DANBURY, Conn.–Praxair, Inc. (NYSE: PX) and Praxair Canada have signed a strategic alliance with Powertech Labs, Inc. to jointly market and sell Praxair’s hydrogen and Powertech’s hydrogen fueling equipment to materials handling customers, specifically to distribution centers for hydrogen fuel-cell powered forklifts.

The alliance between Praxair and Powertech combines North America’s largest liquid hydrogen producer with a leader in innovative hydrogen fueling systems to provide reliable, cost-effective hydrogen fueling to fill a growing need. In 2002, Powertech designed and built the world’s first 700-bar fast-fill hydrogen fueling station, and has since designed, built and installed a host of increasingly innovative and technically advanced mobile and permanent high-pressure vehicle fueling systems.

“Praxair and Powertech bring many years of combined experience and expertise in both hydrogen supply and fueling equipment to successfully meet the growing needs of these leading-edge customers,” said Scott Sanderude, vice president, Marketing & Business Development, for Praxair’s North American Industrial Gases business unit.

“Powertech is a leader in providing clean energy consulting, testing and systems solutions,” said Eamonn Percy, PowerTech president. “Distribution centers with large materials handling fleets are realizing the benefits of hydrogen fuel-cell powered forklifts. This alliance will help increase their productivity while potentially decreasing costs associated with operating traditional battery-powered forklifts.”

About Powertech Labs, Inc.

Powertech Labs, based in Surrey, British Columbia, Canada, specializes in clean energy consulting, testing, and power solutions, and has been serving electrical, oil and gas companies, automotive and electrical equipment manufacturers since 1989 by meeting the complex and changing needs of customers around the world. As the world’s premier hydrogen fueling equipment testing facility, Powertech has played a key role in the development of hydrogen delivery infrastructure in North America. Powertech is a subsidiary of BC Hydro, the third largest electric utility in Canada.

About Praxair Canada, Inc.

Praxair Canada, part of Praxair’s North American operations, supplies atmospheric, process and specialty gases and is a recognized leader in the commercialization of new technologies that bring productivity and environmental benefits to a diverse group of industries.

About Praxair, Inc.

Praxair is the largest industrial gases company in North and South America, and one of the largest worldwide, with 2009 sales of $9 billion. The company produces, sells and distributes atmospheric, process and specialty gases, and high-performance surface coatings. Praxair is a recognized leader in the commercialization of new technologies that bring productivity and environmental benefits to a diverse group of industries, including aerospace, chemicals, electronics, energy, food and beverage, healthcare, manufacturing, metals and others. More information on Praxair is available on the Internet at www.praxair.com.

WILMINGTON, Mass. — Lilliputian Systems, a developer of portable power products for consumer electronic devices, will significantly expand its Wilmington manufacturing plant with help from a low-cost $5 million participation term loan issued by MassDevelopment and the Massachusetts Clean Energy Center.  MassDevelopment, the lead lender, is providing $2.5 million from its Emerging Technology Fund.  The Massachusetts Clean Energy Center (MassCEC) is also providing $2.5 million.

“High-tech manufacturing is a critical component of our economic future,” said MassDevelopment President and CEO Robert L. Culver.  ”We’re proud that Lilliputian Systems has chosen to expand in Wilmington and keep on making its innovative products in the Bay State.”

Lilliputian Systems plans to use the funds to purchase equipment used in manufacturing and assembling key components of the company’s portable power product, USB Mobile Power System, as part of an expansion of the Wilmington site.

Lilliputian Systems is developing a revolutionary portfolio of portable power solutions. The company’s breakthrough Silicon Power Cell™ technology enables the only form-factor battery replacement for portable electronic devices that provides an order-of-magnitude run-time improvement over traditional batteries. Lilliputian Systems’ innovative solutions will provide major improvements in the use of mobile devices today and deliver the energy needed to support the power-intensive application of tomorrow’s wireless world. The company is targeting applications for mobile devices such as: cell phones, smart phones, MP3 players, Bluetooth headsets and portable games; laptops, tablets, and netbooks; and digital recorders such as cameras and camcorders.  Lilliputian Systems has completed the prototype development of its first product, the USB Mobile Power System, and is currently testing devices and signing commercialization agreements with select customers around the world.

