LiFePO4 balancing / voltage limiting
bill von novak
Solar Expert Posts: 891 ✭✭✭✭
So I just replaced my old AGM bank with a bank of 16 180ah CALB cells. I bottom balanced them; paralleled them all and brought them down to 2.70 volts. Let it rest for 2 days and they rebounded to 2.73. Disconnected the parallel connections for another day and they all stayed at 2.73.
Then I seriesed them and did the first charge while monitoring. They tracked very closely for the CC portion of charging. (Charger 20 amps, 56 volts, targeting 3.5 volts per cell.) When they switched to CV I measured again and got:
Then I seriesed them and did the first charge while monitoring. They tracked very closely for the CC portion of charging. (Charger 20 amps, 56 volts, targeting 3.5 volts per cell.) When they switched to CV I measured again and got:
3.52 3.45
3.47 3.43
3.48 3.43
3.44 3.45
3.49 3.58
3.50 3.49
3.50 3.47
3.40 3.49
I was a little worried about cell 13 (3.58) but it was still well below 3.65V and I figured charge was almost complete. I checked 15 minutes later, when current had dropped to 2 amps, and saw:
I was a little worried about cell 13 (3.58) but it was still well below 3.65V and I figured charge was almost complete. I checked 15 minutes later, when current had dropped to 2 amps, and saw:
3.59 3.41
3.45 3.39
3.50 3.39
3.41 3.43
3.52 3.75
3.63 3.40
3.55 3.44
3.36 3.40
So I stopped charge and discharged it until cell 13 was down in the safe range again (3.5 volts.) I let it sit overnight and now everything is back at 3.33 to 3.35 volts. Hopefully no harm was done to 13.
So how do I handle cell 13? Do I have to monitor voltages at all cells and discontinue charging when it hits 3.6V or so? Do I back off the 56 volt charge, go down to 54 volts or something? Do I terminate when current reaches C/20 or something? (hard to do with this charger)
So I stopped charge and discharged it until cell 13 was down in the safe range again (3.5 volts.) I let it sit overnight and now everything is back at 3.33 to 3.35 volts. Hopefully no harm was done to 13.
So how do I handle cell 13? Do I have to monitor voltages at all cells and discontinue charging when it hits 3.6V or so? Do I back off the 56 volt charge, go down to 54 volts or something? Do I terminate when current reaches C/20 or something? (hard to do with this charger)
Comments
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Get a 6 volt brake (or tail) light and clip it on the high voltage cell, and monitor until it gets down to the average pack voltage.
I would wonder if cell 13 is weak/low capacity/not "matched" to the capacity of the other cells (filling up to 100% state of charge first).
-Bill "not a Li Ion battery expert" B.
Near San Francisco California: 3.5kWatt Grid Tied Solar power system+small backup genset -
BB. said:Get a 6 volt brake (or tail) light and clip it on the high voltage cell, and monitor until it gets down to the average pack voltage.
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Then that is the new 100% full bank voltage, as understand.
Unless you replace the (bad/weak?) cell.
Assuming the bottom voltage was done correctly (not doubting you).
Have you contacted the battery folks and see what they suggest?
-BillNear San Francisco California: 3.5kWatt Grid Tied Solar power system+small backup genset -
Do you have a BMS/balancer system installed or are you doing it manually? I've heard some people who have good results without a BMS of any kind but I wouldn't take that chance.
I just upgraded to Battleborn batteries but I'll start a separate post as to not derail this one.Current system: 8-100w Renogy panels mono/poly, 2 strings of 4 panels in series - 24v 100Ah AGM Battleborn LiFePO4 batteries - Morningstar MPPT40 CC - 1500W Samlex PSW inverter -
nickdearing88 said:Do you have a BMS/balancer system installed or are you doing it manually? I've heard some people who have good results without a BMS of any kind but I wouldn't take that chance.
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I'm a no-nothing on these, but that seems like a pretty wide range (3.36-3.75) for cells charged once in series from an apparently equal SOC. My understanding is voltage should be pretty much flat between ~10-90%SOC. That implies when the highest voltage cell gets to whatever 90%SOC voltage, stop charging. Discharge until the lowest gets to 10%SOC voltage. The difference is capacity.Off-grid.
