Hydrogen to Enable Green Industrial and Transportation Applications

DANBURY, Conn. — FuelCell Energy, Inc. (Nasdaq:FCEL), a leading manufacturer of high efficiency ultra-clean power plants using renewable and other fuels for commercial, industrial, government, and utility customers, today announced that the U.S. Department of Defense’s Engineer Research and Development Center – Construction Engineering Research Laboratory (ERDC-CERL) awarded it approximately $1.5 million to continue development of its electrochemical hydrogen separator (EHS). The EHS system separates pure hydrogen from gas internally generated in a fuel cell that can be used for industrial and transportation applications.

The EHS research contributes to the development of FuelCell Energy’s DFC-H2 product. The DFC-H2 integrates an EHS system with the company’s high-efficiency Direct FuelCell (DFC) power plant to produce ultra-clean electricity, heat and pure hydrogen. A DFC300 combined with an EHS would produce 300 kilowatts of power, heat for combined heat and power applications, and up to 300 lbs. per day of hydrogen. If successful, this combination may produce hydrogen more economically than other methods.

“This award recognizes our expertise in electrochemical separation technology and the opportunity to further develop our fuel cell technology,” said Christopher Bentley, Executive Vice President, Government Research and Development Operations for FuelCell Energy. “It also confirms the Department of Defense’s continued commitment to support the development of innovative technologies.”

Conventional methods of separating hydrogen rely on a complex separation step using mechanical compression. FuelCell Energy’s proprietary EHS technology has no moving parts and does not use compression, potentially offering higher reliability and efficiency, resulting in the need for only half the energy compared to conventional compression methods of producing hydrogen.

FuelCell Energy’s DFC stationary power plants use biofuels and fossil fuels more efficiently than the electric grid and other distributed generation their size. Their high efficiency results in low CO2 and, because they produce power without combustion, they produce near-zero nitrous oxides, sulfur oxides, and particulate matter.

The $1.5 million ERDC-CERL program will span twenty months and will support the scale-up of the EHS technology and establish readiness for a field demonstration.

BRUNNTHAL/MUNICH– SFC Smart Fuel Cell AG, leading supplier of fuel cell products for mobile and off-grid power applications, today announced the launch of the EMILY 2200 fuel cell at the 2009 AUSA Annual Meeting & Exposition in Washington, D.C. The EMILY 2200 fuel cell delivers long lasting, reliable power supply for on- and off-vehicle defense applications.

Integrated into tactical vehicles or in the field, the fuel cell operates as a ruggedized fuel cell power generator.  As an auxiliary power unit onboard military vehicles, the EMILY 2200 keeps vehicle batteries charged automatically, reliably, quietly and virtually emission-free. It delivers power for devices ranging from radios and other communication equipment to night-vision goggles, navigation devices and computers. The EMILY 2200 is undetectable by sound or smell and generates power almost imperceptibly — eliminating the need to start a vehicle’s engine to charge batteries.

Off-vehicle, the EMILY 2200 provides power for mobile and stationary defense applications. It is being used in unmanned applications as well as a field-based charging station for batteries. It also can be combined with other alternative power sources like solar or wind. The EMILY 2200 continues to produce maintenance-free electrical power for several weeks.

For operation, the EMILY uses a fuel cartridge; for example, a 10-liter cartridge weighing 8 kg (18 lbs) has enough capacity for more than 10 kWh. This fuel cartridge is sufficient to power devices for more than 100 hours.

“With the EMILY 2200 we offer soldiers in the field a mobile, fuel-cell-based energy supply that guarantees reliable, lightweight and emission-free power, both on-vehicle and off-vehicle,” said Dr. Peter Podesser, CEO of SFC Smart Fuel Cell. “Due to its flexibility, the EMILY 2200 makes an important contribution to the safety, effectiveness, higher mobility and energy efficiency of soldiers on missions.”

The EMILY 2200 underscores SFC Smart Fuel Cell’s leadership in off-grid energy solutions based on fuel cells. In the past five years the company has sold more than 15,000 fuel cell products. The M-25 Portable Fuel Cell System and the JENNY fuel cell won first and third prizes in the U.S. Department of Defense’s 2008 Wearable Power Competition. Moreover, SFC has created an efficient energy network by combining intelligent power solutions, the JENNY and the SFC Power Manager. In combination, the JENNY and the SFC Power Manager can recharge several batteries and power a variety of equipment at the same time. This energy network delivers a maximum of power and flexibility, while significantly reducing battery weight for soldiers in the field.

SFC Smart Fuel Cell will demonstrate the EMILY 2200 and its energy network during the AUSA Annual Meeting & Exposition:·

The hydrogen fuel cell is lifted from the transportation platform and placed alongside the Connecticut Science Center

The first step towards becoming the nation’s FIRST science center or museum to use a hydrogen fuel cell to provide the majority of its power needs was taken today.

A 200kw UTC Power hydrogen fuel cell was “planted” on the south side of the Science Center.

Once the two month installation process is completed, clean energy will be supplied onsite, reducing the carbon footprint of the cutting-edge Science Center even further.

