آمار

تعداد نشریات7
تعداد شماره‌ها405
تعداد مقالات5,425
تعداد مشاهده مقاله5,546,212
تعداد دریافت فایل اصل مقاله5,028,275
Fartashvand, Vahid, Kami, Abdolvahed, Bagheri, Abbasali. (1402). Enhancing Mechanical Properties of Ultrasonically-Treated 3D-Printed AcrylonitrileButadiene-Styrene and Polylactic Acid Parts: A Full Factoria. نشریه مهندسی عمران امیرکبیر, 7(3), 283-296. doi: 10.22060/ajme.2024.22545.6067
Vahid Fartashvand; Abdolvahed Kami; Abbasali Bagheri. "Enhancing Mechanical Properties of Ultrasonically-Treated 3D-Printed AcrylonitrileButadiene-Styrene and Polylactic Acid Parts: A Full Factoria". نشریه مهندسی عمران امیرکبیر, 7, 3, 1402, 283-296. doi: 10.22060/ajme.2024.22545.6067
Fartashvand, Vahid, Kami, Abdolvahed, Bagheri, Abbasali. (1402). 'Enhancing Mechanical Properties of Ultrasonically-Treated 3D-Printed AcrylonitrileButadiene-Styrene and Polylactic Acid Parts: A Full Factoria', نشریه مهندسی عمران امیرکبیر, 7(3), pp. 283-296. doi: 10.22060/ajme.2024.22545.6067
Fartashvand, Vahid, Kami, Abdolvahed, Bagheri, Abbasali. Enhancing Mechanical Properties of Ultrasonically-Treated 3D-Printed AcrylonitrileButadiene-Styrene and Polylactic Acid Parts: A Full Factoria. نشریه مهندسی عمران امیرکبیر, 1402; 7(3): 283-296. doi: 10.22060/ajme.2024.22545.6067

Enhancing Mechanical Properties of Ultrasonically-Treated 3D-Printed AcrylonitrileButadiene-Styrene and Polylactic Acid Parts: A Full Factoria

