EXTRUSION, DEBINDING AND SINTERING OF A COMMERCIAL PURE TITANIUM INK FOR ROBOCASTING

1 KASHIMBETOVA Adelia
Co-authors:
1 TKACHENKO Serhii 1 SLÁMEČKA Karel 1 REMEŠOVÁ Michaela 1 KLAKURKOVÁ Lenka 1 PAVLOUŠKOVÁ Zina 1 ČELKO Ladislav 1 MONTUFAR Edgar B.
Institution:
1 CEITEC - Brno University of Technology, Brno, Czech Republic, EU, kashimbetova@vutbr.cz, eb.montufar@ceitec.vutbr.cz
Conference:
30th Anniversary International Conference on Metallurgy and Materials, Brno, Czech Republic, EU, May 26 - 28, 2021
Proceedings:
Proceedings 30th Anniversary International Conference on Metallurgy and Materials
Pages:
1215-1221
ISBN:
978-80-87294-99-4
ISSN:
2694-9296
Published:
15th September 2021
Proceedings of the conference have already been published in Scopus and we are waiting for evaluation and potential indexing in Web of Science.
Metrics:
767 views / 401 downloads
Abstract

Among additive manufacturing technologies, robocasting emerges as a versatile and an affordable method for processing metallic materials. However, the success and competitiveness of robocasting depend on the development of easy-to-process metallic inks that do not generate residues after debinding and production of high purity metallic parts. The additive manufacturing of titanium is in particular attractive and challenging. Titanium is a high-performance material with high specific mechanical strength, high fracture toughness, low elastic modulus, and high corrosion resistance with important applications in aerospace, marine, medical, alimentary, energy, recreational, and chemical industries. It is difficult to process titanium due to its high reactivity with oxygen and other elements that leads to the formation of oxides and brittle inclusions that impair the mechanical performance. The aim of this study is to understand the extrusion behaviour of a titanium ink and the debinding at different temperatures to obtain carbide- and oxide-free commercially pure titanium structures by robocasting. The results show that the ink meets all rheological requirements for robocasting allowing the fabrication of a variety of different titanium structures with a maximal unsupported span of 2 mm. Furthermore, the optimization of the debinding process avoided the thermal oxidation of titanium while maximised the elimination of the binder, showing superior efficiency than other binders studied previously. The microstructure and chemical analysis of the sintered samples confirmed the chemical and crystalline purity of the material.

Keywords: Additive manufacturing, robocasting, titanium, debinding, sintering

© This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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