The question is not relevant.
240 volts refers to the "potential", and amps refers to the current.
Potential * current = watts, or energy.
You can have 240 volts at 1 amp, which will result in 240 watts, or you can have 240 amps at 1 volt which would also result in 240 watts.
Wiki User
∙ 12y agoWiki User
∙ 15y agoBefore I can answer your question let me ask you this. What is the power rating of the furnace if there is any?
Wiki User
∙ 13y agoAbout 10-20 thousand depending on the house and the type of electrical device.
To calculate the output amps of a 600kVA generator at 240V, you would use the formula Amps = kVA / Volts. In this case, it would be 600kVA / 240V = 2500 amps.
The amperage of an electric heater depends on its power rating in watts and the voltage it operates on. To determine the amperage, divide the wattage by the voltage (Amperes = Watts / Volts). For example, a 1500 watt electric heater running on 120 volts would use 12.5 amperes (1500 watts / 120 volts = 12.5 A).
Electric water heaters typically use between 15 to 20 amps of electrical current. The exact amperage can vary depending on the size and model of the water heater.
The basic formula for the Voltage, Current, Power relationship is P=I*E. To find one when the other two are known, simply fill in the two you know and solve. In this case P=1000W and Voltage = 240V (It is important that you pay attention to the unit definer here, if it were 240 mV, you would have Voltage = .240V and so on). 1000W = I * 240V I = 1000W/240V I = 4.17A
In a 240V system, 1 kW is equal to approximately 4.17 amps. This calculation is done by dividing the power in watts (1000 watts for 1 kW) by the voltage (240V) in the system.
To calculate the output amps of a 600kVA generator at 240V, you would use the formula Amps = kVA / Volts. In this case, it would be 600kVA / 240V = 2500 amps.
The formula you are looking for is I = E/R. Amps = Volts/Resistance.
The amperage of an electric heater depends on its power rating in watts and the voltage it operates on. To determine the amperage, divide the wattage by the voltage (Amperes = Watts / Volts). For example, a 1500 watt electric heater running on 120 volts would use 12.5 amperes (1500 watts / 120 volts = 12.5 A).
Current (Amps) = Power (Watt)/Voltage (V) Therefore a 4500W heating element will draw 18.75A = 4500W/240V
Electric water heaters typically use between 15 to 20 amps of electrical current. The exact amperage can vary depending on the size and model of the water heater.
The basic formula for the Voltage, Current, Power relationship is P=I*E. To find one when the other two are known, simply fill in the two you know and solve. In this case P=1000W and Voltage = 240V (It is important that you pay attention to the unit definer here, if it were 240 mV, you would have Voltage = .240V and so on). 1000W = I * 240V I = 1000W/240V I = 4.17A
In a 240V system, 1 kW is equal to approximately 4.17 amps. This calculation is done by dividing the power in watts (1000 watts for 1 kW) by the voltage (240V) in the system.
The heater should have a wattage rating (very few list amps). Calculate the amps using the wattage and voltage. Amps = Watts/Volts(480).
240v is equal to how many amps
Volts times amps equals watts, so the question is - what times 480 makes 10,000, and the answer is 10,000 divided by 480. That is 10,000 divided by 500 and then increased by 4% which is 20.8 amps.
A 1500-watt electric fireplace would draw 12.5 amps of current, as calculated using the formula P (power in watts) = I (current in amps) x V (voltage). Assuming the standard voltage in the US is 120 volts, the calculation would be 1500 watts = I amps x 120 volts; therefore, I = 12.5 amps.
A block heater typically draws around 6 to 10 amps of current. It may vary depending on the wattage of the heater and the voltage of the electrical system it is connected to.