AUT Journal of Mechanical Engineering
دوره 7، شماره 3، 2023، صفحه 283-296    اصل مقاله (2.26 M)
نوع مقاله: Research Article
شناسه دیجیتال (DOI): 10.22060/ajme.2024.22545.6067
نویسندگان
Vahid Fartashvand1؛ Abdolvahed Kami* 2؛ Abbasali Bagheri2
1Department of Industrial Design, Faculty of Art, Alzahra University, Tehran, Iran
2Faculty of Mechanical Engineering, Semnan University, Semnan, Iran
چکیده
This study explores the enhancement of mechanical properties in 3D-printed polylactic acid and acrylonitrile-butadiene-styrene parts through ultrasonic treatment. Tensile samples were fabricated using fused filament fabrication with varying infill percentages (60% and 100%) and layer thicknesses (0.15 mm and 0.30 mm). Post-processing involved a high-power ultrasonic treatment for 2 seconds, followed by tensile testing. The results demonstrated an average 10% increase in tensile strength for both acrylonitrile-butadiene-styrene and polylactic acid after ultrasonic treatment, with the highest tensile strengths measured at approximately 41 MPa and 38 MPa, respectively. However, strain at fracture experienced a decline, except in the samples with an infill percentage of 100 and a number of layers of 10. Scanning electron microscopy revealed dimensional changes and raster merging, more pronounced in 60% and 100% infill samples, respectively. The study employed a comprehensive full factorial design of experiments and finite element simulation for ultrasonic treatment setup design. The interaction of 3D printing and ultrasonic treatment parameters was investigated, with the infill percentage exhibiting the most substantial impact on the ultimate tensile strength. The results highlight 
the potential of ultrasonic treatment to enhance mechanical properties, reduce defects, and improve the structural integrity of 3D-printed components.
کلیدواژه‌ها
3D-printing؛ Additive manufacturing؛ Ultrasonic Treatment؛ ABS؛ PLA
مراجع
  1. Fico, D. Rizzo, R. Casciaro, C. Esposito Corcione, A Review of Polymer-Based Materials for Fused Filament Fabrication (FFF): Focus on Sustainability and Recycled Materials, Polymers, 14(3) (2022) 465.
  2. Singh, G. Singh, C. Prakash, S. Ramakrishna, Current status and future directions of fused filament fabrication, Journal of Manufacturing Processes, 55 (2020) 288-306.
  3. Safari Mazaheri, V. Abedini, A. Kami, Effects of raster angle and composition of layers on tensile and flexural properties of PLA-PLA/Al multimaterial manufactured by fused deposition modeling, J Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, (2023) 09544089231175202.
  4. R.C. Dizon, A.H. Espera, Q. Chen, R.C. Advincula, Mechanical characterization of 3D-printed polymers, Additive Manufacturing, 20 (2018) 44-67.
  5. Safari, A. Kami, V. Abedini, 3D printing of Continuous Fiber Reinforced Composites: A Review of the Processing, Pre- and Post-Processing Effects on Mechanical Properties, Polym. Polym. Compos., 30 (2022) 1-26.
  6. Li, J. Zhao, J. Jiang, H. Jiang, W. Wu, M. Tang, Ultrasonic strengthening improves tensile mechanical performance of fused deposition modeling 3D printing, The International Journal of Advanced Manufacturing Technology, 96(5) (2018) 2747-2755.
  7. Wu, J. Li, J. Jiang, Q. Liu, A. Zheng, Z. Zhang, J. Zhao, L. Ren, G. Li, Influence Mechanism of Ultrasonic Vibration Substrate on Strengthening the Mechanical Properties of Fused Deposition Modeling, Polymers, 14(5) (2022) 904.
  8. Guivier, J. Kuebler, T. Swanson, C. Lawson, L. Fernandez-Ballester, M. Negahban, M.P. Sealy, Mechanical Behavior of ABS after Interlayer Ultrasonic Peening Printed by Fused Filament Fabrication, in: 2021 International Solid Freeform Fabrication Symposium, University of Texas at Austin, 2021.
  9. Tofangchi, P. Han, J. Izquierdo, A. Iyengar, K. Hsu, Effect of Ultrasonic Vibration on Interlayer Adhesion in Fused Filament Fabrication 3D Printed ABS, Polymers, 11(2) (2019) 315-315.
  10. Li, J. Zhao, W. Wu, J. Jiang, B. Wang, H. Jiang, J.Y.H. Fuh, Effect of Ultrasonic Vibration on Mechanical Properties of 3D Printing Non-Crystalline and SemiCrystalline Polymers, Materials, 11(5) (2018) 826-826.
  11. Maidin, M. Muhamad, E. Pei, Experimental setup for ultrasonic-assisted desktop fused deposition modeling system, Applied Mechanics and Materials, 761 (2015) 324-328.
  12. M.M. Billah, J.L. Coronel, L. Chavez, Y. Lin, D. Espalin, Additive manufacturing of multimaterial and multifunctional structures via ultrasonic embedding of continuous carbon fiber, Composites Part C: Open Access, 5 (2021) 100149.
  13. Qiao, Y. Li, L. Li, Ultrasound-assisted 3D printing of continuous fiber-reinforced thermoplastic (FRTP) composites, Additive Manufacturing, 30 (2019) 100926.
  14. Bagheri, M.S. Aghareb Parast, A. Kami, M. Azadi, V. Asghari, Fatigue testing on rotary friction-welded joints between solid ABS and 3D-printed PLA and ABS, European Journal of Mechanics - A/Solids, 96 (2022) 104713.
  15. C. Paganin, G.F. Barbosa, A comparative experimental study of additive manufacturing feasibility faced to injection molding process for polymeric parts, The International Journal of Advanced Manufacturing Technology, 109(9) (2020) 2663-2677.
  16. Guangzhou Yousu Plastic Technology Co., in, 2023.
  17. . Yang, L. Yang, Digest Ultrasonic Welding I: Localized Heating and Fuse Bonding, arXiv preprint, (2023).
  18. Zhang, X. Wang, Y. Luo, Z. Zhang, L.J.J.o.T.C.M. Wang, Study on heating process of ultrasonic welding for thermoplastics, 23(5) (2010) 647-664.
  19. C. Sanchez, C.A.G. Beatrice, C. Lotti, J. Marini, S.H.P. Bettini, L.C.J.T.I.J.o.A.M.T. Costa, Rheological approach for an additive manufacturing printer based on material extrusion, 105 (2019) 2403-2414.
  20. a. Alafaghani, A. Qattawi, B. Alrawi, A. Guzman, Experimental Optimization of Fused Deposition Modelling Processing Parameters: A Design-forManufacturing Approach, Procedia Manufacturing, 10 (2017) 791-803.
  21. Syrlybayev, B. Zharylkassyn, A. Seisekulova, M. Akhmetov, A. Perveen, D. Talamona, Optimisation of Strength Properties of FDM Printed Parts—A Critical Review, Polymers, 13(10) (2021) 1587.
  22. Rodríguez-Panes, J. Claver, A.M. Camacho, The Influence of Manufacturing Parameters on the Mechanical Behaviour of PLA and ABS Pieces Manufactured by FDM: A Comparative Analysis, Materials, 11(8) (2018) 1333.
  23. S.A. Parast, A. Bagheri, A. Kami, M. Azadi, V. Asghari, Bending fatigue behavior of fused filament fabrication 3D-printed ABS and PLA joints with rotary friction welding, Progress in Additive Manufacturing, 7 (2022) 1345–1361.
آمار
تعداد مشاهده مقاله: 232
تعداد دریافت فایل اصل مقاله: 236


سامانه مدیریت نشریات علمی. طراحی و پیاده سازی از سیناوب