Wire sizing question

Re: Wire sizing question

Hit the brakes.

21 * 280 = 5880 Watts * 0.77 / 48 Volts nominal = 94 Amps.

Not even a MidNite Classic can handle that. Time for redesign.

Re: Wire sizing question

rplarry wrote: »

That wasn't the question, but since you are curious, there are 2 fm 80's for charge control.

May not have been your question, but it is a problem.

This is very important: you do not connect one array to the inputs of two MPPT charge controllers.

Therefore your original premise is also wrong as the current from the total panels must be divided between the two controllers and carried on separate wires.

Re: Wire sizing question

2 AWG will handle 60 Amps no problem.
Now about that Voltage ... 110? Is that possible Voc * 3? Because you should be calculating using Vmp, and on a 280 Watt panel that's usually around 30 so X3 would be around 90.

In any case the V-drop on 35' of 2 AWG even at 60 Amps and 90 or 110 Volts is going to be less than 2%. You could probably use 6 AWG in fact.

Re: Wire sizing question

westbranch wrote: »

I see another anomaly, Panel amps...... 280 W / 30v= ~9.3A not 15 as stated in post #1. Amps are not cumulative in a series configuration only Volts

He is probably going by the maximum series fuse rating, which is of course not right. That rating does not enter in to figuring V-drop (and therefor power loss).

If you take the maximums given and multiply them out you get 110 Volts * 60 Amps = 6600 Watts, which is well above 21 panels * 280 Watts each - 5880 Watts.

You have to use the right numbers to begin with or else the calculations all fall down.

Re: Wire sizing question

rplarry wrote: »

Yes, I am using the max rated amperage of the panel that is how I came up with a 15 amp potential in the string of three. I would rather over wire it than under wire it. also my neighbor happens to have some #2 wire left over from another project so Looks like we can use that. Thanks for your patience with me.
Larry

This is unnecessary.
The series fuse rating has nothing to do with the maximum output of the array. It's about protecting the array (and your house) in case something goes wrong and one string shorts, thus becoming a conductor. At that point it would be subject to the combined Isc of the other strings. In this case you could be looking at 9 Amps Isc * 3 'good' strings dumping a total of 27 Amps to one 'shorted' string which is only capable of handling 15 Amps. Thus the circuit breaker trips and protects against the shorted string from heating up to the point of ignition.

A panel or string of panels with an Isc of 9 Amps is never going to produce 15, even under super-optimum conditions.

So in reality you have 280 Watt panels with a Vmp of ~30 and an Imp of ~9.3 configured as four parallel strings of three in series giving an array with Vmp 90 and Imp 37.2 which are the numbers used when calculating wire size and Voltage drop. V-drop matters most at this maximum power point, and all wires/conductors can take momentary surges above their continuous rating. As such using the 110 Voc is not right, nor is using the maximum series fuse rating X4.

But the 2 AWG wire is going to handle anything that array can produce. The downside is having to work with the heavy wire, especially as the charge controller won't accept it on its input terminals. You will probably need to transition from 2 AWG down to 6 AWG using crimped lugs & bolts or saddled bus bars.