Inverter/Transfer Switch

Re: Inverter/Transfer Switch

Remember, a 7 kW inverter with a 3kW inverter and transfer switch--Normally, you would wire up a maximum of 3kW of loads to the inverter/transfer switch and the more than 3kW loads directly to the 7 kW genset (say everything in the house to the 120 VAC inverter, and a big/deep well 240 VAC well pump to the genset).

Note that large inverters need large battery banks to power the loads/starting surges...

For example, a C/8 discharge rate (healthy rate of continuous discharge for a flooded cell battery):

• 3,000 watts * 1/12 volt battery bank * 8 hour rate of discharge * 1/0.85 inverter eff = 2,353 AH @ 12 volt battery bank

If he wants to support a 3,000 watt surge, then a C/2.5 rate of discharge maximum is suggested (again for flooded cell):

• 3,000 * 1/12 volts * 2.5 rate of surge discharge * 1/0.85 inverter eff = 735 AH @ 12 volts

And the amp rating for 3,000 watt 12 VDC inverter wiring would be:

• 3,000 watts * 1/10.5 inverter cutoff * 1/0.85 inverter eff * 1.25 NEC derating = 420 Amp rated wire and breaker/fuse

To recharge the battery bank, you would want ~5% to 13% rate of charge (nominal). 10% of a 2,353 AH battery bank would be 235 amps. Or 10% of 735 AH would be 74 Amp recommended charging current.

Also, it is nice to size the genset to the amount of charging current you will be supplying to the battery bank... A 3kW inverter system would need around a 2-4kW genset (depending on rating of AC battery charger and the eventual size of the battery bank).

Generator fuel efficiency (kWH per gallon of fuel) typically begins to fall dramatically at 50% of rated output (i.e., fuel flow levels off at 50% of full load from 50% load to 0% load). If the generator is going to run a lot to recharge the battery bank--Sizing the AC charger and the generator to the battery bank charging needs can save a lot of fuel (i.e., use a 2kW genset to recharge the battery bank vs a 7kW could save 1/2 to 2/3 of the fuel used to recharge the battery bank).

Normally--I think many of us here would suggest a small battery based solar pv system (even 300-600 watt range) and then run the genset for larger loads... Possibly even two gensets. A quiet 1-2 kW inverter/generator (Honda/Yamaha/etc.) for "smaller" loads. And the 7kW for large loads (shop loads, saws, well pump, etc.).

But, in the end, it is very difficult to design the "optimum" solar power system without knowing more about the loads. Using a Kill-a-Watt type meter to measure the AC loads (per day, by season if appropriate) would be a big help.

Depending on the needs--Could even simply start with a Honda eu2000i inverter generator and a kill-a-watt meter. Run for a few days to a month or so purely on the genset and log the daily power usage (kill-a-watt meters need to be read before genset is turned off).

Will very quickly identify how much power is really needed to run the operation.

-Bill