Transactions on Additive Manufacturing Meets Medicine
Vol. 5 No. S1 (2023): Trans. AMMM Supplement
https://doi.org/10.18416/AMMM.2023.2309796

Material Properties, Structural Designs, and Printing Technologies, ID 796

Compression set of 3D-printed parts

Main Article Content

Roman Leonov (Fraunhofer IMTE / RWTH Aachen), Annika Dell (Fraunhofer IMTE), Thomas Friedrich (Fraunhofer IMTE)

Abstract

3D-printing of soft materials is a technology that is actively used in various industries: soft robotics [1], implants [2], bioelectronics [2] and many others. The mechanical behavior of 3D-printed parts is defined by the selected printing method, material, and other factors. Understanding of the mechanical properties of the printing material is an important factor affecting the success of adoption of this technology, especially for medical applications such as implant production, and its further development. Polyjet printing is one of the technologies, used in additive manufacturing. Some printers, exploiting this technology, allow the mixing of materials with different characteristics, so to print a part that has aspects of each component. The aim of this work is to measure the compression set of different polymer hardness combinations used for polyjet printing. The compression set is defined as the permanent deformation remaining after applying mechanical force to the part [3]. This property usually is not listed in datasheets provided by the manufacturer, but its measurement is important, since it provides information as to how a part or component will behave when deformed and to what degree its initial geometry will be restored during its utilization. The selected materials were compositions of Agilus30 and Vero photopolymers, produced by Stratasys Ltd. and used in 3D printers of the company. The printer used for the experiment was the Stratasys J850 Prime. It can print polymer composition with a predefined ratio of components, resulting in parts with different mechanical behavior. The compression set experiment was run according to ISO 815-1:2019 standard [4]. Three specimens of a specific cylindrical form were printed of each of compositions involved in the testing. The thickness of all specimens was measured before the deformation. The specimens were compressed for 24 hours, after which the thickness was measured again. In both cases the computer tomograph YXLON FF35 CT was used to measure the thickness with a high degree of precision. The compression set was calculated from that data and represented in dependency of the composition. The results of the experiment will be used by the Fraunhofer IMTE for calculations of the size of 3D printed parts undergoing deformation when in operation.


Author’s statement
Conflict of interest: R. L. is an employee of EnBW Energie Baden-Württemberg AG. Other authors state no conflict of interest. Acknowledgments: Authors thank Franziska Seidensticker for her support in mechanical testing and David Melenberg for his support in CT measurements. Research funding: The authors state no funding involved.


References
[1] Y.-F. Zhang et al., Miniature Pneumatic Actuators for Soft Robots by High-Resolution Multimaterial 3D Printing, Adv. Mater. Technol., vol. 4, p. 1900427, Oct. 2019
[2] L. Weifeng et al., Cartilage-inspired, lipid-based boundary-lubricated hydrogels. Science, vol. 370, pp. 335-338, Oct. 2020
[3] M. F. Sonnenschein et al., Mechanism for compression set of TDI polyurethane foams, Polymer, Vol. 48, pp. 616-623, Jan. 2007
[4] International Organization for Standardization. (2019). Rubber, vulcanized or thermoplastic - Determination of compression set - Part 1: At ambient or elevated temperatures. (ISO Standard No. 815-1:2019). Retrieved from https://www.iso.org/standard/74943.html

Article Details

How to Cite

Leonov, R., Dell, A., & Friedrich, T. (2023). Compression set of 3D-printed parts. Transactions on Additive Manufacturing Meets Medicine, 5(S1), 796. https://doi.org/10.18416/AMMM.2023.2309796