-- 80% of 100 kilowatts = 80 kilowatts
-- Ignoring the power factor, 80 kilowatts is supplied from a 220-volt source
when the current is 3637/11Amperes. (rounded)
Generators are sized by the electrical load that is to be applied to it. If you want to pick up the total house load then a 25 to 30 kW generator will do the job. At 240 volts this will give you just over 100 amps to work with. Amps = Watts/Volts.
To find the amperage of a generator, you can use the formula: Amps = Watts / Volts. Assuming a standard voltage of 120V for household generators, you can calculate the amperage as: 8500 Watts / 120 Volts = 70.83 Amps.
The size of a generator is based on what the connected load will be. Add up all of the connected wattages that will be connected to the generator at one time and add ten percent, this will be the size of the generator you will need. Some equipment does not show the wattage on its nameplate. To find the wattage use the following formula Watts = Amps x Volts.
75 Amps theoretically Need to know if the generator is 3 phase or single phase.
A 7500 watt generator can provide up to about 62.5 amps at 120 volts or about 31.25 amps at 240 volts. While it can handle some of the load for a 60 amp service, it is not sufficient to fully power it, especially under heavy load conditions. It's important to consider the start-up currents of appliances, which can exceed their running wattage, and ensure that the generator can safely manage these loads without overloading. In general, a larger generator would be required to reliably support a full 60 amp service.
Generators are sized by the electrical load that is to be applied to it. If you want to pick up the total house load then a 25 to 30 kW generator will do the job. At 240 volts this will give you just over 100 amps to work with. Amps = Watts/Volts.
To find the amperage of a generator, you can use the formula: Amps = Watts / Volts. Assuming a standard voltage of 120V for household generators, you can calculate the amperage as: 8500 Watts / 120 Volts = 70.83 Amps.
After given 50% load that time engine was start to hunting
The size of a generator is based on what the connected load will be. Add up all of the connected wattages that will be connected to the generator at one time and add ten percent, this will be the size of the generator you will need. Some equipment does not show the wattage on its nameplate. To find the wattage use the following formula Watts = Amps x Volts.
75 Amps theoretically Need to know if the generator is 3 phase or single phase.
If your generator is rated at 1000 watts continuous......and you are using 120V.....available amps are 1000/120 =8.3 .
The load conductor is connected to the load side of the generator breaker. Once the generator is up to speed the load breaker is closed and the voltage is then applied to the load.
the voltage regulation (as a percent) = |V(no-load) -V(rated)|/|V(rated)| * 100 so if V(rated) = 24 V voltage regulation =10% then V(no-load) = 26.4 V
Load rejection occurs when load is suddenly removed from the generator. The most obvious example of this is the breaker connecting the generator to the power grid opens. This results in a full load rejection. Load pick up means the generator is supplying power to a given load. When a generator comes on line, it will pick up some load that might have been supplied by another generator.
A generator, rated at 16 MW, should be able to continuously supply a load of 16 MW. You don't need to compute its 'minimum load', because the minimum load will be zero watts! In other words, you can run the generator with no load whatsoever if you wish to waste fuel.The point is that the power supplied by a generator is determined by the load, NOT by the generator itself -so it is important that the generator is capable of supplying the maximum load applied to it. A generator's 'rated power output' simply tells us the maximum load it is capable of supplying.
your generator may be putting out too much voltage. that is it should be 115-125 volts check it with a voltmetet when running under load. also if a surge of load occurs, the breakers may not be overloaded in normal running conditions, but if a motor starts, it's starting load may be more than the breaker can hold. you may have to size the breaker for the starting motor load, not the running load also, if your generator is running on low voltage, that will increase the amperage on the served appliances. the breaker will then trip
yes.it is possible to start dc series generator on no load condition