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Microstructure and hardness of fixed dental prostheses manufactured by additive technologies

Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Purpose: The additive technologies characterize with building of one layer at a time from a powder or liquid that is bonded by means of melting, fusing or polymerization. The methods, mostly used in dentistry, include selective laser sintering, selective laser melting and 3D printing. The aim of the present paper is to investigate the microstructure and hardness of fixed dental prostheses produced by three different technologies. Design/methodology/approach: Four-part dental bridges were manufactured of Co-Cr alloy by standard lost-wax process, casting of 3D printed wax models and Selective Laser Melting (SLM). The microstructure was investigated by optical microscopy and SEM. EDX and EPMA analyses and Vickers microhardness measurements was done. Findings: It was established that the microstructure of cast samples is dense, inhomogeneous, consisting of large grains with dendrite morphology, while the microstructure of the SLM bridges is porous. Pores, elongated along the direction of the melted layers were observed. The microhardness investigations showed highest average hardness of the samples, produced by SLM (356HV-407HV), followed by the hardness of the samples, cast by 3D printed models (327HV-343HV) and these, manufactured by standard lost-wax process (251HV-274HV). The measurements along depth of the samples showed nearly even microhardness distribution in the bridges, produced by SLM, and fluctuations of the microhardness values along the depth of the cast bridges due to the inhomogeneous microstructure. Research limitations/implications: As the additive technologies for production of dental restorations from wax, polymers and metal alloys are developed last years, additional investigations are needed for development of more precise technological regimes. Originality/value: The comparison between the microstructure and hardness of dental prostheses made by lost-wax process and SLM reveals the peculiarities of the constructions produced by new technology.
Rocznik
Strony
60--69
Opis fizyczny
Bibliogr. 18 poz., rys.
Twórcy
autor
  • Faculty of Dental Medicine, Medical University of Varna, 55 Marin Drinov Str, 9002 Varna, Bulgaria
autor
  • Faculty of Dental Medicine, Medical University of Varna, 55 Marin Drinov Str, 9002 Varna, Bulgaria
autor
  • Medical College, Medical University of Varna, 55 Marin Drinov Str, 9002 Varna, Bulgaria
Bibliografia
  • [1] The Glossery of Prosthodontic Terms, http://www.academyofprosthodontics.org/_Library/ap_articles_download/GPT8.pdf.
  • [2] Ts. Dikova, Dental Materials Science, Lectures and laboratory classes notes, Part II, MU-Varna, Varna, 2014, 150.
  • [3] K.P. Gupta: The Co-Cr-Mo (Cobalt-Chromium-Molybdenum) System. Journal of Phase Equilibria and Diffusion 26/1 (2005) 87-92.
  • [4] M. Podrrez-Radziszewska, K. Haimann, W. Dudzinski, M. Morawska-Soltysik, Characteristic of intermetallic phases in cast dental CoCrMo alloy, Archives of Foundry Engineering 10/3 (2010) 51-59.
  • [5] P. Crook, Metals handbook. Nonferrous alloys and special-purpose materials. 1990, Ohio American Society for Metals: ASM International: Materials Park. 447.
  • [6] G. Bellefontaine, The corrosion of CoCrMo alloys for biomedical applications, MSc thesis, School of Metallurgy and Materials, University of Birmingham, 2010.
  • [7] Sh. Kurosu, N. Nomura, A. Chiba, Effect of sigma phase in Co-29Cr-6Mo alloy on corrosion behavior in saline solution, Materials Transaction 47/8 (2006) 1961-1964.
  • [8] R. van Noort, The future of dental devices is digital, Dental Materials 28 (2012) 3-12.
  • [9] K. Torabi, E. Farjood, Sh. Hamedani, Rapid Prototyping Technologies and their Applications in Prosthodontics, a Review of Literature. J Dent Shiraz Univ Med Sci.,2015 March; 16/1 1-9.
  • [10] Ts. Dikova, N. Panova, M. Simov, Application of Laser Technologies in Dental Prosthetics, Int. Journal “Machines, Technologies, Materials”. 2011; 6: 32-35. http://mech-ing.com/journal/6-2011.html ;
  • [11] S.M. Gaytan, L.E. Murr, E. Martinez, et al. Comparison of microstructures and mechanical properties of solid and mesh cobalt-base alloy prototypes fabricated by electron beam melting, Metall. Mater. Trans. A 41 (2010) 3216-3227.
  • [12] C.G. Meacock, R. Vilar, Structure and properties of a biomedical Co–Cr–Mo alloy produced by laser powder microdeposition, J. Laser Appl. 21 (2009) 88-95.
  • [13] G. Barucca, E. Santecchia, G. Majni et al., Structural characterization of biomedical Co-Cr-Mo components produced by direct metal laser sintering, Materials Science and Engineering C 48 (2015) 263-269.
  • [14] Yanjin Lu, Songquan Wu, Yiliang Gan, Li Junlei Chaoqian Zhao, Dongxian Zhuo, Investigation on the microstructure, mechanical property and corrosion behavior of the selective laser melted CoCrW alloy for dental application, Materials Science and Engineering C 49 (2015) 517-525.
  • [15] H. Minouei, M.H. Fathi, M. Meratin, H. Ghazvinizadeh, Heat treatment of cobalt-base alloy surgical implants with hydroxyapatite-bioglass for surface bioactivation, Iranian Journal of Materials Science & Engineering 9/3 (2012) 33-39.
  • [16] Y. Bedolla-Gil, A. Juarez-Hernandez, A. Perez-Unzueta, E. Garcia-Sanchez, R.D Mercado-Solis, M.A.L. Hernandez- Rodriguez, Influence of heat treatments on mechanical properties of a biocompatibility alloy ASTM F75, Revista Mexicana De Fisica S 55/1 1-5.
  • [17] D. Stavrev, Ts. Dikova., Vl. Shtarbakov, M. Milkov, Laser Surface Melting of Austenitic Cr-Ni Stainless Steel, Advanced Materials Research 264-265 (2011) 1287-1292.
  • [18] Sh. Kurosu, N. Nomura, A. Chiba, Effect of sigma phase in Co-29Cr-6Mo alloy on corrosion behavior in saline solution, Materials Transaction 47/8 (2006) 1961-1964.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-eca60119-7656-4e55-bab5-bc88cb25c405
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