Tribological Characteristic of Titanium Alloy Surface Layers Produced by Diode Laser Gas Nitriding

• Autorzy: Lisiecki A. , Piwnik J.

Identyfikatory

DOI

10.1515/amm-2016-0094

• Języki publikacji: EN

Abstrakty

EN

In order to improve the tribological properties of titanium alloy Ti₆Al₄V composite surface layers Ti/TiN were produced during laser surface gas nitriding by means of a novel high power direct diode laser with unique characteristics of the laser beam and a rectangular beam spot. Microstructure, surface topography and microhardness distribution across the surface layers were analyzed. Ball-on-disk tests were performed to evaluate and compare the wear and friction characteristics of surface layers nitrided at different process parameters, base metal of titanium alloy Ti₆Al₄V and also the commercially pure titanium. Results showed that under dry sliding condition the commercially pure titanium samples have the highest coefficient of friction about 0.45, compared to 0.36 of titanium alloy Ti₆Al₄V and 0.1-0.13 in a case of the laser gas nitrided surface layers. The volume loss of Ti6Al4V samples under such conditions is twice lower than in a case of pure titanium. On the other hand the composite surface layer characterized by the highest wear resistance showed almost 21 times lower volume loss during the ball-on-disk test, compared to Ti₆Al₄V samples.

Słowa kluczowe

EN

titanium alloys; laser gas nitriding; surface layer; wear resistance; ball-on-disk

• Wydawca: Institute of Metallurgy and Materials Science of Polish Academy of Sciences ; Committee of Materials Engineering and Metallurgy of Polish Academy of Sciences
• Czasopismo: Archives of Metallurgy and Materials
• Rocznik: 2016
• Tom: Vol. 61, iss. 2A
• Strony: 543--552
• Opis fizyczny: Bibliogr. 38 poz., rys.

Twórcy

autor

Lisiecki A.

• Silesian University of Technology, Facult y of Mechanical Engineering, Welding Department, 18 A Konarskiego Str., 44-100 Gliwice, Poland

autor

Piwnik J.

• Bialystok University of Technology, Mechanical Faculty, 45C Wiejska Str., 16-351 Białystok, Poland

