Analysis of BLDC Electric Motor Shaft Treatment Model Using Numerical Method

Authors

  • Endra Dwi Purnomo Research Center for Process and Manufacturing Industry Technology, National Research and Innovation Agency, Indonesia
  • Amiruddin Aziz Research Center for Process and Manufacturing Industry Technology, National Research and Innovation Agency, Indonesia
  • Dewi Rianti Mandasari Research Center for Process and Manufacturing Industry Technology, National Research and Innovation Agency, Indonesia
  • Lia Amelia Research Center for Process and Manufacturing Industry Technology, National Research and Innovation Agency, Indonesia
  • Agus Krisnowo Research Center for Process and Manufacturing Industry Technology, National Research and Innovation Agency, Indonesia
  • Cuk Supriyadi Ali Nandar Research Center for Process and Manufacturing Industry Technology, National Research and Innovation Agency, Indonesia

DOI:

https://doi.org/10.29122/mipi.v16i1.5263

Keywords:

AISI 1045, Cold drawn, Finite Element Method, Shaft, Static Structure, S45C, Tempered

Abstract

This research studies the shaft strength of a BLDC electric motor. A Shaft is one of the components in a rotary engine and functions to transmit power. The design calculation is needed to determine the effect of the strength of the material being treated. The strength analysis of the shaft used FEM (Finite Element Method). The shaft is modeled on the manufacturing design and tested by numerical simulation with Ansys Mechanical 14.5-BRIN commercial license software. The static simulation used a structural statics module with static and dynamic load input. The research method comparing the results of FEM simulations with two different types of materials is determined. Based on the simulation parameters, the selected material types are JIS S45C tempered and AISI 1045 cold-drawn. The simulation results represent the maximum stress (von Mises) and total deformation. The deformation value of S45C tempered material is slightly higher than that of AISI 1045 cold drawn. However, both materials have the same maximum von Mises stress.

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Published

07-09-2023

How to Cite

Purnomo, E. D., Aziz, A., Mandasari, D. R., Amelia, L., Krisnowo, A., & Nandar, C. S. A. (2023). Analysis of BLDC Electric Motor Shaft Treatment Model Using Numerical Method. Majalah Ilmiah Pengkajian Industri; Journal of Industrial Research and Innovation, 16(1), 30–35. https://doi.org/10.29122/mipi.v16i1.5263