Over the course of the year the net result of the power produced by the fuel cell and what the Science Center needs in terms of power will equal out, eliminating dependence on the power supply grid system.

The 200-kilowatt fuel cell, built by UTC Power, a United Technologies Corp. business based in South Windsor, will generate 100 percent of the electricity the science center uses.

The fuel cell also will have an educational component. It will be covered by a permanent graphic wrap, like the tarp covering the cell above, showing how it works. “We’re trying to raise public awareness so people can understand what fuel cells are,” said Peg Hashem, a spokeswoman for UTC Power.

UTC fuel cells power buildings, cars and buses. Also, UTC fuel cells have provided power and drinking water on U.S. manned space flights since 1966, company officials said.

Professor Meilin Liu provides a closer look at the anode side of a laboratory-scale button fuel cell, which includes the new material. Shown (left to right) are Mingfei Liu, Meilin Liu, Kevin Blinn, and Lei Yang. (Photo: Gary Meek)

Devices Can Directly Use a Wide Range of Fuels

Atlanta–A new ceramic material described in this week’s issue of the journal Science could help expand the applications for solid oxide fuel cells—devices that generate electricity directly from a wide range of liquid or gaseous fuels without the need to separate hydrogen.

Though the long-term durability of the new mixed ion conductor material must still be proven, its development could address two of the most vexing problems facing the solid oxide fuel cells: tolerance of sulfur in fuels and resistance to carbon build-up known as coking. The new material could also allow solid oxide fuel cells—which convert fuel to electricity more efficiently than other fuel cells—to operate at lower temperatures, potentially reducing material and fabrication costs.

“The development of this material suggests that we could have a much less expensive solid oxide fuel cell, and that it could be more compact, which would increase the range of potential applications,” said Meilin Liu, a Regent’s professor in the School of Materials Science and Engineering at the Georgia Institute of Technology. “This new material would potentially allow the fuel cells to run with dirty hydrocarbon fuels without the need to clean them and supply water.”

The research was supported by the U.S. Department of Energy’s Basic Energy Science Catalysis Science Program.

Like all fuel cells, solid oxide fuel cells (SOFCs) use an electrochemical process to produce electricity by oxidizing a fuel. As the name implies, SOFCs use a ceramic electrolyte, a material known as yttria-stabilized zirconia (YSZ).

The fuel cell’s anode uses a composite consisting of YSZ and the metal nickel. This anode provides excellent catalytic activity for fuel oxidation, good conductivity for collecting current generated, and compatibility with the cell’s electrolyte—which is also YSZ.

But the material has three significant drawbacks: even small amounts of sulfur in fuel “poison” the anode to dramatically reduce efficiency, the use of hydrocarbon fuels creates carbon build-up which clogs the anode—and because YSZ has limited conductivity at low temperatures—SOFCs must operate at high temperatures.

As a result, fuels used in SOFCs, such as natural gas or propane, must be purified to remove sulfur, which increases their cost. Water in the form of steam must also be supplied to a reformer that converts hydrocarbons to hydrogen and carbon monoxide before being fed to the fuel cells, adding complexity to the overall system and reducing energy efficiency. And the high-temperature operation means the cells must be fabricated from costly exotic materials, which keeps SOFCs too expensive for many applications.

The new material developed at Georgia Tech addresses all three of those anode issues. Referred to as BZCYYb as shorthand for its complex composition, the material tolerates hydrogen sulfide in concentrations as high as 50 parts-per-million, does not accumulate carbon—and can operate efficiently at temperatures as low as 500 degrees Celsius.

The BZCYYb (Barium-Zirconium-Cerium-Yttrium-Ytterbium Oxide) material could be used in a variety of ways: as a coating on the traditional Ni-YSZ anode, as a replacement for the YSZ in the anode and as a replacement for the entire YSZ electrolyte system. Liu believes the first two options are more viable.

So far, the new material has provided steady performance for up to 1,000 hours of operation in a small laboratory-scale SOFC. To be commercially viable, however, the material will have to be proven in operation for up to five years—the expected lifespan of a commercial SOFC.

“We don’t see any problems ahead for fabrication or other issues that might prevent scale-up,” said Liu. “The material is produced using standard solid-state reactions and is straightforward.”

The researchers don’t yet understand how their new material resists deactivation by sulfur and carbon, but theorize that it may provide enhanced catalytic activity for oxidizing sulfur and both cracking and reforming hydrocarbons.

In addition to its tolerance of sulfur and resistance to coking, the BZCYYb material’s conductivity at lower temperature could also provide a significant advantage for SOFCs.

“If we could reduce operating temperatures to 500 or 600 degrees Celsius, that would allow us to use less expensive metals as interconnects,” Liu noted. “Getting the temperature down to 300 to 400 degrees could allow use of much less expensive materials in the packaging, which would dramatically reduce the cost of these systems.”

Beyond its use in fuel cells, the material developed by Liu and his team—which also included Lei Yang, Shizhong Wang, Kevin Blinn, Mingfei Liu, Ze Liu and Zhe Cheng—could also be used for fuel reforming to feed other types of fuel cells.

