Tesla battery pack?

In his own words maybe this is what's happening?

You probably meant "cool," but yes -- your data matches my experience, and those of many others. They won't "cook" if they're in good health!

You absolutely do not need to cool Tesla batteries. I'm testing with 100 constant amp draws the temperature doesn't go up more than 1 degree.

I wonder if it might be time to close this thread. It seems to have gone off the rails.

They were your implication. I challenged your understanding and experience with certain lithium topologies as used in residential-scale ESS, and one of your responses was that lithium only makes sense for traction applications and doesn't make sense for residential. But there are whole other categories of users where it also makes sense, some of which involve using very large packs.

The term "battery monitor" is overloaded, so you'll need to be specific. However, I agree with you in part: active battery management systems are generally a waste of money, and they introduce risk with almost no reward.

State estimating monitors, however, are very useful. You might not realize that, because you're not living with one every day like some of us are.

Incorrect. We've had a lengthy discussion up thread about various monitoring algorithms. Each have tradeoffs. The very newest designs ameliorate most of the downside, and they take into account many of those "variables" to which you allude. Moreover, they appear to have good accuracy -- more than usable for making determinations about what to do when.

Can you link us to studies that show that 80% SOH lithium cells are about to die? That would be interesting reading.

Yeah, it's almost a worst-case scenario: lots of great historical experience, but absolutely no contrition, no ability to carry on a measured debate with other adults, and a willingness to double down on his outdated or mistaken understandings when push comes to shove. (And a lack of timely, real-world experience.) I think the rest of us can carry on without him, though, just fine.

So, I think we've gotten to the bottom of things: you don't have any operational experience with a residential-scale lithium ESS.

I'm not sure who Karrak is, but I can promise you this: when you post incorrect or misleading comments, I'll be one of the first to set you straight. Not because it matters what you think, but because the rest of us deserve a productive place to share information while not behaving like my seven-year-old.

Here's to the next eight years!

I have just recently chosen to ignore SK's rants. It is too much work to pick through all the BS to find a snippet of useful information..
I too would like to hear about SK's Lithium experience, especially if he has found a way to extend the life of those Nissan Leaf modules. He advocates bottom balancing but offers no evidence about how it can extend the life of those modules in an ESS.

Ben here for 8 years, all you gotta do is look. When I came here the forum was buried deep in search pages. Today the number 1 hit aand I have a lot to do with it. Folks come here to get straight answers Karrak. You only came here to harass me and a 1-trick lithium pony as you have admitted many times on other forums.

You seem really interested in your peculiar (and largely useless) definition of "SOC". When most of the rest of use a tool to estimate "SOC," we care about how much usable energy we have available, right now. Not how much theoretical reaction space is left in the chemistry of each individual cell.

In real life, in an actual system with a conservatively-managed pack that is healthy, the available storage is dominated by the need to stay away from the limits of the charge envelope, not the cell that happens to be a few percent weaker than its cohort.

I'm not going to debate this with you again, because it's a matter of subjective opinion. But for the benefit of other readers, please do not allow yourself to be dragged off course by sunking's perversion of this common, useful concept.

I almost forgot: you have chosen not to tell us about any of your lithium ESS experience. When do we get to learn about what you've done?

Niche applications are often where the most interesting problems and novel applications of technology. Many of the threads started in this forum are from people looking at a mobile application.

Sometimes those folks are also misguided (either by a salesperson or their own optimism), but that's true with just about anything.

No it is not, 100% SOC has nothing to do with capacity unless you know what full capacity is of the weakest cell. Only way to find that is with a Capacity test which is always going down with each cycle. 100% of nothing is nothing. That is the problem using voltage as SOC.



This sounds like a reasonable opinion, and I mostly agree with you. But to put it in absolutes like that is a mistake: costs are coming down, safety data is piling up. LFP-based ESS are a booming business in some parts of the world, where the needs and demands are different. Cobalt-based ESS offerings are on the market and not burning down houses left and right, yet. The future is soon.

I do not, those are your words, not mine. Bottom Line is battery monitors are up-sales for greater profits. About all they are good for is to tell you that you need to shut down and recharge which is the good ole Idiot Light in autos. There are way to many variables that no algorithm can predict with any meaningful significance.

Now there is one method that is useful and can at least tell you when your battery is at 80% rated capacity, and thus time to replace the battery because after 80% capacity death is around the corner. That would be the battery Internal Resistance. When it doubles in value, capacity is at 80% of rated capacity and time to replace. Makes no difference what the chemistry is. To do that takes a simple 1-minute load test using Dv/Di test.Sounds like complicated calculus which it is to laymen, but is stupid simple.

Your point earlier seemed to be that it was better than an estimation tool that incorporates voltage.

That's silly. A current-integrating estimator is much more useful than that. Within the bounds of reason (and time), and much moreso with sync events.

Incorrect. Most monitors will resync at a "full" charge, and many are programmable to stipulate what "full" means.

This sounds like a reasonable opinion, and I mostly agree with you. But to put it in absolutes like that is a mistake: costs are coming down, safety data is piling up. LFP-based ESS are a booming business in some parts of the world, where the needs and demands are different. Cobalt-based ESS offerings are on the market and not burning down houses left and right, yet. The future is soon.

Don't assume there is only EV and residential.

There is also mobile residential -- boats and RVs -- which is a niche market that nevertheless is sizable and growing. This is where you find large packs, operated at low rates, augmented with multiple charging solutions. Mostly LFP, for safety.

I'm all for pushing back on hype and people with an agenda, but the way you choose to do it is unproductive and detrimental to the forum. I can't stop you (this isn't my forum; I'm not a moderator), but when you post wrong or incomplete or biased information, expect to be corrected.

Agree all niche applications. Just like over 150 or so Cellular applications that no commercial power is available at any cost. Using off-grid battery when there is commercial power available is foolish.

You are in the battery and energy storage forum, not the solar power system forum. What are talking about here are batteries. We measure those in energy.

So, now that we are on the same page, can you tell us about your personal system? We want to know about your lithium-chemistry storage system(s).

You might be surprised how many residential-scale storage systems are in use in mobile applications and in remote geographies. It is a niche market, but one that is growing and that pushes the edge of the performance envelope.