Course trailer and Coupon Code:kzbin.info/www/bejne/ZnfLY2mJitOhrpI

Thank you!!! Good videos, I have seen a few of your videos and they are far better than most not only because of the information but the way you share it! As far as I'm concerned an instructional video is NOT a music video, so I appreciate the fact that no music is included, and we can clearly hear what you're saying, just like in a classroom, thanks! :) If teaching was more effective with music, classrooms would blare loud music while the teacher is speaking... ;) Keep up with the great instructional videos, the information is what's important! :)

You are the only one who describes the way you test and interpret values that exactly. Thank you!

In a solar application when you have many days with no appreciable solar gain I find that lithium is worth their weight in gold. With FLA batteries sulfation is an issue unless they a fully charged. In rainy parts of the world FLA batteries can be at a partial SOC for weeks on end causing irreversible sulfation and batteries degradation. On the other hand Lithium ion can be at a partial SOC with no I'll affect. This is a very difficult thing to put a price on. In the real world of solar FLA batteries are a thing of the past.

Great video. Excellent analysis. The biggest downside of FLA for me are: - long charge time, - maintenance. If we think about it, longer charge time, also means higher electricity cost. That cost is not factored into your calculation. The longevity of 12yrs for a lead-acid is a pipe dream. Even if it's possible, it won't be the brand that costs $0.25/Wh. On the other hand, any lithium could last for 12yrs.

Very nicely presented comparison, nice logical approach to the subject, very comprehensive and very clearly explained. Many thanks.

I have ran 8 (Sam's club specials) 6 volt Duracell golf cart batteries in my 48 volt system and they actually did pretty good. I did put them to work and they have seen many cycles and held up but the real world life expectancy for batteries like this are around 3 to 5 years. I am in my 4th year and the capacity has dropped enough that they need to be replaced. This time I am considering going with LiFePO4 Batteries and from everything I'm reading about these batteries is that if you stay within the manufacturers guidelines of the the LFeP04 batteries that you will get a lot more lifetime out of the LFePO4 Batteries vs lead acid batteries. The price really needs to drop to make this affordable for the average person and this is why the flooded lead acid batteries are still selling pretty good for solar projects. The price was my only hesitation on going with iFePO4 Batteries the first time around with my system.

Could you do a new video based on the new energy usage value now that everyone in the UK now pay 80% more for their energy please. I know lifepo4 will win now.

Li-Ion does not have the PSOC - Partial State of Charge issue that Lead Acid does. Lead Acid batteries require a much longer Absorb Cycle, which requires many more Solar Panels to get Lead Acid up to 100% SOC before the sun sets. Under-Charging a Lead Acid battery, leads to sulfation and an early death. There are many PRO's & CON's to compare.

Great video. You deliver in a clear, concise and very understandable manner! Thanks for sharing your technical knowledge. Much appreciated!!

Not sure if the costs of lithium Iron phosphate have come down dramatically recently. It looks relatively easy to find 12 volt 200 Amp hour LiFePo4 batteries for around $600. $600/2400Wh = $0.25/Wh. Seems like a no brainer at that price. Hopefully prices keep dropping. I want to build an off the grid home in a couple years.

Outstanding explanations with the added diagrams. Very professionally done, thanks Jesse.

Great report. {I had to edit a "typo} Now 2 years on - I guess we can establish the 7% per year reduction in LiFePO4 initial cost and update the difference between types. My interest in not a stationary site, but my Camper Van. In my situation, there is a very significant difference in weight between the 2 types. LiFePO4 come in at about 30% of the same size (Ah) Lead Acid Bank. When comparing 200 Ah vs 200 Ah and factoring in Depth of Discharge; Lithium would be about 20% of the weight. To get a 200Ah house bank, that would be 200 extra pounds of weight using Lead Acid. [400 Ah lead Acid to equal 250 Ah to get 200Ah effective] Not scientific, but the "Hot Rod" rule of thumb; is 10 pounds = 1 HP. The Lead Acid bank nets a MINUS 20hp, with attendant "lifetime" fuel costs. The US EPA reported 100# can lower fuel economy by 1%, so a net loss [with 200 AH House Bank) is 2% decrease in MPG. While "small" about 20 gallons of fuel per year, up to $60-$100 per year increase in fuel. Considering LiFePO4 "life span" nominally 10 years, the fuel cost offset [$600-$1000] would offset the initial investment and the likelihood of a Lead Acid Replacement during that period. Well, I think I have convinced myself which path I'll take. Thank you. Regards, Jim

Fine video ...calm, intelligent. Your outlines are smooth, lucid, perfect for english speaking professionals :] Thank you for your tips and insights ... brilliant and very generous. Thank you!

I am sure your calculations are correct. With my home made power wall I have found the number of cycles a Lion can preform before going bad. Had more to do with how cold / hot it has gotten and how many times this happens. after 6 years of heavy use I lost 5% on my home made pack of 18560. Total of 2kwh the packs farther away from the cooling vent have more loss.

