12V Battery Charger for Lead/Acid
The battery charger circuit below is very simple to build requiring only a handful of cheap parts and an extra winding on your power tranny (or a separate tranny). Since the chargerdescribed is not active during sound reproduction, I have made no criteria on parts quality, so el-cheapo was the way to go.
There are many circuits available for charging batteries, but many are forNiCd or NiMH batteries. They will not work for lead/acide batteries, so don't use these!!! The best way to charge a battery is with a current limited voltage regulator. This sets a maximum current (say 1A) that will flow to charge the battery. If the current rises over this set current, the regulator will be forced to put out a lower voltage. Since voltage drops, so will the current; hence current limited. While thebattery is charging, the current should decrease slowly while voltage starts to increase. In the end the current will be next to zero and the voltage will be equal to the set voltage.
Use the following to design a charger:
There are many circuits available for charging batteries, but many are forNiCd or NiMH batteries. They will not work for lead/acide batteries, so don't use these!!! The best way to charge a battery is with a current limited voltage regulator. This sets a maximum current (say 1A) that will flow to charge the battery. If the current rises over this set current, the regulator will be forced to put out a lower voltage. Since voltage drops, so will the current; hence current limited. While thebattery is charging, the current should decrease slowly while voltage starts to increase. In the end the current will be next to zero and the voltage will be equal to the set voltage.
Use the following to design a charger:
- The charging current should be kept to around 0.1 times the capacity of the battery. So a 10Ah battery should be charged with 1A of current (10 x 0.1 = 1). The battery will not be forced (quick charged) this way and assures a longer lifetime.
- The charging voltage should be set to 2.3 - 2.4V per 2V cell. So a 12V battery (6 cells of 2V) is charged at 6 x 2.3 = 13.8V.
- The transformer winding for the charger supply is chosen at the charging voltage plus 3V regulator drop plus 1.4V rectifier drop (two diodes) plus 10% safety. So for a 2V battery, the winding (AC) is 2V + 3V + 0.7V + 0.7V = 6.4V + 10% = 7V.
- The charging current is limited by the small resistor in the common leg of the charger. The value for this resistor can be calculated with: R = 0.6V / max current. So if I want a maximum current of 0.5A, I will need 0.6V / 0.5A = 1.2 ohms. The 0.6V is the voltage required for the transistor to go fully into conduction. Between 0V and 0.6V the transistor will adjust the regulator to increase or decrease voltage depending on the current it is passing.
- The charging voltage can be set using the potentiometer. Just hook up a volt-meter to the charger (without the battery attached) and adjust the output voltage until it macthes the charging voltage. Use a 1K pot for 2V batteries, use 5K for 6V and 12V batteries.
- Use an extra fuse on the charger, about two times the maximum current you are charging with. Fusing is critical for safety reasons. A battery can deliver 100+ amperes during a short, so it can cause serious damage or even fires when something goes wrong with the charger. Put the fuse behind the regulator in the lead going to thebattery. This fuse is not to protect the supply from a short in the charger, but to protect everything else from the battery in case of a short anywhere. Don't forget to fuse the primary winding of thecharger as well...
- You're set up to charge...