Though the technology for solid oxide fuel cells is currently less mature than that for other types of fuel cells, Liu believes SOFCs will ultimately win out because they don’t require precious metals such as platinum and their efficiency can be higher—as much as 80 percent with co-generation use of waste heat.

“Solid oxide fuel cells offer high energy efficiency, the potential for direct utilization of all types of fuels including renewable biofuels, and the possibility of lower costs since they do not use any precious metals,” said Liu. “We are working to reduce the cost of solid oxide fuel cells to make them viable in many new applications, and this new material brings us much closer to doing that.”

This research was supported by the U.S. Department of Energy’s Basic Energy Science Catalysis Science Program under grant DE-FG02-06ER15837. The comments and conclusions in this document are those of the researchers and do not necessarily represent the views of the U.S. Department of Energy.

Heinsberg Fuel Cell Manufacturing Plant

Ceramic Fuel Cells Limited (AIM / ASX: CFU) a leading developer of high efficiency and low
emission power products for homes, today officially opened its high volume manufacturing plant, one of the first in the world for the volume production of solid oxide fuel cell stacks.

Ceramic Fuel Cells makes fuel cell ‘modules’ which appliance companies can integrate into different
products for many large global markets. The first products to be powered by the Company’s fuel
cells will be compact generators for homes and other buildings that produce low emission power as
well as heat for hot water or space heating. These products will meet the growing need for energy whilst also reducing greenhouse gas emissions.

The manufacturing plant is located in an existing 4,200m2 building in the Industriepark Oberbruch,
40 minutes’ drive from Dusseldorf in the North Rhine-Westphalia region of Germany.

The plant has a design capacity of 10,000 fuel cell stacks per year. Ceramic Fuel Cell’s investment
in the plant construction, including state of the art automated manufacturing equipment, will total 9.5 million Euros. All pieces of equipment have been commissioned on-site and are operational.

The plant was officially opened by Dr Jens Baganz, State Secretary for the Ministry of Economic
Affairs and Energy of the State of North Rhine-Westphalia, before more than 100 invited guests,
including Government representatives and key customers, suppliers, investors and media.

State Secretary Dr. Baganz welcomed the start of fuel cell production in Heinsberg: “Fuel cells with high efficiency are a key technology of the future with significant economic potential. In Oberbruch it is now possible that a future industry can be developed. Given the global challenges of climate change, there are very promising market opportunities for fuel cell technology.”

Ceramic Fuel Cells Chairman Mr Jeff Harding said: “On behalf of the Board of Ceramic Fuel Cells,
we are delighted to open our factory in Heinsberg, Germany. This is an important milestone for the
Company because it allows us to move from making expensive ‘hand built’ products to making semiautomatedmanufactured products at commercially competitive costs, and reflects two years’ work from our staff and key suppliers. We look forward to our Heinsberg plant making fuel cell stacks to go into our clean energy products for Europe, Australia and other global markets.”

The Company has employed four full time staff to manage the construction phase of the plant.

The Company expects to hire more local staff next year as production increases to meet orders.

Ceramic Fuel Cells is developing clean energy products with leading appliance partners and utility
customers in Germany, France, the United Kingdom and Japan. The Company has also developed
a modular power and heat generator called BlueGen which will be available to selected customers in Europe and Australia from early 2010.

To meet future growth the plant can be expanded to a capacity of up to 160,000 fuel cell stacks per year in the same building. The Company also holds an option over a nearby parcel of land for future ‘greenfield’ expansion.

Ceramic Fuel Cells Limited (AIM/ASX: CFU) – a leading developer of high efficiency and low
emission power products for homes – announces today that a leading Australian energy utility has
agreed to install a BlueGen gas-to-electricity generator in a showcase sustainability home.

BlueGen is the latest breakthrough in small scale electricity generation. About the size of a
dishwasher, each BlueGen unit can produce up to 17,000 kilowatt hours of power a year – twice the electricity needed to power an average home. Surplus electricity can be sold back to the grid.
Each BlueGen can cut a home’s carbon dioxide emissions by up to 12 tonnes a year compared to
New South Wales’ current black coal generators and by almost 18 tonnes a year compared to
Victoria’s brown coal generators.

Under the agreement with the utility Ceramic Fuel Cells will supply a BlueGen unit for a six month
demonstration, beginning in February 2010. BlueGen will be connected to the existing natural gas
pipeline and the power grid, and will generate low emission electricity for the house, as well as heat for the hot water system.

This is Ceramic Fuel Cells’ first commercial agreement with an Australian energy utility. The
Company is already deploying demonstration products with leading utility customers and appliance
companies in Germany, France and the United Kingdom.

Ceramic Fuel Cells’ technology has recorded the highest electrical efficiency ever achieved,
worldwide, from any technology that converts hydrocarbon fuels into electricity. It uses 95% less
water than brown coal-fired generators and when deployed in volume is forecast to generate
electricity up to 40% cheaper than the current retail price.