Working principle of geared reluctance motor technology
The switched resistance motor uses the resistance effect and the control switch to achieve rotation. By continuously changing the current path and the position of the control switch, the asymmetry of the resistance causes the rotor to rotate. This kind of motor has the advantages of simple structure and high power density, and is widely used. The accurate analytical induction model is an effective tool for performance evaluation and preliminary design of STSSRMs with single tooth winding segmental rotor switched reluctance motors. Due to the discontinuous rotor structure and special magnetic circuit, the analytical inductance calculation of the STSSRM is larger. The switched reluctance motor SRM benefits from its magnet-free nature, robust construction, low cost, flexible controls and the ability to operate in harsh environments such as high temperatures and the vibration and noise caused by radial electromagnetic force hinder the development of the switched reluctance motor SRM. In this paper, a structure with auxiliary slots in the stator teeth and rotor teeth of SRM is proposed. The radial force density and average torque are optimized by a multi-objective genetic algorithm, and the optimal switched reluctance motors SRMs are controllable motors widely applied in mining, electric vehicles and aerospace industries. SRMs have simple structure, robustness, fault tolerance, and wide speed range functions. However, a comprehensive mathematical modeling of SRMs was hardly possible. Switched reluctance motor SRM is gaining much interest in industrial applications such as wind power systems and electric vehicles due to its simple and robust construction, high speed capability, high temperature insensitivity, and fault tolerance characteristics. Through continued research, various topologies have emerged. The switched reluctance motor SRM is a simple, cheap and robust machine. However, its disadvantages, namely the requirement for accurate position information, complex control structures and high torque ripple, limited its use only to applications with specific requirements. This article focuses on improving flow. academic and industrial level. The most appreciated features are the absence of rare elements and the low construction price. Controlling the switched reluctance motor is not as simple as other traditional machines. In control it is necessary to reduce the reluctance motor. The switched reluctance motor uses the reluctance effect and the control switch to achieve rotation. By continuously changing the current path and the position of the control switch, the asymmetry of the resistance causes the rotor to rotate. This kind of motor has the advantages of simple structure and high power density, and is widely used. The switched reluctance machine SRM or also SWRM started to receive a lot of attention at the end of the century. Its working principle was already known, but could not find practical use because high-speed electronic switches were not available. Today, the switched reluctance motor is 2. Principle. The conventional SRM follows the principle of minimum reluctance, that is, the flux always flows along the path of minimum reluctance. When the axis of the rotor slot coincides with the centerline of the stator pole, the reluctance is largest and the inductance is smallest, which is asymmetric. Since the advent of power electronics, the switched,