BMW Batteries Have 15-Year Life In EVs

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GRA

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Via IEVS: https://insideevs.com/bmw-batteries-have-15-year-life-in-cars/

BMW’s head of battery development, Andreas Raith, interviewed by the CarAdvice, says that lithium-ion batteries in all-electric and plug-in hybrid cars are designed for “15 years and beyond.”

There is nothing to worry about as BMW took a conservative approach to achieve 70% of battery capacity after 15 years. The field data collected so far indicates that results are better than envisioned.

Life-expectancy for BEVs and PHEVs is on par with ICE cars.

  • To make batteries durable, BMW utilized thermal management system with liquid cooling.

Andreas Raith said:

  • “It’s not a marketing statement, those batteries are designed to last as long as the vehicle,”

    “We can prove that with the field data that we see today coming in from our existing fleet of plug-in hybrids… it’s fair to say and I think it’s a statement for the entire industry and community, everyone is so concerned about [battery] life time and the engineering community as a whole takes a very conservative approach to preserving those batteries.”

    “BMW specification in case of durability is no different between combustion engines or battery driven vehicles. . . .”
Now, will they warranty them for that?
 
Jedlacks said:
I seriously doubt the current version of i3 cars, BEV or REX, will last that long.
I agree, esp. the unreliable REx.

I suspect, the current or next owners of the REx will be so fed up w/its lack of reliability that they'll junk the car before 15 years once something expensive that's out of warranty fails. And, if a BEV or REx version hits motor mount breakage outside of warranty... The resulting repairs will be way too costly to be worth fixing. I've seen the receipts of the aftermath from that.

I've seen a few cases on the i3 where some other failure forces the dealer to replace the entire battery pack.
 
Via IEVS:
BMW i3 Samsung SDI 94 Ah Battery Rated For 524,000 Miles
https://insideevs.com/lets-look-at-the-specs-of-the-samsung-sdi-94-ah-battery/

. . . let’s look at the specs of the 94 Ah cells, used in the BMW i3. These cells are considered to be among the longest life-cycle cells available.

Samsung SDI expects up to 4,600 charging cycles at 25ºC to End-Of-Life (EOL), which in the case of batteries is the point when capacity decreases to 80% (battery still can be used, but is generally not desirable in cars any longer).

Since the BMW i3 (33 kWh) is rated at 114 miles (183 km), 4,600 cycles would be more than 524,000 miles (more than 843,000 km).

It’s one of the best results in the industry and it’s totally doable because the i3 pack is equipped with a thermal management system. . . .
There are graphs etc.
 
This really doesn't strike me as controversial at all? I've been working with BMW's and Mercedes' modules from crashed cars and they all pretty much have no degradation, even after significant mileage. They seem to be holding up exactly the same as Panasonic's VW modules and Mitsubishi's Outlander modules - no degradation after hundreds of cycles. Considering Tesla has already shown that NCA can manage cycle life that would translate into about ~300kmi until 80% SoH, I don't see any reason to suspect Panasonic can't deliver on that kind of life in a well-managed battery either.

It's MUCH more likely that some ancillary system fails prematurely, aside from the many mechanical failures around cars. Coolant pumps, coolant leaks, that kind of stuff.

Edit: don't use the Leaf battery as any kind of yardstick for lithium ion battery degradation in cars. They're the absolute worst, in the same class as stuff like Th!nk City as far as the chemistry goes. The majority of automakers don't use AESC's batteries.
 
This really doesn't strike me as controversial at all? I've been working with BMW's and Mercedes' modules from crashed cars and they all pretty much have no degradation, even after significant mileage. They seem to be holding up exactly the same as Panasonic's VW modules and Mitsubishi's Outlander modules - no degradation after hundreds of cycles.

How are you using them? Laboratory battery cycles almost never translate to real world cycles.
 
LeftieBiker said:
These estimates and claims are always good for a chuckle. BMW should make Chinese scooters!
Sure, YMMV and lab results aren't the real world, but it is indicative of what's possible. One half or even one third of that IRL would be terrific.
 
