Solar installtion review request - numbers check - solar install on a boat

niel wrote: »

i can tell you right now that you need at least #2 from the cc to the batteries, but i think i'd go #0. this is not just due to the losses in the run, but also the losses in the interconnecting battery wires. it is also important that losses be kept low in this stretch because of the lowered voltage in it, but also due to v drops fooling the cc into thinking the battery is charged when it isn't. this particular controller i believe has a remote battery sense for voltage and can compensate for the v drops presented by the wires to the batteries only to keep the cc from being fooled into thinking the batteries are charged when they aren't. it will not stop v drop losses from occuring though so good heavy wire is still needed.

The largest gauge wire the Morningstar can use is 2, which is what we'll use. One of the other features is a 'sense' wire monitoring of the batteries.

now you will only need to consider 1 of the pv strings for the v drop % presented from the pvs to the combiner. if one is longer than the other then use that longer one for the v drop % to be added to the rest of the system losses later. remember all v drop percents add together starting from the pvs and going all the way to the batteries. now each pv has about 6ft of wire to consider too. i don't know the specifics on those pvs as to what gauge number or length is used. if the gauge number is different on the pvs then calculate the v drop percents for that wire and the run to the combiner separately and add these together after calculated. remember that the series string here is only pushing the imp of a single pv and would be at 7.67a and this lower current at higher voltage does help to keep losses down. the 30ft run length from the combiner will have the beneficial high voltage the series strings offer, but being there are 2 strings being paralleled that the current will now be doubled and will double your v drop losses. 2 x 7.67a = 15.34a. you have some flexibility here in that no mc4 connections will need to be present so you can use whatever gauge you will in order to go as low in the v drop percentage as you may prefer. also note that a fuse or circuit breaker is not required, but often this can be used to double as a means of disconnecting the pvs. a good dc switch rated for the voltage and current could alternately be put in here too.

to summarize the v drop % for each section needs calculated and later added together that should at least be under 3%, but you could opt for under 2% as well if you like. the following are the sections you can individually calculate for.

Great info, thanks so much. That's a bit to chew on, going to go remeasure some runs, and see if there is some way to shorten some wires.

the built in pv wires
the string run to the combiner
the combiner run to the cc
the cc run to the batteries (at a lower regulated voltage from here on out)
series battery interconnections, and like the pvs, only consider 1 of the battery strings and make each other battery string identical with wire gauge and length used so as to keep symmetry.