Voltage determines a cable's insulation thickness, not its conductor thickness (or, more accurately, its cross-sectional area). It's current that determines the csa of a conductor, not voltage.
The motor would draw about 24 kVA which is 35 amps. For this you would need 10 mm2 cable.
240V. 415 / 1.73 = 240
That would depend on the power output (watts) of the circuit. Volts times the Amperage equals the Wattage of the circuit. You do not have enough information in your question. Volts is the force applied to move the electrons in the circuit, and amps are a measure of the quantity of electrons moved through the circuit over time. Thus a circuit of 415 volts and 1 ampere will deliver 415 watt-hours of power. Yet a circuit of 1 volt at 415 amps will deliver the same 415 watt-hours of power, but with less force.
The voltage drop should not exceed 3% on a feeder or branch circuit.
This is why electricians will always have work. Go to discuss question page.
The motor would draw about 24 kVA which is 35 amps. For this you would need 10 mm2 cable.
The motor would draw about 24 kVA which is 35 amps. For this you would need 10 mm2 cable.
240V. 415 / 1.73 = 240
i try ......gen set 120 KVA and output 415 Volt 1 KVA = 0.8KW so 120 x 0.8 = 96 kW A = w/v ~ A = 96000/415 = 231.3 Amp I' it right ? If wrong give correction
That would depend on the power output (watts) of the circuit. Volts times the Amperage equals the Wattage of the circuit. You do not have enough information in your question. Volts is the force applied to move the electrons in the circuit, and amps are a measure of the quantity of electrons moved through the circuit over time. Thus a circuit of 415 volts and 1 ampere will deliver 415 watt-hours of power. Yet a circuit of 1 volt at 415 amps will deliver the same 415 watt-hours of power, but with less force.
100 KW divided by 415 volts is 241 amperes. Power = voltage times current, so current = power divided by voltage.
If they are in different rooms or side by side in the same room, and not connected together mechanically, there should not be a problem.
The voltage drop should not exceed 3% on a feeder or branch circuit.
Until the requirement for the UK to conform to EU standards, the standard low-voltage three-phase nominal line voltage was 415 V (+/- 6%). After the adoption of this EU requirement, the nominal line voltage became 400 V (+10%/-6%).
10%off 415 = 415 - (0.10 x 415) = 373.5
The instruction for changing the taps on a transformer can be found on the transformers nameplate. These taps will be on the primary side of the transformer. Each tap position will state what the voltage will be on the output when the individual tap is selected.
This is why electricians will always have work. Go to discuss question page.