Pete Comment: "Resin"
and "Polymer" is essentially the same thing. A Resin is liquid when
pored, then cures/hardens into a solid polymer. Meanwhile conventional Lithium-ion
Batteries (LIBs) use an electrolyte which remains liquid.
Pavel Alpeyev in an excellent Bloomberg article of July 8/9, 2020, explains https://www.bloomberg.com/news/articles/2020-07-08/nissan-pioneer-touts-resin-battery-that-s-90-cheaper-to-make :
Lithium-ion batteries play a central role in the world of technology, powering everything from smartphones to smart cars, and one of the people who helped commercialize them says he has a way to cut mass production costs by 90% and significantly improve their safety.
Horie’s innovation is to replace the battery’s basic components -- metal-lined electrodes and liquid electrolytes -- with a resin construction. He says this approach dramatically simplifies and speeds up manufacturing, making it as easy as “buttering toast.” It allows for 10-meter-long battery sheets that can be stacked on top of each other “like seat cushions” to increase capacity, he said. Importantly, the resin-based batteries are also resistant to catching fire when punctured.
In March, APB raised 8 billion yen (US$74 million), which is tiny by the wider industry’s standards but will be enough to fully equip one factory for mass production slated to start next year. Horie estimates the funds will get his plant in central Japan to 1 gigawatt-hour capacity by 2023.
Pavel Alpeyev in an excellent Bloomberg article of July 8/9, 2020, explains https://www.bloomberg.com/news/articles/2020-07-08/nissan-pioneer-touts-resin-battery-that-s-90-cheaper-to-make :
"Power Pioneer Invents New Battery That’s 90% Cheaper Than Lithium-Ion
· All-polymer
batteries could cut manufacturing costs by 90%
· Japanese
startup outfitting factory to begin mass production
Lithium-ion batteries play a central role in the world of technology, powering everything from smartphones to smart cars, and one of the people who helped commercialize them says he has a way to cut mass production costs by 90% and significantly improve their safety.
Hideaki Horie, formerly
of Nissan Motor Co., founded Tokyo-based APB Corp. in 2018 to make “all-polymer batteries” -- hence the company name. Earlier this year
the company received backing from a group of Japanese firms that includes general
contractor Obayashi Corp., industrial
equipment manufacturer Yokogawa Electric Corp.
and carbon fiber maker Teijin Ltd.
“The problem with making lithium batteries now is that
it’s device manufacturing like semiconductors,” Horie said in an interview. “Our
goal is to make it more like steel production.”
The making of a cell, every battery’s
basic unit, is a complicated process requiring cleanroom conditions -- with airlocks
to control moisture, constant air filtering and exacting precision to prevent contamination
of highly reactive materials. The setup can be so expensive that a handful of top
players like South Korea’s LG Chem Ltd., China’s
CATL and Japan’s Panasonic Corp. spend billions of dollars to build a suitable
factory.
Horie’s innovation is to replace the battery’s basic components -- metal-lined electrodes and liquid electrolytes -- with a resin construction. He says this approach dramatically simplifies and speeds up manufacturing, making it as easy as “buttering toast.” It allows for 10-meter-long battery sheets that can be stacked on top of each other “like seat cushions” to increase capacity, he said. Importantly, the resin-based batteries are also resistant to catching fire when punctured.
In March, APB raised 8 billion yen (US$74 million), which is tiny by the wider industry’s standards but will be enough to fully equip one factory for mass production slated to start next year. Horie estimates the funds will get his plant in central Japan to 1 gigawatt-hour capacity by 2023.
Lithium-ion batteries have come
a long way since they were first commercialized almost three decades ago. They last
longer, pack more power and cost 85% less than they did 10 years ago, serving as
the quiet workhorse driving the growth of smartphones and tablets with ever more
powerful internals. But safety remains an issue and batteries have been the cause
of fires in everything from Tesla Inc.’s cars to Boeing Co.’s Dreamliner jets and Samsung Electronics Co.’s smartphones.
“Just from the standpoint of physics, the lithium-ion battery
is the best heater humanity has ever created,” Horie said.
In a traditional battery, a puncture
can create a surge measuring hundreds of amperes, several times the current of electricity
delivered to an average home. Temperatures can then shoot up to 700 degrees Celsius. APB’s battery avoids such cataclysmic
conditions by using a so-called bipolar
design, doing away with present-day power bottlenecks and allowing the
entire surface of the battery to absorb surges.
“Because of the many incidents, safety has been at the top of
mind in the industry,” said Mitalee Gupta, senior analyst for energy storage at
Wood Mackenzie. “This could be a breakthrough for both storage and electric vehicle
applications, provided that the company is able to scale up pretty quickly.”
But the technology is not without
its shortcomings. Polymers are not as conductive as metal and this could significantly
impact the battery’s carrying capacity, according to Menahem Anderman, president
of California-based Total Battery Consulting Inc.
One drawback of the bipolar design is that cells are connected back-to-back in a
series, making control of individual ones difficult, Anderman said. He also questioned
whether the cost savings will be sufficient to compete with the incumbents.
“Capital is not killing the cost of a lithium-ion battery,”
Anderman said. “Lithium-ion with liquid electrolyte will remain the main application
for another 15 years or more. It’s not perfect and it isn’t cheap, but beyond lithium-ion
is a better lithium ion.”
Horie acknowledges that APB can’t compete with battery giants
who are already benefiting from economies of scale after investing billions. Instead
of targeting the “red ocean” of the automotive sector, APB will first focus on stationary
batteries used in buildings, offices and power plants.
That market will be worth $100 billion by 2025 worldwide, more
than five times its size last year, according to estimates by Wood Mackenzie. The
U.S. alone -- which together with China will be the main source of increased energy
storage demand -- is likely to see a 10-fold increase to $7 billion in the period.
Horie, 63, got his start with
lithium-ion batteries at their very beginning. In February 1990, early on in his
Nissan career, he started the automaker’s nascent research into electric and hybrid
vehicles. A few weeks later, Sony Corp. shocked the
industry, which was betting on nickel-hydride technology, by announcing plans to
commercialize a lithium-ion alternative. Horie says he immediately saw the promise
and pushed for the two companies to combine research efforts that same year.
By 2000, however, Nissan was
giving up on its battery business, having just been rescued by Renault SA. Horie had one shot at convincing his new boss
Carlos Ghosn that electric vehicles were worth it. After a 28-minute presentation,
a visibly excited Ghosn proclaimed Horie’s work an important investment and green-lit
the project. Nissan’s Leaf would go on to become the best-selling EV for a decade.
Horie came up with the idea for
the all-polymer battery while still at Nissan but wasn’t able to get institutional
backing to make it real. In 2012, while doing a teaching stint at the University
of Tokyo, he was approached by Sanyo Chemical Industries Ltd.,
known for its superabsorbent materials used in diapers. Together, the two developed
the world’s first battery using a conductive gel polymer. In 2018, Horie founded
APB and Sanyo Chemical became one of his early investors.
APB has already lined up its first customer, a large Japanese
company whose niche and high-value-added products sell mostly overseas, Horie said.
He declined to give further details and said APB plans to make the announcement
as early as August.
“This will be the proof that our batteries can be mass-produced,”
Horie said. “Battery makers have become assemblers. We are putting chemistry back
into the lead role.”
— With assistance
by Jason Clenfield,
David Stringer, and Daixin Li."
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