Efficient three-phase asynchronous motors

The three-phase asynchronous motor, a common form of electric motor, mainly consists of two main parts: the stator (fixed part) and the rotor (rotating part). The stator is fitted with a three-phase winding which, when connected to a three-phase mains supply, generates a rotating magnetic field. The rotor is usually designed as a squirrel cage rotor, in which conductive rods lie in grooves in the iron core and are connected at both ends by rings. This design enables currents to be induced in the rotor by the stator’s magnetic field, which sets the rotor in motion. The speed of the rotor depends on the frequency of the three-phase mains and the number of pole pairs in the motor. The motor housing protects the internal components and serves to dissipate heat. The robust and simple design of the three-phase asynchronous motor makes it ideal for many industrial applications.

The efficiency classes IE1, IE2 and IE3 for asynchronous motors, defined in accordance with the EC Machinery Directive IEC 60034-30-1, indicate the energy efficiency of the motors. IE1, also known as standard efficiency, is suitable for intermittent operation or as a brake motor, but is no longer approved for continuous operation according to the current standard. IE2 stands for motors with higher efficiency, which have been specially developed for continuous operation on frequency converters. IE3 motors offer even greater efficiency and are ideal for direct operation on the mains. Despite the different efficiency levels, our motors in all classes retain the same dimensions in accordance with IEC 60034-30-1, which enables simple integration and interchangeability.

The main difference between a squirrel cage rotor and a slip ring rotor in asynchronous motors lies in their design and mode of operation. A squirrel cage rotor, also known as a squirrel cage rotor, has a rotor consisting of conductive bars that are short-circuited at both ends by rings. This simple and robust design is low-maintenance and cost-effective. Squirrel cage motors are ideal for applications where constant torque and high reliability are required. Slip ring motors, on the other hand, have a winding in the rotor that is guided to the outside via slip rings and brushes. This enables starting current limitation and better control of the starting behavior. Slip ring motors are suitable for applications that require high starting torque and variable speed control, but require more maintenance due to the slip rings and brushes.

The use of a frequency inverter with asynchronous motors offers several advantages, particularly in terms of control and efficiency. Frequency converters enable precise control of motor speed and torque, resulting in improved power regulation and process control. They allow motor power to be adjusted according to actual operating conditions, saving energy and reducing operating costs. In addition, frequency inverters help to reduce mechanical wear on the motor by ensuring smooth starting and stopping. This extends the service life of the motor and reduces maintenance costs. Frequency inverters also help to reduce peak electrical loads on the grid and improve the overall energy efficiency of the motor system.