photo:batteries
Table of Contents
looking after your batteries
see also:
Introduction
- each battery type has unique characteristics and optimised ways to look after them to ensure their life is extended as long as possible, and that the risk of them exploding (this is especially a risk with lithium ion batteries) is reduced
- life span was particularly a problem with the older technologies such as nickel cadmium (NiCd) and nickel metal hydride (NiMH) as well as the old heavy lead acid batteries.
- lithium batteries can explode into flames if short-circuited, over-charged, over-heated or damaged
- people have sustained severe deep burns down to muscle when placing a tool battery in their pocket which also contains car keys which then short circuited the battery - and removing the burning battery from a pocket rapidly is not an easy task!
- even a normal alkaline AA battery can be used to start a fire by intentionally short circuiting it with foil from a chewing gum wrap!
- over-charged or over-heated lithium batteries initially can give off an explosive and toxic vapour cloud and if that ignites, immediately you get long, rocket like flames, 1,000degC
- if the vapour cloud doesn't ignite immediately and the vapour saturates the surroundings, then you can actually get a vapour cloud explosion
- by Jan 2023, there were over 450 fires in Australia in the prior 18 months linked to lithium batteries including 27 house fires linked to electric vehicles in the previous 7 months
- most fires were due to lithium polymer battery issues on e-bikes
- the latest EV cars have competent battery management systems which limit this risk but older cars and no e-scooters have this protection
- Do not charge them when you're out, do not charge them when you’re asleep … do not charge them where, in any way, they impede your escape
- optimising life span of LiFePO4 batteries
- don't store them for long periods almost fully discharged as the self-discharge may end up with excessively low charge which may kill the battery
- self-discharge rate is usually 3% per month but will be higher in warmer climates
- for long storage, store them at around 50% capacity
- don't store them in extremes of temperature
- ensure you charge them to 100% as often as you can but at least once every few months to ensure the cells become balanced
- it is fine to use up all your capacity as this is getting the most out of your battery
- don't charge them when the temperature is below 0degC
- the most common cause of failure tends to be the battery management system (BMS) rather than the battery cells themselves
Lithium ion batteries
rechargeable lithium ion battery cells
- Lithium ion cells are generally 3.6V or 3.7V nominal voltage chemistries
- LiFePO4 cells have a nominal voltage of 3.2V and are safer and generally better performing than Li ion batteries
- a 12V battery usually consists of 4 of the above cells connected in series and regulated by a battery management system (BMS) which helps to ensure the some level of charge is in each cell as well as having safety features to prevent overcharging, overdischarging, etc.
cylindrical
- 32600 cell - similar size to D cell
- 26650 cell - used in 12V battery packs as 3.2V 3.4Ah
- 26500 cell - simiar size to C cell
- 21700 cell
- 21mm diam x 70mm long allowing 3000-5000mAh capacities
- 20700 cell
- 20mm diam x 70mm long which provides ~50% more volume hence capacity than a 18650 battery
- 3.7V Li ion
- 3.2V LiFePO4
- 18650 cell
- 18mm diam by 65mm long;
- nominal 3.7V Li ion:
- 4 are used to create a “12V” battery but nominal voltage is really 14.8V
- 300 to 500 charging cycles, usually take 1-2hrs to charge per 1000mAh to 4.2V
- 3.2V LiFePO4
- 4 are used to create a “12V” battery but nominal voltage is really 12.8V but fully charged is around 13.8-14V
- used in many devices
- max. capacity is around 3500mAh
- some are flat top, some are button top
- some are “Power cells / High Drain” for much higher currents (around 30A instead of 5-10A) such as would be needed in power drills
- smart protected“ cells include overcharge protection and over discharge protection
- 14500 - similar size to AA cell
- 10440 - similar size to AAA cell
prolonging the life of your lithium batteries
- use the correct charger
- an incorrect charger may cause serious overheating within minutes
- avoid “rapid” chargers”
- these will overheat the battery and reduce lifespan
- don't drain them to zero
- doing this may make it very difficult to regain maximum capacity and hold charge
- it increases the risk of dendrites of lithium ions forming which results in increasing internal resistance for that cell which can lead to overheating, reduced charging of the other cells and internal short-circuits resulting in reduced charge capacity
- don't keep them perpetually charging 24×7
- remove them from the charger once they are fully charged
- keeping them on a charger risks overheating, swelling and explosion risk
- supervise them whilst charging
- don't charge them overnight while you sleep in case they overheat and burn your house down
- ideally charge them in the same room, or at least have a smoke detector in that room
- don't store them fully charged
- this can dramatically shorten their life span
- it is better to store them at 50% if they are being stored for long periods
- don't overheat them
- keep them out of your hot car
- don't charge them straight away if they are feeling warm
- don't start charging them while they are hot
- this will only make them hotter and risk damage to the cells
- don't charge them while they are below zero deg C
- most lithium batteries do not tolerate charging at sub-zero temperatures
- remove from device when not being used
- devices often leak current even when turned off leading to battery becoming drained
- optimising a LiFePO4 battery rated at 2000-5000 cycles by keeping it cool, charging to 100% to re-balance cells, and avoiding high charge/discharge rates should prolong the battery life out to 20,000 cycles or perhaps 50yrs albeit with reduced capacity of perhaps 60% (in contrast AGM lead acid batteries will generally last 5-8yrs at best)
