The problem is that 6000 cycles in laboratory are not the same than 6000 cycles in real life scenarios.
It would be interesting to put that battery out in the field and to see how it perform in real life conditions (assuming that they are cheap enough to be produced in large volumes)
If they are really that good you are right, but there are always a lot of revolutionary advance in lab that never leave it.
Indeed: electric vehicle batteries are lasting even longer than estimated. All the constant breaks from use that the batteries get has been interestingly improving their durability (which makes me think that shutting off our phones for 1 whole day per week or even month could improve their lifespan, even for the 40-80% lithium-ion boundary keepers).
There actually was a Chinese EV startup that had battery swap stations: drive up onto the system, and the battery is directly under your car; the swap takes <1 minute. I don’t remember what it was called, though, nor if it ever made it.
Tom Scott did a video on it. In all honesty, there are a number of things about this system that I just don’t see working well in the long term, but it’s an interesting prototype nonetheless.
Tesla did that as well about 10 years ago. They opted to not do it anymore if I recall correctly because they couldn’t control how the batteries were being maintained or what age of battery you would get.
When was hot-swapping batteries normal? What was the backup power source? I’d only ever seen normally swappable batteries where the phone would need to power off and back on.
I’ve never owned a flip phone that I couldn’t plug in and swap the battery with a new one without it turning off. If that wasn’t normal with your phones I’m not sure why, maybe different circuitry?
Regardless making devices easy to repair, and thus open and maintainable was what I was getting at.
Breaks from use makes perfect sense though, it allows the electrolyte to diffuse evenly. During charge /discharge cycles there’s always more or less active electrolyte being consumed/produced at the anodes and cathodes, resting means it can equalize.
It really depends on the charge/discharge conditions that the particular test is using. You can do testing in the lab that is way harsher than typical usage or you can make it easier. In terms of this cycle testing for Li-ion I would say that typically the lab testing would be harsher than real world primarily because lab testing is done between 0% and 100% depth of discharge constantly where most people are charging their batteries much before then and only cycling them at high rates periodically.
It really depends on the charge/discharge conditions that the particular test is using.
True.
You can do testing in the lab that is way harsher than typical usage or you can make it easier. In terms of this cycle testing for Li-ion I would say that typically the lab testing would be harsher than real world primarily because lab testing is done between 0% and 100% depth of discharge constantly where most people are charging their batteries much before then and only cycling them at high rates periodically.
You are right, but we should see what they want to demostrate in the lab test: that the tech works or to have a way to make a sensational announcement based on some data ?
If you put that battery on the market, the 6000 cycles still stand or they are only a lab result ?
Aside the harsh or easy charge/discharge cycles, what other condition they tested ? A battery on a bench has different problems than a battery on a car on the road.
That said, if the tech works really has announced, it would be great.
For a press release bragging about a new advancement especially for a product that doesn’t even exist yet, I would guarantee they’re using the ‘easier’ test.
The problem is that 6000 cycles in laboratory are not the same than 6000 cycles in real life scenarios.
It would be interesting to put that battery out in the field and to see how it perform in real life conditions (assuming that they are cheap enough to be produced in large volumes)
If they are really that good you are right, but there are always a lot of revolutionary advance in lab that never leave it.
Indeed: electric vehicle batteries are lasting even longer than estimated. All the constant breaks from use that the batteries get has been interestingly improving their durability (which makes me think that shutting off our phones for 1 whole day per week or even month could improve their lifespan, even for the 40-80% lithium-ion boundary keepers).
Just make hot swapping batteries normal again like it used to be.
There actually was a Chinese EV startup that had battery swap stations: drive up onto the system, and the battery is directly under your car; the swap takes <1 minute. I don’t remember what it was called, though, nor if it ever made it.
Update: it’s Nio.
Tom Scott did a video on it. In all honesty, there are a number of things about this system that I just don’t see working well in the long term, but it’s an interesting prototype nonetheless.
https://youtu.be/hNZy603as5w
That’s it: Nio! Yeah, I dislike the reliability on the company, too.
Tesla did that as well about 10 years ago. They opted to not do it anymore if I recall correctly because they couldn’t control how the batteries were being maintained or what age of battery you would get.
Isn’t that Nio?
Edit: didn’t see it had been answered already
Gogoro a moped/scooter company in Taiwan has these. Little stations all over the country where you can swap your battery out, it was pretty amazing.
There was one like that in Taiwan for scooters.
When was hot-swapping batteries normal? What was the backup power source? I’d only ever seen normally swappable batteries where the phone would need to power off and back on.
I’ve never owned a flip phone that I couldn’t plug in and swap the battery with a new one without it turning off. If that wasn’t normal with your phones I’m not sure why, maybe different circuitry?
Regardless making devices easy to repair, and thus open and maintainable was what I was getting at.
Somehow, I forgot about charging cables.
Somehow, charging cables returned
Breaks from use makes perfect sense though, it allows the electrolyte to diffuse evenly. During charge /discharge cycles there’s always more or less active electrolyte being consumed/produced at the anodes and cathodes, resting means it can equalize.
Fascinating, I didn’t know that that’s the reason… Would you happen to have any data on how long this diffusion process takes?
I’ve seen some incredible innovations in batteries performing really well in cold temperatures. So the idea of these becoming battle tested seems more feasible today than it did even a couple years ago.
It really depends on the charge/discharge conditions that the particular test is using. You can do testing in the lab that is way harsher than typical usage or you can make it easier. In terms of this cycle testing for Li-ion I would say that typically the lab testing would be harsher than real world primarily because lab testing is done between 0% and 100% depth of discharge constantly where most people are charging their batteries much before then and only cycling them at high rates periodically.
True.
You are right, but we should see what they want to demostrate in the lab test: that the tech works or to have a way to make a sensational announcement based on some data ?
If you put that battery on the market, the 6000 cycles still stand or they are only a lab result ?
Aside the harsh or easy charge/discharge cycles, what other condition they tested ? A battery on a bench has different problems than a battery on a car on the road.
That said, if the tech works really has announced, it would be great.
For a press release bragging about a new advancement especially for a product that doesn’t even exist yet, I would guarantee they’re using the ‘easier’ test.