A 40-foot trailer loaded with 25 tons of liquid metals may be the
solution to the renewable energy industry’s biggest challenge: making
sure electricity is available whenever it’s needed.
A Boston-area startup founded by MIT researchers is working to turn
this new concept into a commercially viable product, liquid-metal
batteries that will store power for less than $500 a kilowatt-hour.
That’s less than a third the cost of some current battery technologies.
The technology promises an alternative to the massive
pumped-water systems that make up 95 percent of U.S. energy storage
capacity. At that price, developers will be able to build wind and solar
projects that can deliver power to the grid anytime, making renewable
energy as reliable as natural gas and coal without the greenhouse-gas
emissions.
“If we can get liquid-metal batteries down to $500 a
kilowatt-hour, we’ll change the world,” Donald Sadoway, chief scientific
adviser at Cambridge, Massachusetts-based Ambri Inc., said in an
interview.
Power storage will compensate for the intermittent
nature of renewable energy. Batteries can store energy when the wind
blows at night, and then send electricity to the grid the next day when
it’s needed.
First Prototypes
Ambri won a $250,000 grant Feb. 5 from New York state
to develop and test a prototype battery with Con Edison Inc. The
company, backed by investors including billionaires Bill Gates and Vinod
Khosla, plans to install its first two prototypes by early 2015 at a
Massachusetts military base and a wind farm in Hawaii. It opened its
first manufacturing facility in November and is planning a larger one
next year.
Ambri is the first company to pursue liquid-metal
storage and the technology has the potential to reshape the battery
industry, said Brian Warshay, an energy smart technologies analyst at
Bloomberg New Energy Finance in New York.
“There’s nothing out there quite like it,” Warshay
said. “If they can get under $500 a kilowatt-hour, that would be a
really good price point.”
Sadoway, who is also the John F. Elliott professor of
materials chemistry at Massachusetts Institute of Technology, wouldn’t
say what goes into liquid-metal batteries. They use materials that are
“abundant” and easy to harvest from the earth, which is key to making
them cost effective.
‘Dirt Cheap’
“To make it dirt-cheap you have to make it out of
dirt,” he said. Earlier versions used molten magnesium and antimony,
separated by a layer of salt, to store and release electricity. Those
materials only worked at temperatures that were too high to sustain and
didn’t produce enough voltage. Sadoway and his team tested more than
1,000 cells with dozens of alloys and salts to find one that’s
commercially viable.
They will compete against lithium-ion batteries, the
same technology used in laptop computers and electric cars, which are
becoming more common for grid-storage. AES Corp., the largest operator
of power-storage systems, said yesterday it’s now selling them to
utilities and renewable-energydevelopers, for about $1,000 a kilowatt.
Lithium Ion
That technology is a better fit for cars and portable
electronics than for large storage systems that feed the transmission
grid, Sadoway said. “Lithium-ion plants are too expensive to build and
it makes no sense to string a bunch of these tiny things together.”
Other companies are developing other storage
technologies. Duke Energy Corp.’s Notrees wind farm in Texas has 36
megawatts of dry cell storage capacity, provided by Xtreme Power Inc., a
Kyle, Texas-based battery maker that filed for bankruptcy protection in
January.
International Business Machines Corp. is developing a
lightweight lithium-air battery for electric vehicles. Toyota Motor
Corp. and Bayerische Motoren Werke AG are also pursuing the technology.
Musk’s ‘Gigafactory’
Collecting and storing energy from the grid costs
about $1,500 a kilowatt-hour using current types of battery
technologies, according to New Energy Finance. Improving the designs may
reduce that to $575 by 2020. The average U.S. home used 903
kilowatt-hours a month in 2012, according the the U.S. Energy
Department.
Billionaire Elon Musk announced last month plans to
lead development of a $5 billion “gigafactory” to produce lithium- ion
batteries for his Tesla Motors Inc. electric cars and solar projects by
2020. He expects to drive down costs by about 30 percent, which New
Energy Finance said would translates to about $500 a kilowatt-hour.
Pumped Hydro
Sadoway expects Ambri’s liquid-metal batteries to be
competitive with pumped-hydropower systems. The most common form of
storage involves pushing water to an uphill reservoir when electricity
demand is low, and releasing it to run hydropower generators when more
energy is required. Some facilities exceed a gigawatt, but they can only
be built in areas with suitable topography.
There’s about 23.4 gigawatts of pumped-hydro capacity
in operation in the U.S., compared to about 304 megawatts of battery
storage, according to the U.S. Energy Department.
Ambri batteries, which can be delivered on a truck,
will be an alternative to pumped-hydro systems, which require a hill, a
nearby hydropower plant and plenty of water to run it, Sadoway said.
“Ours
won’t have any geographical constraint.”
http://www.renewableenergyworld.com/rea/news/article/2014/03/liquid-metal-batteries-may-be-the-answer-for-cheap-energy-storage
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