MAY 27, 2021 by Susan Bauer, Pacific Northwest National Laboratory

Collected at: https://techxplore.com/news/2021-05-on-site-hydrogen-production-technology.html?utm_source=nwletter&utm_medium=email&utm_campaign=daily-nwletter
On-site hydrogen production technology accelerates to market
A new hydrogen generator design, about 11-inches in diameter, combined with a microchannel heat exchanger, enables on-site production of hydrogen at fueling stations. Credit: Scott Butner | Scott Butner Photography, LLC

A new technology that generates hydrogen from conventional natural gas, or renewable natural gas made from biomass, could be the next big thing to advance California’s Hydrogen Highway, fuel cell vehicles and trucks and to create other valuable products.

Tiny channels—about the width of a credit card—that transfer heat underpin the technology developed at the U.S. Department of Energy’s Pacific Northwest National Laboratory. These microchannels are critical to efficiently driving the energy into the chemical reactions that produce hydrogen for transportation, electricity generation and other industrial purposes.

The PNNL-developed hydrogen generator was licensed to a Richland, Wash. cleantech start-up company, STARS Technology Corporation. The hydrogen generator features two recent innovations that may drive down the cost of hydrogen. The first is a new additive manufacturing process that has been licensed to both STARS TC and SoCalGas—a Los Angeles-based gas distribution utility that serves 22 million people in Central and Southern California. The second is a novel spiral reactor design that distributes heat more precisely and improves the reactor efficiency. This design, exclusively licensed to SoCalGas, minimizes the energy required to produce hydrogen while increasing the reactor’s durability and safety.

“One near-term use for this microchannel technology would be making hydrogen for fuel cell electric vehicles,” said Yuri Freedman, senior director of research and development at SoCalGas. “Because this technology offers a small footprint and substantially increases the efficiency of the process that reforms natural gas into hydrogen, it makes hydrogen much cleaner and easier to deliver—you could produce hydrogen anywhere there is a natural gas pipeline nearby. For us at SoCalGas, this is an important step toward meeting our goal to achieve net zero greenhouse gas emissions in our operations and delivery of energy by 2045. This technology could drastically change hydrogen production and use in California, advancing SoCalGas’ efforts to meet the climate objectives of California and our customers.”

Fueling hydrogen infrastructure

Because the STARS technology can generate hydrogen anywhere natural gas is available, developers say this technology can greatly reduce the need for hauling hydrogen in special high-pressure tube-trailers. Eliminating on-road transit improves public safety, reduces greenhouse gas emissions and helps make point-of-use hydrogen production cost competitive with conventional fuels.

“Think of these small, efficient, mass-produced generators as ‘chemical transformers’ similar to electrical transformers on the electric grid,” said Bob Wegeng, president of STARS TC and an inventor of the technology. “They can be placed anywhere along the natural gas distribution system, so it becomes a ‘hydrogen grid’ by providing inexpensive hydrogen for filling stations in quantities that match on-site demand.”

Producing hydrogen from methane

The most abundant element in the universe, hydrogen, is typically part of other compounds like water or methane. Natural gas is comprised mostly of methane, one of nature’s most efficient hydrogen carriers. Conventional hydrogen production processes using natural gas can sometimes emit carbon dioxide and use a lot of energy—much of it generated from carbon emitting sources. But with the new hydrogen generator, a variety of more efficient heating approaches, including concentrated solar thermal and inductive solar-electric heating, can be used to heat natural gas and water to break the chemical bonds, emitting 30 percent less carbon dioxide than other common methane to hydrogen processes.https://www.youtube.com/embed/fOECcrhMFXg?color=whiteA time-lapse video shows the 3-D “printing” of a steam-methane reforming reactor used to produce hydrogen. The advanced manufacturing technique is economical and may advance use of hydrogen fuel cell vehicles. Credit: P.S. Media

The licensed hydrogen production processes are highly efficient, reducing the thermal energy required to produce high value chemicals. Methane and steam travel through compact spiral microchannels—no more than a few millimeters thick—which quickly and evenly expose the gaseous mixture to heat that drives chemical reactions and liberates the hydrogen from the natural gas and water.

Because the hydrogen can be produced in an economical and clean manner, it is well positioned to support California’s Assembly Bill 8, which dedicates up to $20 million per year to support continued construction of at least 100 hydrogen fuel stations in the state.

This spring, SoCalGas will receive a hydrogen generator from STARS TC, which will include six small modular reactors—each about 10 inches in diameter. STARS TC is largely comprised of former PNNL staff, one of whom was an original inventor of the microchannel technology at PNNL.

3D printing to lower cost of hydrogen production

Recently, PNNL, STARS TC and SoCalGas collaborated on advancements to the hydrogen generation system, including the spiral microchannel design. This team has also developed a novel process that uses 3D printing methods to build the hydrogen-producing chemical reactors.

“This additive manufacturing process lowers manufacturing costs by reducing parts, forming geometric shapes that would be nearly impossible to create by casting or machining processes and eliminating time-intensive fabrication steps,” said Sara Hunt, a technology commercialization manager at PNNL. “The patented technology includes unique approaches for building structures within the device to enhance heat transfer. It also enables the material to be coated or impregnated with catalysts that speed up the rate of chemical conversion to energy.”

Separately, PNNL, SoCalGas and others are also collaborating on novel new chemical reactors that co-produce hydrogen and solid carbon materials, such as carbon fiber products and carbon nanotubes, which can offset the cost of greenhouse gas-free hydrogen production even further. This combined with the additional use of renewable natural gas means these reactor systems could help SoCalGas as it strives to net-zero emissions by 2045.

Development of the microchannel technology hydrogen generator has been supported by the RAPID Institute and offices in the U.S. Department of Energy’s Office of Energy Efficiency and Renewable Energy, including the Hydrogen and Fuel Cell Technologies, Solar Energy Technologies and Advanced Manufacturing Offices.

Headquartered in Los Angeles, SoCalGas is the largest gas distribution utility in the United States. SoCalGas delivers affordable, reliable, clean and increasingly renewable gas service to 21.8 million consumers across 24,000 square miles of Central and Southern California. Gas delivered through the company’s pipelines will continue to play a key role in California’s clean energy transition—providing electric grid reliability and supporting wind and solar energy deployment.


Provided by Pacific Northwest National Laboratory

0 0 votes
Article Rating
Subscribe
Notify of
guest
0 Comments
Inline Feedbacks
View all comments