“We are encouraged by the State’s support of our business and we are pleased to be expanding the local economy and reinforcing our Massachusetts roots,” said Lilliputian Systems CEO Ken Lazarus. “The loan from MassDevelopment will help fund the expansion of our Wilmington operations to manufacture key components of our Silicon Power Cells for delivery to customers worldwide.”

“Lilliputian is one of the most exciting innovative clean energy companies choosing to expand in Massachusetts,” said MassCEC Executive Director Patrick Cloney. “We are thrilled that they chose the Commonwealth to manufacture this game-changing technology.”

About MassDevelopment

MassDevelopment, the state’s finance and development authority, works with businesses, financial institutions, and communities to stimulate economic growth across the Commonwealth.  During FY2009, MassDevelopment financed or managed 229 projects statewide representing the investment of nearly $1.2 billion in the Massachusetts economy. These projects are supporting the creation of 1,488 new housing units and 8,232 jobs: 3,362 permanent and 4,870 construction-related.

About Massachusetts Clean Energy Center

Created by the Green Jobs Act of 2008, the Massachusetts Clean Energy Center’s (MassCEC) mission is to foster the growth of the Massachusetts clean energy industry through seed grants to companies, universities, and nonprofit organizations, job training programs, workforce development grants, and support for renewable energy projects. As of November 23, 2009 MassCEC is the new home of the Renewable Energy Trust. This exciting transition comes as a result of legislation, passed by the Massachusetts Legislature and signed by Governor Deval Patrick, to provide the residents, businesses, and communities of the Commonwealth with a single source of support for clean energy.  More information is available at www.MassCEC.com.

About Lilliputian Systems

Lilliputian Systems, Inc. has developed the world’s first Personal Power™ solution for Consumer Electronics (CE) devices, a revolutionary family of products targeted at the $50 billion portable power market.  The Company’s breakthrough solution delivers the only viable small form-factor battery replacement that provides the enormous run-time improvements demanded by today’s CE devices.  Lilliputian’s patented Silicon Power Cell™ technology is based on highly-efficient and proven solid oxide fuel cells (SOFCs) and microelectromechanical systems (MEMS) wafer fabrication methods, and is fueled by recyclable high energy butane cartridges.  The technology is reliable, FAA approved and environmentally friendly.  Lilliputian’s solution enables longer run-time by providing a 5-10 improvement in volumetric energy density and 20-40X improvement in gravimetric energy density at a fraction of the cost.  The Company’s elegantly designed solution both complements today’s devices and can seamlessly integrate into future devices – all while ensuring the consumer enjoys an essentially infinite supply of Personal Power™ for their CE devices.  For more information, visit www.lilliputiansystems.com.

Technical staff at NREL's Safety Sensor Test Laboratory use this test chamber to assess hydrogen sensor performance

Scientists and engineers at the Safety Sensor Test Laboratory at the National Renewable Energy Laboratory (NREL) are collaborating with the European Commission’s Joint Research Centre (JRC) to assess the performance of various hydrogen sensor technologies. Because hydrogen is colorless and odorless, sensors are key safety equipment for fueling stations and other hydrogen facilities.

The Sensor Interlaboratory Comparison (SINTERCOM) Project features the independent assessment of commercial hydrogen sensors via round-robin testing at NREL and JRC. Both organizations are performing the assessments using mutually agreed upon test protocols based on international standards for hydrogen sensors.

“The first round of testing has been completed, and NREL and JRC have exchanged units for the second round of evaluations,” said William Buttner of NREL’s Hydrogen Technologies and Systems Center. “By independently testing the same sensors, both labs gain insight into their respective systems, facilitating improved testing capabilities, protocols, and data analysis.”

Technical staffers at NREL’s Safety Sensor Test Laboratory focus on closing sensor technology gaps and reaching specified sensor targets. NREL works with manufacturers to improve sensor performance and ensure that emerging commercial technologies meet end-user needs.