Bibliografia

• [1] A. Lisiecki, Titanium Matrix Composite Ti/TiN Produced by Diode Laser Gas Nitriding, Metals 5(1), 54-69 (2015), doi:10.3390/met5010054.
• [2] A. Lisiecki, Mechanism of Laser Surface Modification of the Ti-6Al-4V Alloy in nitrogen atmosphere using a High Power Diode Laser, Advanced Materials Research 1036, 411-416 (2014), doi:10.4028/www.scientific.net/AMR.1036.411
• [3] M. Mubarak, Influence of plasma nitriding on fretting wear behaviour of Ti-6Al-4V, Trib. Inter. 43, 152-160 (2010).
• [4] Y u-Chi Lin et al., The effect of different methods to add nitrogen to titanium alloys on the properties of titanium nitride clad layers, Mater. Des. 54, 222-229 (2014).
• [5] S. Katayama, et al., Surface hardening of titanium by laser nitriding. In Proceedings of the ICALEO’83, Los Angeles, CA, USA, pp. 127-134. 14-17 November 1983.
• [6] A. Lisiecki, Welding of titanium alloy by Disk laser, Proceedings of SPIE, Laser Technology 2012: Application of Lasers, 8703 (2013), DOI:10.1117/12.2013431.
• [7] D. Janicki, High Power Diode Laser Cladding of Wear Resistant Metal Matrix Composite Coatings, Sol. St. Phenomena, Mechatronic Systems and Materials V, 199, 587-592 (2013).
• [8] L. A. Dobrzanski, M. Bonek. A. Klimpel, A. Lisiecki, Surfacelayer's structure of X40CrMoV5-1 steel remelted and/or WC alloyed with HPDL laser, Advanced Materials Processing II, Materials Science Forum, 437-4, 69-72 (2003).
• [9] G. Moskal, A. Grabowski, A. Lisiecki, Laser remelting of silicide coatings on Mo and TZM alloy, Sol. St. Phenomena 226, 121-126 (2015). DOI :10.4028/www.scientific.net/ SSP.226.121
• [10] M. Bonek, L. A. Dobrzański, Characterization performance of laser melted commercial tool steels, Mat. Sci. Forum 654-656, 1848-1851 (2010).
• [11] A. Klimpel, L. A. Dobrzanski, D. Janicki, A. Lisiecki, Abrasion resistance of GMA metal cored wires surfaced deposits, J. Mat. Proc. Tech. 164, 1056-1061 (2005) doi: 10.1016/j. jmatprotec.2005.02.242.
• [12] T. Węgrzyn, J. Piwnik, B. Łazarz, D. Hadryś, Main micro-jet cooling gases for steel welding, Arch. Metall. Mater. 58(2), 555-557 (2013).
• [13] T. Węgrzyn, J. Mirosławski, A. Silva, D. Pinto, M. Miro s, Oxide inclusions in steel welds of car body, Mat. Sci. Forum 6, 585-591 (2010).
• [14] A. Kurc-Lisiecka, W. Ozgowicz, W. Ratuszek, J. Kowalska: Analysis of Deformation Texture in AISI 304 Steel Sheets, Sol. St. Phenomena 203-204, 105-110 (2013).
• [15] J. Jezierski, K. Janerka, Parameters of a Gas-Solids Jet in Pneumatic Powder Injection into Liquid Alloys with a Non- Submerged Lance, Metalurgija 54(2), 365-367 (2015).
• [16] W. Sitek, L.A. Dobrzański, Comparison of hardenability calculation methods of the heat-treatable constructional steels, J. Mat. Proc. Tech. 64(1-3), 117-126 (1995).
• [17] T. Węgrzyn, J. Piwnik, D. Hadryś. Oxygen in steel WMD after welding with micro-jet cooling, Arch. Metall. Mater. 58(4), 1067-1070 (2013).
• [18] B. Oleksiak, G. Siwiec, A. Blacha-Grzechnik, J. Wieczorek, The obtained of concentrates containing precious metals for pyrometallurgical processing, Metalurgija 53(4), 605-608 (2014).
• [19] J. Górka, Analysis of simulated welding thermal cycles S700MC using a thermal imaging camera, Adv. Mat. Res. ISI Proceedings 837, 375-380 (2014).
• [20] G. Golański, J. Słania, Effect of different heat treatments on microstructure and mechanical properties of the martensitic GX12CrMoVNbN9-1 cast steel, Arch. Metall. Mater. 58(1), 25-30 (2013).
• [21] G. Golański, P. Gawień, J. Słania, Examination of Coil Pipe Butt Joint Made of 7CrMoVTib10 - 10(T24) Steel After Service, Arch. Metall. Mater. 57(2), 1067-1070 (2012).
• [22] L. Blacha, J. Mizera, P. Folega, The effects of mass transfer in the liquid phase on the rate of aluminium evaporation from the Ti-6Al-7Nb alloy, Metalurgija 53(1), 51-54 (2014).
• [23] T. Węgrzyn, J. Piwnik, Low alloy steel welding with micro-jet cooling, Arch. Metall. Mater. 57(2), 539-543 (2012).
• [24] B. Oleksiak, M. Koziol, J. Wieczorek, M. Krupa, P. Folę g a, Strength of briquettes made of cu concentrate and carbonbearing materials, Metalurgija 54(1), 95-97 (2015).
• [25] G. Golański, J. Jasak, J. Słania, Microstructure, properties and welding of T24 steel - critical review, Kovove Materialy 52, 99-106 (2014).
• [26] R. Burdzik, Ł. Konieczny, Research on structure, propagation and exposure to general vibration in passenger car for different damping parameters, J. of Vibroengineering 15(4), 1680-1688 (2013).
• [27] W. Tarasiuk, B. Szczucka-Lasota, J. Piwnik, W. Majewski, Tribological Properties of Super Field Weld with Micro-Jet Process, Adv. Mat. Res. 1036, 452-457 (2014).
• [28] D. Janicki, High Power Diode Laser Cladding of Wear Resistant Metal Matrix Composite Coatings, Solid State Phenomena, Volume: Mechatronic Systems and Materials V, 587-594 (2013).
• [29] R. Burdzik, Ł. Konieczny, T. Figlus, Activities of Transport Telematics, Book Series: Communications in Computer and Information Science 395, 418-425 (2013).
• [30] R. Burdzik, Research on the influence of engine rotational speed to the vibration penetration into the driver via feet - multidimensional analysis, J. of Vibroengineering 15(4), 2114-2123 (2013).
• [31] R. Burdzik, Z. Stanik, J. Warczek, Method of assessing the impact of material properties on the propagation of vibrations excited with a single force impulse, Arch. Metall. Mater. 57(2), 409-416 (2012).
• [32] J. Bodzenta, A. Kaźmierczak, T. Kruczek, Analysis of thermograms based on FFT algorithm, Journal de Physique IV 129, 201-206 (2005).
• [33] A. Grajcar, M. Różański, S . Stano, A . Kowalski, B. Grzegorczyk, Effect of Heat Input on Microstructure and Hardness Distribution of Laser Welded Si-Al TRIP-Type Steel, Adv. in Mat. Sci. and Eng. 2014 (2014),
• [34] A. Grajcar, M. Różański, S. Stano, A. Kowalski, Microstructure characterization of laser-welded Nb-microalloyed siliconaluminum TRIP steel, Journal of Materials Engineering and Performance 23(9), 3400-3406 (2014).
• [35] M. Kulka, D. Panfil, J. Michalski, P. Wach, The effects of laser surface modification on the microstructure and properties of gas-nitrided 42CrMo4 steel, Optics and Laser Technology 82, 203-219 (2016).
• [36] A. Grabowski, et al., Optical and conductive properties of AlSialloy/SiCp composites: application in modeling CO2 laser processing of composites, Optics and Lasers in Engineering 43, 233-246 (2005).
• [37] H. Bąkowski, A. Posmyk, J. Krawczyk, Tribological properties of rail steel in straight moderately loaded section of railway trucks. Archives of Metallurgy and Materials. 56 (3) 813-822, (2011).
• [38] A. Posmyk, H. Bąkowski, Wear mechanism of cast iron piston ring/aluminum matrix composite cylinder liner. Tribology Transactions, 56 (5), 806-815 (2013). DOI: 10.1080/10402004.2013.798878.