Authors : Pratik Balkrishna Patil; N. D. Patil; P. P. Awate

Volume/Issue : Volume 9 - 2024, Issue 9 - September

Google Scholar : https://tinyurl.com/nf8rrt5h

Scribd : https://tinyurl.com/bdfre3f7

DOI : https://doi.org/10.38124/ijisrt/IJISRT24SEP1078

Note : A published paper may take 4-5 working days from the publication date to appear in PlumX Metrics, Semantic Scholar, and ResearchGate.

Abstract : An introduction to fused deposition modeling, or 3D printing technology, will be given in this chapter. The basic idea of additive manufacturing and its underlying scientific theory will be presented at the outset of this chapter as a novel and emerging industrial technology. The parameters used to predict the melt deposition of polymers and their basic interactions with the structural component qualities will also be covered in this chapter. The chapter will provide a brief description of the quality features of FDM products concerning the process parameters. The additive manufacturing process will involve layering material to produce three-dimensional (3D) parts using a class of manufacturing technologies known as additive manufacturing (AM). This substance will include composite, metal, polymer, or concrete materials. A manufacturing process will need to have the following three main elements to be designated as an AM technique: making visual 3D models with computers and computer-aided design (CAD), utilizing a variety of CAD tools such as AutoCAD, SolidWorks, CATIA, and others. Some of these programs will be either closed- source or open-source. For additive manufacturing to be successful, an engineer or artist working with several computers will need to be proficient in using multiple operating systems. With these CAD tools and user experiences, it will be possible to produce a variety of complex 3D product models. The amount of material a 3D printer will take and the time it will require will be important factors influencing the additive manufacturing process.

Keywords : Leaf Spring, Composite Material, Automobile Suspension System, Finite Element Analysis.

References :

1. S. Junk, C. Kuen, Review of open source and freeware CAD systems for use with 3D-printing. Proc. CIRP 50, 430–435 (2016)
2. Y. Song, Z. Yang, Y. Liu, J. Deng, Function representation-based slicer for 3D printing. Comput. Aided Geom. Des. 62, 276–293 (2018)
3. Huang, S.B. Singamneni, Curved layer adaptive slicing (CLAS) for fused deposition modeling. Rapid Prototype. J. 21(4), 354–367 (2015)
4. Lele, Additive manufacturing (AM), in Smart Innovation, Systems and Technologies, vol. 132 (Springer, Berlin, 2019), pp. 101–109
5. A.M. Forster, Materials testing standards for additive manufacturing of polymer materials: State of the art and standards applicability, in Additive Manufacturing Materials: Standards, Testing and Applicability, pp. 67–123 (2015)
6. W.S.W. Harun et al., A review of powdered additive manufacturing techniques for Ti-6al-4v biomedical applications. Powder Technol. 331, 74–97 (2018)
7. K.S. Prakash, T. Nancharaih, V.V.S. Rao, Additive manufacturing techniques in manufacturing—An overview. Mater. Today Proc. 5(2), 3873–3882 (2018)
8. M.A. Cuiffo, J. Snyder, A.M. Elliott, N. Romero, S. Kannan, G.P. Halada, Impact of the fused deposition (FDM) printing process on polylactic acid (PLA) chemistry and structure. Appl. Sci. 7(6), 1–14 (2017)
9. W.C. Lee, C.C. Wei, S.C. Chung, Development of a hybrid rapid prototyping system using low-cost fused deposition modeling and five-axis machining. J. Mater. Process. Technol. 214(11), 2366–2374 (2014)
10. A.D. Valino, J.R.C. Dizon, A.H. Espera, Q. Chen, J. Messman, R.C. Advincula, Advances in 3D printing of thermoplastic polymer composites and nanocomposites. Prog. Polym. Sci. 98, 101162 (2019)
11. A. Dey, N. Yodo, A systematic survey of FDM process parameter optimization and their influence on part characteristics. J. Manuf. Mater. Process. 3(3), 64 (2019)
12. J.C. Camargo, Á.R. Machado, E.C. Almeida, E.F.M.S. Silva, Mechanical properties of PLA- graphene filament for FDM 3D printing. Int. J. Adv. Manuf. Technol. 103(5–8), 2423–2443 (2019)
13. Y. Liao et al., Effect of porosity and crystallinity on 3D printed PLA properties. Polymers (Basel) 11(9), 1487 (2019)
14. A. Rodríguez-Panes, J. Claver, A.M. Camacho, The influence of manufacturing parameters on the mechanical behavior of PLA and ABS pieces manufactured by FDM: A comparative analysis. Materials (Basel) 11(8), 1333 (2018
15. J. Kiendl, C. Gao, Controlling toughness and strength of FDM 3D-printed PLA components through the raster layup, Compos. Part B Eng. 180 (2020)
16. B. Mansfield, S. Torres, T. Yu, D. Wu, A review on additive manufacturing of ceramics, in ASME 2019 14th International Manufacturing Science and Engineering Conference, MSEC 2019, vol. 1, pp. 36–53 (2019)
17. J.R.C. Dizon, A.H. Espera, Q. Chen, R.C. Advincula, Mechanical characterization of 3D- printed polymers. Addit. Manuf. 20, 44–67 (2018)
18. S. Singh, R. Singh, Integration of fused deposition modeling and vapor smoothing for biomedical applications, in Reference Module in Materials Science and Materials Engineering, Elsevier, pp. 1–15 (2017)
19. K.S. Boparai, R. Singh, Development of rapid tooling using fused deposition modeling, in Additive Manufacturing of Emerging Materials (Springer International Publishing, Cham, 2019),pp. 251–277
20. M.A. León-Cabezas, A. Martínez-García, F.J. Varela-Gandía, Innovative functionalized monofilaments for 3D printing using fused deposition modeling for the toy industry. Proc. Manuf. 13, 738–745 (2017).