New system 24 or 48 volt?

Re: New system 24 or 48 volt?

I've built a 48V system and I have absolutely no regrets about this. And I've never heard of anyone who has.

If you go through this forum, you'll find many cases of people who built 24V systems and then want to switch to 48V, but it's too hard because they have to replace their 24V equipment.

Numerous pluses are: less parallel batteries, more efficient use of MPPT controllers, less losses in the cables, much easier to expand.

I don't think 48V is such a high voltage that it causes any real problems.

Re: New system 24 or 48 volt?

ultimately it will be op's choice on what to get, but i think we are all agreed he needs more than 6 pvs. if you opt for the 48v battery system then the pvs will need to increase by strings of 3pvs whereas the 24v battery system can have the 2 pvs in its strings allowing only 8 pvs to be needed there. there's allot of fence sitting with the system you propose in that it's not as easy to say what works best for you. if it were me and i don't want to worry if it can be handled or expanded upon if need be then i'd go 9 pvs in a 3x3 arrangement into a classic 150 outputting 48v so you can arrange the batteries to have fewer paralleled strings. there is a difference though between 48v and 24v in voltage drops and power surge handling capabilities and you may see less mismatching of the batteries leading to possible longer life. your choice on what inverter to go with.

Re: New system 24 or 48 volt?

mikeo,
i'm glad you brought up the batteries as looking back he does not already own the batteries as i assumed he did. if given a choice on the batteries you probably should look into L16s be they 6v or 2v to have higher amperage batteries to begin with and you could thus avoid having so many paralleled strings of batteries to get out of balance.

Re: New system 24 or 48 volt?

ChrisOlson wrote: »

Yep. It really depends on what panels you choose for that. If you use the ~30 Vmp panels you'll get better efficiency from the controller on 24V with those at 60 Vmp than you will by wiring the same panels three in series for 90 Vmp on 48V. If you wire those panels four in series for 120 Vmp on 48V the efficiency from the controller will be less yet.

Chris

You would also have to factor in the wiring loss, but of course would be dependent on how far away the array is. I am running 90 volts with my Midnite CC on a 24 volt system, and find that I'm getting good power and charging current into the batteries. I figure that the loss in efficiency of the CC would be comparable to the wire loss with the lesser voltage. I'm not so concerned about the CC loss as the little bit of extra heat helps to keep my place warm anyway, and in summer I have plenty of excess power.

Re: New system 24 or 48 volt?

Wiring loss won't be much of a factor for you with #4, even at that distance. I notice that many others make their runs with #10, albeit, their runs are usually shorter as well.

I'm currently using #10, with a short run of about 35 feet or so, from the combiner box into the house with my 1.4 kw array. The combiner box if very close to the solar panels. When I plan to expand the array, I will make separate runs of #10 in for each array of 6 panels.

Re: New system 24 or 48 volt?

Chris, I agree gen support would work for him with the XW.
I wonder if there is a HOA in that little village? Sound like they may be there for the quiet and peace... might nix a gen running

Re: New system 24 or 48 volt?

BB. wrote: »

From what I understand/guess... Higher input voltages "charge" the stray capacitance on the FETs with more stored/wasted energy (Field Effect Transistors). The charging/discharging of these capacitors is a "loss of efficiency" (Energy in Capacitor=1/2 * CV²).

This would be a bigger and bigger problem as the switching frequency is increased to allow the use of smaller coils.

Re: New system 24 or 48 volt?

NorthGuy wrote: »

IMHO, the FET switching losses are proportional to voltage to be dropped multipled by switched current.

This seems to be based on the idea that the resistive loss in the FETs during the switching transition time is the primary loss mechanism.

The FET losses which switched off will be zero and while switched on will be proportional to the current raised to some power greater than one and less than or equal to two.
But during the fractions of a second that they are turning on, the losses will be proportional to the open circuit voltage across them times the current, more or less, for a linear change in current between on and off.
Those both would give higher losses for the higher current, but are only two of several estimating mechanisms. And the the second one makes what I think is a mistaken assumption:
I think that one reason your analysis may give wrong results is that it assumes that the length of the switching time of the MOSFET is constant, were in reality it is proportional to the voltage to which the gate was charged. This causes the power loss during switching to be proportional to V x V x I instead of just V x I.

With your numbers, that gives us 89,100 (skipping the units for now) for the 48 volt case and 72,963 for the 24 volt case. Not enough to make as much of a difference as Chris reports, but definitely favoring the lower voltage drop configuration.
If the gate voltage is actually being switched between Vin and 0, on the other hand, we then get the numbers as:
356,400 for 90 volts and 241,200 for 60 volts. A nearly 50% increase in losses for the higher voltage operation.
Where is the power FET engineer when we need him?