Journal of Graphic Engineering and Design

Lorem ipsum dolor sit amet, consectetur adipisicing elit, sed do eiusmod tempor incididunt ut ero labore et dolore magna aliqua. Ut enim ad minim veniam, quis nostrud exercitation ullamco.

Search
GUIDE FOR AUTHORS SUBMIT MANUSCRIPT
Forthcoming
Original scientific paper

Calibration of the printing process for 3D models using Vat polymerisation and investigation of the mechanical properties of TGM-7 resin

Full text article (PDF)
  • Renata Gudaitiene,
  • Vygintas Minkus,
  • Andrius Darulis
Renata Gudaitiene
Kauno kolegija/Higher Education Institution, Faculty of Computing, Engineering and Technologies, Department of Informatics and Media Technologies, Kaunas, Lithuania
Vygintas Minkus
Kauno kolegija/Higher Education Institution, Faculty of Computing, Engineering and Technologies, Department of Informatics and Media Technologies, Kaunas, Lithuania
Andrius Darulis
MB Labsamera, Kaunas, Lithuania

Published 2025-04-14

abstract views: 6 // Full text article (PDF): 1


Keywords

  • 3D modelling,
  • design,
  • 3D printing,
  • resin,
  • calibration,
  • masked stereolithography,
  • mechanical measurements
    • ...More
    Less

How to Cite

Gudaitiene, R., Minkus, V., & Darulis, A. (2025). Calibration of the printing process for 3D models using Vat polymerisation and investigation of the mechanical properties of TGM-7 resin. Journal of Graphic Engineering and Design, 29–40. Retrieved from https://sp.ftn.uns.ac.rs/index.php/jged/article/view/1690

Copyright (c) 2025 © 2025 Authors. Published by the University of Novi Sad, Faculty of Technical Sciences, Department of Graphic Engineering and Design. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution license 3.0 Serbia

Creative Commons License

This work is licensed under a Creative Commons Attribution 3.0 Unported License.

Abstract

With the development of modern technology, three-dimensional graphics (3D) are increasingly making their way into various fields such as design, advertising, packaging, industry and even medicine. Three-dimensional graphic elements can be not only modelled, but also apadted for the three-dimensional printing. However, the quality of the print is highly dependent on the printing method used, technological process and on the properties of the material. In this work, the models were created using 3D graphics software and tested after 3D printing. The new acrylic resin TGM-7, developed by AmeraLabs, was used for the 3D printing. During the testing process, the models were calibrated in order to obtain accurate and high-quality models with fewer inaccuracies or defects in the future and precise connections. During the experiments, a more significant change in dimensions was observed in the lower part of the models, which could have occurred due to the deposition of the polymer. Samples printed at a 45° angle had more accurate dimensions. The mechanism of parameters compensation in the XY and YX axis was demonstrated. During the work, the mechanical properties of the material were also determined, which are important for the many applications such as packaging, advertising items or other products subject to load. The acrylic resin, printed at different angles, exhibited plastic propertie, and samples printed at a 90° angle were better able to withstand dynamic loads, which averaged 206 N. The obtained results were applied to the creation and printing of an advertising model.

PlumX Metrics

Dimensions Citation Metrics

Full text article (PDF)

