Thanks for the update jehu, those cells are very specific, but sounds awesome. Remember guys, those are not vanilla batteries. They are made for very high burst (like a spot welder), or for a high load over a few minutes. They are not made for range or longevity. They are rated for a low amount of cycles (in the hundreds, compared to more than a thousand for a classic 18650). The main use I see for them, in a vehicle, is for a dragster. Otherwise you better go for the classic cylindrical 1-3C discharge rate cells (18650 or 21k cells). It will be cheaper and you'll have better energy density.
@@dennisyoung4631 You're welcome. I love my 14s batteries for my bike. Too bad you missed this wonderfull 12S battery, jehu had: ruclips.net/video/ZW6FxARACfg/видео.html Those cells are top notch.
@@piterex7 not at all. Most of jehu sell are pretty good for a power wall. Definitely not those. For a power wall, what you need is the highest number of cycles, everything else doesn't matter. The best at this, are LFP batteries.
Great to see you're rediscovering what we'd confirmed over at Endless-Sphere about a decade ago :) I build most of my Hi-Powered LiPo batteries this way, although I moved on to screws instead of solder. Might see that innovation in a couple of years eh? :D
Tabs on pouch cells are the main heat path and as mentioned below, solder has TONS of resistance. The cells weren't heating up but being heated by the resistors placed on their heatsinks.
Would it be better to spot weld the tabs directly to an exposed copper plane on the PCB? (I've never heard of spot welding directly to a PCB --I have no idea if that'd work 😄 )
There are resistors big enough to handle upwards of 100amp. I've seen other DIYers use multiple when they needed more. Now where you get them, I'm unsure, but you would need either a 300 amp, or 3 x 100 amp resistors. Once you get them, I've seen them add fans and holders. If I come across them again, I'll try and see if they remember where they got them.
Need to build your own load bank. The resistors would be a bit expensive, but you already have the wire to join them all up. Just need a couple large switches to add/remove banks (and _never_ swtich under load.. lol.).
Using some brush on flux would make it flow better. At least that's what I have seen when soldering on larger lugs or pcb traces requiring more heat. Sometimes the flux core just doesn't have enough
The only lithium Ion Cells that i have seen that you can buy that do what they are actually rated to do are "Overlander" batteries. There made here in the UK, so not cheap cells. The high end cells are usually rated around 30C max, but usually 20C, but they will actually do what they say on the packaging. I have used them for years on my model aircraft and you can really punish the crap out of them, I had a 3.2ah 20C rated pack that was old already, that I would pull 60 amps from repeatedly, probably 40 amps continuously, the battery would puff up a bit and get hot, but never ever did it fail, it was old when i bought it and i did a few hundred cycles with it in my E-flite Hurricane and it just kept on chugging along! I would love to see an E-bike build with Overlander batteries in it to see how much punch it would have as they are insane cells.
None of these PCBs or the way they are being connected can handle the 200 and 300 amp loads at all. You aren't considering that a 1/4 inch x 1 inch piece of soldier will raise the resistance by a lot, and resistance equals heat. It isn't meant to handle that kind of current transfer. That's why the pack is getting hot, and that's why the voltage losses are so high across the pack. If those connections were made with a piece of solid copper able to handle those kinds of amp loads, and the whole battery tab was touching that copper and each other, it would make a massive difference in how the pack took the load and how much heat was generated and how much voltage drop there was across the pack. This is why education is so important and why actual electrical engineers should be designing high discharge battery packs, or at least someone who considers the most basic electrical principles, like ohms law, should be making high discharge battery packs. It's all good when people don't know what they are doing and they only need 10 or 20 amps from the battery pack. That's a lot less dangerous than trying to build a pack with cells that output 50c and hundreds of amps at almost a hundred volts DC. If it's not designed properly with very low resistance materials, resistance will be high and cause way too much heat, and it's gonna cause a lithium fire eventually. Please, at least consider ohms law and resistance, and how much copper is needed to safely conduct 300 amps of current and consider how much of the battery tabs are in contact with each other to carry that kind of current. Those cells were manufactured with those big tabs for a reason. It's so they can make a lot of contact with a big piece of copper and have minimum resistance.
