Story Appeared in USA TODAY
In February, California, which mandates that 33% of its
electricity come from renewable sources by 2020, required a Los
Angeles-area utility to ensure some capacity comes from energy storage.
On May 1, Germany, which is shuttering its nuclear power plants as it
boosts renewables, began subsidizing homeowners' purchases of batteries
to store power from solar panels. China's five-year plan calls for 5% of
all electricity to be stored by 2020. In the United States, about 2% of electric capacity is pumped hydro storage, the most common form of energy storage.
The
global market for storing power from solar panels is forecast to
explode, from less than $200 million in 2012 to $19 billion by 2017,
according to a report this month by IMS Research.
One factor
driving this growth is the plummeting price of renewables, especially
solar panels that have fallen at least 60% since the beginning of 2011.
As a result, industry groups report historic growth as U.S. electric
capacity from solar panels jumped 76% and from wind turbines, 28%, last
year alone.
OBSTACLES AHEAD
Still, batteries face
obstacles, including cost and safety. Lithium-ion batteries aboard two
Boeing 787s jets failed in January, causing a fire on one and smoke on
the other. In March, batteries from the same manufacturer caused
problems in two Mitsubishi vehicles: a hybrid Outlander car overheated
and an all-electric i-MiEV caught fire during testing at an assembly
plant.
While the EV industry says these incidents are the
exception rather than the rule, money has also been a problem. In
October, Massachusetts-based A123 ,a lithium-ion battery manufacturer
that spent $132 million in federal stimulus funds, filed for bankruptcy.
In December, Wanxiang American, the U.S. arm of a Chinese automotive
parts giant, bought A123's technology.
Toyota's Jaycie Chitwood
said lithium-ion batteries are just too expensive to make electric cars
cost competitive without subsidies. Speaking at the Advanced Energy 2013
conference last month in New York City, she said Toyota is expanding
its line of electric vehicles to meet the U.S. government's
fuel-efficiency targets — not because they're profitable. She said it
gives a $14,000 discount for each new electric RAV4.
Chitwood said
a major battery advance is needed. Toyota is working on several
alternatives, including cheaper, longer-range batteries that use
magnesium instead of lithium. Commercialization, though, is years away.
"Batteries
continue to be a challenge," especially those for electric vehicles,
Esther Takeuchi,chemistry professor at SUNY Stony Brook, said at the
same conference. "Things aren't where we'd want them to be, but they're
getting closer."
Her university and others, some with federal
funding, are looking not only at new chemical mixes but also at
nano-sizing the chemical elements — or making them microscopically small
— to make them more efficient. Takeuchi said successful batteries often
have specific applications, such as lead-acid ones for auto ignition or
lithium-iodine for pacemakers. She said lithium-ion has worked well in
cellphones and laptops, their initial use.
Batteries will improve
"but not at the pace that we've seen in recent years," writes Richard
Muller, a physics professor at the University of California-Berkeley, in
his 2012 book, Energy for Future Presidents: The Science Behind the Headlines. He
says the growing demand for portable electronics sped the development
of already-known battery technologies. He says it will take awhile to
commercialize new ones such as lithium-air.
Batteries are just
one of many ways to store grid-scale energy. The most common is pumped
hydroelectric, in which water is sent to a reservoir and released later
to run generators.
"Storage is the glue that can hold the grid
together," said Matthew Maroon of GE Energy. GE, which opened a $100
million factory in Schenectady, N.Y., to build a sodium nickel chloride
battery, announced earlier this month that Invenergy will install its
Brilliant wind turbine with Durathon batteries at a Texas wind farm
later this year.
The U.S. government is promoting energy storage.
In November, the Department of Energy announced grants for 23 R&D
projects and picked Argonne National Laboratory in Lemont, Ill., as the
first national "innovation hub" for batteries and energy storage.
Argonne will receive $120 million over five years for this work.
Batteries
are getting particular attention, because they're versatile. While
pumped hydro facilities require lots of land and water and are meant for
utility-scale projects, batteries can be used anywhere and are easily
scalable so they can help power not only a car but a factory.
"Everyone's
finally realizing, 'Hey, this works.'... It's the key to the future,"
says Brad Roberts of the Electricity Storage Association, an industry
group. He says the industry's hiccups are part of its growth and adds:
"I don't see any hesitation on the part of venture capitalists."
