When a switch in an RL (Resistor-Inductor) circuit is suddenly closed, the circuit experiences a transient response as the current begins to flow through the inductor. Let's break down what happens step by step:
Initial state: Before the switch is closed, the circuit is assumed to have been disconnected or open for a significant amount of time. During this time, the inductor might have discharged completely (in case it was energized before and then disconnected) or remained uncharged (if the inductor was not previously energized).
Sudden closure of the switch: As soon as the switch is closed, it provides a direct path for the current to flow through the circuit. The inductor, initially acting like a short circuit (since the current couldn't flow through it before the switch was closed), now begins to resist the change in current.
Inductor behavior: The inductor opposes the change in current flowing through it, generating a back EMF (electromotive force) due to the magnetic field it creates. This back EMF is in the direction opposite to the applied voltage from the source. As a result, the rate of increase in current is slowed down, and the current starts to rise gradually.
Transient response: During the initial period, the current in the circuit will increase from zero to its steady-state value (if it was previously energized and then disconnected) or start to ramp up towards its steady-state value (if it was uncharged). The transient response continues until the current reaches its steady-state value.
Steady-state: Once the transient response settles, the current will reach a constant value determined by the resistance and inductance of the circuit. In a DC circuit, if there is no other source of energy or resistance, the current will stabilize at its maximum value, limited only by the resistance.
It's important to note that during the transient period, the current is changing, and voltages and currents might not follow the simple Ohm's Law relationships. Instead, differential equations need to be solved to precisely determine the current at any given time during the transient response.
The behavior of an RL circuit when the switch is suddenly closed is essential in understanding how inductive loads behave in various electrical systems and why proper protective measures, such as flyback diodes, might be necessary to avoid voltage spikes and protect electronic components.