No one, including J.G., thought those things could handle 300 amps. Your comment about needing a college degree to understand basic electrical physics is offensive, disgusting, and more than a bit elitist. Your own understanding is a bit questionable: The total size of the solder joint we see does not add to resistance as you imply - in fact, it lowers it. That's why everyone (including your vaunted 'engineers') adds solder to long traces that carry significant current - increasing the cross-sectional area decreases resistance. Yes, the resistivity of solder is almost 10x that of copper, but we're talking 18 mm (guessing..) wide tabs less than 3 mm from each other. The wide width and tiny distance between them _decreases_ the resistance of the joint. To calculate resistance, you take the electrical length in the direction of current flow (about 3 mm) and divide by the cross sectional area (18 wide x ...3 mm high?). So 3 mm / (18 * 3). Multiply that number by the resistivity of the material. 60/40 solder is about 15 x 10^-8, so each joint is about 8.3 nano-ohms. The extra solder around the tabs decreases that resistance a bit more (admittedly not much). If we guess at 0.3 mm thick, the tabs' cross sectional area is ten times less than the solder joint, making their resistance _per millimeter_ the same as the solder joint (without extra solder!), and they're a lot longer than 1/8" (3mm). (Yes, I chose 0.3 as a convenient number, but it's probably very close.)
@@chrisw1462 I didn't say you needed a degree to build a battery pack, I said you needed to at least consider resistance and ohms law. If you were to connecting together batteries and each one was expected to move 300 amps of current, then you would need 0 guage wire to carry that much current from battery to battery, right? Why is this different all of a sudden? A battery like this needed substantial bus bars made of copper or Aluminum of a certain cross sectional area to properly conduct this amount of power, plain and simple. I was never trying to be elitist. Im not an electrical engineer, but I am an electrician, and I'm smart enough to know that this was a poorly thought out, bad design. Jehu has been doing this for a long time, and I know he's smart enough to know ohms law. The fact is, he's on the internet selling these batteries to any idiot that wants to buy them, and they are still advertised as 300 amp capable cells. The way that he put these together was subpar to say the least, the proof is in the outcome of the experiment, and these pouch cells are the most likely kind of cells to start a fire. What do you think is more likely? That L.G. did a bad job manufacturing these cells, or that Jehu did a bad job of building a pack out of them with only little bits of solder? Come on man, the tabs weren't even touching. Using lead free solder does not lower the resistance when it's literally the only thing connecting these cells. Be honest with yourself and just admit this was a bad design and cells like these need to be connected together using big chunks of aluminum at the very least, or more appropriately, copper bus bars of a substantial size and thickness. Somebody is gonna buy these Cells and one of these crappy PCBs and attempt to replicate this, and there is a 50/50 chance they might burn down an entire building full of people or something. Like I said, he's selling these things on the internet and any idiot can buy these cells. If he was going to try to help people make something with these packs, He should had done a much more proper job of finding a good way to connect and compress and actually build these pouch cells into a proper battery pack that wasn't dangerous. This, in my opinion, and obviously other people's opinion, is really dangerous. Anyone who bought these cells and PCBs and copied this and doesn't really know what they are doing is creating a potential bomb. You ever see what happens when someone smacks one of these pouch cells with a bat or a hammer? It's a lot of fucking energy, and having 16 of them together is enough to do a lot of damage to everything from a huge building, to a car and the people in it, to a bike and the person riding it. You forget the ways that people will try to use these things. They will be used in ways you probably can't imagine, and I hope nobody gets hurt when they inevitably do something stupid with these cells. This is the exact reason that LG and Samsung won't sell lithium batteries to just anyone. Because they have the potential to be really dangerous in the hands of people that don't know what they are doing.
Nice board. For applications where the battery needs to be exposed to vibrations, I would prefer to use a more robust connector for the balance port. Like a Dupont connector with locking for example.
Sounds like a better idea than soldering. Although I can't remember what the tabs were plated with, which could be problematic for spot welding, but certainly worth a try.
That soldering iron is great, but inadequate for this job. You may want to invest in a soldering station and some chisel tips that have more mass. That will allow you to put enough heat, fast enough to melt the solder without sending too much heat into the battery.
Cool to see 20S packs. My electric unicycle runs on 84 volts and is considered bottom of the food chain with the newer wheels being 100 to 118 volts now.
If anyone ever needed any visual proof that that soldering is INFERIOR to joining tabs, skip to @17:21 and look at the heat produced at every single solder point! haha
I am going to guess that the 300 amps is a momentary discharge and continuous discharge is much lower. If you try it in your car, mount the battery outside on some sort of standoff arm and have a fire extinguisher handy. I think it may catch fire most likely from any wiring and perhaps from cell overheating if the wires last.
