In induction motors and synchronous generators, there are various types of rotor windings used to produce the necessary magnetic fields for their operation. The main types of rotor windings in these electrical machines are as follows:
Induction Motor Rotor Windings:
a. Squirrel Cage Rotor: This is the most common type of rotor winding in induction motors. It consists of a cylindrical laminated core with conductor bars (usually made of copper or aluminum) placed parallel to the rotor shaft and short-circuited at both ends by conducting end rings. The shape of the rotor bars resembles a squirrel cage, hence the name. Squirrel cage rotors are simple, robust, and require minimal maintenance, making them widely used in various industrial applications.
b. Wound Rotor (Slip Ring) Rotor: In contrast to the squirrel cage rotor, a wound rotor has insulated rotor coils with multiple taps brought out to slip rings. These slip rings allow external resistors to be connected, enabling control of the rotor resistance. This type of rotor provides better starting torque and speed control, making it suitable for certain applications where adjustable speed is required.
Synchronous Generator Rotor Windings:
a. Salient Pole Rotor: In synchronous generators, the rotor can have salient poles, which means the pole faces project outward from the rotor core. These poles are electromagnetically excited by DC current to create the magnetic field necessary for synchronization with the rotating stator field. Salient pole rotors are typically used in low-speed generators and hydroelectric applications.
b. Cylindrical Rotor: Also known as a non-salient pole rotor, this type of rotor has a smooth, cylindrical shape without projecting poles. The field winding is distributed uniformly around the rotor's circumference and is excited with DC current to establish the magnetic field. Cylindrical rotor generators are more common in high-speed and turbo-generators.
c. Permanent Magnet Rotor: Some modern synchronous generators use permanent magnets embedded in the rotor to create the magnetic field. These generators are known as permanent magnet synchronous generators (PMSGs). PMSGs offer advantages such as higher efficiency and reduced maintenance requirements, making them suitable for certain renewable energy applications.
Each of these rotor winding types has specific advantages and disadvantages, and their selection depends on the intended application, operating conditions, and performance requirements of the electrical machine.