I have found a similar uses for my old 12V and 24V batteries, but .... mmm. I don't think that's a good reason to actually go-out and buy a 12V battery, even if incremental expansion is the goal. You can buy 25Ah 48V batteries (The 48V (51.2V nominal) Lithova)... that's about the smallest increment possible for 48V and it is equivalent to a 100Ah 12V battery. I personally think that 2.56 kWh (50Ah @ 48V, 100Ah @ 24V, or 200Ah @ 12V, all LiFePO4 of course) capacities are the best compromise for weight and portability. Easily lifted and carried around. -Matt

when you buy all the cables and breakers you may find the server rack cheaper, and more durable.

@@davidparker7156 Absolutely correct. BMSs fail all the time too..

400 bucks difference 😊

Awesome, thank you!

It is, but it is not ideal because you are losing out on redundancy (parallel connections) and robustness (balancing is never perfect) when you do that. And its a lot of cabling and takes up more space. But still perfectly doable if no other configurations are economically feasible.

@junkerzn7312 if you already have 2 * 12v 60ah agm batteries to swap to 48v you only need 2 more which is about $130 and an all in one (like a vevor for about $260) so for less then $400 you can swap your agm 12v system to a 48v system then in a few years get a lifepo4 battery or something

@hy1 It doesn't make a whole lot of sense to try to scale-up an old 12V lead-acid system that small, particularly if it would mean mixing batteries of different ages. Better to save up your money and do a complete replacement with LiFePO4 down the road. The voltage you go with really depends on just how big a system you expect you might ever want. If the system is expected to remain small (i.e. less than 1000W of solar, less than 5 kWh of usable storage), it is totally reasonable to go with 24V for your upgrade project instead of 48V. A 24V system can be comfortably built with 50Ah or 100Ah 25.6V LiFePO4 batteries. So roughly storage between 1.28kWh and 5.12 kWh, inverting power up to roughly 2.5 kW, and up to 1000W of solar using 2 AWG main battery cabling and typical bus bars and other low-cost components. If the expectation is that the system would grow more than that in the future, then I'd go with 48V from the beginning. -Matt

The only time you'd want to stick with a 12V system is if it is a really, really tiny system, like literally if you just needed 20Ah or something, or if the entire system is just running one piece of equipment, or if you simply have too much high-powered 12V legacy gear that upgrading is too expensive for you. Those are all good reasons to stick with 12V, but that's about it. Most people blow past the system size where one really ought to have considered going to 24V or 48V and many people wind up stuck with huge 12V systems and lots of problems due to that, especially thermal issues. Often, someone will "start small" and not even realize where that will take them in the future. They select 12V, and wind up stuck with it. Space, weight ... all of that is the same for a 48V system as for a 12V system. 48V systems are actually lighter, in fact, because you can use much thinner cabling. Now of course, the whole point of going with 48V is that the large-load items (inverter, A/C, space heaters, etc)... those run off the 48V system (or run off the AC inverter). That represents the economic hit... the "upgrading" that you might have to do. -- Remaining bursty/low/medium-load 12V legacy gear is easily dealt with. Fridge, lights, toilet macerator, run-outs, levelers, etc. For those you use a 12V down-buffer. Basically a DC-to-DC charger and a 12V battery sized for the loads. No inverter (inverter hangs off the 48V system). It's utterly trivial and the flexibility is immense. And buck converters are like 95% efficient too... no power is being wasted. Some people even just use a 48-to-12V DC-to-DC directly without a down-buffer battery, but I prefer the DC-to-DC charger + battery solution for the 12V legacy gear for multiple reasons. It can be tiny... literally fuse + Victron 75/15 charge controller + 20Ah 12.8V LiFePO4 battery. Or more substantial depending on the remaining legacy loads... A 100Ah 12.8V LiFepO4 battery is usually plenty. Or really beefy with a Victron DC-to-DC Orion charger (in a big RV for example). That might seem complex, but it's actually not... it is completely trivial. One can ask... why go with 48V if there is still 12V gear that needs to be powered? One goes with it because the thermals are low, the cabling is far easier, and you can scale down the road incrementally without having to upgrade other components. Think about the solar for example. On a 48V system, ONE little 20A charge controller can handle 1000W of solar without even breaking a sweat. There's a lot to love her. -Matt

Have you tested these batteries to see if they actually are 150 ah?

Do yourself a favor and buy the 48v "battery equalizer" right away. Those four batteries will drift apart, giving you less system output and working one or two of the batteries harder than the others.