@@Blox117 700A at 1110V is 77,000W. What size DC motor do you need to move a VW bus? Sounds about right to me. You could pull 700A from a bunch of 100Ah cell banks
Hey Jehu, have you thought of making the tab hole wider so the tabs go through it already touching? I bet this would mean, that you need less solder and therefore less heat goes into the cells?
I have an ebike with a 3kw cyclone. I have to turn the torque down to prevent tearing the bike to pieces. Starting my third attempt now with 60% torque and single speed. Seven speed sprockets cannot hold the power, and the teeth just break off. A Sturmey Archer 3 speed is OK in 2nd gear as that is direct drive. 3rd gear bit the dust. And I had to really work on the Sturmey Archer sprocket to make it drive the hub. Ordering parts now for a single speed hub version. I cannot even imagine what would happen with a 22kw motor.
Jump starting a diesel engine might be a good test. DC to DC step down converter. Say 72v to 24v. Just replace the existing battery with your battery and converter. Should take at least 200 amps to crank over. Disable fuel on the diesel motor so it cranks longer but not too long. High compression big block might work too. LOL
Hey, we used water heater heating elements. Take your DMM and go to Lowe's or whatever so you can figure out ac as listed or pure dc load. Hardly ever needed to submerge them in water. obw... don't use salt water :)
I like it but would like a 24V and a 48V Version using series parallel connections. Older APC Smart UPS"s can be had for cheap and I believe 2 24V packs would fit into it and provide a very good solution to the Home Lab crowd! I currently use 2 18650 packs to do this and can keep my whole Lab running for about 4 hours. (Warning! if you do this increase the cooling of the UPS as it cannot run for an extended length of time without over heating!
Also, you are trying to solder dissimilar metals together, the aluminum tab to the copper tab to the copper trace. This is building up a lot of resistance in those solder joints. As shown in the IR the solder points is where the heat was coming from and perhaps, due to the high resistance is the reason you had a flat battery in the pack, its solder point was higher resistance.
@@jehugarcia Thanks for the reply, my apologies for assuming one of the tabs was aluminum. I thought you had mentioned that you were "welding" copper tab extensions to the aluminum tabs in a previous video, then, in this video were trimming the tabs beyond the "weld" point. I am using some bag batteries that have the two different tabs, copper and aluminum... a puzzle...
please try and move the car with the pack! i think with proper thermal management of each cell, this could be quite a potent battery pack for high performance EV's! the only big concern I can think of is thermal management, otherwise youll get some swelling going on
To Speed soldering use a higher wattage iron with larger tip. This allows you to get on and off the joint much faster. In this video his iron tip was way too small.
I wonder if it was possible to overlap the tabs of the cells over one-another on a bare copper patch on the pcb and spot-weld them in place onto the pcb itself... I once had a battery pack in my hands were the tabs were laser-welded to thick copper bus-bars. Clean af but costly to make...
That is exactly the kind of process that these cells need to be made into a proper, well performing battery pack. These were made to be built into an actual battery pack in an enclosure using bus bars of the correct size. It also needs to be contained, protected and slightly compressed. These pouch cells are the most dangerous kind of lithium ion cells, and they should be in something that gives at least a little protection. You can't just slap these things together like this and expect these cells or this kind of slapped together pack to put out 3,000 watts continuous with only tiny solder connections. Jehu should know this. He's been doing this long enough and he wouldn't try to build any other 3,000 watt battery pack like this.
We should make a contraption box for charging this battery pack. Make a box that is ventilated with in/out fans on opposite side. Then please lets apply this pack practically in an e-bike, and show us the performance. Like - capacity test, temperature monitoring while using it, etc
I'm still believing that copper or nickel strips would help the current transfer and reduce the sagging, though it would need to be tested for this theory to be proven
Hook up metering equipment and get some ark welding electrodes (electrode positive) ground negative, and weld something and check the draw current 😉 👌🏻
as per the site specs those batteries are rated 12 amps continuous discharging ,and just temporarily bursts of up to 50C not to tolerate continuous 50C that's why they are over heating ? just saying .
series volts add up parallel amps add up, so 300 amp at 30 amps per cell would be 10 cells in parallel, at 3.3 volts, so i am not seeing 72volts at 300 amps in your pack? do i? are you adding amps when they are not to be added in series?
