Page 17
Sizing the Inverter Battery Bank
One of the most frequently asked question is, “how long will the batteries last?’. This
question cannot be answered without knowing the size of the battery system and the load
on the inverter. Usually this question is turned around to ask “How long do you want your
load to run?”, and then specific calculation can be done to determine the proper battery
bank size.
There are a few basic formulae and estimation rules that are used:
Formula 1
Power in Watts (W) = Voltage in Volts (V) x Current in Amperes (A)
Formula 2
For an inverter running from a 12 V battery system (PST-150S-12A),
the DC current required from the 12 V batteries is the AC power
delivered by the inverter to the load in Watts (W) divided by 10 & for
an inverter running from a 24 V battery system (PST-150S-24A), the
DC current required from the 24 V batteries is the AC power delivered
by the inverter to the load in Watts (W) divided by 20.
Formula 3
Energy required from the battery = DC current to be delivered (A) x
time in Hours (H)
The first step is to estimate the total AC watts (W) of load(s) and for how long the load(s)
will operate in hours (H). The AC watts are normally indicated in the electrical nameplate
for each appliance or equipment. In case AC watts (W) are not indicated, formula 1 given
above may be used to calculate the AC watts by multiplying 120 VAC by the AC current in
Amperes . The next step is to derive the DC current in Amperes (A) from the AC watts as
per formulae 2 above.
An example of this calculation for a 12V inverter is given below:
Let us say that the total AC Watts delivered by the12 V inverter = 1000 W
Then, using formula 2 above, the DC current to be delivered by the 12 V batteries = 1000
W ÷10 = 100 Amperes
Next, the energy required by the load in Ampere Hours (AH) is determined. For example,
if the load is to operate for 3 hours then as per Formula 3 above:
Energy to be delivered by the 12 V batteries = 100 Amperes × 3 Hours = 300 Ampere
Hours (AH)
Now, the capacity of the batteries is determined based on the run time and the usable
capacity. From Table 1, (on page 15), the usable capacity at 3 Hour discharge rate is 60%.
Hence, the actual capacity of the 12 V batteries to deliver 300 AH will be equal to 300 AH
÷ 0.6 = 500 AH
And finally, the actual desired rated capacity of the batteries is determined based on the
fact that normally only 80% of the capacity will be available with respect to the rated
capacity due to non availability of ideal and optimum operating and charging conditions.
So the final requirements will be equal to:
500 AH ÷0.8 = 625 AH (note that the actual energy required by the load was 300 AH)
It will be seen from the above that the final rated capacity of the batteries is almost 2 times
the energy required by the load in AH
Thus, as a thumb rule, the AH capacity of the batteries should be twice the energy
required by the load in AH
