-600vdc
The voltage applied to the corona wire in a xerographic copier or printer varies depending on the manufacturer and model, however, it is a high voltage. On the other hand, that voltage is applied but is not emitted. It is a static electrical voltage and does not go anywhere (there is no effective current)
The relationship between the voltage applied to a circuit and the velocity of electrons within that circuit is direct. When a higher voltage is applied to a circuit, the electrons within the circuit move faster, resulting in an increase in their velocity.
Voltage in cells and batteries drives the flow of electric current in circuits. A higher voltage means more energy is available to push the electrons through the circuit, increasing the rate of energy transfer. Conversely, a lower voltage will result in slower energy transfer.
Heat dissipation is directly proportional to the square of the applied voltage according to Joule's Law. This means that as the voltage increases, the heat dissipated in a circuit also increases quadratically. The relationship is represented by the formula: Heat dissipation = V^2/R, where V is the voltage and R is the resistance in the circuit.
A current is the flow of electric charge, which requires a potential difference (voltage) to drive it. In the case of a light bulb, the voltage from a source (such as a battery or outlet) is needed to create the electric field that allows the electrons to flow through the filament of the bulb, generating light and heat in the process. Without this applied voltage, there is no driving force to push the electrons through the circuit, so no current flows.
The voltage applied to the corona wire in a xerographic copier or printer varies depending on the manufacturer and model, however, it is a high voltage. On the other hand, that voltage is applied but is not emitted. It is a static electrical voltage and does not go anywhere (there is no effective current)
Any voltage that is fed into or "applied" to an electrical circuit is referred to as an "applied voltage".
The voltage is greater than the applied voltage, why?
No current flows when the applied voltage is zero.
For a series circuit, the applied voltage equals the sum of the voltage drops
Current is directly proportional to applied voltage. Ohm's law.
sending voltage means voltage applied to source side.....
The applied voltage is 53+28 = 81V.
When an alternating voltage is applied to a purely resistive circuit, the resulting current is in phase with the voltage.
A: As soon as a DC voltage is applied the capacitor is a short or no voltage
The reason an AC voltage applied across a load resistance produces alternating current is because when you have AC voltage you have to have AC current. If DC voltage is applied, DC current is produced.
A high dc voltage would be applied to test the insulation between the windings.