An Israel-based battery company has demonstrated an aluminum-air chemistry that it claims can deliver as much as 1,000 miles per charge to electric cars.
Clean technology company Phinergy, teaming with Alcoa, demonstrated the new electric car battery on a racetrack in Montreal this week in association with the Canadian International Aluminum Conference. At the demonstration, the two companies suggested the new technology would be used as an electric car range extender, in conjunction with a small conventional lithium-ion battery.
Alcoa and Phinergy demonstrated an EV battery chemistry that they claim can deliver 1,000 miles on a single charge. (Source: Alcoa)
”One of the downsides of any electric vehicle today is that there is range anxiety associated with it,” Ray Kilmer, chief technology officer of Alcoa, tells Design News. “This breaks that paradigm. It gives you the best combination of lithium-ion for normal usage and on-demand aluminum-air for greater range when you need it.”
Aluminum-air chemistry has been available for decades and has seen use in military applications. It works by combining aluminum with ambient air and water, and is known for potentially offering high energy density. The video below shows a vehicle fitted with Phinergy’s battery being charged with water, and then driving 330 km on a single charge.
Aviv Tzidon, founder and CEO of Phinergy, tells Design News that the company’s current aluminum-air battery checks in at 300 Wh/kg at the pack level. He adds, however, that the company is ultimately targeting a specific energy of 1,000 Wh/kg, along with a pack-level cost of less than $100/kWh.
Each of the battery’s aluminum plates can provide about 20 miles of range, Phinergy said. With 50 plates, the aluminum-air chemistry reaches a total of 1,000 miles, according to the companies. (Source: Alcoa)
If those numbers can ever be reached, they would be a big improvement over those of today’s lithium-ion batteries. Current lithium-ion batteries are typically rated from 150 to 240 Wh/kg at the cell level, and far less at the pack level. Cost is estimated at figures ranging from $300 Wh/kg to $450 Wh/kg by various analysts.
The article continues on EE Times sister site, Design News.