3D Modeling of the Ball Bearing for the Front Axle Knuckle

International Journal of Computer Trends and Technology (IJCTT)          
© 2018 by IJCTT Journal
Volume-60 Number-1
Year of Publication : 2018
Authors : Rami Matarneh, Svitlana Sotnik, Vyacheslav Lyashenko


Rami Matarneh, Svitlana Sotnik, Vyacheslav Lyashenko "3D Modeling of the Ball Bearing for the Front Axle Knuckle". International Journal of Computer Trends and Technology (IJCTT) V60(1):65-70 June 2018. ISSN:2231-2803. www.ijcttjournal.org. Published by Seventh Sense Research Group.

In this work, the questions of ball bearings operation and their constructive features are considered. A 3D model of a detail is created as a ball bearing for for The Front Axle Knuckle. With Solid CAD, a finite-element analysis of the developed detail type is implemented. In the SolidWorks Simulation module, a ball bearing deformation analysis was carried out as a result of the 2000 N impact force. Based on the constructed model and the results of the analysis it was found that the support meets the requirements of strength in its application.

[1] A. N. Novikov, A. A. Katunin, and M. D. Tebekin, “Problemy ekspluatatsii sharovykh opor legkovykh avtomobiley,” Mir transporta i tekhnologicheskikh mashin, vol. 3, pp. 42, 2010.
[2] J. Mobley, M., Robertson, and C. Hodges, Extended Life Testing of Duplex Ball Bearings, NASA/CP, 2016.
[3] B. Fang, J., Zhang, J., Hong, Y., Zhu, X., Wang, and J. Gao, Investigation of Optimizing Arrangement Forms for Combined Angular Contact Ball Bearings. In ASME 2017 International Mechanical Engineering Congress and Exposition (pp. V002T02A045-V002T02A045), 2017.
[4] A. Parrish (Ed.), Mechanical engineer's reference book. Elsevier, 2014.
[5] X. T. Xia, Z. Chang, Y. F. Li, L. Ye, and B. Liu, Evaluation method for friction torque life and reliability of satellite momentum wheel bearings. In MECHANICS AND MECHANICAL ENGINEERING: Proceedings of the 2015 International Conference (MME2015) (pp. 493-500), 2016.
[6] M. Kutz (Ed.), Mechanical Engineers' Handbook, Volume 1: Materials and Engineering Mechanics. John Wiley & Sons, 2015.
[7] A. A. Katunin, A. N. Novikov, and M. D. Tebekin, “Stendovyye ispytaniya resursa sharovykh opor,” Mir transporta i tekhnologicheskikh mashin, vol. 3, pp. 39-42, 2011.
[8] X. Kang, M. Yang, W. Yang, and Y. Wu, Research on the Form Design of Mini Car in Perceptual Consumption Times. In International Conference of Design, User Experience, and Usability (pp. 258-271). Springer, Cham, 2017.
[9] V. D. Thorat, and S. P. Deshmukh, “Rigid Body Dynamic Simulation of Steering Mechanism,” International Journal of Research in Engineering & Advanced Technology, vol. 3(1), pp. 47-55, 2015.
[10] B. Leistner, R. Mayer, and D. Berkan, Process design for a companywide geometrical integration of manufacturing issues in the early development phases based on the example of automotive suspension. In 8th International Munich Chassis Symposium 2017 (pp. 353-370). Springer Vieweg, Wiesbaden, 2017.
[11] G. Paliwal, N. Sukumar, U. Gupta, A. Dubey, and N. Chopra, Investigation and Optimization of Front Suspension and Steering Geometrical Compatibility (No. 2015-01-0492). SAE Technical Paper, 2015.
[12] S. Raes, T., Devreese, J. De Pauw, and P. De Baets, “Design of a tribological ball joint tester,” SUSTAINABLE CONSTRUCTION AND DESIGN, vol. 6(1), pp. 1-8, 2015.
[13] V. Averchenkov, and Y. U. Kazakov, Avtomatizatsiya proyektirovaniya tekhnologicheskikh protsessov: uchebnoye posobiye. Litres, 2015.
[14] A. Hamrol, S. Zerbst, M. Bozek, M. Grabowska, and M. Weber, Analysis of the Conditions for Effective Use of Numerically Controlled Machine Tools. In Advances in Manufacturing (pp. 3-12). Springer, Cham, 2018.
[15] G. Verma, and M. Weber, SolidWorks Simulation 2017. Black Book, 2016.
[16] S. Maksymova, R. Matarneh, and V. Lyashenko, “Software for Voice Control Robot: Example of Implementation,” Open Access Library Journal, vol. 4(08), pp. 1-12, 2017.
[17] S. Maksymova, R. Matarneh, V. Lyashenko, and N. Belova, “Voice Control for an Industrial Robot as a Combination of Various Robotic Assembly Process Models,” Journal of Computer and Communications, vol. 5(11), pp. 1-15, 2017.
[18] R. Matarneh, S. Maksymova, V. Lyashenko, and N. Belova, “Speech Recognition Systems: A Comparative Review,” IOSR Journal of Computer Engineering (IOSR-JCE), vol. 19(5), pp. 71–79, 2017.
[19] R. Matarneh, S., Maksymova, Zh., Deineko, and V. Lyashenko, “Building Robot Voice Control Training Methodology Using Artificial Neural Net,” International Journal of Civil Engineering and Technology, vol. 8(10), pp. 523–532, 2017.
[20] V. Lyashenko, R. Matarneh, and S. Sotnik, “Defects of Casting Plastic Products: Causes, Recurrence, Synthesis and Ways of Elimination,” International Journal of Modern Engineering Research (IJMER), vol. 8(2), pp. 1–11, 2018.
[21] V. Lyashenko, M. A. Ahmad, O. Kobylin, and A. Khan, “Study of Composite Materials for the Engineering using Wavelet Analysis and Image Processing Technology,” International Journal of Mechanical and Production Engineering Research and Development, vol. 7(6), pp. 445-452, 2017.
[22] S. Sotnik, R. Matarneh, and V. Lyashenko, “System Model Tooling for Injection Molding,” International Journal of Mechanical Engineering and Technology, vol. 8(9), pp. 378–390, 2017.
[23] R. Matarneh, S., Sotnik, Z. Deineko, and V. Lyashenko, “Highlights methodology of time characteristics optimization for plastic products production,” International Journal of Engineering & Technology, vol. 7(1), pp. 165-173, 2018.
[24] R. Matarneh, S., Sotnik, and V. Lyashenko, “Search of the Molding Form Connector Plane on the Approximation Basis by the Many-Sided Surface with Use of the Convex Sets Theory,” International Journal of Mechanical and Production Engineering Research and Development, vol. 8(1), pp. 977-98, 2018.

Modeling, construction, ball support, analysis, deformation