storage conditions
Recoverable battery capacity after storage for 1 yr at various temperatures and charge - avoid temperatures above 30°C (86°F)
ambient temperature | stored at 40% charge | stored at 100% charge |
---|---|---|
0degC | 98% | 94% |
25degC | 96% | 80% |
40degC | 85% | 65% |
60degC | 75% | 60% after 3 months |
avoid over heating battery
- heat degrades lithium batteries
- avoid high charge/discharge rates
- avoid charging in hot environments
fully charging the battery
- charging to 100% is required to ensure cells are re-balanced
- some people recommend only charging to 80% but this will result in failure of re-balancing
- note that LiFePO4 batteries handle over-charging better than the lithium ion batteries in the table below
cell charge voltage for a rated 4.2V cell | discharge cycles | available stored energy |
---|---|---|
4.3V over-charged | 150-200 | 110% |
4.25V | 200-350 | 105-110% |
4.20V | 300-500 | 100% |
4.15V | 400-700 | 90-95% |
4.10V | 600-1000 | 85-90% |
4.05V | 850-1500 | 80-85% |
4.00V | 1200-2000 | 70-75% |
3.9V | 2400-4000 | 60-65% |
optimise the charge-discharge bandwidth
- this is the degree you allow the battery to discharge to and the degree to you charge it back up to
- most lithium ion batteries do best at around 50% charge
- discharging too much results in dendrite formation which can create internal short circuits which result in increased temperature during charging and may result in one cell within the battery being at different voltages during charge which also means greater heat
- note that LiFePO4 batteries will do better than the lithium ion batteries in the table below
charge-discharge bandwidth at 20degC | % total capacity after 4000 cycles |
---|---|
75-65% (only 10% used between charges) | 94% |
75-45% (only 30% used between charges) | 91% |
75-25% (only 50% used between charges) | 88% |
85-25% (only 60% used between charges) | 86% |
100-50% (only 50% used between charges) | 83% |
100-40% (only 60% used between charges) | 82% |
100-25% (only 75% used between charges) | 79% |
state of charge vs voltage
- most 12V batteries do not have a state of charge (SOC) meter to show how much charge is in the battery
- this can be very approximately estimated by the voltage
- a much more accurate method is to install a SOC meter with a shunt device
- some batteries are “smart” and have a dedicated module to display SOC without need for a shunt device such as:
LiFePO4 12V batteries
discharge voltage at 0A load | discharge voltage under load | Approx. SOC | Approx. Ah for 100Ah battery |
---|---|---|---|
14V | 13.6V | 100% | 100Ah |
13.8V | 13.4V | 99% | 99Ah |
13.6V | 13.35V | 98% | 98Ah |
13.4V | 13.3V | 90% | 90Ah |
13.3V | 13.2V | 70% | 70Ah |
13.2V | 13.1V | 40% | 40Ah |
13.1V | 13.05V | 35% | 35Ah |
13.0V | 13.0V | 30% | 30Ah |
12.9V | 12.9V | 20% | 20Ah |
12.8V | 12.8V | 17% | 17Ah |
12.5V | 12.4V | 14% | 14Ah |
12.0V | 12.0V | 9% | 9Ah |
11.7V | 11.7V | 0% | flat |
NiMH batteries
- one can expect 2000 charge/discharge cycles out of a standard NiMH battery
- use the correct SMART charger
- Most chargers made since about 2005 charge both NiMH and NiCd batteries. But some newer chargers charge only NiMH, not NiCd.
- Any NiMH charger will charge both regular NiMH batteries and LSD NiMH's (Low Self Discharge NiMH).
- Old NiCd chargers can't tell when to stop charging a NiMH battery
- Use a smart charger! Smart chargers charge each battery separately, giving each one exactly as much energy as it needs and stops charging once it is full.
- If your NiMH charger manages each cell separately, you can mix NiMh and NiCD, different sizes, and semi-fresh and nearly dead batteries at the same time. If it doesn't you can't. If you insist on mixing them anyway, some of your batteries will be undercharged and some will be overcharged.
- NiZn batteries require a special charger. NiMH and NiCd chargers will not work.
- Trickle Charging is the safest method
- charge at the lowest possible rate that will keep your overall charge time BELOW 20 hours
- Most would suggest to aim for 4-5 hours - a 4-5-hour charge means about a 500 mAh charge for most 2000mAh AA's, and 200 mAh for most lower capacity AAA's.
- If the battery charges too slowly, the charger might miss the voltage change and not stop charging.
- don't keep them perpetually charging 24×7
- remove them from the charger once they are fully charged, excessive charging reduces battery life
- Smart chargers will stop charging when charge completed HOWEVER, most chargers give a “trickle” charge after charging is finished. Some chargers give too much of a trickle, and even those which give a reasonable trickle can still overcharge if the batteries are left in the charger too long.
- almost fully discharge battery prior to charging
- NiCd and, to a lesser extent, NiMH batteries have a “memory” issue
- You can recharge at any degree of depletion (you don't have to wait until the battery is mostly discharged), but the sooner you recharge the better, because you'll get more cycle life out of the battery.
- for a 1.5V battery, it is better to re-charge at 1.1V than wait until 1.0V
- failing to deplete the battery each time reduces its capacity
- Newer NiMHs can be restored by “exercising” the battery (fully charging and discharging the battery a few times)
- there are methods to REVIVE “dead” batteries that won't charge
NiCd batteries
- use the correct charger
- Most chargers made since about 2005 charge both NiMH and NiCd batteries. But some newer chargers charge only NiMH, not NiCd.
- almost fully discharge battery prior to charging
- NiCd have a major “memory” issue
- failing to deplete the battery each time reduces its capacity
- ideally the aim is to charge once the battery is ALMOST fully depleted (voltage will be around 1.0-1.1V for a 1.5V battery)
- Dispose battery safely - cadmium is TOXIC
photo/batteries.txt · Last modified: 2024/11/08 13:52 by gary1