Still 30 amps, but at 240 V you'll have twice the watts that you would on a 120 V, 30 amp circuit, and after all, watts are what actually does the work.
If a 240V circuit has 30 amps per phase, the total amperage would be 30 amps. Since the current is measured per phase in a three-phase circuit, you would have 30 amps on each phase, totaling 30 amps.
To calculate the amperage, you can use the formula: Amperage (A) = Power (W) / Voltage (V). Assuming a standard 240V supply for a range, the amperage drawn by a 12.9 kW range would be approximately 54 Amps.
To calculate the amperage for 2kW, you need to know the voltage of the circuit. For example, if the voltage is 120V, then the amperage would be 16.67A (2000W / 120V = 16.67A). If the voltage is 240V, then the amperage would be 8.33A (2000W / 240V = 8.33A).
To calculate the amperage, use the formula: Amps = Watts / Volts. For a 3000-watt load on a 220-volt AC single-phase circuit, the amperage would be approximately 13.6 amps.
For a 4800W oven, you can calculate the amperage by dividing the wattage by the voltage. Assuming a standard voltage of 240V for residential ovens, the amperage would then be 4800W / 240V = 20A. Therefore, you would need a 20A circuit breaker for the oven.
The amperage in the circuit can be calculated using Ohm's Law: Amperage = Voltage / Resistance. Plugging in the values, we get Amperage = 110V / 7ohms = 15.71A. Therefore, the circuit would have approximately 15.71 amps of current flowing through it.
To calculate the amperage, you can use the formula: Amperage (A) = Power (W) / Voltage (V). Assuming a standard 240V supply for a range, the amperage drawn by a 12.9 kW range would be approximately 54 Amps.
Typically single phase motors go up to 10hp. Wouldn't be very efficient at about 100 amps. A 20hp 3 phase motor at 230v pulls 52 amps. The 10hp single phase 230v pulls 50 amps.
Amperage or Amps is a measure of is the flow rate of electrical current that is available.
60 amps
The amperage in the circuit can be calculated using Ohm's Law: Amperage = Voltage / Resistance. Plugging in the values, we get Amperage = 110V / 7ohms = 15.71A. Therefore, the circuit would have approximately 15.71 amps of current flowing through it.
To answer this question a voltage needs to be stated and whether the load is three phase or single phase. Without the voltage the amperage can not be calculated. For single phase, Amps = kva x 1000/voltage, for three phase, Amps = kva x 1000/1.73 x voltage.
Answer for USA, Canada and countries running a 60 Hz supply service.No. Even though 240 volts uses two breakers it is still classed as a single phase service. Kirchhoff's law states that current entering a circuit is equal to current leaving the circuit. Since the appliance draws 10 amps, the whole circuit has 10 amps flowing through it.
Volt amps is the same way of saying watts. This is seen in the formula Watts = Volts x Amps. Using the formula I = W/E we transpose I = 20000/240 = 83.33 amps.
Clamp the meter around the energized conductor that is connected to the load to be measured and read the amperage off of the dial face of the meter.
To calculate the amperage draw, you need to know the voltage of the circuit where the 2500 watts appliance will be used. You can use the formula: Amps = Watts / Volts. For example, if it is a 120V circuit, the amperage draw would be 2500 watts / 120 volts = 20.83 amps.
Answer: To determine the amperage in a circuit. Notes: Power (in watts) = Volts * Amps 16.4 KVA = 480V * Amps 16400 / 480 = Amps ~34.2 = Amps
A 30 amp circuit can handle a maximum of 30 amps of current flow continuously without tripping the circuit breaker. It is important not to exceed this amperage to prevent overheating and potential fire hazards.