For a resistive load it is 120 Watts.
The power (in watts) can be calculated by multiplying the current (in amps) by the voltage (in volts). In this case, 10 amps at 12 volts would result in 120 watts of power (10A * 12V = 120W).
A 10 amp switch connected to a 240 volt circuit can carry up to 2400 watts (10 amps x 240 volts = 2400 watts). It's important to ensure that the switch is rated for the anticipated load to prevent overheating or failure.
The TDA85600 is a class-D amplifier chip that can deliver up to 50 watts per channel into a 4-ohm load or 30 watts per channel into an 8-ohm load.
A transformer does not use, it transforms voltage from one value to another. The output amperage is governed by the connected load. If the load wattage is higher than the wattage rating of the transformer then either the primary or secondary fuse will blow or the transformer will burn up if the fusing is of the wrong sizing. The maximum primary amperage can be found by using the following equation, Amps = Watts/Volts, A = W/E = 600/120 = 5 amps. The same equation is used for the calculating the maximum secondary amperage, A = W/E = 600/12 = 50 amps.
20 Amp * 120 Volts = 2400 Watts 2400 Watt * 80% max use = 1920 Watts planned normal usage for a circuit with a 20 Amp breaker.
There is no direct conversion between RPM (revolutions per minute) and watts as they are measurements of different quantities. RPM measures rotational speed, while watts measure power. The power output in watts of a rotating object would depend on factors such as its torque and the load it is driving.
There is zero watts in 10 amps.
A 10 amp switch connected to a 240 volt circuit can carry up to 2400 watts (10 amps x 240 volts = 2400 watts). It's important to ensure that the switch is rated for the anticipated load to prevent overheating or failure.
1 watt will do the job.
250 watts divided by 12 volts = amps or around 20 amps
Depends on the voltage. Volts x Amps = Watts
Varies from product to product, but a standard 12ch dimmer pack will supply a 10amp load per channel.
The TDA85600 is a class-D amplifier chip that can deliver up to 50 watts per channel into a 4-ohm load or 30 watts per channel into an 8-ohm load.
To calculate the number of watts when given volts, you also need to know the current (in amps) flowing through the circuit. The formula for power (in watts) is P = V x I, where P is power in watts, V is voltage in volts, and I is current in amps. Without knowing the current, we cannot determine the number of watts from just volts.
To calculate the current in milliamps, use the formula: current (in milliamps) = power (in watts) / voltage (in volts). In this case, 1.5 watts / 12 volts = 0.125 amps. To convert this to milliamps, multiply by 1000: 0.125 A * 1000 = 125 mA. Therefore, 1.5 watts at 12 volts is equivalent to 125 milliamps.
Assuming 120 VAC in a residence maximum watts = 15 x 120 = 1800 Watts. For a continuous load you can support 1440 watts which is 80& of maximum. You need 14 AWG gauge wire.
A transformer does not use, it transforms voltage from one value to another. The output amperage is governed by the connected load. If the load wattage is higher than the wattage rating of the transformer then either the primary or secondary fuse will blow or the transformer will burn up if the fusing is of the wrong sizing. The maximum primary amperage can be found by using the following equation, Amps = Watts/Volts, A = W/E = 600/120 = 5 amps. The same equation is used for the calculating the maximum secondary amperage, A = W/E = 600/12 = 50 amps.
20 Amp * 120 Volts = 2400 Watts 2400 Watt * 80% max use = 1920 Watts planned normal usage for a circuit with a 20 Amp breaker.