Optimizing PEEK impact strength through multi-objective FDM 3D printing

Authors

  • Chinmaya Padhy Department of Mechanical Engineering, Gandhi Institute of Technology and Management, 500081, Hyderabad, India
  • Suryakumar S. Department of Mechanical and Aerospace Engineering, Indian Institute of Technology, 502284, Hyderabad, India
  • D. Bhattacharjee Department of Operations and Analytics, FLAME University, 412115, Pune, India

DOI:

https://doi.org/10.15282/jmes.17.4.2023.6.0770

Keywords:

Fused Deposition Modelling, Impact strength, Print time, High grade polymer, Composite desirability, Predictive modelling

Abstract

Thermoplastic materials such as Polylactic acid, Acrylonitrile Butadiene Styrene, Polyethylene terephthalate glycol, Nylon, and Thermoplastic polyurethane are favoured in Fused deposition modeling 3D printing due to their cost-effectiveness and versatile properties. However, with the introduction of high grade thermoplastic material poses compatibility challenges with existing machines and processes, impeding widespread adoption in FDM 3D printing. Incorporating new materials into 3D printing requires adjustments to hardware, software, and settings, leading to potential expenses and time investments. Maintaining quality control and consistency becomes complex as each material demands specific parameters and processing conditions. This variability hinders achieving consistent part quality in 3D printing. Moreover, achieving optimal FDM parameters for high-grade polymers (HGPs) like Polyether ether ketone (PEEK) is a challenge due to the distinctive nature of the property, requiring specialized careful considerations during its optimization process. The considerable thermal gradient and heat distribution during printing can lead to residual stresses and deformations, significantly affecting the quality and, in particular, its impact strength. This article optimizes an industry grade 3D printing PEEK based on the limited number of process parameters, namely, build orientation, in-fill density and chamber temperature. Further, the research tries to derive a predictive model for Impact Strength (IS), which is an important consideration for the 3D printed object. In this article, along with the Impact Strength, Printing Time and Material Usage are also studied to find empirical evidence of association between these output variables or response variables. The result indicates that there is a positive significant correlation or association between them. When utilizing a specific parameter setup, the resulting IS of 86.5 kJ/m², a print time of 89 minutes, and a material usage of 3.26 grams are achieved. Notably, there is a measurable reduction of 9.18% in printing time and a 11.66% decrease in material usage when the print density is set to 100% to optimize impact strength. This optimization approach proves the use of composite desirability is a better approach where multiple objectives need to be achieved. The proposed regression model predicts the impact strength with coefficient of determination value more than 50%.

References

S. Vyavahare, S. Teraiya, D. Panghal and S. Kumar, “Fused deposition modelling: A review,” Rapid Prototyping Journal, vol. 26, no. 1, pp.176-201, 2020.

L. Sandanamsamy, W. S. W. Harun, I. Ishak, F. R. M. Romlay, K. Kadirgama, D. Ramasamy, S. R. A. Idris and F. Tsumori, “A comprehensive review on fused deposition modelling of polylactic acid,” Progress in Additive Manufacturing, vol. 8, pp. 775-799, 2023.

S. Sunpreet, P. Chander and R. Seeram, “3D printing of polyether-ether-ketone for biomedical applications,” European Polymer Journal, vol. 114, pp. 234-248, 2019.

D. Arit, A. C. Camden, J. F. Jacob, E. Z. Callie, L. G. Eric, B. W. Christopher and J. B. Michael, “Current understanding and challenges in high temperature additive manufacturing of engineering thermoplastic polymers,”Additive Manufacturing, vol. 34, p. 101218, 2020.

D. Garcia-Gonzalez, A. Rusinek, T. Jankowiak, and A. Arias, “Mechanical impact behavior of polyether–ether–ketone (PEEK),” Composite Structures, vol. 124, pp. 88-99, 2015.

K. Rajan, M. Samykano, K. Kadirgama, W. S. W. Harun, and M. M. Rahman, “Fused deposition modeling: Process, materials, parameters, properties, and applications,” International Journal of Advanced Manufacturing Technology, vol. 120, no. 3-4, pp. 1531–1570, 2022.

H. Gonabadi, Y. Chen, A. Yadav, and S. Bull, “Investigation of the effect of raster angle, build orientation, and infill density on the elastic response of 3D printed parts using finite element microstructural modeling and homogenization techniques,” International Journal of Advanced Manufacturing Technology, vol. 118, pp. 1485–1510, 2022.

A. Murali, M. A. Vakkattil and R. Parameswaran, “Investigating the effect of processing parameters on mechanical behavior of 3D fused deposition modeling printed polylactic acid,” Journal of Material Engineering and Performance, vol. 32, pp. 1089–1102, 2023.