I'm getting to a point I am going to build a battery bank for rv. Great videos on testing inverter and batteries. 13:00 Your so close to saying it. Make a 118 volt so when loaded it's nominal voltage, and directly wire heaters. Resistance type, same as what you have. If they have basic circuits, most heaters that are ac can also run DC in a pinch. Most electronics rectify the ac anyway to DC for control voltage and heaters are great for DC test too. Or get a load bank tester
I want to make a 72volt battery what would be your best battery for the specifications i need it for? i need a pack that is not to bulky and maximum space of 14" W X 15" L X 4" D to sit flat on a scooter I am wanting to build and perhaps connect two of the same packs to make the capacity greater....so what batteries do you have that I can possibly use that can discharge fast for such a pretty quick strong motor ill be putting?.
That's not what they are made for. Those high discharge battery are made for huge burst (50C), or for 10mn high load. Not for a 1h trip with a scooter. They are mostly used in RC models
Those packs are made for huge burst (50C). Or high rate 10mn discharge (we are talking dozen kW). If your unicycle doesn't need that type of load, go for a classic 18650 battery, better energy density, way less expensive
hey man! superior work! is this pack capable to run mid drive motor like QS 5KW 165 ? i mean if you make an assembly of enough cells. sorry if the question is silly, i am absolute 0 in batteries and voltages etc... thanks in advance! and thanks for classy content!
The standard is distance per watt hour. Like miles per kilowatt hour, or KM, per kilowatt hour. A unit of fuel has a particular energy when used in an ICE. So we get things like miles per gallon, and KM per liter. Unfortunately the energy in the fuel varies a whole lot from summer to winter and now with ethanol added you lose a lot of energy per gallon. MPG is basically just a guess at the efficiency of the vehicle.
Thanks for the update jehu, those cells are very specific, but sounds awesome.
Remember guys, those are not vanilla batteries. They are made for very high burst (like a spot welder), or for a high load over a few minutes.
They are not made for range or longevity. They are rated for a low amount of cycles (in the hundreds, compared to more than a thousand for a classic 18650).
The main use I see for them, in a vehicle, is for a dragster.
Otherwise you better go for the classic cylindrical 1-3C discharge rate cells (18650 or 21k cells). It will be cheaper and you'll have better energy density.
Thanks for the information. Am planning to make up my own batteries, mostly 14s.
@@dennisyoung4631 You're welcome.
I love my 14s batteries for my bike.
Too bad you missed this wonderfull 12S battery, jehu had:
ruclips.net/video/ZW6FxARACfg/видео.html
Those cells are top notch.
So you would not recommend them to build a power wall to last at least 10-15 years ?
@@piterex7 not at all.
Most of jehu sell are pretty good for a power wall. Definitely not those.
For a power wall, what you need is the highest number of cycles, everything else doesn't matter.
The best at this, are LFP batteries.
Great to see you're rediscovering what we'd confirmed over at Endless-Sphere about a decade ago :) I build most of my Hi-Powered LiPo batteries this way, although I moved on to screws instead of solder. Might see that innovation in a couple of years eh? :D
Absolutely awesome video jehu. Very cool to see the "50c" cells struggle. And that cell #3 was hot!
Tabs on pouch cells are the main heat path and as mentioned below, solder has TONS of resistance. The cells weren't heating up but being heated by the resistors placed on their heatsinks.
Yes. Horrible idea!
Would it be better to spot weld the tabs directly to an exposed copper plane on the PCB? (I've never heard of spot welding directly to a PCB --I have no idea if that'd work 😄 )
There are resistors big enough to handle upwards of 100amp. I've seen other DIYers use multiple when they needed more. Now where you get them, I'm unsure, but you would need either a 300 amp, or 3 x 100 amp resistors. Once you get them, I've seen them add fans and holders. If I come across them again, I'll try and see if they remember where they got them.
Manufacturer: These cells can do 300A.
Me: And survive?
Manufacturr...
Me: and survive right?
YOU ARE THE BEST JEHU
To test it, put a big piece of metal in some water and dead short the battery with the metal while an amp clamp is connected.
then you damage the battery
Hello sir looking good and sound much better great too see u in action what we do without you !
Thanks for the live Lab work
I think those batteries are for spot welders or emergency starters for cars.
They are also vastly used in the RC world. Those applications need a lot of specific power.
Need to build your own load bank. The resistors would be a bit expensive, but you already have the wire to join them all up. Just need a couple large switches to add/remove banks (and _never_ swtich under load.. lol.).
Using some brush on flux would make it flow better. At least that's what I have seen when soldering on larger lugs or pcb traces requiring more heat. Sometimes the flux core just doesn't have enough
Hello sir , glad to see you looking better and you sound good too !