There are 48V "auto battery" form factor batteries. I use tons of them myself... no comms. Works just fine. You don't need communication, nor do you even need a hybrid solar inverter. You can build a 48V system with discrete components the same way you build a 12V system. Unless the 12V system is really tiny, like 20Ah, the 48V system won't weigh any more or be any less portable or cost any more than the 12V system. The hybrid solar inverter solutions are really meant for larger systems. They can be useful in that regard... an EG4 6000XP, for example, integrates breakers and removes an immense amount of wiring work from the build. But you don't have to spend the money if you are slapping together something small. 12V systems shine only in very tiny setups... less than 200Ah of storage. Once you hit 200Ah @ 12V of storage, 48V @ 50Ah is better, everything is better, cabling is thinner and lighter. Battery weighs the same capacity-wise. I don't really understand why so many people seem to think that 48V is hard, or more expensive, or takes up more space. It just doesn't. -Matt

@@junkerzn7312 IMHO it's the marketing of these systems that creates this impression. This is a developing market for the average consumer out there, and as technology has improved, recommendations continue to change to meet what manufacturers want to sell. I bought a Battleborn 100ah 12V LiFePO4 back around 2018 or 2019 for $899. I still have it. Back then it was about all you could buy. Today, you have 48V systems being manufactured, and the vendors are pushing them into the market largely via these kinds of videos. Consumers were sold 12v systems initially because that's what was there, and they are used to the concept of 12v because their car batteries are 12v. Now the shiny new toy is a 48v systems, and the marketing juggernaut is now trying to get consumers to spend more money and upgrade. There's a lot of re-educating going on in the space, and it will take time for the average consumer to come around to 48v. I compare it to the same thing that is happening with American car manufacturers: they only want to sell large luxury vehicles, and so have simply stopped making small sedans and economy cars. The day will come when no manufacturer will make a 12v LiFePO4.

Right on Matt

This is a good observation. Even at $250 for a 12v 100ah battery, they cost less than most of the 48v server-rack options. Now, it's not apples-to-apples, because the 48v batteries typically have communication options to integrate with an inverter, but for raw storage capacity, you're right.

$180? That sounds like lead-acid to me though I wouldn't be surprised given the fire-sale prices 12V LiFePO4 batteries are selling at right now. A 100Ah 48V battery has FOUR TIMES the capacity of a 100Ah 12V battery. The equivalent for a 100Ah 12V battery is a 25Ah 48V battery... so something like a Lithova, which is $260 or so. Definitely not $800. As you get into the larger capacities, the cost differential drops to basically zero. Price out 50Ah @ 48V vs 200Ah @ 12V, for example. Then look at 100Ah @ 48V vs 400Ah @ 12V. And so forth. One other thing to consider is that the bigger 12V batteries have smaller BMSs. A 400Ah 12V LiFePO4 typically only has a 250A BMS in it (3.2kW). Whereas a 100Ah 48V LiFePO4 will have a 100A BMS in it (5kW). -Matt

@@junkerzn7312 there are a few different 100ah Lifepo4 on Amazon selling between 180 and 200. I will say I can’t speak to the quality of them so buyer beware.

Yes your spending more. That's said you are generally getting much more from 1 battery vs multiple. For example would take 4 100ah 12 v batteries to even equal one battery.

@@EatingWild Agreed. I think I would like the pricing to be closer though. If I can get 4x12v for under 800, I would say that 1x48v at $1000 would be good enough. It looks like recently in the last week or 2 I'm seeing pricing get closer to that now on the 48v front so it may just take a little more time.

I have a couple of videos that walk through the key elements. The one on that specific inverter is here: kzbin.info/www/bejne/eV62n5h5adSLn6M And I've also done one recently on an upgraded inverter from SunGoldPower here: kzbin.info/www/bejne/iGfQioCMoKesl9U I hope that helps.

@@ReeWrayOutdoors thanks for the videos very useful. You gain a subscriber. I was thinking on a EG4 inverter 3000 all in one and noticed that max current imput is 80amps, what does it means compared to the Powmr? I am a begginer , so i am still learning. I hope you can comment. Thanks again!

@@alexherrera3918 Between the EG4 3000 and the POWMR 5000, I'd go with the EG4 if you don't need the extra power capacity, because EG4 is based in TX and you'll get better service and support, which is definitely worth something. The 80A cited on the EG4 is referring to the maximum current it can provide when charging batteries.