LeftieBiker said:
This really doesn't strike me as controversial at all? I've been working with BMW's and Mercedes' modules from crashed cars and they all pretty much have no degradation, even after significant mileage. They seem to be holding up exactly the same as Panasonic's VW modules and Mitsubishi's Outlander modules - no degradation after hundreds of cycles.

How are you using them? Laboratory battery cycles almost never translate to real world cycles.

In cars :p Like, they are literally from insurance car sales and I've yet to encounter a pack with a state of health measurably different from 100%.
 
Nope, other than Leaf batteries. Pretty much all (plugin-hybrid) electric cars except for the Leaf, Zoe and iMiev came out in 2015 or later, so there's very few that are older. I've obviously seen Tesla batteries, but those have been analyzed to death already.
 
mux said:
...I've been working with BMW's and Mercedes' modules from crashed cars and they all pretty much have no degradation, even after significant mileage. They seem to be holding up exactly the same as Panasonic's VW modules and Mitsubishi's Outlander modules - no degradation after hundreds of cycles. .... [Leaf batteries are] the absolute worst, in the same class as stuff like Th!nk City as far as the chemistry goes. The majority of automakers don't use AESC's batteries.

If that's the case, I'm a little bit surpised that you drive a Leaf and are working on replacement Leaf battery packs. :mrgreen:

If you have the time....are the BMW/Panasonic/etc more prone to fires? More expensive? Absolutely require TMS? What is your opinion on why Nissan went with the chemistry they did?

And what are the odds that a different, longer-lived chemistry could find its way into Leaf-compatible replacement packs?

I love my Leaf but it is just a city car for me and by city, I really mean commuter and errand car. That is still >80% of my trips (probably normal for most in US) but IMHO EV's need to get better before more folks consider them acceptable as ICE replacements. I'm a little surprised that batteries this much better are available and Nissan is not using them. There must be a legitimate reason for their decision.
 
goldbrick said:
If you have the time....are the BMW/Panasonic/etc more prone to fires? More expensive? Absolutely require TMS? What is your opinion on why Nissan went with the chemistry they did?

Because they're cheap bast*rds.

I too do lots of battery work, and agree. The Leaf chemistry sucks. I see lots of "next-gen" stuff and we work with the automakers on some of the BMS circuits that surround the batteries so we get packs. Some of the automakers do things that make you scratch your head.
 
goldbrick said:
If that's the case, I'm a little bit surpised that you drive a Leaf and are working on replacement Leaf battery packs. :mrgreen:

Oh, don't get me wrong, I'm not replacing Leaf packs with Leaf cells... I'm replacing them with Panasonics :) Without TMS though.

If you have the time....are the BMW/Panasonic/etc more prone to fires? More expensive? Absolutely require TMS? What is your opinion on why Nissan went with the chemistry they did?

Conjecture ahead, because as much as I am sort of a broad-knowledge engineer in this field, I'm not an expert in these things and don't actually design battery packs, I just apply them.

Fire risk depends on three things: 1) the prevalence of circumstances that lead to fire, 2) the extent of such a fire and 3) the consequences of that fire. All lithium ion batteries bar a rare few types have an inherent failure mode called thermal runaway. When the cathode material gets to about 130-150C at any point, an exothermic chemical reaction will spontaneously occur. That will generally boil the electrolyte, melt or vaporize other internal materials and cause the cell to bulge and rupture. Heat from the battery will first infect and spread thermal runaway within the cell, and depending on the thermal capacity of its surroundings it may also jump to neighboring cells, engulfing the entire pack.

The Leaf battery is basically the perfect storm here; it's got a relatively fire-prone chemistry. Not only are LMO/LCO chemistries relatively fire-prone; they have a large amount of flammable electrolyte. The cells are also not very well pressure-sealed (they're polymer pouch types in a compression frame) and have fairly low thermal capacity. The back row of cells is a LOT of cells packed right next to each other. A fire in one cell will quickly spread to the whole stack, basically setting the entire pack on fire. There are only 2 (or 4 in the new packs) thermal sensors and the pack isn't actively cooled.

Now, have I scared you yet?

