Obtaining of ceramic materials by stereolithography method
UDC
66.017:666.7
DOI
10.18577/2307-6046-2023-0-9-79-89
Article PDF (Russian)
(726.23 KB)
How to cite
Turchenko M.V., Lebedeva Yu.E., Belyachenkov I.O., Prokofiev V.A. Obtaining of ceramic materials by stereolithography method // Proceedings of VIAM. 2023. No. 9. DOI: 10.18577/2307-6046-2023-0-9-79-89. URL: https://test.viam.ru/en/journal/2023/9/7
Keywords
stereolithography, ceramic materials, additive technologies, 3D printing, additive manufacturing, photocurable polymer
Abstract
The main advantages of additive technologies (AT) include the possibility of obtaining parts of a complex configuration of the external and internal structure, as well as the material utilization factor, which is close to unity. For example, traditional methods for producing products from ceramic materials cannot compete with AT in this parameter. In this review, the principle of the stereolithography method is considered, works are presented, the purpose of which is to obtain ceramic products of varying complexity by stereolithography, a description of the methods for obtaining ceramic paste, from which products are obtained.
Reference list
- Scheithauer U., Schwarzer E., Richter H.-J. et al. Thermoplastic 3D Printing – An Additive Manufacturing Method for Producing Dense Ceramics. International Journal of Applied Ceramic Technology, 2014, vol. 12, is. 1, pp. 1–6.
- Zhangwei Ch., Ziyong Li, Junjie Li et al. 3D printing of ceramics: a review. Journal of the European Ceramic Society, 2019, vol. 39, pp. 661–687.
- Deckers J., Vleugels J., Kruth J.-P. Additive Manufacturing of Ceramics: a review. Journal of Ceramic Science Technology, 2014, vol. 04, is. 05, pp. 245–260.
- Gibson J., Rosen D., Stacker B. Technology of additive manufacturing. 3D printing, rapid prototyping and direct digital manufacturing. Moscow: Technosfera, 2016, 83 p.
- Kruglov D.V., Pavlyukova N.L. Advantages and disadvantages of additive technologies. Energy-2019, 2019, vol. 4, pp. 65–66.
- Williams C.B. Design and development of a layer-based additive manufacturing process for the realization of metal parts of designed mesostructure: Dissertation. Georgia Institute of Technology, 2008, 390 p.
- Abouliatim Y., Chartier T., Abelard P. et al. Optical characterization of stereolithography alumina suspensions using the Kubelka–Munkmodel. Journal of the European Ceramic Society, 2009, vol. 29, is. 5, pp. 919–924.
- Badev A., Abouliatim Y., Chartier T. et al. Photopolymerization kinetics of a polyether acrylate in the presence of ceramic fillers used in stereolithography. Journal of Photochemistry and Photobiology A: Chemistry, 2011, vol. 222, is. 1, pp. 117–122.
- Smirnov A.V., Chugunov S.S., Tikhonov A.A. Development and research of methods for additive production of BaTiO3 ceramics using laser stereolithography processes. Perspective technologies and materials: materials of scientific and practical. conf. with international participation. Sevastopol: Sevastopol State Univ., 2020, pр. 182–185.
- Santoliquido O., Camerota F., Rosa A. et al. A novel device to simply 3D print bulk green ceramic components by stereolithography employing viscous slurries. Open Ceramics, 2021, vol. 5, p. 100089.
- Bae C.-J., Halloran J.W. Concentrated suspension-based additive manufacturing – viscosity, packing density, and segregation. Journal of European Ceramic Society, 2019, vol. 39, pp. 4299–4306.
- Xing H., Zou B., Lai Q. et al. Preparation and characterization of UV curable Al2O3 suspensions applying for stereolithography 3D printing ceramic microcomponent. Powder Technology, 2018, vol. 338, pp. 153–161.
- Xing H., Zou B., Liu X. et al. Effect of particle size distribution on the preparation of ZTA ceramic paste applying for stereolithography 3D printing. Powder Technology, 2020, vol. 359, pp. 314–322.
- Griffith M.L., Halloran J.W. Freeform fabrication of ceramics via stereolithography. Journal of American Ceramic Society, 1996, vol. 79, pp. 2601–2608.
