Effect of Gear Transmission System to Vibration Test Machine
Abstract
This research aims to investigate the vibration analysis for equipment test of chassis. The frame model of the gear transmission vibration test is developed. The prototype of the vibration and noise testing tool was constructed for the gear transmission system. The vibration equipment test consists of three gears that function as a gear transmission. The chassis is considered to be one of the vital elements of equipment. The rotation of gears and shafts can occur the vibration. The simulation with the 3D model using ANSYS was resulted in structure analysis. The simulation was resulted in total deformation, equivalent strain, and equivalent stress where the structure of the equipment was definitely safe and had good stability.
##Keywords:##
Vibration, Gear transmission, Deformation, Chassis.
Published
Jul 30, 2023
How to Cite
JUNAIDI, Abdul Khair et al.
Effect of Gear Transmission System to Vibration Test Machine.
Journal of Ocean, Mechanical and Aerospace -science and engineering-, [S.l.], v. 67, n. 2, p. 63-66, july 2023.
ISSN 2527-6085.
Available at: <https://isomase.org/Journals/index.php/jomase/article/view/347>. Date accessed: 19 aug. 2024.
doi: http://dx.doi.org/10.36842/jomase.v67i2.347.
References
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[2] Kang, Z.H.W.Q.H. & Peng, Q.M.L. (2013). Status and problem research on gear study. Journal of mechanical Engineering, 49(19), 19.
[3] Badri, M. & Junianto, F. (2018). Vibration measurement method using 3 accelerometer cmcp770a on beam cylinder with fix-fix support and double selenoid. Journal of Ocean, Mechanical and Aerospace -Science and Engineering-, 56(1), 5-10.
[4] Lee, A.S. & Ha, J.W. (2005). Prediction of maximum unbalance responses of a gear-coupled two-shaft rotor-bearing system. Journal of Sound and Vibration, 283(3-5), 507-523.
[5] Liu, D., Zhang, H., Tao, Z. & Su, Y. (2011). Finite element analysis of high-speed motorized spindle based on ANSYS. The Open Mechanical Engineering Journal, 5(1).
[6] Mei, Y., Wang, F.P., Liu, Q.Y. & Mao, Y.T. (2011). Finite element analysis on thermal structures of heavy machinery gearbox. Advanced Materials Research, 228, 651-655.
[7] Nawir, R., Dwianda, Y., Febrianton, A. & Irwan, P. (2022). The effect of misalignment to vibration, electric current and shaft rotation speed on gear transmission. Journal of Ocean, Mechanical and Aerospace -Science and Engineering-, 66(1), 14-19. doi:10.36842/jomase.v66i1.278.
[8] Kumar, S., Lokesha, M., Kumar, K. & Srinivas, K.R. (2018). Vibration based fault diagnosis techniques for rotating mechanical components. In IOP Conference Series: Materials Science and Engineering, IOP Publishing, 376(1), 012109.
[9] Ranjan, R., Ghosh, S.K. & Kumar, M. (2020). Fault diagnosis of journal bearing in a hydropower plant using wear debris, vibration and temperature analysis: A case study. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, 234(3), 235-242.
[10] Glowacz, A. (2021). Ventilation diagnosis of angle grinder using thermal imaging. Sensors, 21(8), 2853.
[11] Glowacz, A., Tadeusiewicz, R., Legutko, S., Caesarendra, W., Irfan, M., Liu, H. & Xiang, J. (2021). Fault diagnosis of angle grinders and electric impact drills using acoustic signals. Applied Acoustics, 179, 108070.
[12] Zoungrana, W.B., Chehri, A. & Zimmermann, A. (2021). Automatic classification of rotating machinery defects using machine learning (ml) algorithms. In Human Centre Intelligent Systems: Proceedings of KES-HCIS 2020 Conference, Springer Singapore, 193-203.
[13] Elango, S., Aravind, J.G. & Boopathi, S. (2018). Vibration analysis of bearing by using mechanical stethoscope. International Journal of Advanced Science and Research, 3(1), 1137-1149.
[14] Kim, Y.H., Tan, A.C.C. & Kosse, V. (2008). Condition monitoring of low-speed bearings - a review. Australian Journal of Mechanical Engineering, 6(1), 61-68.