The Yuasa and Panasonic packs (that's basically what we're talking about when talking about the other brands) are all some variation of NCA chemistry (nickel-cobalt lithium-ion). The Panasonics are *incredibly* low impedance, meaning they are using really thick conductor plates internally (aluminum/copper touching the active material) and low electrolyte volume. This increases thermal capacity and reduces the amount of flammable material, as well as simply making the battery more efficient (although heavier). They're all cooled to some extent (although some of this cooling is token) and they're in individual compression frames, meaning bulging cells can't cause other modules to get crushed. Add to that the fact that NCA is for the purposes of fire safety more stable (nickel is actually less stable, but the reactions that cause thermal runaway occur at higher temperatures), and you should have a battery system that just has to be much more fire-safe. I don't have statistics and there is always a way to **** this up (e.g. some packs have the pyrofuse unnecessarily close to the actual cells, I'm sure they did their engineering right but I think it's scary), but this has to be an order of magnitude safer than the Leaf mk1/1.5.

All that said, battery fires are super-rare and much safer to be in than gas or diesel fires. There's something like 200 000 fuel fire accidents in the US a year. Even on a per-vehicle basis, battery fires are more rare and less deadly.

But if you really want the pinnacle of battery safety, you have to hand it to Tesla. Their coolant runs beside almost every cell, the thermal capacity of the matrix is tuned to never allow thermal runaway to infect neighboring cells. And each cell is fused individually. You can't do better than Tesla. They also have the most awesome BMSes and TMSes. Pure engineering porn. Overkill, though. i'd say this is all a bit of wasteful engineering, making their cars unnecessarily expensive.

And what are the odds that a different, longer-lived chemistry could find its way into Leaf-compatible replacement packs?

I'm going to try and either make a business out of it or tutorialize it. Oh, or fail (that's a very real possibility)

I love my Leaf but it is just a city car for me and by city, I really mean commuter and errand car. That is still >80% of my trips (probably normal for most in US) but IMHO EV's need to get better before more folks consider them acceptable as ICE replacements. I'm a little surprised that batteries this much better are available and Nissan is not using them. There must be a legitimate reason for their decision.

I'm very torn on the Leaf's design. If I give Nissan the benefit of the doubt, they must have really had a hard time finding a long-term, high-volume supplier. AESC, their battery supplier, is a pleb-tier shitty supplier now, but you have to keep in mind the Leaf was in development in the mid-00's. Batteries just weren't what they are now. NCA didn't exist, they HAD to use some doped form of LMO or LCO, and the latter can't provide the required current. They clearly wanted a sporty car, because the car is built like an absolute tank, with provisions for anti-roll and anti-dive, a sway bar and articulated suspension. I think the car was originally designed to be much less city commuter and much more fun car. It still is, really. Compare it to the sub-50kW Zoe and iMiev of the time, or the sub-30kW Wheego, Th!nk City, etc. But to get 80kW out of a 24kWh battery (almost 4C!), LMO was the only way to go. Or NiMH...

But... if I look at the car now, it's not well-designed at all. As an electric car with a small battery, you NEED to work on efficiency. Norway is one of the biggest markets for the Leaf, and it's fucking cold there. They should AT LEAST have put a heat pump in the first iteration. They should have had battery heating/cooling as standard using the general coolant loop. They should really have increased the battery to 30kWh immediately - they had plenty of room under the car. They shouldn't have had the hump in the back as an afterthought. They should have included the 6.6kW charger. They should have fucking known to put a light in the charging bay. They should have worked on the aerodynamics - the Leaf is one of the least efficient electric cars.

The entire car seems half-assed - not in its finish quality, but in its fitness for purpose. Why bother making an EV from the ground up if it's so bad at being an EV? Seriously, somebody had their head firmly stuck in their ass when designing this. Still the most successful EV...

Is Nissan delinquent here? Were they too soon, was the technology not ready? Bit of both I guess. I'd love to talk to their engineers to find out more.
 
Wow, great answer and thanks for sharing your insights. I'm sure the design/build/ship pipeline is very long for automobiles and the fixed costs have to be huge but still, it's interesting that Nissan is doing it so poorly. It will be interesting what the 2019 looks like.

And good luck with your project. I have 7.5 years left on my warranty so I consider it Nissan's problem, not mine, but I'd love to see you succeed as I'm sure most of these cars will far out-live their batteries.
 
