Dickieboy said:
This is where I keep going back to the 3 phase load center and doing one calc for overall
dick
FWIW, you can calculate the volt drop several ways: using the IEEE exact method (see post #4), the IEEE approximate method (V = IRcos@ + IXsin@), or the cmil method (see post #2 where K is 12.9 for cu and 21.2 for al and you can find the cm in the NEC table 8).
As for the load center method, you still have to make a series calculation until you have reached the allowable volt drop %.
The load center method works fine (except that you need to divide by the current, not the # segments), but it does not reduce the problem down to one calculation:
12124.36 amp-ft / 17.3 amp = 700 ft load center
700 ft @ 17.3 amp with #8 = 3.41% vd
700 ft @ 17.3 amp with #6 = 2.14% vd
As you can see, this is not a complete solution so you have more work to do. You will have to start the next calculation using the accumulated vdrop of the source sections. This is how you make a series vd calc.
The next step would be to calculate the vd in segment 1 with #6. The load center for the remaining segments is 250 ft, 13.9 amps, 3464.1 amp-ft and you will need #10 and it gets you a 3% vdrop. Since there is no remaining vd capacity, you are done (unless you want other wire combinations).
If using a computer, you get the same result making the series vd calculation by segment.
This is quite simple to put in a spreadsheet. Start all segments with the smallest wire needed to get to 3% or less, then use this size for segment 1. Then let segments 2+ have a size that gets to 3% or less, then use this size for segment 2. Then let segments 3+ have a size that gets to 3% or less, then use this size for segment 3...
You will find that once you get to segment #2, you have the same result as in the load center calc, meaning you have run out of vdrop allowance and you are done when you get to the #10 in segment 2.