The only lithium Ion Cells that i have seen that you can buy that do what they are actually rated to do are "Overlander" batteries. There made here in the UK, so not cheap cells. The high end cells are usually rated around 30C max, but usually 20C, but they will actually do what they say on the packaging. I have used them for years on my model aircraft and you can really punish the crap out of them, I had a 3.2ah 20C rated pack that was old already, that I would pull 60 amps from repeatedly, probably 40 amps continuously, the battery would puff up a bit and get hot, but never ever did it fail, it was old when i bought it and i did a few hundred cycles with it in my E-flite Hurricane and it just kept on chugging along! I would love to see an E-bike build with Overlander batteries in it to see how much punch it would have as they are insane cells.
None of these PCBs or the way they are being connected can handle the 200 and 300 amp loads at all. You aren't considering that a 1/4 inch x 1 inch piece of soldier will raise the resistance by a lot, and resistance equals heat. It isn't meant to handle that kind of current transfer. That's why the pack is getting hot, and that's why the voltage losses are so high across the pack. If those connections were made with a piece of solid copper able to handle those kinds of amp loads, and the whole battery tab was touching that copper and each other, it would make a massive difference in how the pack took the load and how much heat was generated and how much voltage drop there was across the pack. This is why education is so important and why actual electrical engineers should be designing high discharge battery packs, or at least someone who considers the most basic electrical principles, like ohms law, should be making high discharge battery packs. It's all good when people don't know what they are doing and they only need 10 or 20 amps from the battery pack. That's a lot less dangerous than trying to build a pack with cells that output 50c and hundreds of amps at almost a hundred volts DC. If it's not designed properly with very low resistance materials, resistance will be high and cause way too much heat, and it's gonna cause a lithium fire eventually. Please, at least consider ohms law and resistance, and how much copper is needed to safely conduct 300 amps of current and consider how much of the battery tabs are in contact with each other to carry that kind of current. Those cells were manufactured with those big tabs for a reason. It's so they can make a lot of contact with a big piece of copper and have minimum resistance.
Also the type of solder. Leaded may be better for this process.
No one, including J.G., thought those things could handle 300 amps. Your comment about needing a college degree to understand basic electrical physics is offensive, disgusting, and more than a bit elitist. Your own understanding is a bit questionable: The total size of the solder joint we see does not add to resistance as you imply - in fact, it lowers it. That's why everyone (including your vaunted 'engineers') adds solder to long traces that carry significant current - increasing the cross-sectional area decreases resistance.
Yes, the resistivity of solder is almost 10x that of copper, but we're talking 18 mm (guessing..) wide tabs less than 3 mm from each other. The wide width and tiny distance between them _decreases_ the resistance of the joint. To calculate resistance, you take the electrical length in the direction of current flow (about 3 mm) and divide by the cross sectional area (18 wide x ...3 mm high?). So 3 mm / (18 * 3). Multiply that number by the resistivity of the material. 60/40 solder is about 15 x 10^-8, so each joint is about 8.3 nano-ohms. The extra solder around the tabs decreases that resistance a bit more (admittedly not much). If we guess at 0.3 mm thick, the tabs' cross sectional area is ten times less than the solder joint, making their resistance _per millimeter_ the same as the solder joint (without extra solder!), and they're a lot longer than 1/8" (3mm). (Yes, I chose 0.3 as a convenient number, but it's probably very close.)
