Synchronous motors are designed to operate in synchronism with the AC power supply, meaning their rotor speed remains constant and synchronized with the frequency of the power supply. This is achieved through their construction and the interaction between the stator (stationary part) and rotor (rotating part) of the motor. Here's how synchronous motors maintain synchronism:
Pole Configuration: Synchronous motors are built with a specific number of poles in their stator and rotor. The number of poles determines the motor's synchronous speed, which is given by the formula:
Synchronous Speed (in RPM) = (120 * Frequency) / Number of Poles
This means that for a given AC power supply frequency, the synchronous speed is fixed based on the number of poles.
AC Power Supply Frequency: The frequency of the AC power supply is constant in most cases. This frequency determines the speed at which the magnetic field in the stator rotates.
Stator Magnetic Field: The stator of a synchronous motor generates a rotating magnetic field due to the AC power supply. This rotating field interacts with the rotor, which contains a set of permanent magnets or field windings.
Rotor Construction: The rotor of a synchronous motor is designed to be magnetically locked in step with the rotating stator field. It has a specific number of poles that correspond to the stator poles, ensuring that the two fields maintain synchronization.
DC Excitation: In many synchronous motors, the rotor is equipped with field windings. These windings are supplied with direct current (DC), creating a magnetic field in the rotor. The polarity and strength of this field can be controlled to adjust the motor's power factor and efficiency.
Field Current Control: By controlling the current supplied to the rotor's field windings, the strength of the rotor's magnetic field can be adjusted. This allows for control of the motor's power factor and torque output while maintaining synchronism.
Load Changes: Synchronous motors can handle varying loads without significant changes in speed. When the load on the motor changes, the field current can be adjusted to keep the motor in synchronism and maintain the desired speed.
Governors and Control Systems: In some applications, synchronous motors are equipped with governors or advanced control systems that monitor the motor's speed and adjust the field current to maintain synchronization under changing conditions.
By combining these factors, synchronous motors maintain synchronism with the AC power supply. This makes them suitable for applications that require precise speed control, constant speed operation, and power factor correction, such as industrial drives, generators, and large-scale machinery.