Analysis of Stress Relaxation During Compression of 3D-Printed Samples Using Mex Technology and the Taguchi Method

SZCZYGIEŁ, Paweł; SZOT, Wiktor; KOWALSKA, Natalia; RUDNIK, Mateusz

doi:10.2478/ama-2025-0067

Abstract

The study investigated the impact of various Additive Manufacturing parameters in Material Extrusion technology on stress relaxation during compression using a biocompatible filament. The Taguchi method was applied for the analysis. The examined parameters included layer height, shell count (number of contours), nozzle temperature, print orientation, and overlap. The results enabled the assessment of how printing parameters influence elastic moduli and dynamic viscosity coefficients. It was determined that layer height and shell count have the most significant effect on the percentage decrease in stress over time.

References

Zmarzły P, Kozior T, Gogolewski D. The effect of non-measured points on the accuracy of the surface topography assessment of elements 3D printed using selected additive technologies. Materials. 2023;16.
Search in Google Scholar Back to article
Ghosh B, Karmakar S. 3D printing technology and future of construction: a review. IOP Conf Ser Earth Environ Sci; 2024.
Search in Google Scholar Back to article
Kroczek K, Turek P, Mazur D, Szczygielski J, Filip D, Brodowski R, et al. Characterisation of selected materials in medical applications; 2022.
Search in Google Scholar Back to article
4Rwaiha O, Jwaili MA, Rwaiha OM, Ebid E. Novel of 3D printing technology: review. Int J Creative Research Thoughts; 2024.
Search in Google Scholar Back to article
Wang Y, Zhu F, Rao Q, Peng X. A 3D finite strain viscoelastic model with uncoupled structural and stress relaxations for shape memory polymers. Polym Test. 2021;103.
Search in Google Scholar Back to article
Du Y, Wang P, Liang R, Zhou X, Chen S. Automatic testing system for performance parameters of viscoelastic materials. Int J Comput Sci Inf Technol. 2024;3:103–111.
Search in Google Scholar Back to article
Kozior T, Kundera C. Rheological properties of cellular structures manufactured by additive PJM technology. Teh Vjesn. 2021;28: 82–87.
Search in Google Scholar Back to article
Wijesinghe S, Perahia D, Ge T, Salerno KM, Grest GS. Stress relaxation of comb polymer melts. Tribol Lett. 2021;69.
Search in Google Scholar Back to article
Ibrulj J, Dzaferovic E, Obucina M, Kuzman MK. Numerical and experimental investigations of polymer viscoelastic materials obtained by 3D printing. Polymers (Basel). 2021;13.
Search in Google Scholar Back to article
Szot W, Bochnia J, Zmarzły P. Effect of selective laser sintering on stress relaxation in PA12. Polimery. 2024;179–185.
Search in Google Scholar Back to article
Bochnia J, Blasiak S. Stress relaxation and creep of a polymer-aluminum composite produced through selective laser sintering. Polymers (Basel). 2020;12.
Search in Google Scholar Back to article
Lin CY, Chen YC, Lin CH, Chang KV. Constitutive equations for analyzing stress relaxation and creep of viscoelastic materials based on standard linear solid model derived with finite loading rate. Polymers (Basel). 2022;14.
Search in Google Scholar Back to article
Bochnia J. Evaluation of relaxation properties of digital materials obtained by means of PolyJet Matrix technology. Bull Pol Acad Sci Tech Sci. 2018;66:891–897.
Search in Google Scholar Back to article
Bochnia J, Kozior T, Szot W, Rudnik M, Zmarzły P, Gogolewski D, et al. Selected mechanical and rheological properties of medical resin MED610 in PolyJet Matrix three-dimensional printing technology in quality aspects. 3D Print Addit Manuf. 2024;11:299–313.
Search in Google Scholar Back to article
Stankiewicz A, Juściński S. How to make the stress relaxation experiment for polymers more informative. Polymers (Basel). 2023;15.
Search in Google Scholar Back to article
Chepurnenko AS, Kondratieva TN, Al-Wali E. Processing of polymers stress relaxation curves using machine learning methods. 2023.
Search in Google Scholar Back to article
Bertocco A, Bruno M, Armentani E, Esposito L, Perrella M. Stress relaxation behavior of additively manufactured polylactic acid (PLA). Materials. 2022;15.
Search in Google Scholar Back to article
Stepanov DY, Dontsov YV, Panin SV, Buslovich DG, Alexenko VO, Bochkareva SA, et al. Optimization of 3D printing parameters of high viscosity PEEK/30GF composites. Polymers (Basel). 2024;16.
Search in Google Scholar Back to article
Guduru KK, Setti SG. 3D printed carbon fiber reinforced PLA composite using fused deposition modeling by Taguchi’s optimization: influence of printing parameters. Int J Interact Des Manuf. 2024.
Search in Google Scholar Back to article
Abed SA, Hassan SR, Jomah AJS, Hanon MM. Prediction on the wear rate of epoxy composites reinforced micro-filler of the natural material residue using Taguchi–neural network. Eureka Phys Eng. 2023;149–159.