NREL’s Safety Sensor Test Laboratory was designed to test hydrogen sensors under precisely controlled conditions. Sensors are mounted in a stainless steel test chamber, which controls pressure, temperature, relative humidity, and gas composition. The apparatus can accommodate simultaneous testing of multiple sensors, and can handle all common electronic interfaces—voltage, current, resistance, controller area network, and serial communication. The lab is set up for around-the-clock operation; tests can be run and monitored remotely via the Internet.

NREL staffers visited JRC’s hydrogen sensor test facility in The Netherlands earlier this month. During the visit, the groups compared test procedures and results, proposed protocols for data analysis, and identified additional sensors for future assessment. NREL will present the latest results of the SINTERCOM Project at the National Hydrogen Association Conference in May.

Figure 1: SOEC cells function according to two different principles. In one SOEC cell with a proton-conducting electrolyte, the hydrogen ions pass from the anode through the electrolyte to the cathode. These cells can operate at lower temperatures and can be used to produce different kinds of synthetic fuels. In cells with an oxide ion-conducting electrolyte, the oxygen ions (oxide ions) pass from the cathode through the electrolyte to the anode. These cells require a high operating temperature which will cause the synthetic fuels to split. This type can therefore only be used to produce synthesis gas. The figure also shows how the processes at the anode correspond to photosynthesis in nature. As we know, this process results in nature’s fuel, sugar.

Today, most energy is produced at large centralised power stations based on fossil fuels such as coal, oil and natural gas. And then there is the energy produced by hydroelectric power stations, nuclear power stations and wind farms. The energy flows only one way, from the central power stations to the electricity grid and on to consumers. The idea now is that much more renewable energy should be fed into the grid. This calls for new solutions that take account of the considerable variations in the amount of wind energy, hydropower, solar energy etc. One of the solutions is a distributed energy system.

A distributed energy system consists of many small, geographically dispersed production units and a few large, central units. The different parts of the transmission systems function independently of each other but can play together using IT, making it possible to utilise both central and local technologies to meet the energy needs of the moment. Locally, energy will be produced to a greater extent from local energy resources such as the sun, wind, straw etc.

Energy storage important

Locally this will entail a need to be able to transform surplus electricity from renewable sources to energy which can be stored. One of the options is to store surplus production as chemical energy. This might be in the form of compounds such as liquid methanol (CH3OH) or gasses such as natural gas (CH4) or synthesis gas (CO+H2). Once the energy has been transformed into these chemical compounds, known as synthetic fuels, it is easy to store in tanks and pressure tanks. The synthetic fuels can be used directly in cars and as starting materials for the chemical industry. There is basically nothing new in this principle. The only problem is that today’s technologies are best-suited for large-scale central plants operating at high temperatures. Therefore, it is necessary to develop new types of plants that operate at lower temperatures and are thereby suitable for installing together with local wind turbines.

The objective is to realise these goals through a new research initiative, Catalysis for Sustainable Energy (CASE), which will develop catalysts to transform local renewable energy into chemical energy, for example hydrogen or methanol. CASE is headed by Professor Jens K. Nørskov from DTU Physics.

Electrolytic cells can turn CO2 into a useful fuel

Making the step from electricity to chemical energy requires an electrolytic process. Through electrolysis, water is transformed into hydrogen and oxygen (and CO2 to CO and oxygen) using electricity. The ABF (Fuels Cells and Solid State Chemistry Division) develops electrolytic cells for this purpose in the form of SOEC electrolytic cells. “An SOEC electrolytic cell is built up of ceramic materials and is, in principle, a reversed SOFC fuel cell which Risø is developing in conjunction with, among others, Topsoe Fuel Cells,” says Research Professor Mogens Mogensen from ABF (Fuels Cells and Solid State Chemistry Division).

The process in the electrolytic cells corresponds in reality to part of nature’s own photosynthesis, which takes CO2 out of the air and transforms it into a store of chemical energy in the form of sugar. Electrolytic cells can therefore contribute to removing CO2 from the air. In other words, they resemble the role of forests in absorbing CO2.

