Modeling, Simulation, and Parameter Design of Actuation Mechanisms Based on New Magnetic Control Materials

• Published in: 2024 IEEE 25th China Conference on System Simulation Technology and its Application (CCSSTA) pp. 203 - 207
• Main Authors: Shen, Ruixuan, Tian, He, Zhao, Guanqiao, Zhu, Ziliang, Li, Jiangping, Liang, Chao
• Format: Conference Proceeding
• Language: English
• Published: IEEE 21.07.2024
• Subjects: actuation mechanism; Circuit breakers; Genetic algorithms; Integrated circuit modeling; Magnetic circuits; Mathematical models; new magnetic control materials; Optimization; parameter design; Power system dynamics; Software; Systems simulation; vacuum circuit breaker; Vacuum systems
• DOI: 10.1109/CCSSTA62096.2024.10691872

With the rapid advancement of technology, the reliability and efficiency of power systems have become increasingly critical. In power systems, pole-mounted circuit breakers play a vital role. This paper presents a design scheme for an actuation mechanism of a pole-mounted circuit breaker based on new magnetic control materials. By analyzing the working principle of this actuation mechanism, a mathematical model was constructed, and a corresponding virtual prototype model was established using multi-body dynamics simulation software ADAMS and the dynamics mathematical model of this type of actuation mechanism. Key performance parameters of the circuit breaker were optimized using a quantum genetic algorithm. Simulation experiments verified that the proposed parameter settings achieved a closing time of 7.6 ms, demonstrating significant improvements in circuit breaker performance. The results of this study are of great importance for the optimization design and performance enhancement of circuit breakers in power systems.