Main daytime system ~4kw panels into 2xMNClassic150 370ah 48v bank 2xOutback 3548 inverter 120v + 240v autotransformer
Night system ~1kw panels into 1xMNClassic150 700ah 12v bank morningstar 300w inverter -
The problem is that you cannot have an LFP battery balanced at both the top and bottom unless all the cells have exactly the same capacity which is unlikely. If you have it bottom balanced you have to use a BMS to terminate the charge when the weakest cell hits ~3.45V-3.50V. If you top balance you can set your charge controller to 3.45*16 and all cells will be charged to the same level but you will need a BMS to warn you or shut down the loads when the weakest cell gets close to 0%.
You are correct in saying that you only need a pack LVD if you bottom balance but this only holds true if the balance does not drift with time. Again this is unlikely and doesn't match my experience and experience of others. Of course the only way you can check if the battery has gone out of balance is to do another bottom balance.
Because of the very flat charge curve for an LFP battery, you cannot reliably charge an LFP battery to say 90% unless you have a constant current power supply. Solar is not a constant current supply.
Simon
Off-Grid with LFP (LiFePO4) battery, battery Installed April 2013
32x90Ah Winston cells 2p16s (48V), MPP Solar PIP5048MS 5kW Inverter/80A MPPT controller/60A charger, 1900W of Solar Panels
modified BMS based on TI bq769x0 cell monitors.
Homemade overall system monitoring and power management https://github.com/simat/BatteryMonitor
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Hi bill,
I can't say I've heard of a single person bottom balancing their LFP cells, except EV guys. If you want to charge the bank to 55.2 volts (3.45v/cell) without a BMS then top balancing is the way to go. I agree with karrak that the reason for the increasing delta in voltage, as the cells are being charged, is slightly differing cell capacities. I have read that they can vary as much a 5%. So we use the top 80% or the bottom 80%. I believe it is easier to manage charging with top balancing because as the bank nears the end of absorb, all the cells are nearing the same voltage. As they are discharged, they will stay fairly close, probably within 10 millivolts, down to 20% SOC. Could be even lower, however I can't say for sure because I haven't taken mine below 20%. Something to consider is, deeper discharge means shorter life, so I try to keep usage between 70 and 80% of capacity. Charge to 99+% then down to 20 to 30%.
It's easy to get freaked out when you see the cells coming so close to overcharging. Top balance does away with that concern. Over a year of daily cycling and my cells voltage delta is 25 millivolts at the end of absorb.
Rick
4480W PV, MNE175DR-TR, MN Classic 150, Outback Radian GS4048A, Mate3, 51.2V 360AH nominal LiFePO4, Kohler Pro 5.2E genset. -
hey I will talk this tomorow
so, I have a few EXP about using LFP
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If you bottom-balance, you will be slightly ragged at the top. That is to be expected. When the first cell of your bank reaches your target voltage, your HVD is supposed to shut off charge. Some of the simpler setups will note when the first cell hits the upper limit, and take a bank-voltage reading, and use that as the HVD cutoff.
But you must choose either top or bottom - you can't combine both techniques. Bottom is great for high-current EV's and other high-draw applications. But here, as a solar storage application that typicall draws no more than 0.1C or less (to get through many day's autonomy), top balance is the most practical choice, as our relatively low current draw gives us PLENTY of time for a bank-level LVD to react, if it is set conservatively.
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You can balance at both the top and the bottom - but you need to use a charge shuffling design.
I am available for custom hardware/firmware development
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How often do you have to balance? What is the best way to balance a new 50% soc 12.8v lifepo4 battery? https://www.victronenergy.com/batteries/lithium-battery-12-8v
I have a nominal battery bank of 51.2 v, shall I set the inverter cutoff at 51.2 v to avoid over discharge ? The charger cutoff at 56.8? Is this healthy? -
Another question, it gets quite hot in summer. Around 45 c. Would I need to cool the batteries? Would it be a good idea to seperate the charger and inverter from the batteries to reduce excess heat?
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How often do you have to balance? What is the best way to balance a 12.8v
I have a nominal battery bank of 51.2 v, shall I set the inverter cutoff at 51.2 v to avoid over discharge ? The charger cutoff at 56.8? Is this healthy? -
Yerf said:How often do you have to balance? What is the best way to balance a new 50% soc 12.8v lifepo4 battery? https://www.victronenergy.com/batteries/lithium-battery-12-8v
I have a nominal battery bank of 51.2 v, shall I set the inverter cutoff at 51.2 v to avoid over discharge ? The charger cutoff at 56.8? Is this healthy?
