Charging 6 volt batteries in series

**Sunking** · 02-15-2013, 10:22 AM

Originally posted by Beanyboy57

Secondly what is the difference between "over priced crappy battery panels" and "less expensive GT panels. I have paid a lot of money for my 5 battery panels damn it! Why are GT panels less expensive?

Battery panels are low voltage, and cost significantly more than GT panels because of supply and demand. Very little demand for battery panels. When you use MPPT controllers you can use much higher voltage panels which is also much more efficient and save money on installation cost by using smaller wire between the panels and batteries.

**Naptown** · 02-15-2013, 10:45 AM

Originally posted by Beanyboy57

Good to see you are back to your normal self Derek!

Couple of points, the manufacturer of my MPPT controller recommends a panel voltage of at least double the battery voltage, in my case that means I need at least 48v for my 24v battery bank.
Secondly what is the difference between "over priced crappy battery panels" and "less expensive GT panels. I have paid a lot of money for my 5 battery panels damn it! Why are GT panels less expensive? Or should that question be placed on another thread?

Because the market for smaller battery panels is limited there are not many made. Most are made for grid tie and are much less expensive than the small panels due to economy of scale.

**ImpactBattery** · 02-26-2013, 09:10 PM

Originally posted by Sunking

OK you need to go back to school, or slap the crap out of your crappy physics instructor for making you an idiot who taught you garbage. That is why he or she likely teaches and not in the private sector making real money.

You have no idea of how a MPPT or PWM Controller operates.

A PWM controller is a very simple on/off switch where Input Current = Output Current. So take a standard 12 volt 100 watt battery panel the typical specs are Vmp = 18 volts and Imp = 5.55 amps. Connect that panel either directly to a discharged 12 volt battery, or through a PWM controller and you will have 12 volts x 5.55 amps = 67 watts. You just lost 33 watts using a PWM controller. Minimum losses with a PWM controller is 33% period. If you are an idiot and say buy a 100 watt 24 volt battery panel and connect it to a 12 volt battery you have 12 volts x 2.778 amps or 33 watts out of a 100 watt panel.

Now wake up and smell the coffee burning and lets talk about a MPPT controller. Input Current Does Not = Output Current. They are true Power Converters where Input Power = Output Power - Conversion loss of about 3%. Take that same 12 volt 100 watt battery panel and at the input of the controller you get 18 volts @ 5.55 amps, and on the output you get 12 volts @ 8.1 amps or 97 watts.

Lets go one step further with that same MPPT controller. Except this time I want to get rid of using over priced crappy battery panels and use a Grid tied panel 100 watts with 100 Vmp and 1 amp Imp. At the input of the controller I have 100 volts at 1 amp. On the output I have 12 volts @ 8.1 amps or still 97 watts. Not only do I get to use a much less expensive GT panel, but I get to use much smaller less expensive wire with less losses.

Now run they by your understanding of physics and you will quickly realize you do not know much, or what you think you know is wrong. Bet your physics teacher name was Mr Dunno Chit

Fair enough. Thanks for the lesson.

In your opinion, what is a good brand/model for Grid Tied Panels at 100 watts with 100 Vmp and 1 amp Imp?

**Naptown** · 02-26-2013, 09:51 PM

Originally posted by ImpactBattery

Fair enough. Thanks for the lesson.

In your opinion, what is a good brand/model for Grid Tied Panels at 100 watts with 100 Vmp and 1 amp Imp?

Don't think that animal exists. At least in a hard cell. Maybe in an an amorphous panel.

**inetdog** · 02-26-2013, 10:05 PM

Originally posted by ImpactBattery

I am applying my understanding of physics.
...

The panels put out what they put out (from next to nothing voltage to their peak voltage)...

Reduce the amount of energy wasted in conversion and save the amount that is useful energy. The closer you can have side A to side B, the more efficient (the least amount of energy wasted) the system.

Let's start with the easy one first. Technically, over a wide range from moonlight to full sunlight, all the way down to where the internal leakage current consumes the entire cell output, the PV panel puts out almost exactly the same voltage. It is the current that is changing.

Second, the mere fact that a voltage conversion is taking place does not mean that there is any particular level of inefficiency.

Going back to your physics education, if you use a lever with a one-to-one ratio of its arms to move something, the efficiency will be exactly the same as if you use a lever with a 10:1 or 1:10 ratio. The results in terms of the required forces and range of output motion will be different, but power in ~= power out. Any inefficiencies will come from bending of the lever, friction at the pivot, and other factors not directly associated with the leverage ratio.

By the same token, a DC to DC convertor can have roughly the same conversion efficiency independent of voltage, since the major losses in transformers, inductors, switching transistors, etc are pretty much the same when working at a 1.1:1 ratio or a higher ratio.

An MPPT CC optimized for a 120 volt input to 48 volt batteries will not necessarily be more efficient at a 60 volt input to charge the same battery bank.

Charging 6 volt batteries in series

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