Yes it can. It is within the normal voltage / HZ tolerance.
A volt-amp or VA is equivalent to watts, provided the voltage and amperage are in phase. So 1 kilo volt amp is the same as 1 kilowatt. Wattage, or power, is equal to volts times amps. So the original question is effectively nonsense. The number of amps depends on the voltage. If the voltage is 1000 volts, then there's 1 amp in 1 kilo volt amp. If the voltage is 1 volt, then there's 1000 amps. If there's 50 volts, then the amperage is 20 amps. And so on.
A #6 copper conductor will limit the voltage drop to 2% or less when supplying 50 amps for 80 feet on a 240 volt system.
A 12 Volt, 50 AH battery delivers 6,000 Watt-Hours of electricity. Two 12 volt, 50 AH batteries, wired in series provide 24 Volts at 50 AH, which now delivers 12,000 Watt-Hours of electricity. Wiring the two batteries in series changes the voltage, but not the amperage. Wiring the two batteries in parallel changes the Amperage, but not the voltage.
50 kVA is 16.667 kVA per phase and you divide that by the phase voltage. Current = 16667 / 277 = 60 Amps
Yes it can. It is within the normal voltage / HZ tolerance.
The input voltage must match (within a few percent) the rated voltage of the light. If you're using a 12 volt light, a 50 volt supply will destroy it within seconds. "low voltage" is not sufficient information to help you answer your question.
Hong Kong uses the same British Standard BS 1363 (220 Volt, 50 Hertz) electrical system used in the UK.
Put a 50 volt is what inducer operates on. So does a furnaces.
A 500 MCM copper conductor will limit the voltage drop to 3% or less when supplying 50 amps for 800 feet on a 120 volt system. 500 MCM wire diameter is 1/2 inch. As you can see there will be trouble getting that size wire into a 50 amp breakers lug. On installations like this to offset the voltage drop at such a low voltage, a transformer should be used at both ends. The first transformer to raise the voltage and the second transformer to lower it at the 800 foot end. If you use two 480 volt transformers a #1 wire can be used between them. A #1 copper conductor will limit the voltage drop to 3% or less when supplying 50 amps for 800 feet on a 480 volt system. By increasing the voltage you can see that a smaller wire size can be used. On an installation of this nature, a primary line should be brought to the RV site and a service distribution panel established at that point and any RV vehicles can then be fed from that service.
India's standard electrical supply for home outlets is 230 volts at 50 Hz. This is what the country has chosen for their supply. Lots of outer countries use the exact same voltage.
50 percent of 480 is 240.
If you mean 50% of 480 then it is 240
Its a 12 Volt System. The Standard battery is 4Ah
A volt-amp or VA is equivalent to watts, provided the voltage and amperage are in phase. So 1 kilo volt amp is the same as 1 kilowatt. Wattage, or power, is equal to volts times amps. So the original question is effectively nonsense. The number of amps depends on the voltage. If the voltage is 1000 volts, then there's 1 amp in 1 kilo volt amp. If the voltage is 1 volt, then there's 1000 amps. If there's 50 volts, then the amperage is 20 amps. And so on.
The fuse will fail at 50 amps regardless of which voltage you use.
In the electrical trade, there is no such thing as "medium" voltage. Line voltage is broken down into "low" and "high". Low line voltage is 220/110 volt power. In a single phase supply the only required colors are white or grey for the neutral or grounded conductor and green or bare copper for the earth ground, or grounding conductor.In three phase power supplies, low line voltage (220/110) is marked : Phase A -black, Phase B - red, Phase C - blue.In three phase high line voltage (480/277) conductors are marked : A -brown, B - orangeC - yellow. Neutrals are still marked white or grey. White is normally used for low voltage neutrals and grey for high voltage neutrals.In the trade, "low voltage" is considered circuits below 50 volt, such as 12 and 24 volt control circuits, fire alarm, etc.