ANALYZING EFFICIENT WORKSPACES AND DESIGNING PID CONTROLLERS FOR MAGNETIC LEVITATION SYSTEMS
Abstract
In this paper, a fundamental model of a magnetic levitation system is analyzed and investigated. The research involves determining magnetic forces through calculations and simulating the system using ANSYS software to identify the efficient operational domain. Mathematical equations are formulated, and a PID controller is designed. The PID controller utilizes the pole placement method in conjunction with Matlab tools to optimize its coefficients. Employing this comprehensive combination of computational analysis and simulation tools enhances the efficiency, performance, and stability of the magnetic levitation system.
References
ROGG, D., General survey of the possible applications and development tendencies of magnetic levitation technology. IEEE Transactions on Magnetics, 1984, 20.5, pp. 1696-1701.
MOON, Francis C., Superconducting levitation: Applications to bearings and magnetic transportation. John Wiley & Sons, 2008.
SARABI, Misagh Rezapour; YETISEN, Ali K.; TASOGLU, Savas, Magnetic levitation for space exploration. Trends in Biotechnology, 2022.
DABBAGH, Sajjad Rahmani, et al., Biomedical applications of magnetic levitation. Advanced NanoBiomed Research, 2022, 2.3, 2100103.
ASHKARRAN, Ali Akbar; MAHMOUDI, Morteza, Magnetic levitation systems for disease diagnostics. Trends in Biotechnology, 2021, 39.3, pp. 311-321.
BLEULER, Hannes, et al. Magnetic bearings: theory, design, and application to rotating machinery. Springer Science & Business Media, 2009.
POST, Richard F.; RYUTOV, Dmitri D., The inductrack: A simpler approach to magnetic levitation. IEEE Transactions on applied superconductivity, 2000, 10.1, pp. 901-904.
CHO, Han-Wook, et al., Analysis on the Levitation Force Characteristics of Longitudinal Flux Type Levitation Magnet using Equivalent Magnetic Circuit Model. The Transactions of The Korean Institute of Electrical Engineers, 2011, 60.12, pp. 2236-2245.
SASE, Masanori; TORII, Susumu, Magnetic levitation control with real-time vibration analysis using finite element method. International Journal of Applied Electromagnetics and Mechanics, 2002, 13.1-4, pp.129-136.
HASIRCI, Ugur, et al., 3-D FEM analysis of a novel magnetic levitation system. IEEE Transactions on plasma science, 2015, 43.5, pp. 1261-1265.
BISWAS, Pabitra Kumar, et al., ANSYS based fem analysis for three and four coil active magnetic bearing-a comparative study. International Journal of Applied Science and Engineering, 2013, 11.3, pp. 277-292.
BISWAS, Pabitra Kumar, et al., Design and ANSYS Software Based Simulation of UI Type Actuator and Rail Used in Electromagnetic Levitation System. International Journal of Applied Science and Engineering, 2014, 12.3, pp. 225-239.
KUMAR, Parichit, et al., Development of a magnetic levitation system for additive manufacturing: Simulation analyses. IEEE Transactions on Magnetics, 2020, 56.8, pp. 1-7.
JUMAAT, Siti Amely; AHAMAD, Muhammad Nassie, Analysis of Eddy Current Density using ANSYS MAXWELL Software. Journal of Electronic Voltage and Application, 2020, 1.2, pp. 37-45.
