A synchronous motor is a type of AC (alternating current) electric motor that operates in synchronization with the frequency of the AC power supply. It is designed to maintain a constant speed that corresponds to the frequency of the applied voltage. The synchronous motor's rotor turns at the same rate as the rotating magnetic field produced by the stator, resulting in synchronous rotation. Here's how a synchronous motor operates:
Stator: The stator is the stationary part of the motor and consists of a cylindrical core made of laminated steel sheets. Around the inner circumference of the stator, there are evenly spaced coils of wire. These coils are energized with three-phase AC voltage, creating a rotating magnetic field.
Rotor: The rotor is the rotating part of the motor and is also constructed with laminated steel sheets. The rotor has field windings or permanent magnets embedded in it. The rotor's field windings are connected to a DC power source, producing a magnetic field that interacts with the stator's rotating magnetic field.
Synchronization: When the AC power supply is applied to the stator windings, a rotating magnetic field is generated due to the phase difference between the three-phase voltages. The speed of this rotating magnetic field is determined by the frequency of the AC power supply.
Locking in Phase: In a synchronous motor, the rotor is designed to rotate at the same speed as the rotating magnetic field of the stator. The magnetic field produced by the rotor's field windings or permanent magnets aligns with the stator's rotating magnetic field, causing the rotor to "lock in" and rotate in sync with the stator field.
No Slip: Unlike asynchronous motors (such as induction motors), synchronous motors don't experience slip. Slip is the relative difference in speed between the rotating magnetic field of the stator and the rotor. In synchronous motors, there's no slip because the rotor speed matches the stator's magnetic field speed.
Applications: Synchronous motors are used in applications where precise speed control and synchronization with the power supply frequency are crucial. They are commonly used in industries where constant speed operation is required, such as in electric clocks, timers, precision machinery, and certain types of industrial drives.
Excitation Control: Synchronous motors require a separate DC power source for their rotor's field windings. The strength of this field current determines the motor's torque and power factor. By adjusting the field current, it's possible to control the motor's output characteristics.
Starting: Synchronous motors require some external means to bring them up to synchronous speed initially. This could involve using auxiliary starting motors or methods like "pony motors" to assist the synchronous motor in reaching its synchronous speed before being connected to the main power supply.
Overall, synchronous motors are known for their ability to maintain a precise speed under varying load conditions, making them suitable for applications that demand stable and controlled speed performance.