Thanks for the expert opinion:
mux said:
...The Leaf battery is basically the perfect storm here; it's got a relatively fire-prone chemistry. Not only are LMO/LCO chemistries relatively fire-prone; they have a large amount of flammable electrolyte. The cells are also not very well pressure-sealed (they're polymer pouch types in a compression frame) and have fairly low thermal capacity. The back row of cells is a LOT of cells packed right next to each other. A fire in one cell will quickly spread to the whole stack, basically setting the entire pack on fire. There are only 2 (or 4 in the new packs) thermal sensors and the pack isn't actively cooled.

Now, have I scared you yet?

... if you really want the pinnacle of battery safety, you have to hand it to Tesla. Their coolant runs beside almost every cell, the thermal capacity of the matrix is tuned to never allow thermal runaway to infect neighboring cells. And each cell is fused individually. You can't do better than Tesla...
One more question.

Why is it then, that no Nissan leaf has ever reported a pack fire, and Tesla battery packs burn and/or explode with some regularity?

As in at least twice this month, most recently:

https://www.youtube.com/watch?v=SwbnRH2osZE

You think when the investigation is complete, it just might be determined that the pack in that Tesla caught fire?
 
From what I understand, actual Tesla pack fires are really rare. I haven't followed it super closely, but most NHTSA reports with a Tesla fire that were publicized had most or all of the battery intact, with the rest of the car burning down. If there was a battery fire, in most cases this was contained or signalled well in advance to the driver before it became a problem. TL;DR: not all Tesla fires are battery fires.

Nissan Leafs have had battery fires! I know of at least two that are relevant to my project, in that they were either rebuilt or replaced packs that spontaneously caught fire and caused the rest of the car to burn down as well. One was due to water ingress in a poorly resealed pack, one was an old pack that was overdischarged fast-charging. I'm sure there are plenty others, but I wouldn't know where to get those statistics. There are certainly more than zero.

Furthermore, Tesla is stressing the batteries and surrounding electronics a LOT more. A P100D is essentially a hypercar by any definition other than top speed and price. They're pulling what, 500kW from the pack? When the pack is already pre-heated? If you're hammering the pack like that, it's simply Arrhenius' law that you're going to increase risk of thermal issues. I'd be interested in the actual comparative statistics.

And just to be clear: I wouldn't be driving a 2011 Leaf and be putting so much effort into improving and customizing it if I didn't think it was a great fit for me and a good car in some sense. But it's really staggering how Tesla is making such excellent electric vehicles (as in: fit for purpose as an electric car, taking advantage of the inherent strengths of electric drivetrains and at the same time putting effort into diminishing the biggest weaknesses) while a very established car manufacturer like Nissan is struggling so much with many times the engineering and manufacturing capacity, seemingly. And they still are, I don't consider the 2018 Leaf to be that much better engineering-wise.
 
Off:-topic:

mux said:
... I haven't followed it super closely, but most NHTSA reports with a Tesla fire that were publicized had most or all of the battery intact, with the rest of the car burning down. If there was a battery fire, in most cases this was contained or signalled well in advance to the driver before it became a problem...
Those statement are demonstrably false.

mux said:
..Nissan Leafs have had battery fires! I know of at least two that are relevant to my project, in that they were either rebuilt or replaced packs that spontaneously caught fire and caused the rest of the car to burn down as well...
If you are unable to document those statements, any reader would be wise to consider them as most likely false as well, as no reputable source has ever reported a Nissan LEAF pack fire, even when the packs are severely damaged, or when LEAFs have been entirely engulfed by forest or structure fires.

And pack fires in all other USA market BEVs are nearly unheard of as well, as their packs also are designed to be extremely fire-resistant.

Tesla alone among major BEV manufactures decided to sell BEVs with packs that burn intensely and/or explode when damaged or exposed to an external heat source.

The record to date is really quite clear. Look into it, and if you have more to say on these subjects, please do so on an appropriate thread.
 
Alright, considering you have more information on this: can you start a thread with falsifications for my statements? I agree its off-topic here and I have only had cursory glances at NHTSA reports whenever they appeared in appropriate subreddits. I don't care enough to dive into the statistics myself but am happy to concede or discuss.
 
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