A synchronous motor is a type of electric motor that operates in synchronization with the frequency of the alternating current (AC) power supply. It is widely used in various industrial applications, such as driving large machinery, pumps, compressors, and generators. The primary characteristic that sets synchronous motors apart from asynchronous (induction) motors is their ability to maintain a constant speed under varying loads.
Here's how a synchronous motor operates:
Stator: Like other AC motors, a synchronous motor consists of a stator and a rotor. The stator contains the stationary winding, which is connected to the AC power supply. When the AC voltage is applied to the stator winding, it creates a rotating magnetic field that sweeps around the inside of the motor.
Rotor: The rotor of a synchronous motor features field windings, which are electromagnets. These field windings are supplied with direct current (DC) to create a magnetic field. This field must align itself with the rotating magnetic field produced by the stator.
Synchronization: In order for the synchronous motor to operate properly, the rotor's magnetic field must lock in step with the rotating magnetic field of the stator. This alignment of the fields is known as synchronization or the "synchronous speed." The synchronous speed is determined by the frequency of the AC power supply and the number of poles in the motor.
Start-up: Unlike induction motors that can start on their own, synchronous motors cannot self-start. Initially, the rotor is at a standstill. External means, such as another motor or a prime mover, are required to bring the rotor close to synchronous speed. This is often done using auxiliary devices like pony motors or wound-rotor motors.
Maintaining Synchronization: Once the synchronous motor is brought close to synchronous speed, the AC power supply is applied to the stator windings. The rotating magnetic field produced by the stator drags the rotor's magnetic field along, causing the rotor to turn and maintain synchronization. As long as the rotor remains synchronized, the motor will run at a constant speed regardless of the load.
Load Changes: The synchronous motor is capable of handling varying loads while maintaining a constant speed. However, if the load increases beyond a certain point, the motor can lose synchronization, resulting in a sudden drop in speed. To prevent this, the motor is equipped with a device called a "synchronizing relay" that monitors the synchronization status and can initiate corrective measures to bring the motor back into sync.
Applications: Synchronous motors are often used in applications where maintaining a precise speed is crucial, such as in power plants for driving generators, in industrial processes that require accurate control, and in large HVAC systems.
In summary, a synchronous motor operates by synchronizing its rotor's magnetic field with the rotating magnetic field produced by the stator, allowing it to maintain a constant speed regardless of load variations.