Those are actually for horse bridle storage. Here are similar ones on Amazon: amzn.to/3YK8COO

Pushing house-sized amounts of power reliably can get expensive, for sure. Regardless of the voltage. Usually you don't try to do that unless you are willing to spend like $50K-$100K on a large battery + solar + whole-home system. Instead for the moment I just focus on the critical loads in the home... a few lights, furnace fan, and fridge mostly. I've been planning a whole-home system for ages and it keeps changing... haven't pulled the trigger yet but I'm getting closer. I'm already up to 10 kWh of storage and 2 kW of panels "off-grid" (grid is used for low-battery support only). Most of my house is still on the grid, though. -Matt

@@junkerzn7312 That's what I was thinking a bit back, and even started looking at it again; started looking at a simple UPS for my desktop and the router, as I am in college, and thats how I do my work, but couldn't wrap my head around how it would work and felt I shouldn't mess around with that until I do lol.

@@Suzuki_Hiakura If you want to throw together something really cheap just to play with that is suitable as a desktop UPS, try this for a little project: 30Ah @ 12.8V LiFePO4 battery ($80) Victron Phoenix 500VA 12V 120V pure sine wave inverter ($148). Victron Blue Smart IP65 12V 5A battery charger ($85) An alternatively, you could try a cheap vehicle 12V inverter for around $40 instead of spending $148 on the Phoenix... but make sure it is pure sine wave and don't operate it at more than 50% load (vehicle inverters are poorly built) Total: $313 w/ the phoenix, $205 w/cheap vehicle inverter, not including wiring or wire splices. -- Wiring... 10 AWG cabling is sufficient Wire splices, I recommend using WAGOs for splicing wires together. Get a little $25 assortment. Wire cutters, strippers, etc. -- That's a fun little project to get your feet wet. The Victron charger even has a bluetooth app for playing around with the mode and operation. -Matt

@scottmartinetti4875 if your system voltage is not already 12V, yes. And keep in mind that many DC appliances (fridges in particular) are often already compatible with 12V or 24V so in those cases you might not even need a step-down converter.

@@ReeWrayOutdoors have you seen those electric car generators for $600 in eBay? Auto start, 48 volts. Thinking about doing that in my old Toyota motorhome and then getting a set of 48 volt batteries.

Yeah but you're wasting a ton of space with the smaller batteries. I would rather deal with 4 batteries vs 12-16

No, it didn't come with any cables. I just crimped my own. :)

@@ReeWrayOutdoors that's good to know! What awg did you use?

@thedabbler2753 I used 2awg since it can handle up to about 120A which should be a solid 15-20% higher than the 5000W 48V inverter I'm using will ever pull (and my DC breaker is rated for 120A as well).

Fusing and breakers have to match the capabilities of the wiring they are protecting, at a minimum, or be smaller. The breaker on the battery is for the capabilities of the battery and/or expected battery cabling, often inclusive of battery surge capacity. But this breaker is ONLY for the battery cabling to the bus-bar. It isn't for other cabling hanging off the bus-bar. The cabling for the inverter is typically NOT 2 AWG on a 48V system. So it needs to be fused and often also breaker'd for the smaller of (cabling current capability) and (inverter-size / expected loads). This is usually substantially less current than the battery breaker. Breakers are also often installed even when there is also a fuse on the same cable. The reason is to make maintenance easier to perform. If I want to mess around with an inverter I can just flip the breaker for its cable off and leave the rest of the system live. Same thing for a solar charge controller or any other cable hanging off the bus bar. Even though fuses are there for protection too, having to unscrew and rescrew fuses all the time just to do minor work is really annoying. In fact, solar cabling often has a breaker both in the combiner box AND also at the point where it goes into the charge controller, allowing work to be performed in either location with a convenient flip of a nearby breaker. In solar / battery / inverter systems, nearly all breakers should be 2-pole. Break on both the positive and the negative. Fuses are usually only on the positive. Breakers are generally on both the positive and the negative. All DC wiring must use DC breakers. The breakers on the battery are DC breakers (they had better be!). They are DC breakers and also generally they should be *unpolarized* DC breakers since power can often flow in both directions (plus people wire polarized DC breakers up incorrectly *all* the time, creating a fire risk instead of adding safety).

680 at Amazon (2×48v, 50ah). There is also an option for additional 10% off...

Labor Day sale at HQST.......12v 100Ah for $150 !!!!!......free shipping.....