Abstract
This paper focuses on the matter of cogging torque reduction by combining various methods of cogging torque minimization. Due to the high costs of prototype construction, cogging torque is minimized during the design phase by using numerical methods, while computer simulations are used to find a magnetic circuit arrangement for which the cogging torque has the smallest possible value. Cogging torque occurs as a result of combined impact of the magnetic field of a permanent magnet located at rotor and stator with variable magnetic conductivity depending on an angle of rotation. It is a pulsating torque and occurs permanently during machine operation, impacting the operation of the entire device cooperating with the electric machine and causing vibrations, tension, and noise. It results in braking torque and subsequent power losses and leads to faster wear and tear of machine structural elements. High cogging torque values cause problems with rotational speed adjustment. In the case of electric generators used in wind power plants, it impedes the start-up of power plants at high wind speeds. Considering the above, the reduction of cogging torque in permanent-magnet machines is extremely important.
Highlights
Innovative electric machines are characterized by such parameters as high efficiency, high energy density, high reliability and compact size
Permanent-magnet electric machines have multiple pros and two cons: they are more expensive than asynchronous machines, and are characterized by cogging torque that occurs as a result of the combined impact of the magnetic field of permanent magnets and a stator with variable magnetic conductivity
We focus on cogging torque reduction
Summary
Innovative electric machines are characterized by such parameters as high efficiency, high energy density, high reliability and compact size All these parameters can be achieved thanks to simultaneously occurring progress in the area of machine design and to rapid development in related areas of science, namely power electronics, materials engineering, and microprocessor techniques [1,2]. Reaching high efficiency in electric machines is possible thanks to the application of advanced computer techniques during the design process [3,4,5]. Energies 2020, 13, 6108 higher than by using traditional ferrite magnets and AlNiCo [1] Combining these elements results in the production of innovative energy-saving motors, widely used in industry, and permanent-magnet electric generators used in renewable energy generation systems [6]. As a result of these adverse phenomena, minimization of the cogging torque is still an unsolved problem in permanent-magnet machines, and finding the most efficient minimization methods is of high importance [9,10,11,12,13,14,15]
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