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Purpose: The work aims to propose a comprehensive design framework for additive manufacturing and apply it to a case study of the height adjuster handle of a car. The aim is to provide designers and engineers with a practical example of how the framework can be used to design a complex part for additive manufacturing. The article also aims to demonstrate the potential benefits of additive manufacturing in the automotive industry, such as improved performance, reduced times, and cost savings. Additionally, the article aims to compare the developed framework with existing design for additive manufacturing (DFAM) methodologies and highlight its unique features and advantages in designing the height adjuster handle. Design/methodology/approach: The study used qualitative and quantitative data collection and analysis methods. The first phase of the study involved a systematic review of existing DfAM methodologies and a critical analysis of their strengths and weaknesses. Based on this analysis, a new DfAM framework is developed, which aims to address the limitations of existing frameworks and provide a comprehensive design approach for additive manufacturing. The second phase of the study involved applying the developed framework to a case study of a complex automotive part - a height adjuster handle. The design requirements of the height adjuster handle were identified based on the principles of DfAM, and the part was designed using computer-aided design (CAD) software and optimised topologically using ANSYS software. In the third phase, the performance of the height adjuster handle designed using the developed framework was compared with a part manufactured with injection moulding technology. The comparison was based on various performance criteria, including mechanical properties, dimensional accuracy, and production time and cost. Findings: The findings of the study demonstrate the effectiveness of the developed design framework for additive manufacturing (DfAM) in producing a complex automotive part with improved performance characteristics and reduced lead time. Research limitations/implications: Although the results of the study provide important insights into the effectiveness of the developed DfAM framework for producing a complex automotive part, there are some limitations to the research that should be considered, such as the case study involved the design of a single part, and the results may not be generalisable to other parts or applications. Further research is needed to validate the effectiveness of the DfAM framework for a broader range of automotive parts. for the automotive industry. The developed DfAM framework can be used in the FDM technology. It can be used as a decision aid in the manufacturing of FDM parts in order to improve the efficiency and cost-effectiveness of the production process for complex automotive parts. Originality/value: The value of the study is the development of a novel DfAM framework and the demonstration of its effectiveness in a case study. The proposed framework can be used as a reference for future research. It can also provide practical guidance for industry professionals seeking to improve the efficiency and cost-effectiveness of their additive manufacturing processes.
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Tom
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32--41
Opis fizyczny
Bibliogr. 28 poz.
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autor
- National High School of Electricity and Mechanics (ENSEM), University Hassan II of Casablanca, Casablanca, Morocco
autor
- National High School of Electricity and Mechanics (ENSEM), University Hassan II of Casablanca, Casablanca, Morocco
autor
- Laboratory of Mechanics, Production, and Industrial Engineering (LMPGI), High School of Technology of Casablanca (ESTC), University Hassan II of Casablanca, Casablanca, Morocco
autor
- Laboratory of Mechanics, Production, and Industrial Engineering (LMPGI), High School of Technology of Casablanca (ESTC), University Hassan II of Casablanca, Casablanca, Morocco
Bibliografia
- [1] E. Avdibasic, A.S. Toksanovna, B. Durakovic, Cybersecurity challenges in Industry 4.0: A state of the art review, Defense and Security Studies 3 (2022) 3249. DOI: https://doi.org/10.37868/dss.v3.id188
- [2] B. Rudalija, Quality management research trends in context of Industry 4.0: A short review, Defense and Security Studies 1 (2021) 44-52. DOI: https://doi.org/10.37868/dss.v1.id149
- [3] O. Lkadi, M. Nassraoui, O. Bouksour, An Overview on Additive Manufacturing: Technologies, Materials and Applications, Uncertainties and Reliability of Multiphysical Systems 6/2 (2022) 1-15 (in French). DOI: https://doi.org/10.21494/ISTE.OP.2022.0881
- [4] B. Durakovic, Design for additive manufacturing: Benefits, trends and challenges, Periodicals of Engineering and Natural Sciences 6/2 (2018) 179-191. DOI: https://doi.org/10.21533/pen.v6i2.224
- [5] M. Di Nicolantonio, E. Rossi, T. Alexander (eds), Advances in Additive Manufacturing, Modeling Systems and 3D Prototyping: Proceedings of the AHFE 2019 International Conference on Additive Manufacturing, Modeling Systems and 3D Prototyping, July 24-28, 2019, Washington D.C., USA, Advances in Intelligent Systems and Computing Series, vol. 975, Springer International Publishing, Cham, 2020. DOI: https://doi.org/10.1007/978-3-030-20216-3 [6] M. Salmi, Additive Manufacturing Processes in Medical Applications, Materials 14/1 (2021) 191. DOI: https://doi.org/10.3390/ma14010191
