1] Voltage: 3.6V or 3.7V
Are all 18650 lithium ion battery cells 3.6 or 3.7 voltsor or are there different voltage Lithium Ion cells in the market as well?

2] Possible Voltage Shortage?
Do all 3.6/3.7V li ions work the same standard way with a + a - and a T or do they really differ? What does the T stand for? Temperature sensor?

3] Physics Voltage Reason
Whats the reason for the 3.6/3.7 Volts per Li Ion Cell? I never saw a 3.0V or 5 Volts... Curious...

4] Parallel Charging of many Li Ion Cells
I was thinking of putting two or four of those Panasonic/Sanyo 18650 Li Ion cells in parallel, soldering together from the instant the are new, that way giving me lots of mAhs. Can I use the same Li Ion charger that was made for charging just 1 cell, and let it be in the charger for longer time?

5] Charging Wiring... How?
I found a nice small cheap charger about 30~40$ called Turnigy Accucel-6 (there is also an Accucel-8 for double price and double weight). Could I attach the + to + of all the cells and the - to all the - poles of the cells without needing any extra in-between-wiring?

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    \$\begingroup\$ In practice 3.6V and 3.7V are exactly the same. Just by looking at a circuit one value can change into the other one. \$\endgroup\$ – stevenvh Aug 1 '11 at 10:28

1] VOLTAGE: 3.6V or 3.7V - 18650 Li Ion Batteries

All single cell lithium ion batteries are going to be 3.6-3.7v. There are applications where multiple cells will be tied together in series. This will result in voltages that are multiples of 3.6-3.7v. So as long as you match the number of cells and approximate mAH you should be fine.

2] Possible Voltage Shortage?

The voltages and battery life responses for all batteries are going to have slight difference. For the most part this won't matter. Most projects that use batteries are not terribly voltage dependent. They will either boost or regulate their voltage to get the voltage they want out, or they will be able to run at a wide range.

As a note, "Shortage" in this context usually means you are creating a short across your battery. Might want to be careful with that terminology.

3] Fundamental Reason for this Voltage Range

I am not an expert on this, but I know it deals with the chemistry of the battery itself.

4] Parallel Cell Charging - One BIG Li-Ion Battery Pack

This can be done. There are some issues that can come up when doing it. This might be worthy of a question by itself. If you do ask, might want to ask if the same can be done for packs in series.

5] Charging... How?

Same as previous answer.

  • \$\begingroup\$ Thanks Kellenjb for the answered parts! Good to get a positive push in my headings. the remaining 9more secialistic questions remain unanswered byt that Q nr. 3 needs an expert, indeed! \$\endgroup\$ – Sam Jan 22 '11 at 21:23
  • \$\begingroup\$ In the item #1 of your answer you mention that capacity (mAh) should be simuilar, but the OP seems to be replacing a 1300mAh battery with a 2900 mAh, more than doubling capacity. Is there a problem with that? \$\endgroup\$ – Ricardo Dec 12 '13 at 16:01

Well, actually I was also interested here.

  1. Rated voltage might be rated different to make it serve more in expense of capacity.
  2. LiIon batteries have lots of variants of chimestry - all are LiIon, but different voltages, prices, reliability.
LiCoO2    3.7 V   140 mA·h/g  0.518 kW·h/kg
LiMn2O4   4.0 V   100 mA·h/g  0.400 kW·h/kg
LiNiO2    3.5 V   180 mA·h/g  0.630 kW·h/kg
LiFePO4   3.3 V   150 mA·h/g  0.495 kW·h/kg
Li2FePO4F     3.6 V   115 mA·h/g  0.414 kW·h/kg
LiCo1/3Ni1/3Mn1/3O2   3.6 V   160 mA·h/g  0.576 kW·h/kg
Li(LiaNixMnyCoz)O2    4.2 V   220 mA·h/g  0.920 kW·h/kg


  • \$\begingroup\$ Wauw, thats very interesing BarsMonster! So, if I understand correctly, then its a matter of give or take: you can have bit higher Volt 3.7, but give bit away in capacity of current. And vise versa the 3.6 V might hold bit more amp? I guesse the main question then would be: Can i rate/charge a 3.6V batt as 3.7 V batt and input a bit lower Amps in the smart charger? \$\endgroup\$ – Sam Jan 23 '11 at 1:02
  • \$\begingroup\$ No, you sacrifice battery life, not current. (But in long term yes, max current will decline). If you charge 3.6 battery to 3.7v it will die sooner, but probably not instantly. Extra stored charge is too little. It's more important when undercharging 4.2v one :-) \$\endgroup\$ – BarsMonster Jan 23 '11 at 10:27
  • \$\begingroup\$ "Can i rate/charge a 3.6V batt as 3.7 V batt …?" Yes you can, since 3.6 / 3.7 V is the nominal voltage of the cells, taken as midpoint voltage during 0.5C discharge. The difference is mainly for marketing reasons, indicating lower internal resistance of LiMnO2 cells over LiCoO2 cells. For charging, the cutoff voltage is the value to look at, which is 4.2 V for both 3.6 V and 3.7 V cells (some nickel-based Li cells charge to 4.1 V though, so check your specs). (source) \$\endgroup\$ – tanius Feb 9 '16 at 13:35

LI-Ion batteries are left with a charge of about 40% when they leave their factory. The discharge under storage is best then. This results in a voltage of about 3.7 for most types. When fully loaded or 100% charge the voltage is about 4.1V to 4.2V Do not charge them higher or they will lose their lifetime. They can be discharged until 3.3V or even lower but again lifetime is shortened when discharged too much. I have much experience in charging an discharging as i am using solar cells to charge my li-ion batteries. I use for charging my mobile phone(s)


It can in fact be very important!

The charging voltage of a 3.7V LiPo or LiIon is 4.2V, but for a 3.6V one it is only 4.1V! You could easily damage a 3.6V LiIon cell by charging it to 4.2V.

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    \$\begingroup\$ A good charger doesn't use a single charging voltage. You want current limiting, voltage limiting, and the charge profile indicates when the battery is done charging. \$\endgroup\$ – Ben Voigt Mar 20 '14 at 22:45
  • \$\begingroup\$ There are some chargers with a 3.6 V setting for 4.1 V charge cutoff, but I think this is not typically used for cells in consumer items: "Li-ion with the traditional cathode materials of cobalt, nickel, manganese and aluminum typically charge to 4.20V/cell. … Some nickel-based varieties charge to 4.10V/cell" – source. The 3.6 / 3.7 V difference is mainly for marketing reasons, they are both charged to 4.2 V (with the mentioned exception) – source. \$\endgroup\$ – tanius Feb 9 '16 at 14:21

The nominal voltage of Li-ion cells is 3.6V-3.7V, depending on the manufacturing technique. I doubt if you will see any difference between one delivering 3.6V and one delivering 3.7V, in practice, as there are many other factors involved.


most of the devices are not that sensitive to voltage. but when they tied up in a series that results in a big voltage difference and this difference is directly proportional to number of cells you tied in series. If your series contains 2-3 cells thats fine if you go beyond 5-10 cells that results in around 1V difference that matters for sensitive devices such as loptops.

gave a good one


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