This is driving me nuts!!!

The general answer is:

Amp*Hours * Voltage = Watt*Hours

The specific issue about why AH vs WH... When working with battery systems, everything is 12 volts (or whatever)--So you assume that amps*time is always referenced to a fixed system voltage.

When working with 120 VAC and 12 VDC (mixed) voltage systems--You have to pay attention to the actual voltage... 1 amp at 120 VAC would take 10 Amps at 12 VDC:

120 VAC * 1 Amp = 12 VDC * 10 Amps = 120 Watts

So to keep things straight with off grid power systems, we tend to work in Watts and Watt*Hours, and then do the final conversions when need to Amps and Amp*Hours (wiring size, fusing, battery bank capacity).

Lead Acid batteries are actually pretty close to 100% efficient regarding current/AH flow... You draw 100 AH from a lead acid battery, you recharge ~100 AH back into the battery (during final charging/floating when batteries are gassing, the AH "efficiency" does drop--gassing/generating hydrogen+oxygen is a 100% loss).

Since lead acid batteries have a change in voltage (14.5 volts charging, 12.7 volts 100% SOC resting, 12.0 volts 50% SOC, 10.5 volts at near 0% SOC and/or heavy surge loads)--The Amp*Voltage or actual power output varies:

14.5 volts * 10 amps = 145 Watts
10;5 volts * 10 amps = 105 Watts

One reason (I believe) reason why battery systems tended to use Amp*Hours vs Watt hours... Many of the old DC loads were kind of fixed at current (i.e. loads would draw 5 amps at 12 volts or 5 amps at 14.5 volts--roughly). Filament lamps, motors, etc. tended to be self regulating (current wise)...

However, when we throw an AC inverter into the mix--These inverters are "constant power" loads on the DC system side... For example, a 120 VAC @ 1 amp load looks on the DC side like:

• 120 VAC * 1 amp = 120 Watts
• 120 Watts * 1/0.85 AC inverter eff * 1/14.5 volts battery (charging) = 9.7 amps @ 12 VDC (charging)
  
• 120 Watts * 1/0.85 AC inverter eff * 1/12.0 volts battery (charging) = 11.8 amps @ 12 VDC (discharging)
• 120 Watts * 1/0.85 AC inverter eff * 1/10.5 volts battery (charging) = 13.4 amps @ 12 VDC (near dead battery)
  

So--A fixed "AH" rating for a battery over a wide range of voltages and states of charge is not really very easy to "understand" the amount of available energy in the battery.

You will now see some batteries (generally those designed for UPS systems) not only have an AH rating, but also have a Watt*Hour Rating--Which better matches how an AC inverter actually draws power/current from the battery bank.

In the end--Use AH for battery rating, and I suggest "nominal voltage" (like 12 VDC) to estimate battery energy capacity. Use Watt*Hours for all of your other power/energy calculations--And just convert to Amps and Amp*Hours when needed (fusing/breakers/wiring at 120 VAC or 12 VDC as an example).

For us, when helping... We get people say they have a 10 amp load--But we don't know if that is 10 amps @ 12 volts (120 watts) or 10 amps @ 120 Volts (1,200 Watts) or even some other voltage (12/24/36/48/120/230/240 volts etc.)--So we trip over each other trying to clear things up.

We stay with Watts and Watt*Hours for initial system design, and do the voltage conversions when we select components (charge controller, battery bus voltage, battery sizes, etc.).

-Bill

48 volt input inverter?

How much Power do you need (peak watts at 120 VAC)?
How much Energy do you need (Average Watts * Hours per day--1,000 Watts * 5 hours per day = 5,000 WH per day)?
Is this an emergency backup system, weekend/seasonal cabin, or a full time off grid system 9+ months of the year?
Where (roughly) will the system be installed (near what major city)?
Do you plan on having a genset? Will there be grid power?
What is your expectation of they system (how do you want to use it, install yourself, are you prepared to perform maintenance)?

Define your needs first--Then design a system that will support those needs. Remember that a 6 volt @ 200 AH battery is basically the same size/weight as a 12 volt @ 100 AH battery:

6 volts * 200 AH = 12 volts * 100 AH = 1,200 WH of storage

-Bill