Are you running this battery with the Victron VE.bus BMS?
Simon
Off-Grid with LFP (LiFePO4) battery, battery Installed April 2013
32x90Ah Winston cells 2p16s (48V), MPP Solar PIP5048MS 5kW Inverter/80A MPPT controller/60A charger, 1900W of Solar Panels
modified BMS based on TI bq769x0 cell monitors.
Homemade overall system monitoring and power management https://github.com/simat/BatteryMonitor
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Yerf said:Another question, it gets quite hot in summer. Around 45 c. Would I need to cool the batteries? Would it be a good idea to seperate the charger and inverter from the batteries to reduce excess heat?Current system: 8-100w Renogy panels mono/poly, 2 strings of 4 panels in series - 24v 100Ah AGM Battleborn LiFePO4 batteries - Morningstar MPPT40 CC - 1500W Samlex PSW inverter
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Yerf said:Another question, it gets quite hot in summer. Around 45 c. Would I need to cool the batteries? Would it be a good idea to seperate the charger and inverter from the batteries to reduce excess heat?
We too have hot summers where the temperature gets to 45C. The amount of time that the temperature is above 45C is fairly low and the average daily temperature is in the mid 20s. Under these conditions I don't think the losses will be too severe.
I agree with @nickdearing88 that you should take whatever steps you can to keep the battery temperature as low as possible but above 0C.
Simon
Off-Grid with LFP (LiFePO4) battery, battery Installed April 2013
32x90Ah Winston cells 2p16s (48V), MPP Solar PIP5048MS 5kW Inverter/80A MPPT controller/60A charger, 1900W of Solar Panels
modified BMS based on TI bq769x0 cell monitors.
Homemade overall system monitoring and power management https://github.com/simat/BatteryMonitor
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karrak said:The graph below from this paper http://jes.ecsdl.org/content/145/10/3647.full.pdf+html gives an idea about how temperature effects the lifespan of LFP batteries.
We too have hot summers where the temperature gets to 45C. The amount of time that the temperature is above 45C is fairly low and the average daily temperature is in the mid 20s. Under these conditions I don't think the losses will be too severe.
This appears to be a very useful chart - are there similar, easily understood charts of the popular EV LI battery types? NMC, LMO, NCA, etc.?
Couple of questions;
1. The "x" axis - Can it be interpreted as => a 1 ahr cell will degrade approx 5% with 4000 total ahrs (both discharge and recharge through it) at 15 oC? (And at 60oC, may not even make 4000 total ahrs!)?
2. The chart likely does not take into effect idle time at SOC/temperatures (i.e., a LFP battery sitting for two years at a certain temperature and SOC may lose "throughput" also)?
Just trying to understand better the basic degradation mechanisms in my Nissan Leaf (LMO/NMC) battery (understanding that the "dynamic" use would be a so interdependent of power cycling, cell operating temperatures, ambient temperatures, idle time at certain SOC, etc, etc, make actual, real life predictions very difficult).
Mark
3850 watts - 14 - 275SW SolarWorld Panels, 4000 TL-US SMA Sunny Boy Grid tied inverter. 2760 Watts - 8 - 345XL Solar World Panels, 3000 TL-US SMA Sunny Boy GT inverter. 3000 watts SMA/SPS power. PV "switchable" to MidNite Classic 250ks based charging of Golf cart + spare battery array of 8 - 155 AH 12V Trojans with an APC SMT3000 - 48 volt DC=>120 Volt AC inverter for emergency off-grid. Also, "PriUPS" backup generator with APC SURT6000/SURT003 => 192 volt DC/240 volt split phase AC inverter. -
MarkC said:
This appears to be a very useful chart - are there similar, easily understood charts of the popular EV LI battery types? NMC, LMO, NCA, etc.?Couple of questions;
Yes, that is how I read it.
1. The "x" axis - Can it be interpreted as => a 1 ahr cell will degrade approx 5% with 4000 total ahrs (both discharge and recharge through it) at 15 oC? (And at 60oC, may not even make 4000 total ahrs!)?2. The chart likely does not take into effect idle time at SOC/temperatures (i.e., a LFP battery sitting for two years at a certain temperature and SOC may lose "throughput" also)?
