Inverter to Panel Help

Cariboocoot wrote: »

Looking for about 60 Volts @ 100 Amps you get 6 kW of panel.

BB. wrote: »

A battery bank (48 volt) will run from ~42 volts dead to ~60 volts high (equalization).

A MPPT charge controller is a "constant power device... For example a 1,200 watts (nominal) array would output:

• Power = Volts * Amps
• Amps = Power / Volts
• Amps = 1,200 watts / 42 volts = 28.6 amps into a "dead battery"
• Amps = 1,200 watts / 60 volts = 20.0 amps into a "well charged battery"

So, since we are looking at getting XX% of battery AH capacity into the battery, we choose the "worst case" amperage conditions for a MPPT controller--Charging a battery near Vbatt-max charging voltage.

To charge a 48 volt battery bank at rated current and nearly fully charged, vs rated current into a well discharged battery.

So lets say we want 60 amps into a well charged 48 volt battery bank... (I use ~58-59 volts), assume 0.77 charge+panel losses:

• 60 amps * 59 volts * 1/0.77 system charging losses = 4,597 watt array

If I was to use the "nominal" 48 volt battery rating (which is fairly discharged battery voltage when under charged):

• 60 amps * 48 volts * 1/0.77 system charging losses = 3,740 watt array
• 4,597 watts / 3,740 watts = 1.23x larger array...

To be honest, if your "real numbers" are within 10-20% of what is calculated for your solar power system (with all of the variables)--you are doing well...

I like to use the "worst case" values when making these estimates... It will make the array / system a little bit larger (~23% in this case)--but it does a better job of accounting for losses and how the various devices work.

Could you build a minimum 5% rate of charge system with the smaller numbers--That would be really a ~4% rate of charge system (about 20% smaller)... Not the end of the world--but every place if we "error" to the smaller numbers--we may end up with a system that will not meet your performance expectations.

Anyway--too many words explaining why this I (and others) do it "this way".

-Bill

Cariboocoot wrote: »

(I know we need a picture library of basic schematics for solar wiring but I'm not going to mention it 'cause I'll get volunteered to create it. )

BB. wrote: »

Each panel has a set of parameters:

• Voc=Voltage open circuit
• Vmp=Voltage maximum power
• Isc=Current short circuit
• Imp=Current maximum power
• Series Protection Fuse (maximum current/fuse rating per panel/series string)
• Temperature compensation (as panels get cold, Voc rises. As panels get hot, Vmp falls)

For the Controllers:

• Vmax = Maximum Rated input voltage
• Voperational = Min/max range of operating voltage
• Ioutput-rated = Maximum continuous rated output current
• Iinput-max = Maximum Array Isc before you need an input fuse/breaker

So--You basically have to configure your solar array for:

• Vmp... Typically 17.5/35/70 volts < Vmp-array < ~100 volts Note:
  • low voltage is for 12/24/48 volt banks (for a 150 Vmax controller in cold region)
• Vmax must be less than Voc-Array on the coldest morning/ambient temperature you would expect with the sun above the horizon. Typically for a Vmax=150 vdc in cold climate, roughly Vmp-array~100 VDC maximum will work for most location.

Note, the array can be >> than the MPPT Charge Controller's "rated output power"--MPPT controller will regulate their output current to the maximum rated current (safely).

For example, to figure out the maximum (cost effective) array wattage for a typical MPPT system:

• Parray ~ Controller Current * Vbatt-charging * 1/0.77 controller+panel deratings

So, for a 12, 24, and 48 volt battery bank:

• P-12volts @ 60 amp = 14.5 volts charging * 60 amps * 1/0.77 = ~1,130 watt maximum cost effective array
• P-24volts @ 60 amp = 29 volts charging * 60 amps * 1/0.77 = ~2,260 watt maximum cost effective array
• P-48volts @ 60 amp = 58 volts charging * 60 amps * 1/0.77 = ~4,520 watt maximum cost effective array

You can go larger, but the MPPT charge controller will spend more time "current limiting" -- so the extra panel power is largely wasted.

Note, it is not unusual for the input voltage range from Vmp-hot to Voc-cold to be almost a 2:1 range (~Vmp=70 volts; Vmp-hot to be ~60 volts or less; Voc-cold ~120 volts or more). All depends on panels and climate.

You can go real small on a large MPPT controller--but they do have their own losses--below 400 watts, the controller operating power requirements, on a large controller, become significant and waste a fair amount of power (not very efficient with small arrays on large controllers).

For many MPPT controllers--their "optimum" efficiency is Vmp-array about 2x the Vbatt voltage.

-Bill

• 60v= 72.5v * 60 amps * 1/.77 = ~5649 Watt array