References

  1. D Maker Noob. (2018) 3D Printing in TPU - Tips and Tricks. 3D Maker Noob. [Video]. Available from: https://www.youtube.com/watch?v=ACRh-51hdBxo [Accessed 6th March 2024]
  2. DP.Lighting. (n.d.) Digital Light Processing (DLP). Available from: https://www.3dprinting.lighting/3d-printing-technologies/digital-light-processing/ [Accessed 6th March 2024]
  3. All3DP. (2023) 3D Printing Technology Guide: The 7 Main Types of 3D Printing Technology. Available from: https://all3dp.com/1/types-of-3d-printers-3d-printing-technology/#section-vat-polymerization [Accessed 6th March 2024]
  4. Ameralabs. (n.d.) Resin 3D printing troubleshooting: a comprehensive guide. Available from: https://ameralabs.com/blog/resin-3d-printing-troubleshooting-a-comprehensive-guide/ [Accessed 6th March 2024]
  5. AMFG. (2021) 5 Ways 3D Printing Can Benefit the Consumer Goods Industry. Available from: https://amfg.ai/2018/06/08/3d-printing-consumer-goods-industry-5-benefits/# [Accessed 6th March 2024]
  6. Avid Product Development. (2024) Unlocking Limitless Possibilities: The Incredible Benefits of 3D Printing. Available from: https://avidpd.com/knowledge-base/what-is-topology-and-why-optimize-it/ [Accessed 15th September 2024]
  7. Berman, B. (2012) 3-D printing: The new industrial revolution. Business Horizons. 55 (2), 155-162. Available from: doi: 10.1016/j.bushor.2011.11.003
  8. Chapiro, M. (2016) Current achievements and future outlook for composites in 3D printing. Reinforced Plastics. 60 (6), 372-375. Available from: doi: 10.1016/j.repl.2016.10.002
  9. Chaudhary, R., Fabbri, P., Leoni, E., Mazzanti, F., Akbari, R. & Antonini, C. (2023) Additive manufacturing by digital light processing: a review. Progress in Additive Manufacturing. 8, 331–351. Available from: doi: 10.1007/s40964-022-00336-0
  10. Dawood, A., Marti, B. & Sauret-Jackson, V. (2015) 3D printing in dentistry. British Dental Journal. 219, 521-529. Available from: doi: 10.1038/sj.bdj.2015.914
  11. Dizon, J. R. C., Espera, Jr. A. H., Chen, Q. & Advincula, R. C. (2018) Mechanical characterization of 3D-printed polymers. Additive Manufacturing. 20, 44-67. Available from: doi: 10.1016/j.addma.2017.12.002
  12. Faroze, F., Srivastava, V. & Batish, A. (2024) Modelling and prediction of mechanical properties of FFF-printed polycarbonate parts using ML and DA hybrid approach. Colloid and polymers science. 302 (12), 1891-1909. Available from: doi: 10.1007/s00396-024-05315-1
  13. FirmLabs. (2024a) Guide to Resin 3D Printers: SLA vs. DLP vs. MSLA vs. LCD. Available from: https://formlabs.com/blog/resin-3d-printer-comparison-sla-vs-dlp/ [Accessed 6th March 2024]
  14. FirmLabs. (2024b) Guide to Stereolithography (SLA) 3D Printing. Available from: https://formlabs.com/blog/ultimate-guide-to-stereolithography-sla-3d-printing/ [Accessed 6th March 2024]
  15. Gaikwad, S. R., Pawar, N. H. & Sapkal, S. U. (2022) Comparative evaluation of 3D printed components for deviations in dimensional and geometrical features. Materials Today: Proceedings. 59 (1), 297-304. Available from: doi: 10.1016/j.matpr.2021.11.157
  16. Govaert, L. E., van der Vegt, A. K. & van Drongelen, M. (2019) Polymers: From Structure to Properties. Delft Academic Press. Available from: https://ris.utwente.nl/ws/portalfiles/portal/301365831/Polymers_from_structure_to_properties.pdf [Accessed 6th March 2024]
  17. Jaycon. (2024) Top 15 Design software for 3D Printing. Available from: https://www.jaycon.com/top-15-design-software-for-3dprinting/ [Accessed 6th March 2024]
  18. Kuang, X., Chen, K., Dunn, C. K., Wu, J., Li, V. C. F. & Qi, H. J. (2018) 3D Printing of Highly Stretchable, Shape-Memory, and Self-Healing Elastomer toward Novel 4D Printing. ACS Applied Materials & Interfaces. 10 (8), 7381-7388. Available from: doi: 10.1021/acsami.7b18265
  19. Lasec group. (n.d.) 3D educational models. Available from: https://www.laseceducation.com/products/3d-education-models.html [Accessed 6th March 2024]