- Wang Z., Huang C., Wang J. et al. Development of a novel aqueous hydroxyapatite suspension for stereolithography applied to bone tissue engineering. Ceramic International, 2019, vol. 45, pp. 3902–3909.
- Zhang S., Sha N., Zhao Z. Surface modification of α-Al2O3 with dicarboxylic acids for the preparation of UV-curable ceramic suspensions. Journal of European Ceramic Society, 2017, vol. 37, pp. 1607–1616.
- Deckers J., Wlugels J., Root J.-P. Additive manufacturing of ceramics: a review. Ceramic Science and Technology, 2014, vol. 5, no. 4, pp. 245–260.
- Klocke F., Derichs C., Ader C. et al. Investigations on laser sintering of ceramic slurries. Production Engineering, 2007, vol. 1, is. 3, pp. 279–284.
- Travitzky N., Bonet A., Dermeik B. et al. Additive manufacturing of ceramic-based materials. Advanced Engineering Materials, 2014, vol. 16, is. 6, pp.729–754.
- Tang H.H. Direct laser fusion to form ceramic parts. Rapid Prototyping Journal, 2002, vol. 8, is. 5, pp. 284–289.
- Krieger I.M., Dougherty T.J. A mechanism for non-Newtonian flow in suspensions of rigid spheres. Transaction of Society of Rheology, 1959, vol. 3, pp. 137–148.
- Camargo I.L., Mateus Mota Morais M.M. et al. A review on the rheological behavior and formulations of ceramic suspensions for vat photopolymerization. Ceramics International, 2021, vol. 47, pp. 11906–11921.
- Jie T., Xiaotian G., Haotian Ch. et al. The preparation of SiC ceramic photosensitive slurry for rapid stereolithography. Journal of the European Ceramic Society, 2021, vol. 41, is. 5, pp. 10115–10126.
- Guojiao D., Rujie H., Keqiang Zh. et al. Stereolithography 3D printing of SiC ceramic with potential for lightweight optical mirror. Ceramic International, 2020, vol. 46, is. 11, pp. 18785–18790.
- Kihm H., Yang H.S. Design optimization of a 1-m lightweight mirror for a space telescope. Optical Engineering, 2013, vol. 52, is. 9, pp. 1239–1246.
- Xing H., Zou B., Li Sh. et al. Study on surface quality, precision and mechanical properties of 3D printed ZrO2 ceramic components by laser scanning stereolithography. Ceramics International, 2017, vol. 43, is. 18, pp. 16340–16347.
- Sun J., Huang C., Wang J. et al. Mechanical properties and microstructure of ZrO2–TiN–Al2O3 composite ceramics. Materials Science and Engineering, 2006, vol. 416, is. 1, pp. 104–108.
- Evdokimov S.A., Shchegoleva N.E., Sorokin O.Yu. Ceramic materials aviation engineering (review). Trudy VIAM, 2018, no. 12 (72), paper no. 06. Available at: http://www.viam-works.ru (accessed: February 06, 2023). DOI: 10.18577/2307-6046-2018-0-12-54-61.
- Kuznetsov B.Yu., Sorokin O.Yu., Vaganova M.L., Osin I.V. Synthesis of model high-temperature ceramic matrices by the method of spark plasma sintering and the study of their properties for the production of composite materials. Aviacionnye materialy i tehnologii, 2018, no. 4 (53), pp. 37–44. DOI: 10.18577/2071-9140-2018-0-4-37-44.
- Zhitnyuk S.V. Oxygen-free ceramic materials for the space technics (review). Trudy VIAM, 2018, no. 8 (68), paper no. 08. Available at: http://www.viam-works.ru (accessed: February 06, 2023). DOI: 10.18577/2307-6046-2018-0-8-81-88.
- Kablov E.N., Karachevtsev F.N., Shilov A.L. et al. Thermodynamics and vaporization of ceramics based on the Gd2O3–ZrO2 and Gd2O3–HfO2 systems studied by kems. Journal of Alloys and Compounds, 2022, vol. 908, pp. 164575.
- Kablov E.N. Innovative developments of FSUE «VIAM» SSC of RF on realization of «Strategic directions of the development of materials and technologies of their processing for the period until 2030». Aviacionnye materialy i tehnologii, 2015, no. 1 (34), pp. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.