A. C. Christopher, Í. G. da Silva, K. D. Pangilinan, Q. Chen, E. B. Caldona and R. C. Advincula, “High performance polymers for oil and gas applications,” Reactive and Functional Polymers, vol. 162, p. 104878, 2021.

Z. Zhang, C. Breidt, L. Chang and K. Friedrich, “Wear of PEEK composites related to their mechanical performances,” Tribology International, vol. 37, no. 3, pp. 271-277, 2004.

W. Z. Wu, P. Geng, J. Zhao, Y. Zhang, D. W. Rosen and B. H. Zhang, “Manufacture and thermal deformation analysis of semicrystalline polymer polyether ether ketone by 3D printing,” Materials Research Innovations, vol. 18, no. 5, pp. 12-16, 2014.

C. Yang, X.Tian, D. Li, Y. Cao, F. Zhao and C. Shi, “Influence of thermal processing conditions in 3D printing on the crystallinity and mechanical properties of PEEK material,” Journal of Materials Processing Technology, vol. 248, pp. 1-7, 2017.

S. Berretta, R. Davies, Y.T. Shyng, Y. Wang and O. Ghita, “Fused deposition modelling of high temperature polymers: Exploring CNT PEEK composites,” Polymer Testing, vol. 63, pp. 251-262, 2017.

M. Rinaldi, T. Ghidini, F. Cecchini, A. Brandao and F. Nanni, “Additive layer manufacturing of poly (ether ether ketone) via FDM,” Composites Part B, vol. 145, pp. 162-172, 2018.

X. Deng, Z. Zeng, B. Peng, S. Yan and W. Ke, “Mechanical properties optimization of poly-ether-ether-ketone via fused deposition modeling,” Materials, vol. 11,no. 2, pp. 216, 2018.

M. F. Arif, S. Kumar, K. M. Varadarajan and W. J. Cantwell, “Performance of biocompatible PEEK processed by fused deposition additive manufacturing,” Materials & Design, vol. 146, pp. 249-259, 2018.

S. A. Muhsin, P. V. Hatton, A. Johnson, N. Sereno and D. J. Wood, “Determination of Polyetheretherketone (PEEK) mechanical properties as a denture material,” The Saudi Dental Journal, vol. 31, no. 3, pp. 382-391, 2019.

P. Wang, B. Zou, H. Xiao, S. Ding and C. Huang, “Effects of printing parameters of fused deposition modeling on mechanical properties, surface quality, and microstructure of PEEK,” Journal of Materials Processing Technology, vol. 271, pp. 62-74, 2019.

Q. Li, W. Zhao, Y. Li, W. Yang, and G. Wang, “Flexural properties and fracture behavior of CF/PEEK in orthogonal building orientation by FDM: Microstructure and mechanism,” Polymers, vol. 11, no. 4, pp. 656, 2019.

S. Yingshuang, W. Xian, L. Yifan, J. Zilong, W. Zhaoyang, J. Zhenhua and Z. Haibo, “Preparation of PEEK/MWCNTs composites with excellent mechanical and tribological properties,” High Performance Polymers, vol. 31, no. 1, pp. 43–50, 2019.

G. Haijun, X. Xiaodong and N. Jan, “Impact strength of 3D printed polyether-ether-ketone (PEEK),” in Proceedings of the 30thAnnual International Solid Freeform Fabrication Symposium—An Additive Manufacturing Conference, Austin, Texas, USA, pp. 12–14, 2019.

S. Singh, C. Prakash and S. Ramakrishna, “3D printing of polyether-ether-ketone for biomedical applications,”European Polymer Journal, vol. 114, pp. 234-248, 2019.

J. Zheng, J. Kang, C. Sun, C. Yang, L. Wang and D. Li, “Effects of printing path and material components on mechanical properties of 3D-printed polyether-ether-ketone/hydroxyapatite composites,” Journal of the Mechanical Behavior of Biomedical Materials, vol. 118, p. 104475, 2021.

G. Cicala, A. Latteri, B. Del Curto, A. L. Russo, G. Recca and S. Farè, “Engineering thermoplastics for additive manufacturing: A critical perspective with experimental evidence to support functional applications,” Journal of Applied Biomaterials & Functional Materials, vol. 15, pp. 10–18, 2017.

C. Padhy, S. Suryakumar, D. Bhattacharjee, R. Reddy, “Parametric analysis of 3D printing (FDM) process parameters on mechanical behaviour of PEEK-A high-grade polymer”, International Interdisciplinary Conference on Energy, Nanotechnology and Internet of Things, ENT-2023, NIT-Puducherry, India, February 2-4, 2023.

