To supply 100 amps from 1.5 volts, you would need to use a very low resistance load. Using Ohm's Law (V = I*R), you can calculate that in order to achieve 100 amps with 1.5 volts, the load resistance would need to be approximately 0.015 ohms. Such low resistance loads can be challenging to find and may not be practical for most applications.
The terminal strip's rating is 15 amps at 600 volts. It does not matter what the voltage is up to 600 volts, the maximum amperage allowed on the strip is 15 amps. It could be 15 amps at 12 volts or 15 amps at 600 volts or any voltage in between.
To convert watts to amps, you can use the formula: Amps = Watts / Volts. Assuming a standard voltage of 120V, 1500 watts would be equivalent to 12.5 amps (1500 watts / 120 volts = 12.5 amps).
The capacity of a 1.5kVA inverter is 1.5 kilovolt-amperes, which is equivalent to 1500 volt-amperes. When connected to a 24-volt battery, this setup can provide approximately 62.5 amps of power (1500 VA / 24 V = 62.5 A) for a certain duration depending on the battery capacity and load demand.
To find the amperage, you can use the formula: Amps = Watts/Volts. Plugging in the values, you get Amps = 1800 Watts / 110 Volts ≈ 16.36 Amps.
To convert 15 amps at 415 volts to kilowatts, use the formula: kW = (amps x volts) / 1000. So, kW = (15 A x 415 V) / 1000 = 6.225 kW.
a 1.5 kVa source of electrical power has the capacity to supply 100 volts at 15 amps, 300 volts at 5 amps, or 1000 volts at 1.5 amps.
The terminal strip's rating is 15 amps at 600 volts. It does not matter what the voltage is up to 600 volts, the maximum amperage allowed on the strip is 15 amps. It could be 15 amps at 12 volts or 15 amps at 600 volts or any voltage in between.
To convert watts to amps, you can use the formula: Amps = Watts / Volts. Assuming a standard voltage of 120V, 1500 watts would be equivalent to 12.5 amps (1500 watts / 120 volts = 12.5 amps).
The capacity of a 1.5kVA inverter is 1.5 kilovolt-amperes, which is equivalent to 1500 volt-amperes. When connected to a 24-volt battery, this setup can provide approximately 62.5 amps of power (1500 VA / 24 V = 62.5 A) for a certain duration depending on the battery capacity and load demand.
To find the amperage, you can use the formula: Amps = Watts/Volts. Plugging in the values, you get Amps = 1800 Watts / 110 Volts ≈ 16.36 Amps.
15 amps
To convert 15 amps at 415 volts to kilowatts, use the formula: kW = (amps x volts) / 1000. So, kW = (15 A x 415 V) / 1000 = 6.225 kW.
15 amps at 80% = 12 amps continuous. Watts = Amps x Volts.
A # 14 copper conductor will be fine to carry 8 amps at 120 volts. This size conductor is rated at 15 amps.
volts X amps = watts standard 120 X 15 amps =1800watts microwaves generally use about 1000 watts which is 8.33 amps...
Divide the total circuit wattage (15 amps x 120 volts = 1800 watts) by the individual lamp wattage (100 watts). This gives you 18 lamps that can be used on the circuit. However, it's recommended to leave some capacity for safety, so a practical limit might be around 15 lamps to be safe.
Volts times amps equals watts, so watts divided by volts equals amps, so 15 amps