Influence of Nd: YAG Laser Parameters on Tensile Behaviour, Microhardness and Surface Roughness of Ni-Cr Alloy for Dental Prostheses

K. Gurusami; Karibeeran Shanmuga Sundaram; R. Vijay

doi:10.4028/www.scientific.net/AMM.766-767.539

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 766-767Influence of Nd: YAG Laser Parameters on Tensile...

Influence of Nd: YAG Laser Parameters on Tensile Behaviour, Microhardness and Surface Roughness of Ni-Cr Alloy for Dental Prostheses

Abstract:

The paper presents the results of tensile behaviour, microhardness, surface roughness and microstructure of Ni-Cr alloy surface treated using high power Q-switched Nd: YAG laser has been studied. The major clinical disadvantage of the Ni – Cr is their lack of adequate ductility and yield strength. These properties combined made finishing, polishing and burnishing of conventional base metal alloys rather difficult. The dumbbell shaped tensile and cylindrical specimens of Ni-Cr were cast with a phosphate bonded investment material, using an induction melting centrifugal casting machine. The microhardness values of the surface melted layers increased as compared with Ni-Cr as - cast condition. The results of experiment showed that the surface treatment process has improved the % elongation, and surface roughness and microhardness as compared with as-cast. The improvement of the mechanical properties may be attributed due to grain refinement imparted by laser shock peening. The microstructure and changes in crystal orientation presented in the surface layer of the laser treated material were analyzed by optical, SEM as well as XRD. The chemical composition of laser treated surface was determined by EDAX attached along with SEM. Vickers microhardness was measured as per ASTM E384 11el standard test method. The data were compared using ANOVA and post hoc –Tukey test. In our present study, the laser shock peening process shows, a substantial increase in surface roughness from Ra = 0.440 μm before LSP treatment to 1.781 μm and surface hardness of Ni-Cr was achieved by 53.5% the base material hardness (i.e. from284 HV to 436 HV) and the mean values of % elongation of Ni-Cr alloy was higher (double) than that of after laser shock peening. The mean values of UTS, YS, modulus of elasticity of Ni-Cr were significantly lower after LSP. The experimental results showed that the mean values of percentage elongation of Ni-Cr increased by 200 % after LSP. It is evident from the above experimentation, increase of ductility of Ni-Cr alloy facilities workability which could produce a reliable removable partial denture (RPD) metal framework for dental prostheses.

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Periodical:

Applied Mechanics and Materials (Volumes 766-767)

Pages:

539-545

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.766-767.539

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Online since:

June 2015

Authors:

K. Gurusami*, Karibeeran Shanmuga Sundaram, R. Vijay

Keywords:

Laser Shock Peening, Microstructure, Nickel Chromium Alloy, Scanning Electron Microscopy, Surface Layer

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References

[1] American Dental Association. Guide to dental materials and devices specification n. 5 for Dental casting gold alloy. Chicago: American Dental Association, (1972).

DOI: 10.14219/jada.archive.1966.0055

Google Scholar

[2] Morris HF, Manz M. Stoffer W. Weir D. Casting alloys the materials and the clinical effects. Adv. Dent Res. Vol. 6: 28 -31, (1992).

DOI: 10.1177/08959374920060011101

Google Scholar

[3] Andre Rocha Pimenta, Marilia Garcia Diniz, Sidnei Paciornik, Carlos Antonio Freire Sampaio, Mauro Sayao de Miranda, Mechanical and Microstructural Properties of a nickel – chromium alloy after casting process, RSBO, 9910: 17 – 24, (2012).

DOI: 10.21726/rsbo.v9i1.960

Google Scholar

[4] H.F. Morris, M. Manz, W. Stoffer, and D. Weir, Casting alloys: the materials and clinical effects, Advances in Dental Research, vol. 6. 28 – 31, (1992).

DOI: 10.1177/08959374920060011101

Google Scholar

[5] Thomas A. Wight, Richard J. Grisius, R.W. Gaugler, Evaluation of three variables affecting the casting of base metal alloys. J. Prosthet Dent., 43: pp.415-418, (1980).

DOI: 10.1016/0022-3913(80)90212-7

Google Scholar

[6] Kenneth J. Anusavice, Charless F. DeFreest, Science of dental materials – Constitution of alloys. 10th ed. USA:W.B. Saunders company, 327 – 346, (1996).

Google Scholar

[7] Duncan, J.D., the casting accuracy of nickel p- chromium alloys for fixed prosthesis. J. Prosthet Dent., 47: p.63 – 68, (1982).

Google Scholar

[8] G.R. Baran, The metallurgy of Ni-Cr alloys for fixed prosthodontics, Journal of Prosthetic Dentistry, 50(5), 639 –650, (1983).

DOI: 10.1016/0022-3913(83)90201-9

Google Scholar

[9] J.P. Chu, Laser –shock processing effects on surface microstructure and Mechanical properties of low carbon steel, Materials Science and Engineering, A260, 260 –8, (1999).

DOI: 10.1016/s0921-5093(98)00889-2

Google Scholar

[10] Y.K. Zhang , Investigation of the surface qualities of laser shock processed zones and the effect on fatigue life of aluminium alloy, Surface and Coatings Technology, 92, 104 – 9, (1997).

DOI: 10.1016/s0257-8972(97)00009-1

Google Scholar

[11] J.E. Masse and G. Barreau, Laser generation of stress waves in metal, Surface and Coatings Technology, 70, 231- 4, (1995a).

DOI: 10.1016/0257-8972(95)80020-4

Google Scholar

[12] J.E. Masse and G. Barreau, Surface modification by laser induced shock waves, Surface Engineering, 11, 131 – 2, (1995b).

DOI: 10.1179/sur.1995.11.2.131

Google Scholar

[13] Sakino Yoshihiro, Ano Yuji and KIM you –chul, Residual Stress for structure and Fillet Weld Zone after Laser Peening, Transactions of JWRI, Vol. 36, 81 -86, (2007).

Google Scholar