Great will buy a AGM lead carbon battery already have two Lithium 500 watt Jackery power stations.

An excellent presentation, thank you. Consideration should also be given to whether the battery is being used in a fixed setting or a mobile one. It takes energy to move mass. If it is a mobile application, the lithium weight savings reduces the cost of moving from one place to another. If the battery is being used in a fixed location, the weight differential might not even be a consideration.

Thank you. helps me make my choice!

Super video, thanks

I'd love to see an update 3 years later because as you said, lithium batteries are new and there are frequent upgrades. Are your verdicts still the same?

Dekuji , super info

Thank you

Bought your course on Off-Grid and just starting watching the first videos. That said I am building my own lifepo4 battery with 16 grade A 280ah modules, that I just bought (May 2022) I was able to find them for 2200 euros in total including a strong 300A BMS with 80% capacity it’s 0.20 euros per KWh… with the peace of mind of having no maintenance and such great performance. I think in the future lifepo4 or other lithium batteries will be a no brainer compared to lead acid

Thanks for the information. I found out about your work from Jason from Primal Outdoors or from his new KZbin channel.

As unbiased as you can get. Great video

Thank you so much. What about temperature range between the two?

Apologies if I missed it. I was under the impression that lithium can accept a much faster charge than lead acid. That might contribute to cost to charge. I'd heard it makes a difference in fuel economy when used as a car battery. I'm still looking for a report on that.

I have a off grid cottage in eastern Ontario Canada, would like your opinion on a generator automatic transfer switch when the lead acid battery bank drops to 50%. This is crucial in the winter with little daylight and snow covered solar panels. Thanks for your informative videos.

I watched a documentary regarding the useable life in Lithium car batteries using data from car companies that had been producing electric cars for a decade or so. The main point of the documentary seemed to point out that in electric cars that had no system management software (Nissan Leaf) the battery performance diminished rapidly. Whereas in the Tesla cars which do have a management software the battery performance over the life span was markedly better. I have no doubt this also is the same for whatever purpose the batteries are being used for. The reason for the differences seemed to be based mainly on the temperature of the batteries over their lifespan. The ones that had the benefit of the management system and had their temperature monitored and controlled seemed to fare much better. Just wondered on your comments on this? Also, are you excited by the fact that we are getting closer to 'solid-state' lithium batteries and would you invest in companies that are researching this technology ?

Would u recomend any lithium if client require stable voltage, no maintenance in door starage ,High Dept of discharge.

Excellent video, as always! I do have one question. How would a Lead Crystal battery compare here? Is it an alternative to traditional AGM/GEL batteries? And can it be charged with normal 3 step chargers, I does look as if it has a somewhat different charge profile but it also seems to be a better performing battery, if it is used correctly. Would be interesting to see a video about this topic. Thanks!

In Australia I can’t get a flooded lead acid to last any more than 3 years But interesting on your theories I just built 2x16S48 volt packs and hoping to get 7 years service from them but good luck to every one and stay safe !

In 2024 LiFePo4 prices got that cheap that they are comparable to AGM, especially as they are VAT free in some EU countries due to solar engagement of goverments.

Thank you for another great video Jesse. I've been doing my homework on lithium battery cost/benefit and it seems that the capital cost is now dropping faster than 7% p/year. DIY Solar with Will Prowes recently did a bench test of BigBattery .com 12 and 24-volt Powerblock batteries and revealed a cost of $0,45 and $0,35 p/watt hour (USD). It's remarkable how competition for this space seems to be driving capital costs down so rapidly. Bedankt!

Is the basic advantage to using a dc/dc charger having a ramped 3 cycle charge? The dc/dc charger can not make more energy than the alternator can produce, but does it change the current to higher amps and lower volts?

Interesting video but I have a couple of questions. What happens to different battery types at end of life? Which are easier to deal with & recycle? Will Super & ultra capacitors enhance or eventually replace other energy storage systems?

Hi Jesse, interesting video. Only thing that bothers me is this: You compare life cycle when charging/discharging every day. Thats not real world. And gives a completely wrong image. When you for example would charge/disch once a week Then lead acid would be dead after 8 years, but Lifepo4 would run happily for many many years. Also when Not using a lead acid battery for say 4 months, you can usually throw them away., kaput. Lifepo4 battery's don't care, and stay happy uncharted for months. When you take is in consideration lead acid is very expensive and heavy. I have a camper an and replace my lead battery's 3x 90Ah approx 100kg for Lifepo4 2x 150 Ah approx 30 kg. And when I'm not using the camper, the battery's don't die on me. Groetjes, Rijk Almere

Some manufacturers even use a very low 50% REMAINING Capacity for their End-OF-Life

damn didnt know it was that expensive, 0.3-0.4usd per kWh for LiFePO4. That's more than most people pay over the world for grid power.

Thanks for the information! Could you please do a video on the best battery for the application. Off grid seasonal Off grid full time grid back up 10-20 cycles per year grid back up 20-100 cycles per year grid back up 365 cycles per year

Foam batteries (firefly) a vid on this would help

With updated prices, I get LiFePO4 is 7X cheaper ($/Kwh-cycle) over battery life than deep cycle lead acid with LiFePO4 50%DOD and deep cycle Pb 30%DOD.

