Five-Minute EV Charging Could Become a Reality Thanks to Hot NASA Tech

The widespread adoption of electric vehicles is still an ongoing process, with charging infrastructure being a weakness regularly mentioned by critics (and owners). The few EV charging stations aren't even disbursed, can be tricky to use, and aren't always fast enough for drivers used to filling up a tank with liquid fuel. It could be argued that one of the best ways to encourage EV adoption is to make EV charging a 1-to-1 experience (or better) than pumping gasoline.

Charging an EV can be a lengthy process by comparison. Even Tesla's superchargers still need 40 minutes to charge a typical battery to 80 percent capacity. There are some chargers that are a bit faster. For example the 2022 Hyundai Ioniq 5 can chargefrom 10 to 80 percent in 18 minutes when using a 350 kW DC charger. Still, 18 minutes is a long time to hang out at a charging station.

Thanks to NASA, the world may soon have access to chargers that can top off an EV in as little as five minutes. One of the biggest obstacles to fast charging is dealing with temperature. According to NASA, for an EV to be charged in five minutes, the charger must deliver an electric current of 1,400 amperes. For reference, the fastest chargers currently available max out at around 520 amperes. More amperes equals more heat. Alotmore heat. Companies and research organizations are pursuing solutions to the problem; Ford and Purdue University, for example, are exploring liquid-cooled charging cables.

A team sponsored by NASA's Biological and Physical Sciences Division is working on technology that could provide another solution needed for ultra fast EV charging. The technology has been developed for use in space, in which massive temperature differentials require massive heat transfer capabilities. An experiment to prove the new tech, the Flow Boiling and Condensation Experiment (FBCE), was installed on the International Space Station and is providing data that NASA will use to determine if the system will provide the claimed orders-of-magnitude benefits in heat transfer efficiency.

We'redefinitely notNASA-level engineers but we will try to explain the FBCE the best we can. The FBCE is made up of several modules; one of which is called a "Flow Boiling Module" (FBM). When cooling liquid inside the FBM begins to boil, the bubbles formed draw liquid from the inner part of the flow channel to its walls. The process "efficiently transfers heat by taking advantage of both the liquid's lower temperature and the ensuing change of phase from liquid to vapor." The technique has been dubbed "subcooled flow boiling."

According to the team behind the experiment, subcooled flow boiling allows them to deliver 4.6 times the current of the fastest available EV chargers on the market—up to 2,400 amps—which is more than enough to achieve the five-minute charging goal, and which NASA believes could remove one barrier to EV adoption. The prospect of charging an EV that quickly is certainly alluring, but as with most cutting edge technology, it will be a while before it's ready for the masses.