Cable size?

Re: Cable size?

2/0 $3.70 a foot shipped, 4/0 $5.30 a foot shipped in 10' lengths. If You make all the Interconnects 9 1/2 " cable length plus the lugs and gives you a nice air space between the batteries easy room for expansion and contraction. The series cable goes in a "S " shape and the outside buses loop from battery to battery.

You always going to have a voltage sag with 12v , why tempt any drop for a $1.60 a foot.

Added: Every thing about being successful with batteries is about attention to detail. It's every crimp, Lugs that fit the battery lug posts. 2" of adhesive lined heat shrink on each lug, proper nut and washer. You have to reduce resistance in every connection that is possible. It's just not place to skimp. You drop a 180 amp load on a 12v bank everything has the best it can be. Even the charger in your inverter produces a lot of amps overtime ( 125 amps) one weak connection you'll have big trouble, that kind of amps will cause it to glow cherry red on a bad connection. Everything on 12V paralleled batteries is about getting them to charge and discharge evenly as possible.

I recommend you number each battery, the first pair on the positive end take the brunt of the current demand. Once a year tear the bank apart and shuffle the position of the batteries in the bank and brush every connection and coat every connection with a corrosion protectant. The vent caps on your batteries will clock 180°, make vent holes in the sides face away from the connections, attention to detail.
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Re: Cable size?

vtmaps wrote: »

He has 6 batteries (three parallel strings). Do you mean that the three (not two) batteries on the positive end will take the brunt of the demand?

--vtMaps

The way that I read it, he means the string (pair of batteries) whose + terminal is closest to the inverter and CC. Assuming that the batteries are wired diagonally, that pair would be the last pair on the negative end.
I do not think that he means that the two batteries in one series string will behave differently from each other, ignoring the other 4 batteries.

Re: Cable size?

Blackcherry04 wrote: »

Yes they are wired diagonally.

As explained at Smartgauge, diagonal charging is uneven charging for three or more parallel strings. Better, would be to use battery bus bars or combiner (smartgauge method 4).

Your wiring method may charge and discharge the middle batteries differently than the batteries at either end, but the batteries at the positive end and the negative end should be the same as each other. I guess that the reason the batteries in the positive end of your setup charge differently is because of temperature difference at that end of the battery bank.

--vtMaps

Re: Cable size?

Erinscot wrote: »

.... But now we have discovered that the generator is dying, and are looking at integrating solar much earlier.....r.

But you will have some sort of generator to provide backup power for when the sun don't shine, and the batteries are low ?

Re: Cable size?

This is kind of a FAQ here. Someone has a boat or RV that was historically a small 12V system, a few lights and electronic kit. They then decide to add a few things, then a few more things, and next thing you know they trying to run 5000W inverter off of 12v. A 5000W inverter will draw upwards of 550 amps. No average battery anywhere will cope with that. And least of all, not a few golf carts.

The investment in 12V gear prevents people from doing the rational thing, of going to a higher system voltage. But the fact is each step up in system voltage quarters the current related losses.

Following the forum rule of thumb, you need 100Ah of battery for each 1000W of inverter on a 48V system. That implies that for a 12V system you need 400Ah per kW. With AGM you can go a bit less, due to lower internal resistance.

Blackcherry has through long experience found a way to make it work, but read and reread carefully the preconditions he specifies.

Re: Cable size?

P=I^2*R, thus for a fixed R, I/2 means P/4. Can you mitigate that? Sure you can.

Re: Cable size?

On the pv side the voltage is relatively constrained and its the current that varys. So yes, the power losses are lower at lower insolation levels. Also you are horse trading copper costs, extra panels, and controller losses and so on, so losses on the pv side arent quite as critical as elsewhere.

2% is only a guide, and you certainly want much lower percentages between controller and battery, and battery and inverter for obvious reasons.