It depends on the power rating of your voltage source. This should be indicated on its nameplate. Divide the power rating (in watts) by the voltage (in volts) to find the rated current available (in amperes).
The actual current drawn from the voltage source is, of course, determined by the load, but this value must not exceed the rated current described in the first paragraph.
Probably ok if the new supply can produce the required amount of current in amps.
Amps (A) measure electrical current flow, while volt-amps (VA) measure apparent power in an electrical circuit, which is the combination of both real power (measured in watts) and reactive power. Essentially, amps refer to current, while volt-amps refer to total power.
Since watts and volt-amps are different units of power, you cannot directly convert watts to volt-amps without considering the power factor of the load. In an ideal resistive circuit, 100 watts would be equivalent to 100 volt-amps. However, in practical applications with reactive components, the relationship between watts and volt-amps can vary.
To calculate the amperage in a circuit with a power of 6kW on a 240-volt supply, you can use the formula: Amperage (A) = Power (W) / Voltage (V). In this case, the amperage would be 25A. This calculation is based on the relationship between power, voltage, and current in an electrical circuit, as defined by Ohm's Law.
To calculate the fuse rating for a 600 watt appliance on a 220 volt supply, you can use the formula: Fuse rating = (Power/Voltage). In this case, it would be 600 watts / 220 volts, which equals approximately 2.73 amps. Therefore, you would need a 3 amp fuse for the 600 watt appliance on a 220 volt supply.
Probably ok if the new supply can produce the required amount of current in amps.
A 24 volt DC power supply provides DC amps, not AC amps. You cannot draw 1.8 amps AC from a DC power supply, without some kind of inverter stage.That is the answer to the specific wording of the question. Now the answer to the question I think was originally intended...If 1.8 amps AC is being supplied to a 24 volt DC power supply, what would the current supplied by the power supply be?Power is volts times amps, so power supplied to the power supply is 120 VAC (assumed) times 1.8 amps, or 216 watts. If the power supply is 100% efficient, then the power input equals the power output, so use the some equation to take 216 watts and divide by 24 volts, and you get 9 amps.Keep in mind, this is ideal state, assuming 100% efficiency, and no real power supply will be that.
62.5 amps
if you connect a 0.5 ohm load to it, the power supply will try to push 4 amps through it. but 4 amps@ 2 volts is quite a lot, and it may not succeed.
Multiply the vots by the amps to find the volt-amps. Or divide the volt-amps by the voltage to find the amps.
Amps (A) measure electrical current flow, while volt-amps (VA) measure apparent power in an electrical circuit, which is the combination of both real power (measured in watts) and reactive power. Essentially, amps refer to current, while volt-amps refer to total power.
No, volt-amps (VA) and watts (W) are not the same. Watts measure real power in an electrical circuit, while volt-amps represent the apparent power, which includes both real power and reactive power.
0.5 amps
The 2wire 2700 and 2701 models both use a 5.1 volt power supply rated 2 or 2.2 amps
Since watts and volt-amps are different units of power, you cannot directly convert watts to volt-amps without considering the power factor of the load. In an ideal resistive circuit, 100 watts would be equivalent to 100 volt-amps. However, in practical applications with reactive components, the relationship between watts and volt-amps can vary.
The cost is about the same using the equation Power= Voltage X Current . However , if the 115 volt electrical circuit is produced from a 230v supply though a transformer , then the transfomer incurs loses and therefore the cost is greater .
Watts measure real power in an electrical circuit, while volt-amps measure apparent power, which includes both real and reactive power. Watts represent actual energy consumed or produced, while volt-amps account for the total power flowing in a circuit.