Inductive Load Current Lags Voltage at Charlotte Farmer blog

Inductive Load Current Lags Voltage. As the current in the circuit is flowing in opposite direction, the back emf of inductor will start building up in opposite to the direction of flow of current and hence net back. The applied voltage reaches its maximum positive value a quarter ( 1/4ƒ ) of a cycle earlier than the current reaches its maximum positive value, in other words, a voltage applied. This results in a voltage wave that is 90° out of phase with the current wave. If you apply a ramping waveform of current to the coil it produces a ramping magnetic flux and across the terminals of the inductor the voltage will be constant. So if we know the value. Looking at the graph, the voltage wave seems to have a “head start” on the current wave; Therefore, the current lags the applied voltage by 90° in a purely inductive circuit. Since the current always lags the voltage by 90 o in a purely inductive circuit, we can find the phase of the current by knowing the phase of the voltage or vice versa.

The applied voltage reaches its maximum positive value a quarter ( 1/4ƒ ) of a cycle earlier than the current reaches its maximum positive value, in other words, a voltage applied. So if we know the value. This results in a voltage wave that is 90° out of phase with the current wave. Therefore, the current lags the applied voltage by 90° in a purely inductive circuit. Since the current always lags the voltage by 90 o in a purely inductive circuit, we can find the phase of the current by knowing the phase of the voltage or vice versa. Looking at the graph, the voltage wave seems to have a “head start” on the current wave; If you apply a ramping waveform of current to the coil it produces a ramping magnetic flux and across the terminals of the inductor the voltage will be constant. As the current in the circuit is flowing in opposite direction, the back emf of inductor will start building up in opposite to the direction of flow of current and hence net back.

For a purely inductive ac circuit show that the current lags the

Inductive Load Current Lags Voltage As the current in the circuit is flowing in opposite direction, the back emf of inductor will start building up in opposite to the direction of flow of current and hence net back. Looking at the graph, the voltage wave seems to have a “head start” on the current wave; Since the current always lags the voltage by 90 o in a purely inductive circuit, we can find the phase of the current by knowing the phase of the voltage or vice versa. So if we know the value. As the current in the circuit is flowing in opposite direction, the back emf of inductor will start building up in opposite to the direction of flow of current and hence net back. If you apply a ramping waveform of current to the coil it produces a ramping magnetic flux and across the terminals of the inductor the voltage will be constant. This results in a voltage wave that is 90° out of phase with the current wave. The applied voltage reaches its maximum positive value a quarter ( 1/4ƒ ) of a cycle earlier than the current reaches its maximum positive value, in other words, a voltage applied. Therefore, the current lags the applied voltage by 90° in a purely inductive circuit.