PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
Tytuł artykułu

The influence of prosthetic elements manufacturing technology on properties and microstructure shaping Co-Cr-Mo alloys

Treść / Zawartość
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The presented publication discusses the test results regarding samples of a prosthetic alloy from the Co-Cr-Mo system. The test samples were obtained by means of two different methods applied in prosthetics laboratories to compare their properties and microstructure. To obtain the samples via the traditional lost wax casting method, the cast alloy Co-Cr-Mo was used, commercially known as Wironit LA. In the case of the modern technique DMLS (Direct Metal Laser Sintering), metallic powder Co-Cr-Mo, called EOS Cobalt Chrome MP1, was used. The samples of both Co-Cr-Mo alloys obtained via the two methods were prepared for metallographic tests; they also underwent microstructural observations with the use of light microscopy (LM) and scanning electron microscopy (SEM), and next they were subjected to hardness tests. The obtained samples demonstrated a dendritic structure. In the samples cast with the lost wax casting method, a segregation of the chemical composition was revealed. The samples obtained by means of the DLMS method were characterized by chemical composition homogeneity. The hardness measurements with the statistical analysis of the measurement results showed a difference between the examined alloys. On the basis of the performed studies, it was stated that the applied methods of manufacturing prosthetic elements make it possible to obtain diversified microstructural and mechanical properties of the alloys. The hardness value significantly affects the subsequent mechanical and finishing treatment of prosthetic elements, such as metal bases of crown caps, bridges, mobile prostheses or other retention elements.
Rocznik
Strony
24--31
Opis fizyczny
Bibliogr. 38 poz., rys., tab., zdj.
Twórcy
  • AGH University of Science and Technology, Faculty of Metals Engineering and Industrial Computer Science, Department of Physical and Powder Metallurgy, Mickiewicza Av. 30, 30-059 Krakow, Poland
  • Silesian University of Technology, Faculty of Materials Engineering, Department of Advanced Materials and Technologies, Krasinskiego Str. 8, 40-019 Katowice, Poland
Bibliografia
  • [1] Cervino G., Fiorillo L., Vladimirovna Arzukanyan A., Spagnuolo G., Cicciù M.: Dental Restorative Digital Workflow: Digital Smile Design from Aesthetic to Function. Dentistry Journal 7(30) (2019) 1-12.
  • [2] Kashapov R.N., Korobkina A.I., Platonov E.V., Saleeva G.T.: The method of manufacture of nylon dental partially removable prosthesis using additive technologies. IOP Conf. Series: Materials Science and Engineering 69 (2014) 1-4.
  • [3] Bilgin M.S., Baytaroğlu E.N., Erdem A., Dilber E.: A review of computer-aided design/computer-aided manufacture techniques for removable denture fabrication. European Journal of Dentistry 10(2) (2016) 286-291.
  • [4] Marciniak J., Kaczmarek M., Ziębowicz A.: Biomaterials in Dentistry, Publisher Silesian University of Technology, Gliwice 2008 (in Polish).
  • [5] Hin T.S.: Engineering Materials for Biomedical Applications. Biomaterials Engineering and Processing Series Vol. 1. World Scientific Publishing Company, Singapore 2004.
  • [6] Augustyn-Pieniążek J., Łukaszczyk A., Zapała R.: Microstructure and corrosion resistance characteristics of Co-Cr-Mo alloys designed for prosthetic materials. Archives of Metallurgy and Materials 58 (2013) 1281-1285.
  • [7] Surowska B.: Metallic biomaterials and the combination metal - ceramics in dental applications, Publishing College, Lublin 2009 (in Polish).
  • [8] Song B., Zhao X., Li S., Han Ch., Wei Q., Wen S., Liu J., Shi Y.: Differences in microstructure and properties between selective laser melting and traditional manufacturing for fabrication of metal parts: A review. Frontiers of Mechanical Engineering 10 (2015) 111-125.
  • [9] Xiang D.D., Wang b P., Tan X.P., Chandra S., Wang C., Nai M.L.S., Tor S.B., Liu W.Q., Liu E.: Anisotropic microstructure and mechanical properties of additively manufactured Co–Cr–Mo alloy using selective electron beam melting for orthopedic implants. Materials Science and Engineering: A Vol. 765 (2019) 138270.
  • [10] Barucca G., Santeccchia E., Majni G., Girardin E., Bassoli E., Denti L., Gatto A., Iuliano L., Moskalewicz T., Megucci P.: Structural characterization of biomedical Co–Cr–Mo components produced by direct metal laser sintering. Materials Science and Engineering: C 48 (2015) 263-269.
  • [11] Podrez-Radziszewska M., Haimann K., Dudziński W., Morawska- Sołtysik M.: Characteristic of intermetallic phases in cast dental CoCrMo alloy. Archives of Foundry Engineering 10(3) (2010) 51-56.
  • [12] Zhou Y., Li N., Yan J., Zeng Q.: Comparative analysis of the microstructures and mechanical properties of Co-Cr dental alloys fabricated by different methods. The Journal of Prosthetic Dentistry 120(4) (2018) 617-623.
  • [13] Loch J., Krzykała A., Łukaszczyk A., Augustyn-Pieniążek J.: Corrosion resistance and microstructure of recasting cobalt alloys used in dental prosthetics. Archives of Foundry Engineering 17(2) (2017) 63-68.
