CharIN

I suppose at 350 kW you could Char it In.

Every other charger seems awful compared to Tesla.

This advancement gets them close on charging speed, but there's still no comparison in location, ease of use or cost.

200 mile batteries in mainstream price cars is a fait accompli. I'll be surprised if you see less than 100 mile EPA range in any BEV after 2017.

Ford, Fiat, Smart and Mercedes will have to give away their BEVs unless they add QC and 30%+ range. I'm guessing they'd rather sell them.

Tesla's superchargers are 120k watt. They use thick unhandy cables to get that much power through the cable without overheating so they can keep it low tech and inexpensive. I think 120kw or perhaps 150k watt is the absolute limit with that technology. Next step is to add cooling for the cable to increase the power. Much more expensive to build and maintain the charging station. But that may enable 350k watt charging. For almost limitless charging you could use superconductors with liquid nitrogen cooling. Then a million watt would definitely be possible in a cable that can be handle relative easily. But it will be even more expensive.

However, for that to work we also need batteries that can take more charge without overheating and that have high energy density. The interesting is that Huawai seem to have developed a substance to be added to high energy density batteries so that they are also able to take a high charge something that so fart has been impossible. See http://www.greencarcongress.com/2015/11/huawei-unveils-new-fast-charging-li-ion-batteries.html

We also need better power electronics that is more compact and more efficient or it will overheat quickly at 350k watt. I do not know when we will see 350k watt charging of BEVs but it is at least 5 years away. It will come I am certain. The more important issue though is to make autonomous cars and use them to transform the auto industry from an industry that sell cars into one that sell miles from a fleet of autonomous taxis that they build, maintain, clean and charge.

@E-P,
"What do we need hydrogen for again?" Absolutely nothing.

It's a total waste of time and by the time it would deploy to any appreciable level, batteries will be to the point that it will be even more of a joke.

At this point, hydrogen is nothing more than a distraction that slows down investment in building out EV infrastructure.

All weather extended range (500+ Km) BEVs need a minimum of 120 kWh (usable) battery back or a total capacity of about 150 kWh depending of vehicle design, size and weight. This will become a reality between 2020 and 2025 or so,

Relatively Slow charging (20+ minutes) would need something around 360 KW minimum to pick up enough energy for another 500 KM. That is now a near term possibility.

Relatively Quick charging (10 minutes) would need something around 720 KW minimum to pick up another 120 kWh of energy. This represents a much bigger challenge and will not be low cost.

Real quick ( 5 minutes like FCEVs) would need a minimum of 1440 KW charging facilities. This represent a major challenge and special cables, electronics and will cost much more.

Most, if not all 500+ KM range FCEVs can refill in less than 5 minutes and supply enough emergency power for a standard size home for up to 10 days.

Both technologies can replace our current ICEVs and will probably be competitive by 2025 or so.

In my present ev now, mitsubishi i-miev I have a 16 kw-hr battery bank. Charging fast is desireable, but with batteries limitations on heat, I'm reluctant to charge them hard. Even with my 60 mile range, most of my driving can be done with my EV. The rest I do with my pickup truck to do the long distance driving at 25 mpg. The harder you charge your batteries, the shorter the battery life is.

At today's $200/kWh, 16 kWh should be down to $3200; at a near-future $130/kWh, about $2100.  I think your biggest limit is going to be the existing charging system, because designing and retrofitting a high-current system for a low-volume vehicle might not have a big enough market to justify the effort.

@Henrik, Tesla started using liquid cooling of Supercharger cables at their Mountain View (California) Supercharger Station

@Rik I know that. I think Tesla is working on using that cooled cable design in combination with that robotic "snake" they also develop for autonomous charging. I think in order for that robotic "snake" to handle the charging cable they need it to be thinner and more flexible so they use cooling. I think Tesla's priority is to develop a supercharging station that can automatically charge Tesla's that use the autopilot to get the vehicle in and out of the parking space that has this robotic "snake" charger. I guess Tesla is so far in that development program that we will see it rolled out to cars by an OTA upgrade of the autopilot software and some supercharger stations sometime in 2016. It will be another world first for Tesla. A car that can park and charge itself without human interaction. You just drive to the entrance of where you need to go and the car can be ordered to park and charge itself. That self-charging technology is also absolutely necessary if you want to transform the auto industry into a autonomous taxi service selling miles instead of cars. I think this is key in Tesla's long-term business plan (5 to 10 years).

There is another way to increase the charging capacity in a cable without overheating it. Increase voltage. I think Tesla is using 400 volts currently. Tesla may shift to 800 or 1200 volts in 5 to 7 years from now. That could also do the trick to get to 350k watt charging.

I think autonomous capability is a more important selling point than ultra fast charging capability. It makes more business sense to make a fully autonomous BEV than a BEV that charges at 350k watt. Autonomous taxi's will only drive say 8 hours per day. That leaves 16 hours per day for charging so 120k watt is quite enough.

An interesting sight out here in the wild west (think central Utah, northern Nevada, parts of Wyoming, etc are signs that say "Next Fuel 120 Miles". This causes real range anxiety. A few years back, I drove about 8 hrs in western Utah and never even passed another vehicle.

Many (most) people living in large Condoniums, not equipped with e-charging facilities, hesitate to buy slow charging PHEVs because they would be driving on gas most of the time @ about 25 to 30 mpg. For them, extended range 40 mpg to 56 mpg HEVs is a better interim solution.

In that case, very quick charge (5 to 10 minutes max) extended range BEVs would be a far better clean solution. Charging facilities will soon reach 240+ KW to 350+ KW and that would do about half the job.

Of course, 700+ KW charging facilities will be developed. That could do the job in 10 to 12 minutes.

The same posters who claimed that 200+ KW and 350+ KW chargers where not possible a few months ago will also claim that 700+ KW is not possible. They will be wrong again.

To be successful, future extended range BEVs must:

1. have all weather 500 Km range
2. be able to recharge in less than 10 minutes
3. be affordable, i.e. with a total 10 year cost equivalent to similar size ICEVs.

It will come when under $100/kWh, 3-3-3 to 5-5-5 batteries become available.