@@chrisw1462 I didn't say you needed a degree to build a battery pack, I said you needed to at least consider resistance and ohms law. If you were to connecting together batteries and each one was expected to move 300 amps of current, then you would need 0 guage wire to carry that much current from battery to battery, right? Why is this different all of a sudden? A battery like this needed substantial bus bars made of copper or Aluminum of a certain cross sectional area to properly conduct this amount of power, plain and simple. I was never trying to be elitist. Im not an electrical engineer, but I am an electrician, and I'm smart enough to know that this was a poorly thought out, bad design. Jehu has been doing this for a long time, and I know he's smart enough to know ohms law. The fact is, he's on the internet selling these batteries to any idiot that wants to buy them, and they are still advertised as 300 amp capable cells. The way that he put these together was subpar to say the least, the proof is in the outcome of the experiment, and these pouch cells are the most likely kind of cells to start a fire. What do you think is more likely? That L.G. did a bad job manufacturing these cells, or that Jehu did a bad job of building a pack out of them with only little bits of solder? Come on man, the tabs weren't even touching. Using lead free solder does not lower the resistance when it's literally the only thing connecting these cells. Be honest with yourself and just admit this was a bad design and cells like these need to be connected together using big chunks of aluminum at the very least, or more appropriately, copper bus bars of a substantial size and thickness. Somebody is gonna buy these Cells and one of these crappy PCBs and attempt to replicate this, and there is a 50/50 chance they might burn down an entire building full of people or something. Like I said, he's selling these things on the internet and any idiot can buy these cells. If he was going to try to help people make something with these packs, He should had done a much more proper job of finding a good way to connect and compress and actually build these pouch cells into a proper battery pack that wasn't dangerous. This, in my opinion, and obviously other people's opinion, is really dangerous. Anyone who bought these cells and PCBs and copied this and doesn't really know what they are doing is creating a potential bomb. You ever see what happens when someone smacks one of these pouch cells with a bat or a hammer? It's a lot of fucking energy, and having 16 of them together is enough to do a lot of damage to everything from a huge building, to a car and the people in it, to a bike and the person riding it. You forget the ways that people will try to use these things. They will be used in ways you probably can't imagine, and I hope nobody gets hurt when they inevitably do something stupid with these cells. This is the exact reason that LG and Samsung won't sell lithium batteries to just anyone. Because they have the potential to be really dangerous in the hands of people that don't know what they are doing.
Nice board. For applications where the battery needs to be exposed to vibrations, I would prefer to use a more robust connector for the balance port. Like a Dupont connector with locking for example.
You can test pull 300A by reducing the voltage, so a 3s at 300A is about 3.3kw from a 12v inverter
You could leave the tabs 1/4 inch longer and then fold them and spot weld them, might be quicker.
Sounds like a better idea than soldering. Although I can't remember what the tabs were plated with, which could be problematic for spot welding, but certainly worth a try.
@@DDCRExposed aluminum wit a piece of copper spot welded on the positive side
That soldering iron is great, but inadequate for this job. You may want to invest in a soldering station and some chisel tips that have more mass. That will allow you to put enough heat, fast enough to melt the solder without sending too much heat into the battery.
It is a 50C BURST...continuous is only 12C
yeah no way its doing 1kw per cell
Nice looking batteries ;)
Cool to see 20S packs. My electric unicycle runs on 84 volts and is considered bottom of the food chain with the newer wheels being 100 to 118 volts now.
they actually go up to around 140v. and motorcycles/high end bikes go up to 180v. cars are usually 200+ volts unlike the guy in the video claims
@@Blox117 what unicycle runs on 140 volts? I have been riding them for 3 years and see no mfg producing a 140 volt wheel?
@@slickjimmy76 a new one begode master
Some may have pointed out that you created a heater next to the cell. Plus the tabs are thin and tiny. No way they can handle that amperage.
We're can I buy it and how much?
Looks like drilling and pop rivets with ring terminal would work on tabs solder free ? And board free?
if you know any generator techs in your area you can use their load banks
Hi do you still have the pcb design for these ?please as I would like to buy a copy
If anyone ever needed any visual proof that that soldering is INFERIOR to joining tabs, skip to @17:21 and look at the heat produced at every single solder point! haha
Looks perfect for an ebike.
I am going to guess that the 300 amps is a momentary discharge and continuous discharge is much lower. If you try it in your car, mount the battery outside on some sort of standoff arm and have a fire extinguisher handy. I think it may catch fire most likely from any wiring and perhaps from cell overheating if the wires last.
pretty sure his car isnt pulling 700+ amps as he claims either
@@Blox117 700A at 1110V is 77,000W. What size DC motor do you need to move a VW bus? Sounds about right to me. You could pull 700A from a bunch of 100Ah cell banks
You can use spot welding with bush bars
Hey Jehu, have you thought of making the tab hole wider so the tabs go through it already touching? I bet this would mean, that you need less solder and therefore less heat goes into the cells?
HOW DO I TEST IT?!?!?
Build a ebike (or even better, an eDIRT bike) with one of those cyclone high torque 22kw motors & 200A controller
I have an ebike with a 3kw cyclone. I have to turn the torque down to prevent tearing the bike to pieces. Starting my third attempt now with 60% torque and single speed. Seven speed sprockets cannot hold the power, and the teeth just break off. A Sturmey Archer 3 speed is OK in 2nd gear as that is direct drive. 3rd gear bit the dust. And I had to really work on the Sturmey Archer sprocket to make it drive the hub. Ordering parts now for a single speed hub version. I cannot even imagine what would happen with a 22kw motor.