I think this is one of the big factors affecting battery life. Leaving any lithium ion batteries idle at high SOC at high temperature will diminish their lifespan. As you can see from the graphs its is particularly true for NMC batteries.Just trying to understand better the basic degradation mechanisms in my Nissan Leaf (LMO/NMC) battery (understanding that the "dynamic" use would be a so interdependent of power cycling, cell operating temperatures, ambient temperatures, idle time at certain SOC, etc, etc, make actual, real life predictions very difficult).
As you say it is difficult to make real life predictions. From my understanding, cycling a lithium ion battery between ~70%-30%, storing at low SOC, keeping the temperature down and limiting the charge and discharge current will lead to the best life span. One has to balance lifespan against utilisation. Comply with the manufacturers recommendations and you will get in excess of ten years use and/or the rated number of charge/discharge cycles out of the battery.
When you talk about a Leaf battery, it is in a car?
Simon
Off-Grid with LFP (LiFePO4) battery, battery Installed April 2013
32x90Ah Winston cells 2p16s (48V), MPP Solar PIP5048MS 5kW Inverter/80A MPPT controller/60A charger, 1900W of Solar Panels
modified BMS based on TI bq769x0 cell monitors.
Homemade overall system monitoring and power management https://github.com/simat/BatteryMonitor
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Hey Simon! Hope all is well down there
Have you seen anything on LFP or NMC that discusses how accurate a BMS Soc reading is near the end of warranty?
I know that the battery stays very efficient near the end of life as it loses its capacity but does that affect Soc accuracy?
The Leaf is a car by Nissan. I have charged one here and it was a fun ride up into our park near here."we go where power lines don't" Sierra Nevada mountain area
htps://offgridsolar1.com/
E-mail offgridsolar@sti.net -
Dave Angelini said:Hey Simon! Hope all is well down there
Have you seen anything on LFP or NMC that discusses how accurate a BMS Soc reading is near the end of warranty?
I know that the battery stays very efficient near the end of life as it loses its capacity but does that affect Soc accuracy?
The Leaf is a car by Nissan. I have charged one here and it was a fun ride up into our park near here.
Finally some rain and the end of the fire season. Have had some big fires in our corner of the state in the last week! All the best for your fire season!!!
I haven't seen anything specific about BMS SOC accuracy over the life of a battery. It will depend on how the coulomb/current efficiency changes as the battery ages and whether the BMS takes this change into account. My BMS software dynamically adjusts for any efficiency changes that might occur, hopefully the commercial units will do likewise. I have noticed an increase in efficiency of ~0.1% in my battery over the past three years, although this might just be inaccuracies in obtaining the data. This matches information I have read that implies that the efficiency will improve as the SEI layer thickens and stops unwanted side reactions. It ties in with this rather nice graph from here which shows the rate of decrease in capacity of the Tesla batteries decreasing with time/use.
Off-Grid with LFP (LiFePO4) battery, battery Installed April 2013
32x90Ah Winston cells 2p16s (48V), MPP Solar PIP5048MS 5kW Inverter/80A MPPT controller/60A charger, 1900W of Solar Panels
modified BMS based on TI bq769x0 cell monitors.
Homemade overall system monitoring and power management https://github.com/simat/BatteryMonitor
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Thanks for the info! Very nice to hear that as I was told that a couple years ago by an engineer at LG. I was translating Korean on google and there were some pauses that I thought weird. He said the same thing with the efficiency and I was skeptical after 25 years of lead acid and how it just degrades right from the start.
Nice to be past the fire season hump! Where I live the fire danger from wildfire is 2 weeks after the last rain. It almost never rains in the next 4 months so we are knee deep in it now. In the old days the insurance guys would look on google earth to actually see the terrain and how safe you had made the dwelling. Now they just say no.
It seems the Insurance companies learned nothing last year from the really bad fires. They said they were going to do physical inspections of the homes and base their rates on how safe the exterior of the home was. I think they just thought it was cheaper to raise everyone's rates.
Take care and again thanks!"we go where power lines don't" Sierra Nevada mountain area
htps://offgridsolar1.com/
E-mail offgridsolar@sti.net
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