ALTERNATIVES IN THE WORKS
IBM's
Allan Schurr is bullish on his company's new lithium-air battery, which
takes in oxygen from the air to form a chemical reaction that generates
an electric charge. It's lighter and denser than the lithium-ion ones
in most of today's electric vehicles, which use heavy metal oxides to
drive the chemical reactions that produce power.
"The performance
we've seen in tests so far is at or above our expectations," he says.
With 500 miles on a single charge, he says, "You'd take the 'range
anxiety' out of the equation." The current Nissan Leaf gets up to 75
miles on a single charge, and the Mitsubishi i-MiEV, 62 miles. Schurr
expects a prototype to be developed next year, but its commercial
availability will take at least five years.
Toshiba has developed a
rechargeable lithium-ion battery, the SCiB, that has a new oxide-based
material, lithium titanate, that allows quicker charging times. It's
used in the Honda Fit's EV and Mitsubishi's i-MiEV.
Huge
lithium-ion batteries, filling 53-foot shipping containers, are being
used for grid-scale projects. Since September 2011 on a ridge of Laurel
Mountain in West Virginia, AES Storage has used them to store 64
megawatts of energy generated by windmills. That capacity, if it ran
continuously, would be enough to power nearly 50,000 U.S. households for
a year.
Batteries are also taking homes off the grid or providing
back-up energy. SolarCity, a California-based solar installer, is
piloting a back-up battery for some of its solar projects in California
and may extend that option to other states this year. Minnesota-based
Juhl Energy's SolarBank system pairs solar panels with batteries.
Detroit-based Nextek Power Systems offers a portable off-grid option
that combines a solar panel with a battery.
Ontario-based
Electrovaya plans to bring to the U.S. market this year a residential
system, now being tested in Canada, that would install solar panels and a
big-enough lithium-ion battery that homes could go completely off grid.
Sankar Das Gupta, the company's CEO, says it would cost less than
$10,000 for an average-size home to add such a battery to a solar array.
"There's
no one battery technology that is one-size-fits-all," says GE's Maroon.
He says each has its own advantages and disadvantages, adding: "The
market is big enough for each technology to survive."
American
Vanadium says flow batteries that use vanadium last longer and are more
powerful than lithium-ion ones, because they absorb and release huge
amounts of energy quickly and can do so thousands of times. They can be
used for grid-scale projects, and smaller lithium-vanadium batteries can
power vehicles.
Radvak says if his project is approved, it could
provide 5% of the world's vanadium supply and help reduce battery costs.
The Bureau of Land Management, which is examining the project and will
hold a public meeting Tuesday in Eureka, says the mine could cause a
loss of habitat for greater sage grouse and of acreage for livestock
grazing.
"There is no mining operation that doesn't have a
consequence," Radvak says. But he says the Eureka mine won't involve
moving lots of earth, because the vanadium is in surface deposits and
can be simply leached with a sulfuric acid. "It's a very low-risk
project," he says.
Radvak says while the U.S. has lagged behind
other countries, notably Germany, on energy storage, he expects that in
the long run, it will become the world's leader.
GLOSSARY OF COMMON BATTERIES:
Batteries
often work the same basic way even if they use different metals.
They're mini power plants that produce electricity by creating chemical
reactions. As atoms move between two plates of different metals, via a
chemical solution called an electrolyte, they produce voltage that is
discharged through a metal wire on the other side.
• Lead-acid:
(auto ignition). They have atoms pass from a plate of metallic lead
through sulfuric acid to a plate of solid lead oxide.
•
Lithium-ion (personal electronics, electric vehicles). They have carbon
on one end and a metal oxide on the other, using lithium salt in an
organic compound as the electrolyte in the middle.
• Lithium-air
(still in development; possible uses include electric vehicles). They
use lithium metal and oxygen as inputs at the two ends.
• Nickel-cadmium (portable electronics, electric vehicles). Their metal plates are nickel oxide hydroxide and cadmium.
• Sodium-sulfur (electric vehicles, grid-scale storage). A type of molten-salt battery, it's made from liquid sodium and sulfur.
•
Vanadium redox flow (grid-scale storage). They use vanadium, a metal
named for Vanadis — the Scandinavian goddess of beauty and youth — in
different oxidation states to store chemical energy for repeated use.
