Numerical Modal Analysis of a Multi-Material 3D-Printed Composite Bushing and Its Application
Authors: Paweł Żur, Alicja Żur, Andrzej Baier
Abstract:
Modal analysis is a crucial tool in the field of engineering for understanding the dynamic behavior of structures. In this study, numerical modal analysis was conducted on a multi-material 3D-printed composite bushing, which comprised a polylactic acid (PLA) outer shell and a thermoplastic polyurethane (TPU) flexible filling. The objective was to investigate the modal characteristics of the bushing and assess its potential for practical applications. The analysis involved the development of a finite element model of the bushing, which was subsequently subjected to modal analysis techniques. Natural frequencies, mode shapes, and damping ratios were determined to identify the dominant vibration modes and their corresponding responses. The numerical modal analysis provided valuable insights into the dynamic behavior of the bushing, enabling a comprehensive understanding of its structural integrity and performance. Furthermore, the study expanded its scope by investigating the entire shaft mounting of a small electric car, incorporating the 3D-printed composite bushing. The shaft mounting system was subjected to numerical modal analysis to evaluate its dynamic characteristics and potential vibrational issues. The results of the modal analysis highlighted the effectiveness of the 3D-printed composite bushing in minimizing vibrations and optimizing the performance of the shaft mounting system. The findings contribute to the broader field of composite material applications in automotive engineering and provide valuable insights for the design and optimization of similar components.
Keywords: 3D printing, composite bushing, modal analysis, multi-material.
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[1] El Ouatouati, A., & Johnson, D. A. (1999). A new approach for numerical modal analysis using the element‐free method. International Journal for Numerical Methods in Engineering, 46(1), 1-27.
[2] Żur, A., Żur, P., Michalski, P., & Baier, A. (2022). Preliminary study on mechanical aspects of 3D-printed PLA-TPU composites. Materials, 15(7), 2364.
[3] Oktav, A. (2016). Experimental and numerical modal analysis of a passenger vehicle. International Journal of Vehicle Noise and Vibration, 12(4), 302-313.
[4] Kwon, Y. W., & Plessas, S. D. (2014). Numerical modal analysis of composite structures coupled with water. Composite Structures, 116, 325-335.
[5] Kawrza, M., Furtmüller, T., & Adam, C. (2022). Experimental and numerical modal analysis of a cross laminated timber floor system in different construction states. Construction and Building Materials, 344, 128032.
[6] Kalsoom, U., Nesterenko, P. N., & Paull, B. (2016). Recent developments in 3D printable composite materials. RSC advances, 6(65), 60355-60371.
[7] Blanco, I. (2020). The use of composite materials in 3D printing. Journal of Composites Science, 4(2), 42.
[8] Wang, X., Jiang, M., Zhou, Z., Gou, J., & Hui, D. (2017). 3D printing of polymer matrix composites: A review and prospective. Composites Part B: Engineering, 110, 442-458.
[9] Bedri, R., & Al-Nais, M. O. (2005). Prestressed modal analysis using finite element package ANSYS. In Numerical Analysis and Its Applications: Third International Conference, NAA 2004, Rousse, Bulgaria, June 29-July 3, 2004, Revised Selected Papers 3 (pp. 171-178). Springer Berlin Heidelberg.
[10] Lengvarský, P., Bocko, J., & Hagara, M. (2013). Modal analysis of titan cantilever beam using ANSYS and SolidWorks. American Journal of Mechanical Engineering, 1(7), 271-275.
[11] Khadse, N. A., & Zaweri, S. R. (2015). Modal analysis of aircraft wing using Ansys workbench software package. International Journal of Engineering Research & Technology (IJERT), ISSN, 2278-0181.
[12] Żur, P., Kołodziej, A., Baier, A., & Kokot, G. (2020). Optimization of Abs 3D-printing method and parameters. European Journal of Engineering Science and Technology, 3(1), 44-51.
[13] Żur, P., Kołodziej, A., & Baier, A. (2019). Finite elements analysis of pla 3d-printed elements and shape optimization. European Journal of Engineering Science and Technology, 2(1), 59-64.
[14] Baier, A., Grabowski, Ł., Stebel, Ł., Komander, M., Konopka, P., Kołodziej, A., & Żur, P. (2018). Numeric analysis of airflow around the body of the Silesian Greenpower vehicle. In MATEC Web of Conferences (Vol. 178, p. 05014). EDP Sciences.
[15] Żur, P., Baier, A., & Kołodziej, A. (2020). Chassis Geometry Optimization based on 3D-scans of the Ergonomic Driving Position. International Journal of Mechanical Engineering and Robotics Research, 9(8), 1213-1218.
[16] Nadeem, S. S., Giridhara, G., & Rangavittal, H. K. (2018). A Review on the design and analysis of composite drive shaft. Materials Today: Proceedings, 5(1), 2738-2741.
[17] Feldman, M. (2011). Hilbert transform in vibration analysis. Mechanical systems and signal processing, 25(3), 735-802.
[18] Olson, B. J., Shaw, S. W., Shi, C., Pierre, C., & Parker, R. G. (2014). Circulant matrices and their application to vibration analysis. Applied Mechanics Reviews, 66(4), 040803.
[19] Neild, S. A., McFadden, P. D., & Williams, M. S. (2003). A review of time-frequency methods for structural vibration analysis. Engineering Structures, 25(6), 713-728.
[20] Steinberg, D. S. (2000). Vibration analysis for electronic equipment.
[21] Petyt, M. (2010). Introduction to finite element vibration analysis. Cambridge university press.