Modeling and Simulation of a Magnetic Levitation Virtual Module for Undergraduate Rotodynamic Teaching
Authors: 
Juan C. Vives Garnique, Carlos A. Alvarado Silva, Orlando D. Bonilla Bravo, Hans M. PerezAuthors Info & Claims
Pages 19 - 26
Abstract
In this research, a programming of a graphical user interface (GUI) was developed in the MATLAB environment to be used as a virtual teaching technological tool to design a rotor test bench with magnetic bearings. The programming of this virtual tool was based on the parametric design grounded on mathematical models of electromagnetism and resistance of materials, so that step by step, the user recognizes the influence of the information as it is added and determines through comparative curves the most appropriate data, improving learning in the subject through the analysis of results. This module allows to manipulate the input variables and geometric variables to calculate the data of the current in pole, load exerted by the pole, current flow; sizing of the elements of the test bench, in addition to calculating the electromagnetic forces necessary to levitate the axis of the steering wheel. Finally, the sizing of the shaft and active magnetic bearing are selected based on the available values provided by the manufacturer.
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Published In
January 2021
410 pages
ISBN:9781450388542
DOI:10.1145/3450148
Copyright © 2021 ACM.
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Association for Computing Machinery
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Published: 13 June 2021
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IC4E 2021
IC4E 2021: 2021 12th International Conference on E-Education, E-Business, E-Management, and E-Learning
January 10 - 13, 2021
Tokyo, Japan
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