This pack is really compact compared to my 18650 360wh
Looks easy enough that is good
Jump starting a diesel engine might be a good test. DC to DC step down converter. Say 72v to 24v. Just replace the existing battery with your battery and converter. Should take at least 200 amps to crank over. Disable fuel on the diesel motor so it cranks longer but not too long. High compression big block might work too. LOL
Hey, we used water heater heating elements. Take your DMM and go to Lowe's or whatever so you can figure out ac as listed or pure dc load. Hardly ever needed to submerge them in water. obw... don't use salt water :)
I like it but would like a 24V and a 48V Version using series parallel connections. Older APC Smart UPS"s can be had for cheap and I believe 2 24V packs would fit into it and provide a very good solution to the Home Lab crowd! I currently use 2 18650 packs to do this and can keep my whole Lab running for about 4 hours. (Warning! if you do this increase the cooling of the UPS as it cannot run for an extended length of time without over heating!
These are not the cells you wanna use to run your ups,
Also, you are trying to solder dissimilar metals together, the aluminum tab to the copper tab to the copper trace. This is building up a lot of resistance in those solder joints. As shown in the IR the solder points is where the heat was coming from and perhaps, due to the high resistance is the reason you had a flat battery in the pack, its solder point was higher resistance.
No sir, both are copper tabs at the point where they are soldered together
@@jehugarcia Thanks for the reply, my apologies for assuming one of the tabs was aluminum. I thought you had mentioned that you were "welding" copper tab extensions to the aluminum tabs in a previous video, then, in this video were trimming the tabs beyond the "weld" point. I am using some bag batteries that have the two different tabs, copper and aluminum... a puzzle...
please try and move the car with the pack!
i think with proper thermal management of each cell, this could be quite a potent battery pack for high performance EV's!
the only big concern I can think of is thermal management, otherwise youll get some swelling going on
My best advice is use thermal imaging. That tells you everything.
did I not do so in this video?
To Speed soldering use a higher wattage iron with larger tip. This allows you to get on and off the joint much faster. In this video his iron tip was way too small.
I wonder if it was possible to overlap the tabs of the cells over one-another on a bare copper patch on the pcb and spot-weld them in place onto the pcb itself... I once had a battery pack in my hands were the tabs were laser-welded to thick copper bus-bars. Clean af but costly to make...
That is exactly the kind of process that these cells need to be made into a proper, well performing battery pack. These were made to be built into an actual battery pack in an enclosure using bus bars of the correct size. It also needs to be contained, protected and slightly compressed. These pouch cells are the most dangerous kind of lithium ion cells, and they should be in something that gives at least a little protection. You can't just slap these things together like this and expect these cells or this kind of slapped together pack to put out 3,000 watts continuous with only tiny solder connections. Jehu should know this. He's been doing this long enough and he wouldn't try to build any other 3,000 watt battery pack like this.
We should make a contraption box for charging this battery pack. Make a box that is ventilated with in/out fans on opposite side. Then please lets apply this pack practically in an e-bike, and show us the performance. Like - capacity test, temperature monitoring while using it, etc
what is the weight of single cell ?
this is only 12C (74.4Amp)continious discharge
Yup, I was thinking it would work on the Bus!
What AWG size leads are you using?
Why the bms copper on the pcb so thin?
I'm still believing that copper or nickel strips would help the current transfer and reduce the sagging, though it would need to be tested for this theory to be proven
That would be great power supply for thousand watts amplifier for cars
Hi! How did you sold the positive and negative cable terminals? Thank you
Hello sir I'm looking for a custom battery and it appears you would have a good idea.
Load it down with light bulbs direct to the battery
I need a 72v 40ah for my 3000 hub motor build can you help me please????
Hook up metering equipment and get some ark welding electrodes (electrode positive) ground negative, and weld something and check the draw current 😉 👌🏻
My suggestion is using flux speeds the soldering process
as per the site specs those batteries are rated 12 amps continuous discharging ,and just temporarily bursts of up to 50C not to tolerate continuous 50C that's why they are over heating ? just saying .
Those specs are a direct result of this tests
do you have a config for 12v? thinking of doing something like that for my kayak
I miss your battery content Jehu!
this might be good for an electric motorcycle?
Hope that its available to purchase from the philippines
series volts add up parallel amps add up, so 300 amp at 30 amps per cell would be 10 cells in parallel, at 3.3 volts, so i am not seeing 72volts at 300 amps in your pack? do i? are you adding amps when they are not to be added in series?
