25KVA
Yes. 240 volts at 10 amps is 2400 watts. The generator is 2500 watts maximum. If the generator is 2500 peak power it may not run it very long. If the continuous power rating is at least 2400 watts it should be OK.
It could be as much as 63 kW (63,000 Watts) into a load with a power factor of 1.0. For other loads, multiply the kVA by the power factor.
The amount of power a standby generator should put out to maintain the avg. US household for a one day is 20 watts system. This a standard amount watts to power you home and today they more selection in watts to power the house more than one day.
You can use a power bar that needs 1500 watts or less.
25KVA
6.3 liters/hour at full load
not you kan not start 22kw motor with 25kva generator (οχι)
Yes. 240 volts at 10 amps is 2400 watts. The generator is 2500 watts maximum. If the generator is 2500 peak power it may not run it very long. If the continuous power rating is at least 2400 watts it should be OK.
If the 1600 represents 1600 watts like most generator numbers do, then the generator can deliver enough power to run a 1600 watt load connected to it.
it depends on the power production capabilities of the generator, and the power usage of the electronic applications...this power is measured in Watts, usually just W, and all the parts should have the relative information on how much Watts they use/produce
5000 Watts if it runs ideally. It really depends on the generator's efficiency. Lets say, if its working on 80% efficiency, it'll provide with 0.8 * 5000 watts of electric power.
It could be as much as 63 kW (63,000 Watts) into a load with a power factor of 1.0. For other loads, multiply the kVA by the power factor.
No it what work 756 watts = 1 HP. You would need a generator that can supply 756 x 25 = 18900 watts.
1 hp = 746 watts 2.5 x 746 = 1825 watts or 1.825Kw The Generator is large enough.
A person may consider using a Honda Generator EU2000i to power electrical objects such as a cooker, TV or radio. This generator has 200 watts of power.
Make two lists. List the appliances you want the generator to run when commercial power is available. Next, list the appliances you want the generator to run when commercial power is NOT available. Determine the wattage of each appliance and then add them together for the first list. Repeat this for the second list. This will give you total wattage for each list. This will help you determine the size of the generator needed to power your devices when commercial power is available and for when commercial power is not available.Understanding the wattage values of each appliance is important for correctly choosing the wattage values to add together to get the total estimated wattage needed to power your appliances.If all of your loads are resistive, such as incandescent lamps and heaters, you simply add up their wattage to get a total. However if you have electric motors which will cycle on and off or appliances like a heat pump or an air conditioner, you must take into consideration the required starting current of these devices. The start up current of these devices can be up to 6 times the running current.Starting Watts are the power the generator can produce for short periods of time.Running Watts are the power the generator can produce continuously.Here is an example of how to determine generator size:Question: I am considering the purchase of a standby portable generator to power key appliances in the event of a power loss which sometimes occur during winter snow storms. Do I just add up the total number of watts required by the appliances I want to run? In the event of a winter storm interruption of electricity, I am looking to keep the refrigerator/freezer running, along with the blower motor of a pellet stove, a few electric lights, and a radio. All else can wait until power is restored!Answer: The total estimated wattage of 1840 watts is needed for the radio (15 watts), the motor (575 watts), and the refrigerator/freezer (1250 watts). To this I added 500 watts for five 100 watt light bulbs for a total of 2340 running watts. Next I added the starting watts of the motor to the running watt total of 2340 watts, to get the total estimated wattage of the generator needed to power all these appliances simultaneously. For example, assuming the starting watts needed for the blower motor are 3 times its running watts (3 times 575 watts = 1725 watts), so the total estimated wattage of the generator needed to power all these appliances simultaneously is 2340 running watts plus the 1725 starting watts of the blower motor, for a total of 4065 watts. The generator needed to run all these appliances simultaneously would need to have a maximum power output of at least 4065 watts.Note: The maximum power output is also called short time watts, peak watts, maximum watts, surge watts, and starting watts. It's helpful to keep this in mind when reading portable generator wattage ratings.