By transforming CO2 to liquid synthetic fuels in an electrolytic cell, our means of transport can use sustainable energy, power from wind turbines and solar cells. When a car runs on synthetic fuel, CO2 is released to the atmosphere. However, no more CO2 than has been used to produce the synthetic fuel, which in effect means that no CO2 is added to the atmosphere.

High temperatures for large central synthetic fuel plants

High-temperature cells are very efficient compared with other electrolysis methods as they produce more oxygen and carbon monoxide from a given amount of electricity. This is because at high temperatures water and carbon dioxide can be split into synthesis gas (hydrogen + carbon monoxide) and oxygen using the heat, and the SOEC cell is thereby self-cooling: The heat which is inevitably produced when electricity runs through something – this is needed for the electrolytic process. Moreover, it is possible to utilise the heat which is often available as surplus heat from, for example, power stations and industry.

“These high-temperature electrolytic cells will be good for large, central plants for manufacturing synthetic fuel from synthesis gas. The catalytic processes which follow the electrolytic process require a complete facility with a catalytic reactor coupled to an electrolytic cell plant because the synthetic hydrocarbons are not stable at such high temperatures (over 650 C). Such a facility probably needs to exceed 100 MW for it to be financially viable,” says Mogens Mogensen. In addition, you avoid heat loss in the large plants.

Work has been conducted on the high-temperature cells for some time in SERC (Strategic Electrochemistry Research Center), where a number of enterprises and research centres are collaborating on the development of these types of electrolytic cells.

Low temperatures in local production of synthetic fuel

For local production conditions, it is necessary to develop cells which can operate at temperatures in the 200-400° C range. This way, small, local electrolysis plants can be established, which can be connected directly to a local wind turbine and produce synthec fuel for the local area. “The vision is to be able to build small, modular plants, with one standing beside each wind turbine in the local area,” says Mogens Mogensen.

The lower temperature means less heat loss and makes it easier to build small and modular electrolysis plants.
For this to succeed, it is necessary to develop completely new materials. These will be developed within the CASE research initiative. ABF is working with two electrolyte types. One is a mesoporous ceramic material, which can absorb liquid electrolytes in their nanopores and retain them. The second type is low-temperature proton-conducting materials (see Figure 1), which uses a solid ceramic electrolyte.

Figure 1: SOEC cells function according to two different principles. In one SOEC cell with a proton-conducting electrolyte, the hydrogen ions pass from the anode through the electrolyte to the cathode. These cells can operate at lower temperatures and can be used to produce different kinds of synthetic fuels. In cells with an oxide ion-conducting electrolyte, the oxygen ions (oxide ions) pass from the cathode through the electrolyte to the anode. These cells require a high operating temperature which will cause the synthetic fuels to split. This type can therefore only be used to produce synthesis gas. The figure also shows how the processes at the anode correspond to photosynthesis in nature. As we know, this process results in nature’s fuel, sugar.

Limestone from the Danish subsoil can be used in the production of sustainable synthetic fuels

It is hard and costly to directly separate CO2 from the atmosphere. Professor Mogens Mogensen therefore envisages the necessary CO2 coming from other sources. For example breweries and second-generation bioalcohol plants, where fermentation produces large volumes of CO2. Another possibility is using Denmark’s most widespread raw material, limestone (calcium carbonate). Heating limestone liberates CO2, leaving quicklime (calcium oxide). Water is mixed – or ‘slaked’ – with quicklime, producing slaked lime (calcium hydroxide), whereby most of the heat which was used is again released.

It is very well known that slaked lime reabsorbs CO2 from the air relatively quickly. Slaked lime mixed with sand is called mortar, which has traditionally been used as a binding paste in masonry. The wet mortar between the bricks absorbs CO2 from the air and hardens through the formation of lime to a stone-hard substance that binds the bricks together.

In other words, the lime is part of a carbon cycle. The CO2 which is released when the lime is burnt is absorbed again when the slaked lime absorbs CO2 and is thereby converted back to lime. It is precisely this cycle which can be used to manufacture synthetic CO2-neutral fuel. “You can therefore produce synthetic fuel with a clear conscience based on CO2 from lime and use it for motor transport, as the liberated CO2 is reabsorbed by the slaked lime which the CO2 originally came from,” says Mogens Mogensen.