A wound rotor motor, also known as a slip ring motor, is a type of electric motor that has a unique design and characteristics that make it suitable for certain applications. It is commonly used in scenarios where the motor needs to have adjustable speed control, high starting torque, and the ability to withstand variable or heavy loads. Wound rotor motors are often used in industrial settings like cranes, hoists, conveyor systems, and traction applications.
The key feature of a wound rotor motor is its rotor, which has windings or coils that are connected to slip rings. The stator, similar to other types of electric motors, contains the stationary windings that create a rotating magnetic field when powered with electricity. The rotor windings are connected to the slip rings, which are rings that rotate along with the rotor shaft but are electrically insulated from it.
Here's how a wound rotor motor works:
Starting Phase: When the motor is initially powered on, both the stator windings and the rotor windings are energized. The stator windings create a rotating magnetic field, which induces a current in the rotor windings. This current produces its own magnetic field, and due to the interaction between the stator and rotor magnetic fields, the rotor begins to turn.
Adjustable Resistance: Unlike a standard induction motor, a wound rotor motor allows for additional control by introducing resistance in the rotor circuit. This can be done by connecting external resistors to the slip rings. By varying the resistance, the amount of current flowing through the rotor windings can be controlled, which in turn affects the torque and speed characteristics of the motor. This feature is particularly useful for applications where controlled acceleration and deceleration are required.
Slip Rings and Brushes: The slip rings on the rotor are connected to brushes that maintain electrical contact as the rotor turns. These brushes allow for the transfer of electrical power and control signals to and from the rotor windings, enabling the control of rotor circuit parameters.
Speed Control: By adjusting the resistance in the rotor circuit, the speed-torque curve of the motor can be modified. Lowering the resistance increases the current in the rotor windings, producing more torque at lower speeds. Conversely, increasing the resistance reduces the current and results in lower torque but higher speeds. This ability to control the rotor circuit resistance provides the wound rotor motor with a wide range of speed and torque capabilities.
Transition to Normal Operation: As the wound rotor motor reaches its desired speed, the external resistors can be gradually short-circuited, essentially bypassing the added resistance. This transition to normal operation allows the motor to run efficiently with reduced losses.
In summary, a wound rotor motor offers advantages in terms of speed control, high starting torque, and the ability to handle varying loads. Its unique design with slip rings and rotor windings connected to external resistors allows for a wide range of applications that require adjustable motor characteristics.