In an induction motor, the direction of rotation is determined by the direction of the rotating magnetic field produced by the stator's three-phase AC currents. Reversing the direction of rotation in an induction motor involves changing the phase sequence of the AC power supply that is connected to the motor's terminals.
When the phase sequence of the AC power supply is changed, the sequence of the magnetic fields produced by the stator windings also changes. This alteration in the magnetic field's sequence leads to a reversal in the direction of the rotating magnetic field, which in turn causes the rotor to rotate in the opposite direction.
To reverse the direction of rotation in a three-phase induction motor, you typically need to swap any two of the three input phases in the power supply. This effectively changes the sequence in which the currents flow through the stator windings and produces a reverse rotation of the magnetic field. As a result, the rotor also experiences a change in the direction of rotation.
It's worth noting that reversing the direction of rotation in an induction motor is generally a straightforward process when dealing with three-phase power supplies. However, for single-phase induction motors, reversing the direction can be a bit more complex due to their inherent design limitations.