75 Amps theoretically Need to know if the generator is 3 phase or single phase.
The minimum is (6000/240) amps for an ideal load, i.e. 25 amps.
20.8
The equation that you are looking for is I = W/E. Amps = Watts/Volts. The generator has the capacity to supply 25 amps. Of course the load is what governs the amount of amperage drawn. Any load greater than 25 amps will load the generator down and probably trip the generator's breaker.
The following formula is used to find amperes when kilowatts are shown. kw x 1000/1.73 x E x pf. The term pf is the power factor value usually using a value of .9. 18000 watts is equal to 18 kWs. 18 x 1000/1.73 x 240 x .9 = 18000/374 = 48 amps.
If you need 50 amps you can use a 60 amp generator or any other generator rated to supply more amps. The voltage, 110 v or 240 v, must be the right voltage for the load used.
Watts = Amps x Volts. Amps = Watts/Volts. 10000/120 = 83.3 amps can be used at 120 volts. On a generator that large it is most likely that it also has the capacity to produce 240 volts. 10000/240 = 41.6 amps can be used at 240 volts. What you can connect to the generator will be totals of the amperage of devices that do not go above these amp ratings.
1.5kva has enough electrical power to supply 100 volts of electricity that is at 15 amps. You can also supply 300 volts at 5 amps and 1000 volts at 1.5 amps.
The equation that you are looking for is I = W/E. Amps = Watts/Volts. The generator has the capacity to supply 25 amps. Of course the load is what governs the amount of amperage drawn. Any load greater than 25 amps will load the generator down and probably trip the generator's breaker.
The following formula is used to find amperes when kilowatts are shown. kw x 1000/1.73 x E x pf. The term pf is the power factor value usually using a value of .9. 18000 watts is equal to 18 kWs. 18 x 1000/1.73 x 240 x .9 = 18000/374 = 48 amps.
If you need 50 amps you can use a 60 amp generator or any other generator rated to supply more amps. The voltage, 110 v or 240 v, must be the right voltage for the load used.
Watts = Amps x Volts. Amps = Watts/Volts. 10000/120 = 83.3 amps can be used at 120 volts. On a generator that large it is most likely that it also has the capacity to produce 240 volts. 10000/240 = 41.6 amps can be used at 240 volts. What you can connect to the generator will be totals of the amperage of devices that do not go above these amp ratings.
If your generator is rated at 1000 watts continuous......and you are using 120V.....available amps are 1000/120 =8.3 .
First you need to specify what voltage you require the generator to supply...Lets Assume its 240 Volts AC. Watts=Volts x Amps so 240x1200= 28.8 Kw. Then you have to take the efficiency of the generator into account. Mechanical power in is usually quite a bit more than the electrical power you get out...The difference is mostly the mechanical and thermal losses added together. If we say the generator is 70% efficient then you will need a generator 30% more powerful to supply a constant 1200 Amps...Thats a generator of about 38-40 Kw.
1.5kva has enough electrical power to supply 100 volts of electricity that is at 15 amps. You can also supply 300 volts at 5 amps and 1000 volts at 1.5 amps.
There are zero amps in 18000 kilowatts. A watt is the produce of amps times volts. With out a voltage stated the calculation can not be made. When the voltage is stated, the following equation should be used, I = W/E. Amps = Watts/Volts. Remember 1000 watts is equal to 1 kW.
No. Your power supply must be able to supply rated voltage (12 volts) and rated current (3 amps).
If running at 120 volts that is 8.33 ampsIf running at 120 volts that is 8.33 amps
No
No you cannot.