- [7] M. Orquera, Design for additive manufacturing: methodological approach for multibody mechanical systems, PhD Thesis, University of Toulon, Toulon, 2019 (in French). Available from: https://theses.hal.science/tel-02895646
- [8] O. Diegel, A. Nordin, D. Motte, A Practical Guide to Design for Additive Manufacturing, Springer Series in Advanced Manufacturing, Springer, Singapore, 2019. DOI: https://doi.org/10.1007/978-981-13-8281-9
- [9] M.K. Thompson, G. Moroni, T. Vaneker, G. Fadel, R.I. Campbell, I. Gibson, A. Bernard, J. Schulz, P. Graf, B. Ahuja, F. Martina, Design for Additive Manufacturing: Trends, opportunities, considerations, and constraints, CIRP Annals 65/2 (2016) 737-760. DOI: https;//doiLorg/10J.1016/j.cirpi2016i05i004
- [10] A. Alfaify, M. Saleh, F.M. Abdullah, A.M. Al-Ahmari, Design for Additive Manufacturing: A Systematic Review, Sustainability 12/19 (2020) 7936. DOI: https://doi.org/10.3390/su12197936
- [11] M. Kumke, H. Watschke, T. Vietor, A new methodological framework for design for additive manufacturing, Virtual and Physical Prototyping 11/1 (2016) 3-19. DOI: https://doi.org/10.1080/17452759.2016.1139377 [12] H.I. Medellin-Castillo, J. Zaragoza-Siqueiros, Design and Manufacturing Strategies for Fused Deposition Modelling in Additive Manufacturing: A Review, Chinese Journal of Mechanical Engineering 32/1 (2019) 53. DOI: https://doi.org/10.1186/s10033-019-0368-0
- [13] S.C. Renjith, K. Park, G.E. Okudan Kremer, A Design Framework for Additive Manufacturing: Integration of Additive Manufacturing Capabilities in the Early Design Process, International Journal of Precision Engineering and Manufacturing 21/2 (2020) 329-345. DOI: https://doi.org/10.1007/s12541-019-00253-3
- [14] T. Vaneker, A. Bernard, G. Moroni, I. Gibson, Y. Zhang, Design for additive manufacturing: Framework and methodology, CIRP Annals 69/2 (2020) 578-599. DOI: https://doi.org/10.1016/j.cirp.2020.05.006
- [15] I. Bahnini, M. Rivette, A. Rechia, A. Siadat, A. Elmesbahi, Additive manufacturing technology: the status, applications, and prospects, The International Journal of Advanced Manufacturing Technology 97/1-4 (2018) 147-161. DOI: https://doi.org/10.1007/s00170-018-1932-y
- [16] N. Zohdi, R. Yang, Material Anisotropy in Additively Manufactured Polymers and Polymer Composites: A Review, Polymers 13/19 (2021) 3368. DOI: https://doi.org/10.3390/polym13193368
- [17] S. Yang, Y.F. Zhao, Additive manufacturing-enabled design theory and methodology: a critical review, The International Journal of Advanced Manufacturing Technology 80/1-4 (2015) 327-342. DOI: https://doi.org/10.1007/s00170-015-6994-5
- [18] A. Wiberg, J. Persson, J. Ölvander, Design for additive manufacturing - a review of available design methods and software, Rapid Prototyping Journal 25/6 (2019) 1080-1094. DOI: https://doi.org/10.1108/RPJ-10-2018-0262
- [19] R. Ponche, O. Kerbrat, P. Mognol, J.-Y. Hascoet, A novel methodology of design for Additive Manufacturing applied to Additive Laser Manufacturing process, Robotics and Computer-Integrated Manufacturing 30/4 (2014) 389-398. DOI: https://doi.org/10.1016Zi.rcim.2013.12.001
- [20] R. Ponche, J.-Y. Hascoet, O. Kerbrat, P. Mognol, A new global approach to design for additive manufacturing: A method to obtain a design that meets specifications while optimizing a given additive manufacturing process is presented in this paper, Virtual and Physical Prototyping 7/2 (2012) 93-105. DOI: https://doi.org/10.1080/17452759.2012.679499
- [21] R. Ponche, Design methodology for additive manufacturing, application to powder spraying, PhD Thesis, Centrale Nantes, Nantes, 2013 (in French). Available from: https://theses.hal.science/file/index/docid/916534/filen ame/manuscrit these.pdf
- [22] H. Rodrigue, M. Rivette, An Assembly-Level Design for Additive Manufacturing Methodology, Proceedings of the IDMME - Virtual Concept 2010, Bordeaux, France, 2010, 1-9.
- [23] B. Vayre, Design for additive manufacturing, application to EBM technology, PhD Thesis, University of Grenoble, Grenoble, 2014 (in French). Available from: http://www.theses.fr/2014GRENI096/document
- [24] N. Boyard, Design methodology for the production of parts in Additive Manufacturing, PhD Thesis, National School of Arts and Crafts - ENSAM, Paris, 2015 (in French). Available from: https://pastel.hal.science/tel-01176962/document
- [25] O. Aourik, M. Othmani, B. Saadouki, K. Abouzaid, A. Chouaf, Fracture toughness of ABS additively manufactured by FDM process, Journal of Achievements in Materials and Manufacturing Engineering 109/2 (2021) 49-58. DOI: https://doi.org/10.5604/01.3001.0015.6258
- [26] A. Ouballouch, Numerical and experimental study of the process additive manufacturing by wire deposition (FDM), PhD Thesis, National Higher School of Arts and Crafts of Meknes, Meknes, 2021 (in French).
- [27] R.A. Malloy, Prototyping and Experimental Stress Analysis, in: Plastic Part Design for Injection Molding, 2nd Edition, Carl Hanser Verlag GmbH & Co. KG, München, 2010, 285-339. DOI: https://doi.org/10.3139/9783446433748.005
- [28] D.M. Bryce, Plastic Injection Molding: Material Selection and Product Design Fundamentals, Fundamentals of Injection Molding Series, Society of Manufacturing Engineers, Southfield, MI, 1997.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-475cfd54-07e9-430c-b15c-e845b4a70eb4