$1 per wh seems very high, whereas I've heard of nmc lithium batteries for less than $200 per kwh...and Tesla powerwall is ~$520 per kwh. What's driving your cost estimates? Thanks!

Whats a Betry?

Can you do the same calculations with a (IFLA) forklift battery?.... it is probably half the price of regular FLA... capacity is given at C/6, not C/20...capacity @ C/6 x 1.57 = capacity at C/20.. and discharge at 80%, can last 20 years,

Interesting. An engineer who posts on You Tube as well, knurlknar24, came to the same conclusion. Hard to argue with the science. I am still using AGM's but have been seriously considering going to Lithium Iron Phosphate. This has me pausing right now. One thing I don't like about the lead acid battery is that one really should only use 50% DOD for longevity of the battery and Lithium and I can supposedly take it down to around 10% without harm. That means a LOT less battery pack in terms of size and weight.

This vid may be outdated since lithium much cheaper today

this was a surprice to me .... i thought the lithium batteries had become cheaper than lead acid by now

I would like to know how to size solar panels, inverters, and batteries in a way so they all work well together. I don't want to waste money on oversizing one set of components.

Lifepo4 batteries have come down in price a lot.. If you know where to buy, not retail then they can even be cheaper that lead acid

2 years ago

Just one more point. Lithium is much lighter so it's great for electric cars and planes.

What about the nasty Peukert Effect in Lead Acid Batteries? Having huge load spikes like electric kitchen appliances is not a rare circumstance. The Peukert effect is not applicable in LiFePo4 as it is compensated by the self-heating -> capacity increase effect. It should be part of the comparison to make it an apple to apple one let alone the nasty consequences for lead-acid batteries when staying in a 50% SoC for several days during non-laboratory real-world circumstances.

This video is already out of date in pricing. LiFePo4 prices are much lower now. Example: 3.2v 280AH 896wH cell Sells for $80-90 per cell This means, based on 80%, this battery has $0.11/wH cost. This is greater than 50% cheaper than Solar Solution quote of lead-acid cost of $0.25/wH

If you are willing to DIY a LiFePO4 battery, it can be competitive. I purchased raw LiFePO4 cells for $1420, shipping included to build a 25.6V, 202AH nominal pack, or around 5 kWh. I also had to purchase a BMS, some wire and connectors. All told, I spent no more than $1700. That is about 34 cents per watt-hour, and I know there are places out there to get the raw cells for less if you're willing to wait 2+ months for shipping.

I like how your cost per use conveniently doesn’t include maintenance, which is a big disadvantage for lead. You never talk about entertainment density or charge rates which make lead more difficult to build a system. also with Lithiums high usable energy capacity the 80% EoL standard isn’t apples to apples because a lithium battery would still have more usable energy at 60% EoL to a lead battery at 80% EoL.

For fixed installations, it's still hard to beat lead acid. Very durable especially to temperature extremes, and dead cheap. Not great for weight or power density but with fixed sites you usually don't care. For vehicles the power density of lithium makes more sense.

$1/KWH for LiFePO ? No way. I'm paying $0.35 /KWH (at 80% usage) for 48V 28AH ($381 each, including shipping and charger) and that's not even a very good deal. Note also that going to 80% discharge, these batteries average 51.5V, not 48V, so the actual cost of my slightly-over-priced batteries is actually $0.33, and I have tested the capacity, which is as claimed. I also buy 12V 35AH AGM (lead-acid) at $60 including shipping, but the LiFePOs are more efficient at fast discharge.

One big disadvantage of LA batteries that you did not mention is that they are hard to charge! If you start with a fixed amount of power to charge the batteries with, lithium will absorb & store much more of that power for later use than LA. Trying to charge LA batteries from about 70 to 100% requires a lot of energy, not very efficient in that range. Typical sealed LA batteries are only good for about 3 years. So I guess you are comparing lithium with flooded LA batteries. Flooded batteries are hazardous because they contain acid and vent explosive H gas. You also have to add water all the time, maintenance is painful.

Lithium is way too expensive . I don't know how people can even buy those .

Tesla Model 3 battery brick on ebay = $2000 / 18 kWh = $111/kWh / 3500 cycles = $0.03 / kWh. Lead is dead.

Did you consider risk into the equation? If 1 time the FLA battery is drawn down past 50% or down to 0% which is likely in off grid applications the batteries are ruined. Risk is not free or insurance wouldn't cost anything. LifePo4 has "supposedly" no degradation if drawn down fully. If you are off grid and have the chance of drawing down your bank to 0 or close to 0 then you should NEVER buy FLA batteries. Example, customers well pump faulted and ran overnight. Batteries drew down to Zero state of charge. Her 1 year old $8K AGM battery bank was ruined.

Battle born 10 year warranty...

Lead is dead boss, sorry. Good try though.