Search in Google Scholar Back to article
Zubrzycki J, Quirino E, Staniszewski M, Marchewka M. Influence of 3D printing parameters by FDM method on the mechanical properties of manufactured parts. Adv Sci Technol Res J. 2022;16:52–63.
Search in Google Scholar Back to article
Vochozka V, Černý P, Šramhauser K, Špalek F, Kříž P, Čech J, et al. Fused filament fabrication 3D printing parameters affecting the translucency of polylactic acid parts. Polymers (Basel). 2024;16:2862.
Search in Google Scholar Back to article
Bruère VM, Lion A, Holtmannspötter J, Johlitz M. The influence of printing parameters on the mechanical properties of 3D printed TPU-based elastomers. Prog Addit Manuf. 2023;8:693–701.
Search in Google Scholar Back to article
Alzyod H, Ficzere P. Material-dependent effect of common printing parameters on residual stress and warpage deformation in 3D printing: a comprehensive finite element analysis study. Polymers (Basel). 2023;15.
Search in Google Scholar Back to article
Kowalska N, Szczygieł P, Skrzyniarz M, Błasiak S. Effect of shells number and machining on selected properties of 3D-printed PLA samples. Polimery. 2024;69:186–190.
Search in Google Scholar Back to article
Rudnik M. Study of cellular structures built from self-similar models and repeatable structures manufactured by FDM/FFF technology. Polimery. 2024;173–178.
Search in Google Scholar Back to article
Faidallah RF, Abd-El Nabi AM, Hanon MM, Szakál Z, Oldal I. Compressive and bending properties of 3D-printed wood/PLA composites with re-entrant honeycomb core. Results Eng. 2024;24.
Search in Google Scholar Back to article
Estefanía D, Pérez C, Geovanny E, Novay Z, Patricio H, Mazón C, et al. Elasticity and plasticity of PLA, PETG, ABS polymers for printing automotive parts. Rev Multidiscip Investig Científica. 2024;8: 51–66.
Search in Google Scholar Back to article
Grigoriev S, Nikitin N, Yanushevich O, Krikheli N, Khmyrov R, Strunevich D, et al. Experimental and statistical study of strength properties of FDM-printed specimens made from ABS, PLA and PETG plastics depending on the percentage and structure of filling. Research Square. 2024. Available from: https://www.researchsquare.com/article/rs-4627817/v1
Search in Google Scholar Back to article
Yu J. The application and significance of 3D printing technology in biomedicine. Appl Comput Eng. 2024;58:215–221.
Search in Google Scholar Back to article
Mathews Jacob J, Nachiappan B. An overview on 3D printing technology: technological, materials, and applications; 2023.
Search in Google Scholar Back to article
Wang Z, Wang XY, Yu X. Application of 3D printing surgical training models in the preoperative assessment of robot-assisted partial nephrectomy. BMC Surg. 2024;24.
Search in Google Scholar Back to article
Ali F, Kalva SN, Koc M. Advancements in 3D printing techniques for biomedical applications: a comprehensive review of materials consideration, post processing, applications, and challenges. 2024.
Search in Google Scholar Back to article
Turek P. Automating the process of designing and manufacturing polymeric models of anatomical structures of mandible with Industry 4.0 convention. Polimery. 2019;64:522–529.
Search in Google Scholar Back to article
Zakręcki A, Cieślik J, Bazan A, Turek P. Innovative approaches to 3D printing of PA12 forearm orthoses: a comprehensive analysis of mechanical properties and production efficiency. Materials. 2024;17.
Search in Google Scholar Back to article
Cooper3D. Material technical datasheet PLACTIVE; 2025.
Search in Google Scholar Back to article
Cooper3D. Material safety data sheet PLACTIVE; 2025.
Search in Google Scholar Back to article
Karimi A, Rahmatabadi D, Baghani M. Various FDM mechanisms used in the fabrication of continuous-fiber reinforced composites: a review; 2024.
Search in Google Scholar Back to article
Ma T, Zhang Y, Ruan K, Guo H, He M, Shi X, et al. Advances in 3D printing for polymer composites: a review; 2024.
Search in Google Scholar Back to article
Bustos Seibert M, Mazzei Capote GA, Gruber M, Volk W, Osswald TA. Manufacturing of a PET filament from recycled material for material extrusion (MEX). Recycling. 2022;7.
Search in Google Scholar Back to article
Mittal YG, Patil Y, Kamble PP, Gote GD, Mehta AK, Karunakaran KP. Warpage control in thermoplastic ABS parts produced through material extrusion (MEX)-based fused deposition modeling (FDM). Rapid Prototyp J. 2024;30:1822–1835.
Search in Google Scholar Back to article
Shina S. Industrial design of experiments. Cham: Springer International Publishing; 2022.
Search in Google Scholar Back to article

Analysis of Stress Relaxation During Compression of 3D-Printed Samples Using Mex Technology and the Taguchi Method

Abstract

Paradigm

My account