Solar Powered Sumbermisble Pump

Thank you for the info.

If you are refer to Mapmaker's corrected figure in BOLD, Yes it is base on 24 volts. I think is over kill for a 157watts load. I would just get 1500 watts Panels and 500 amps hour batteries at 24 volts system and a backup Generator for cloudy/rainy days.

I am confused now.
Is this calculation in bold for a 24 volt system?

Please clarify, thank you.

Have heard that before, but these were the measurements I took a couple years ago when the system ran off-grid. Just coincidence perhaps?

Untitled.jpg

P.S. Running the capacitive load of the lights on the same circuit as the inductive load of the pumps pulled the PF up closer to one just as you would expect. Lights & pumps were more efficient that just running pumps or just running the lights.

Actually, low power factor loads have very little effect on the draw from the battery.

The low power factor load means the inverter must be rated higher than the watt consumption, and there will be a lightly higher cable loss.

Suppose the loads have a watt draw of 150 watts, and a PF of 0.5. The VA will be 300 watts. The inverter must be rated 300 watts, but only the 150 real watts are drawn from the battery. The excess VA watts (over the real watts) is current just "sloshing around" in the wiring. It is not consumed.

If 300 watts from the battery were consumed, and only 150 watts were consumed by the load, the inverter would be turning 150 watts into heat.... and you would know it... the inverter would be running very hot.

--mapmaker

Now, something is seriously wrong with your setup!!. I have 6400watts array that run my whole house with pond pumps and 2 refrigerator and a freezer, washing machine and other lights etc. I only need to use my generator for few hours when the sun is covered with cloud for the day.

I have a small pond with 2 pumps rated 125VA each, when I use the kill-a-watt meter to check them , it say 65 watts and 120VA on the meter. I use 3 225watts solar panel and a 60 amps CC with 4 6volts 225 amps deep cycle batteries. I have one pump run 24/7 and the other run 8 to 12 hours on the day depend on the weather. so I don't see how you have to use 5000watts to run a little 125watts pump and 2 air pumps with 2 lights.

Now account for the aquaponic pump and lights having power factors of 0.35 and 0.6, respectively and you may end up back where you started

Like I said earlier, my experience was that a 3 kw array barely kept up with my system which is similar to what the OP appears to be designing (albeit my pumps were lower wattage). He's gonna be adding air pumps into that setup to, so a large array is inevitable. If he has no backup power source, he best overdesign the array or the tanks will go off-line at some point in the first few months of operation. Depending on his stocking density, he could lose many of his fish friends within the first 6-12 hours of the pumps stopping.

You are correct. I will go back and correct it. thanks for catching it. We seem to have lost the OP. --mapmaker

I think here is what is wrong. 683 amps is for 24 volt and the last calculation 6000 watts is base on 48 volts.

I guess I see what is wrong. You use 24 volts here. and you use 48 volt on the next reply.

Seriously? Use 6KW PV array to run 3.2kwh daily load? Am I missing something?

Thank you very much for breaking it down for me and the OP.
At least next time I should be able to calculate it for myself.

I ran 500 gallons of aquaponics (600 gph of pumps, two air pumps, two T8 fixtures, etc) on a 3 kwatt array but that was marginal. Much happier to be expanded to a 5 kwatt array and grid tied now.

Based on experience (without doing the calcs) I'd say a 6 kwatt array need is realistic based on what's been presented. Bravo, mapmaker . Not a bad guess at all. Takes a lot more panels than what people might first feel is necessary.

I usually, as a starting point, design for a 10% charge rate. The units are a bit idiomatic... What I'm getting at is that the battery's capacity, in amphours at the 20 hour rate (C20) is 683 amphours. Ten percent of that number is 68.3 amphours... but we want to be able to charge at 68.3 amps (not amphours). That, by the way, may be expressed as C20/10 (the 20 hour Capacity divided by 10).


The solar array needs to provide 68.3 amps, and you must account for loads and controller losses and cable losses. This system has small, but constant loads. I will somewhat arbitrarily call those loads and losses 10% (the controller, solar array string voltages, temperature and many other factors make up that 10%). In the OPs system the loads are small enough to fit within the 10%).


So now we need 68.3 amps + 6.83 amps = 75 amps.


You need to be able to make that 75 amps at about 60 30 volts (that 60 30 volts is somewhat near your absorb and or equalization voltage)
75 amps X 60 30 volts = 4500 2250 watts.


Of course solar panels rarely produce their nameplate power, so you must derate them. For a first approximation, 75%


4500 2250 watts ÷ 75% = 6000 3000 watts


So to answer your question... first approximation is 6000 3000 watt solar array.


In any real system, the numbers can be worked out more precisely, depending on many factors, including some that I have mentioned.


--mapmaker
------ Edit: should have used numbers for a 24 volt system. Correct numbers in bold. Thanks, Paul

So.....how many watts of panels does this member need to do the job ?