  20. Liaw, C-Y. & Guvendiren, M. (2017) Current and emerging applications of 3D printing in medicine. Biofabrication. 9 (2). Available from: doi: 10.1088/1758-5090/aa7279
  21. Low, Z., Chua, Y. T., Ray, B. M., Mattia, D., Metcalfe, I. S. & Patterson, D. A. (2017) Perspective on 3D printing of separation membranes and comparison to related unconventional fabrication techniques. Journal of Membrane Science. 523 (1), 596-613. Available from: doi: 10.1016/j.memsci.2016.10.006
  22. Macdonald, E. & Wicker, R. (2016) Multiprocess 3D printing for increasing component functionality. Science. 353 (6307). Available from: doi: 10.1126/science.aaf2093
  23. Nassar, H., Markellos, N., Navaraj, W. T. & Dahiva, R. (2018) Multi-Material 3D Printed Bendable Smart Sensing Structures. In: IEEE Sensors 2018 - Italian National Conference on Sensors, 28-31 October 2018, New Delhi, India. Piscataway, IEEE. Available from: doi: 10.1109/ICSENS.2018.8589625
  24. Ngo, T. D., Kashani, A., Imbalzano, G., Nguyen, K. T. Q. & Hui, D. (2018). Additive manufacturing (3D printing): A review of materials, methods, applications and challenges. Composites Part B: Engineering. 143, 172-196. Available from: doi: 10.1016/j.compositesb.2018.02.012
  25. Rieland, R. (2014) Forget the 3D Printer: 4D Printing Could Change Everything. Smithsonian Magazine. Available from: https://www.smithsonianmag.com/innovation/Objects-That-Change-Shape-On-Their-Own-180951449/ [Accessed 6th March 2024]
  26. Shahrubudin, N., Chuan, L. T. & Ramlan, R. (2019) An Overview on 3D Printing Technology: Technological, Materials, and Applications. In: The 2nd International Conference on Sustainable Materials Processing and Manufacturing, SMPM 2019, 8-10 March 2019, Sun City, South Africa. Amsterdam, Elsevier. pp. 1286-1296. Available from: doi: 10.1016/j.promfg.2019.06.089
  27. Shields, G. (2023) How to Design Snap Fit Joints for 3D Printing. PrintPool. Available from: https://www.printpool.co.uk/articles/how-to-design-snap-fitjoints-for-3d-printing [Accessed 6th March 2024]
  28. Stansbury, J. W. & Idacavage, M. J. (2016) 3D Printing with polymers: Challenges among expanding options and opportunities. Dental Materials. 32, 54-64. Available from: doi: 10.1016/j.dental.2015.09.018
  29. Tracey, T., Predeina, A. L., Krivoshapkina, E. F. & Kumacheva, E. (2022) A 3D printing approach to intelligent food packaging. Trends in Food Science & Technology. 127, 87-98. Available from: doi: 10.1016/j.tifs.2022.05.003
  30. Unifize. (n.d.) How to reduce product design & engineering cycle times by up to 75% in 30 days. Available from: https://www.unifize.com/blogs/how-to-reduce-product-design-engineering-cycle-times-byup-to-75-in-30-days [Accessed 6th March 2024]
  31. Vaira, Z. & Linkuvienė, D. (2013) Multimedijos technologijos. Klaipėda, College of Social Studies.
  32. Vaz, M. V. & Kumar, L. (2021) 3D Printing as a Promising Tool in Personalized Medicine. Journal of the American Association of Pharmaceutical Scientists. 22 (1). Available from: doi: 10.1208/s12249-020-01905-8
  33. Weitzer, A., Huth, M., Kothleitner, G. & Plank, H. (2022) Expanding FEBID-Based 3D-Nanoprinting toward Closed High Fidelity Nanoarchitectures. ACS Applied Electronic Materials. 4 (2), 744−754. Available from: doi: 10.1021/acsaelm.1c01133
  34. Wyss, J. (2019) Masked Stereolithography 3D Printing. Diyode. 29.
  35. Yao, H., Wang, J. & Mi, S. (2018) Photo Processing for Biomedical Hydrogels Design and Functionality: A Review. Polymers. 10 (1). Available from: doi: 10.3390/polym10010011
  36. Štaffová, M., Ondreáš, F., Svatík, J., Zbončák, M., Jančář, J. & Lepcio, P. (2022) 3D printing and post-curing optimization of photopolymerized structures: Basic concepts and effective tools for improved thermomechanical properties. Polymer testing. 108. Available from: doi: 10.1016/j.polymertesting.2022.107499

Similar Articles

<< < 5 6 7 8 9 10 11 12 13 14 > >> 

You may also start an advanced similarity search for this article.