Thank you for pushing forward with ideas and progress to continue moving DIY Battery systems forward!!
Have you tested their capacity? Can do they deliver the capacity promised if discharged at, say, 8C?
Would you say this pack is ideal for E-mountain bikes. What would you guess the range would be in a off road setting?
I am also looking for a dc to dc converter for 120vdc to 12vdc
You shuld make a Eletric outboard 20 hp
I'm getting to a point I am going to build a battery bank for rv. Great videos on testing inverter and batteries.
13:00 Your so close to saying it. Make a 118 volt so when loaded it's nominal voltage, and directly wire heaters. Resistance type, same as what you have. If they have basic circuits, most heaters that are ac can also run DC in a pinch. Most electronics rectify the ac anyway to DC for control voltage and heaters are great for DC test too. Or get a load bank tester
You could also charge a bigger battery. Battery and inverter being tested by a battery bank and charger powered test setup. Less power "wasted"
Muy buenos tus videos Jehu , te consulto tenés versión en español? Saludos desde Argentina Horacio técnico electrónico y aficionado a los EV
Which clamp meter is that?
Thanks for the videos
What charger do you use for your car?
Using AGM 12v 35ah battery's to get 72v and 70ah but at 296.4 lb it wood be more!
I have a 2011 Vantage Electric Green Truck and the AGM battery's get me nomalee 72v and 198ah@20 but at 780 lb do i have to ?
I need a 96 volt battery discharge 800
Yes 300A !⚡🔋🔋🔋👍
I want to make a 72volt battery what would be your best battery for the specifications i need it for? i need a pack that is not to bulky and maximum space of 14" W X 15" L X 4" D to sit flat on a scooter I am wanting to build and perhaps connect two of the same packs to make the capacity greater....so what batteries do you have that I can possibly use that can discharge fast for such a pretty quick strong motor ill be putting?.
Could this be used for a jump box for cars
Awesome 👌 this can give my scooter over 200 miles range
That's not what they are made for.
Those high discharge battery are made for huge burst (50C), or for 10mn high load.
Not for a 1h trip with a scooter.
They are mostly used in RC models
I want to make a big pack for a unicycle.. Is it safe to mix lg50t with Lg50tL?
Those packs are made for huge burst (50C). Or high rate 10mn discharge (we are talking dozen kW).
If your unicycle doesn't need that type of load, go for a classic 18650 battery, better energy density, way less expensive
@@xmtxx That's not what he asked about.
@@zaprodk I didn't realize he was completely off topic in the first place.
@@xmtxx I am sorry if I disturbed... Just wanted to now if it safe to mix those two..
@@omidel. No problem.
Maybe you'll get better luck if you go on a dedicated forum.
those battery can be useful in battelebots
hey man! superior work!
is this pack capable to run mid drive motor like QS 5KW 165 ? i mean if you make an assembly of enough cells.
sorry if the question is silly, i am absolute 0 in batteries and voltages etc...
thanks in advance!
and thanks for classy content!
pretty cool
1 piece of battery 6200mAh 3.7v and 20 piece of battery 124000mAh.
What is energy density per kg
P.C. Board (printed circuit board) - A PCB Board would be double the board :D
Informative video.
how do I even determine mileage on electric ?
The standard is distance per watt hour. Like miles per kilowatt hour, or KM, per kilowatt hour. A unit of fuel has a particular energy when used in an ICE. So we get things like miles per gallon, and KM per liter. Unfortunately the energy in the fuel varies a whole lot from summer to winter and now with ethanol added you lose a lot of energy per gallon. MPG is basically just a guess at the efficiency of the vehicle.
My diy car uses 300wh/Wh
Do you fabricate and sell batteries.?
When you soldered the tabs did you consider that you might have to scratch them at the top to get a good connection to the solder
No he didn't, and I can't believe he didn't notice the tabs weren't taking on any solder.
In America it's Aluminum. In England it's Aluminium.
Maybe it's an isotope only found in England?
Someone at the factory added a zero next to the five C
Gallium is off the charts on this one 😂
You could load it with some nichrome wire wrapped around a rock in a bucket of water
Or get some oven/water tank heating elements in parallel
When you do thé test with car put a external temp sensor working. With Arduino and blynk this Will ben a Nice test grafiek
got flux?
Thanks Good Video
looks to me there only rated for 6.2 amp hour to me
60V40Ah