Electrical – Low-power Li-Ion Battery Charging

Preamble:

I'll assume a standard Lithium Ion (LiIon ) battery tyoe as used in the very large majority of laptops and similar equipment. Lithium Polymer (LiPo) is for practical purposes the same.
Lithium Ferro Phosphate (LiFePO4) is of the same family as LiIon but has some fundamental differences which mean these nswers apply only partially. I may comment on LiFePO4 separately.

I'll assume "normal" ambient conditions - say about 10C to 35C unless otherwise noted. I may comment on results out of that range.

I'll assume the battery (or cell) has not been deep discharged below the normally recommended minimum discharge level. All well designed equipment will not allow deep discharge below minimum recommended level. This can cause battery damage or destruction and special care is needed to recover a battery from that condition, if it is possible. I may comment on that at the end.

I will tend to use the term "battery" to mean cell or battery (= N cells) when the text applies to either. If I mean 1 cell specifically I will use "cell".

Answers:

Force charging-Charging even after reaching 100% in battery backup.

• You cannot "force charge" a LiIon cell as long as you do not exceed design parameters of maximum charge rate and maximum charging terminal voltage. The battery is normally charged at design current until maximum terminal voltage is reached and then allowed to accept whatever current the chemistry involved desires until a cutoff point is reached.

Two parameters that affect life and charge capacit are the maximum terminal voltage used and the % of maximum current that you allow the current to fall to before you terminate charging. Reducing maximum terminal voltage and/or limiting that the current falls by before charging is terminated will increase cell life, at the expense of storage capacity in both cases.

Here is an immensely informative chart, care of Battery University, that tabulates the affect on capacity of various endpoint voltages and charging cutoff point. eg the traditional maximum charge voltage is 4.2V. When this cell voltage is reached the cell has 85% or maximum capacity. If charging is at 1C hen this occurs in about 85% x 1 hour =~ 50 minutes. If charging is allowed to continue for another 180-50 = 230 minutes the capacity will be 100% and charge current will be close to zero - say maybe 1% of max. Leaving the charger connected will have minimal additional effect. Disconnecting the charger when 4.2V is first reached will reduce available capacity by 15% BUT will increase cell lifetime by much more than 15%.

Charging only after the battery empty.

More soon.
Worst case.

Better to charge little and often with battery more full.
Recharging back to point of 1st reaching 4.2V is best.

Charging parallel while working.

Good. Charger may charge battery plus operate computer if of enough capacity - this is almost always the case with chargers supplied with the computer. If not, it will slow down the discharge rate.

BUT, Best

Charge to cutoff voltage as per table above.
Disconnect battery and operate computer from mains supply.
This is the best point to maintain the battery at.
Battery will achieve maximum calendar life.

More on the above plus other comments later probably ...

Added comments:

Manufacturers tend to produce chargers which achieve close to maximum capacity. This gives longer operating life which assists the "consumer experience" [tm].
It also much shortens the available battery cycle life which is not so noticeable to users. This increases the number of batteries needing to be bought at accessory level prices during the equipment lifetime. This enhances ghe manufacturer and reseller experience :-).

While it would be possible for manufacturers to stop charging at less than complete capacity, and while some may truncate charging somewhat early in the final "current taper" part of the charging cycle, the majority dio not reduce capacity as much as is desirable for long life.

The OLPC laptops use either LiFePO4 or NimH cells. By limiting NimH charge and discharge to not include the top 10% and bottom 10% of capacity they get 2000 cycles from a NimH cell !!! LiIon can be extended by such methods.

Best cycle life a a given end-point voltage is achieved by stopping charging when the voltage "pedestal" is reached. As per the above table this gives 85% capacity at Vpedestal = 4.2V, and 75% at Vpedestal = 4.0V.

Batteries when unused last longest when stored at the end of constant current / start of constant voltage point.

Charging while working was covered above. Stopping the battery discharging further is a major gain. Extremely high temperature is not tolerated wll by LiIn cells but temperatures to about 40C are tolerable with no great problem.

LiIon is usually charged at constant current until a max allowed voltage is reached and then is held at that voltage while current tails off under "control" of chemistry of battery until Ichg = k% of Imax where k% is chosen according to longevity or max energy concerns.50% or 25% of Imax gives longer life. 10% or 5% tail gives max capacity but lower life.

Lowering Vpedesatl by 0.1V greatly assists battery life.

Discharging to higher cutoff voltage aids cycle life.

LiIon also has calendar life and starts self destructing from day one so a lightly used battery still dies.

Best cycle life is achieved by stopping charge when Vpedestal is reached and systen changes from CC to Cv. By monitoring voltage this point can be observed. You could even do a "dumb" system that simply watched delta Vbat and declared constant V when delta fell to zero. Only slightly more than a comparator and an RC delay in one input would achieve that.(While Vin is ramping a delayed vin is lower. When Vin pedestals the delayed Vin almost catches up. An offset voltage is needed to allow comparator towork).

LiIon cells mechanically flex the cell as metallic Lithium is "plated" in and out of the cell*. Cycle life is in large part due to battery beating itself to death mechanically.(This is why LiFePO4 lasts much longer and has lower capacity - the material is held in an Olivine matrix that maintains constant shape as active material is moved in/out BUT it takes up some space. )

*Note: Bill Dubuque has suggested that this sentence would be better replaced with " 'LiIon cells mechanically flex the cell as Lithium ions are intercalated".
The distinction is a finer one than may be apparent. However, it is true to say that if you cut open a LiIon cell you would not usually find metallic Lithium in it. Bill notes that this makes primary Lithium cells, which do contain metallic Lithium, a greater fire hazard than LiIon cells.
If you charge a LiIon cell with excessive voltage metallic Lithium will be 'plated out' and "vent with flames" mode usually occurs at about the same time.

Charge to CV level as often and as soon as possible.

If charging all the way their "disconnect message" is a sign of bad ethos. They are probably trying to minimise the risk of fire without telling you.

For longest storage life (as opposed to long life in regular use) storing at a lower voltage than Vmax is in order. Probably at about 3.6 V and only about 30% state of charge. The various Mars Rovers use LiIon batteries and have a design life of about 8000 cycles - but charge to about 3.6 - 3.7 V maximum.
8000 / 365(~=) ~= 22 Terran years.