D. C. Montgomery. Design and Analysis of Experiments, 10thEd. John Wiley & Sons Inc., 2019.[27]M. Ezekiel. Methods of Correlation Analysis, 2ndEd. John Wiley & Sons Inc., 1941.

B. Şimşek and T. Uygunoğlu, “Multi-response optimization of polymer blended concrete: A TOPSIS based Taguchi application.” Construction and Building Materials, vol. 117, pp. 251-262, 2016.

D. Bhattacharjee, T. Ghosh, P. Bhola, K. Martinsen and P. Dan, “Ecodesigning and improving performance of plugin hybrid electric vehicle in rolling terrain through multi-criteria optimisation of powertrain,” Proceedings of the Institution ofMechanical Engineers, Part D: Journal of Automobile Engineering, vol. 236, no. 5, pp. 1019-1039, 2022.

H. Korucu, B. Şimşek and A. Yartaşı, “A TOPSIS-based Taguchi design to investigate optimum mixture proportions of graphene oxide powder synthesized by hummers method,” Arabian Journal for Science and Engineering, vol. 43, pp. 6033-6055, 2018.

N. R. Costa, J. Lourenço and Z. L. Pereira, “Desirability function approach: A review and performance evaluation in adverse conditions," Chemometrics and IntelligentLaboratory Systems, vol. 107, no. 2, pp. 234-244, 2011.

S. Ruder, "An overview of gradient descent optimization algorithms," ArXiv, vol, abs/1609.04747, 2016.

R. J. Freund, W. J. Wilson and P. Sa. Regression Analysis, 2ndEd. Academic Press, 2006.

A. K. Seghouane, "New AIC corrected variants for multivariate linear regression model selection," IEEE Transactions on Aerospace and Electronic Systems, vol. 47, no. 2, pp. 1154-1165, 2011.

NWA3D, “Glossary of 3D Printing Terms,” Accessed: August 2023, Available at https://www.nwa3d.com/education/glossary-of-3d-printing-terms/

J. Dobos, M. M. Hanon and I. Oldal, "Effect of infill density and pattern on the specific load capacity of FDM 3D-printed PLA multi-layer sandwich,"Journal of Polymer Engineering, vol.42, no. 2, pp. 118-128, 2022.

I. J. Petrick and T. W. Simpson “3D printing disrupts manufacturing: how economies of one create new rules of competition,” Research-Technology Management, vol. 56, no. 6 pp. 12–16, 2013.

B. P. Conner, G. P. Manogharan, A. N. Martof, L. M. Rodomsky, C. M. Rodomsky, D. C. Jordan, and J. W. Limperos, “Making sense of 3-D printing: Creating a map of additive manufacturing products and services,” Additive Manufacturing, vol. 1–4, pp. 64–76, 2014.

B. Liseli, M. Guha, M. Hazel, “Study ofinfill print design on production cost-time of 3D printed ABS parts,” International Journal of Rapid Manufacturing,vol. 5, no. 3/4, pp. 308-319, 2015.

S. J. Park, J. E. Lee, J. Park, N. K. Lee, Y. Son and S. H. Park, “High-temperature 3D printing of polyetheretherketone products: Perspective on industrial manufacturing applications of super engineering plastics,” Materials & Design, vol. 211, p. 110163, 2021.

R. Kumrai-Woodruff and Q. Wang, “Temperature control to increase inter-layer bonding strength in fused deposition modelling” Proceeding of theASME 2020 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference, vol. 6, p. V006T06A002, 2020.

S. Kannan, R. Vezhavendhan, S. Kishore and K. V. Kanumuru, “Investigating the effect of orientation, infill density with Triple raster pattern on the tensile properties for 3D Printed samples,” IOPSciNotes,vol.1, p.024405, 2020.

B. W. Kaplun, R. Zhou, K. W. Jones, M. L. Dunn and C. M. Yakacki, “Influence of orientation on mechanical properties for high-performance fused filament fabricated ultem 9085 and electro-statically dissipative polyetherketoneketone,” Additive Manufacturing, vol. 36, p. 101527, 2020.

O. A. Mohamed, S. H. Masood and J. L. Bhowmik. "Optimization of fused deposition modeling process parameters: A review of current research and future prospects," Advances in Manufacturing, vol.3, pp. 42-53,2015.

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Published

2023-12-28

How to Cite

[1]
C. Padhy, S. S., and D. Bhattacharjee, “Optimizing PEEK impact strength through multi-objective FDM 3D printing”, J. Mech. Eng. Sci., pp. 9725–9741, Dec. 2023.

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