  • [14] Augustyn-Pieniążek J., Kurtyka P., Sulima I., Stopka S.: Properties and tribological wear of materials used in dental prosthetics Co-Cr-Mo and Co-Cr-Mo-W alloys. Archives of Metallurgy and Materials 60(3A) (2015) 1569-1574.
  • [15] Augustyn-Nadzieja J., Frocisz Ł., Krawczyk J., Pańcikiewicz K.: Analysis of properties and tribological wear of the Co−Cr alloys used for prosthetic constructions. Tribology: theory and practice 287(5) (2019) 5-12.
  • [16] Örtorp A., Jönsson D., Mouhsen A., Vult von Steyern P.: The fit of cobalt–chromium three-unit fixed dental prostheses fabricated with four different techniques: A comparative in vitro study. Dental Materials 27(4) (2011) 356-363.
  • [17] Zhou Y., Li N., Yan J., Zeng Q.: Comparative analysis of the microstructures and mechanical properties of Co-Cr dental alloys fabricated by different methods. The Journal of Prosthetic Dentistry 120(4) (2018) 617-623.
  • [18] Szala M., Beer-Lech K., Gancarczyk K., Kilic O., Pędrak P., Özer A., Skic A.: Microstructural characterization of Co-Cr-Mo casting dental alloys. Advances in Science and Technology Research Journal 11(4) (2017) 76-82.
  • [19] Padrós R., Punset M., Molmeneu M., Velasco A. B., Herrero- -Climent M., Rupérez E., Gil F.J.: Mechanical Properties of CoCr Dental-Prosthesis Restorations Made by Three Manufacturing Processes. Influence of the Microstructure and Topography. Metals 10(6) (2020) 788-806.
  • [20] Ciaputa T., Ciaputa A.: Basics of prosthetic work, permanent work, frame dentures, combined work, Publishing house Elamed, Katowice 2009 (in Polish).
  • [21] Pietruski J.K., Pietruska M.D.: Materials and technologies used in modern prosthetics - advantages and disadvantages presented on the basis of a review of the literature and own experience. Aesthetic dentistry 9(3) (2013) 89-99 (in Polish).
  • [22] Hajduga M., Aplikowska I.: Influence of pouring temperature on structural defects of metallic prosthetic restorations. Arts and Crafts part II (2011) 239-246 (in Polish).
  • [23] Craig R., Powers J.M., Wataha J.W.: Dental materials. Medical Publishing House Urban & Partner, Wrocław 2000 (in Polish).
  • [24] Siemiński P., Budzik G.: Additive techniques Printing, 3D printers. Publishing House of the Warsaw University of Technology, Warsaw 2015 (in Polish).
  • [25] https://cadxpert.pl/technologie-druku-3d/technologia-dmls/
  • [26] https://drukarki3d.pl/oferta/dmls/
  • [27] Majewski S., Pryliński M.: Materials and technologies of modern dental prosthetics, Publishing house Czelej, Lublin 2013 (in Polish).
  • [28] Rumińska M., Zarzecka J.: Contemporary prosthetic restorations of teeth, after root canal treatment - review of literature. Implant prosthetics 8/3 (2007) 33-36.
  • [29] https://dental.pl/produkt/wironit-la/
  • [30] https://drukarki3d.pl/wp-content/uploads/2020/09/eos_cobaltchrome_ mp1_en.pdf
  • [31] Świeczko-Żurek B., Zieliński A., Ossowska A., Sobieszczyk S.: Biomaterials. Gdansk University of Technology, Gdańsk 2011 (in Polish).
  • [32] Giacchi J.V., Morando C.N., Fornaro O., Palacio A.H.: Microstructural characterization of as-cast biocompatible Co-Cr-Mo alloys. Materials Characterization 62/1 (2011) 53-61.
  • [33] Mendes S.N.P., Lins J.F.C., Mendes P.S.N., Prudente W.R., Siqueira R.P., Pereira R.E., Rocha S.M.S., Leoni A.R.: Microstructural Characterization of Co-Cr-Mo-W Alloy as Casting for Odontological Application. International Journal of Engineering Research and Application 7/3 (2017) 34-37.
  • [34] Park J.B., Jung K-H., Kim K.M., Lee J-II., Ryu J.H.: Microstructure of As-cast Co-Cr-Mo Alloy Prepared by Investment Casting. Journal of the Korean Physical Society 72 (2018) 947-951.
  • [35] Karpiński R., Walczak M., Śliwa J.: Tribological studies of cobalt alloys used as biomaterials. Journal of Technology and Exploitation in Mechanical Engineering 1/1 (2015) 17-32.
  • [36] Mazurkiewicz A., Poprzeczka A.: Assessment of the quality of layers applied by laser metal deposition in LDT powder. Coaches 6 (2018) 591-596 (in Polish).
  • [37] Wyszyński D., Chuchro M.: Manufacturing metal elements using the DMLS method, Institute of Advanced Manufacturing Technologies, VIII Forum ProCAx, Sosnowiec 2009 (in Polish).
  • [38] Maliński M.: Selected problems of mathematical statistics in Excel and the Statistica Package, Publishing house of the Silesian University of Technology, Gliwice 2015 (in Polish).
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-10379d03-7e11-449a-9c18-234463e06d34
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.