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Initiation and tolerance of macro-damage of first ply (FBF) in a process of damaging of hybrid multi-ply structures due to reinforcement architecture

Autorzy
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The objective of this paper was study and analysis of damaging process of multi-ply structure applied in dentistry. The aim was to analyze and experimentally evaluate tolerance of macro-damage of first ply (FPF - first ply failure) of multi-ply composite. A studied structure of composite makes a carrying structure for dental applications e.g. adhesive bridges. Influence of reinforcement structure on the residual carrying capacity of the studied multi-ply materials has been demonstrated. It has been shown that the type of fiber and fiber ribbon architecture play a major role in strength of studied reinforcements. Structures included in the study differ by the moment of macro-damage occurrence, carrying capacity and residual stiffness.
Rocznik
Strony
77--91
Opis fizyczny
Bibliogr. 38 poz., rys., wykr., tab.
Twórcy
autor
  • University of Economics and Innovation in Lublin, Faculty of Transport and Computer Science, Mechanical Engineering Section, 20-209 Lublin, Projektowa 4 Street, Poland
Bibliografia
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  • 5. Karbhari V.M., Strassler H., Effect of fiber architecture on flexural characteristics and fracture of fiber-reinforced dental composites. Dental Materials, 23(8) (2007).
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  • 8. Ferracene J.L., Palin W.M. Effects of particulate filler systems on the properties and performance of dental polymer composites [In] Non-Metallic Biomaterials for Tooth Repair and Replacement, [Ed] P. Vallittu, Woodhead Publishing, Cambridge 2013.
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  • 18. Imielińska K., Wojtyra R.: Wpływ absorpcji wody na właściwości laminatów winyloestrowych wzmocnionych włóknem aramidowym i szklanym. Kompozyty (Composites), 3(7) (2003), in Polish.
  • 19. Lung C.Y., Sarfraz Z., Habib A., Khan A.S., Matinlinna J.P.: Effect of silanization of hydroxyapatite fillers on physical and mechanical properties of a bis-GMA based resin composite. Journal of the Mechanical Behavior of Biomedical Materials, 54 (2016).
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  • 23. ISO 4049:2009 Dentistry - Polymer - based restorative materials.
  • 24. Karbhari V.M., Strassler H., Effect of fiber architecture on flexural characteristics and fracture of fiber-reinforced dental composites. Dental Materials, 23(8) (2007).
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  • 32. LLoyd C.H., The fracture toughness of dental composites. Journal of Oral Rehabilitation, 11(4) (1984).
  • 33. Fani M., Farmani S., Bagheri R., Fracture toughness of resin composite under different modes and media: review of articles. Journal of Dental Biomaterials, 2(3) (2015).
  • 34. Hamouda I.M., Hagag E.A., Evaluation the mechanical properties of nanofiled composite resin restortive material. Journal of Biomaterials and Nanobiotechnology, 3(3) (2012).
  • 35. Soderholm K.J., Fracture of dental materials, [In] Applied Fracture Mechanics, [Ed] Belov A. InTech, 2012.
  • 36. Bełzowski A., Stasieńko J., Ziółkowski B., Kamińska A., Niektóre kryteria akceptacji defektów w kompozytach na przykładzie laminatu ciętego strumieniem wody. Kompozyty (Composites), 4(12) (2004), in Polish.
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  • 38. Dyzia M., Dolata A.,J., Śleziona J., Preliminary Analysis of Aluminum Matrix Compositions for Composites Reinforcement with Carbon Fibers, Steel Research International, 83(10), 2012.
Uwagi
PL
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-c9d6b373-06b8-43dd-8b8d-b73fa46e0959
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