Karakterizacija prevlake 316L nanete postupkom plazma navarivanja
Article Sidebar
Main Article Content
Abstract
Article Details
Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution License that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
Authors grant to the Publisher the following rights to the manuscript, including any supplemental material, and any parts, extracts or elements thereof:
- the right to reproduce and distribute the Manuscript in printed form, including print-on-demand;
- the right to produce prepublications, reprints, and special editions of the Manuscript;
- the right to translate the Manuscript into other languages;
- the right to reproduce the Manuscript using photomechanical or similar means including, but not limited to photocopy, and the right to distribute these reproductions;
- the right to reproduce and distribute the Manuscript electronically or optically on any and all data carriers or storage media – especially in machine readable/digitalized form on data carriers such as hard drive, CD-Rom, DVD, Blu-ray Disc (BD), Mini-Disk, data tape – and the right to reproduce and distribute the Article via these data carriers;
- the right to store the Manuscript in databases, including online databases, and the right of transmission of the Manuscript in all technical systems and modes;
- the right to make the Manuscript available to the public or to closed user groups on individual demand, for use on monitors or other readers (including e-books), and in printable form for the user, either via the internet, other online services, or via internal or external networks.
How to Cite
References
Levy AV, Crook P. The erosion properties of alloys for the chemical processing industries. Wear. 1991; 151: 337-350.
Andrews DR, Field JE. Temparature dependence of the impact response of copper: erosin by melting. J Phys D Appl Phys. 1982; 15:2357-2367.
Tilly GP. Erosion Caused by Impact of Solid Particles. in: Scott D, ed. Treatise on Materials Science and Technology. vol. 13: Wear. New York, Academic Press; 1979:287-320.
Bousser E, Martinu L, Klemberg-Sapieha JE. Effect of erodent properties on the solid particle erosion mechanisms of brittle materials. J Mater Sci. 2013; 48: 5543-5558.
Maasberg JA, Levy AV. Erosion of elevated-temperature corrosion scales on metals. Wear. 1981; 73: 355-70.
Islam MdA, Farhat ZN. Effect of impact angle and velocity on erosion of API x42 pipeline steel under high abrasive feed rate. Wear. 2014; 311: 180-190.
Gat N, Tabakoff W. Some effects of temperature on the erosion of metals. Wear. 1978; 50: 85-94.
Sundararajan G, Roy M. Solid particle erosion behaviour of metallic materials at room and elevated temperatures. Tribol Int. 1997; 30: 339-359.
López D, Congote JP, Cano JR, Toro A, Tschiptschin AP. Effect of particle velocity and impact angle on the corrosion-erosion of AISI 304 and AISI 420 stainless steels. Wear. 2005; 259: 118-124.
Lindsley BA, Marder AR. The effect of velocity on the solid particle erosion rate of alloys. Wear. 1999; 225-229: 510-516.
Manisekaran T, Kamaraj M, Sharrif SM, Joshi SV. Slurry erosion studies on surface modified 13Cr-4Ni steel: effect of angle of impingement and particle size. J Mater Eng Perform. 2007; 16: 567-572.
Oka YI, Ohnogi H, Hosokawa T, Matsumura M. The impact angle dependence of erosion damage caused by solid particle impact. Wear. 1997; 203-204: 573-579.
Al-Bukhaiti MA, Ahmed SM, Badran FMF, Emara KM. Effect of impingement angle on slurry erosion behaviour and mechanisms of 1017 steel and high-chromium white cast iron. Wear. 2007; 262: 1187-1198.
Fauchais PL, Heberlein JVR, Boulos MI. Thermal Spray Fundamentals — From Powder to Part. New York, Springer, 2014.
Maslarevic A, Bakic G, Lukic U, Martic I. Impact of parameters of plasma transferred arc welding process on the weld layer geometry. In: Poceedings of 18th International Research/Expert Conference "Trends in the Development of Machinery and Associated Technology" TMT 2014, Budapest, Hungary, 2014, pp. 1-4.
Pawlowski L. The Science Engineering of Thermal Spray Coatings. 2nd ed., London, London: John Wiley & Sons; 2008.
Bakic GM, Maksimovic V, Maslarevic A, Djukic MB, Rajicic B, Djordjevic A. Microstructural Characterization of WC and CrC Based Coatings Applied by Different Processes. In: Procedings and book of abstract of Metallurgical and Materials Engineering Congress of South-East Europe, MME SEE 2015, Belgrade, Serbia, 2015, pp. 195-201.
Ulutan M, Kiliҫay K, Ҫelik ON, Er Ü. Microstructure and wear behaviour of plasma transferred arc (PTA)-deposited FeCrC composite coatings on AISI 5115 steel. J Mater Process Tech. 2016; 236: 26–34.
Balasubramanian V, Lakshminarayanan AK, Varahamoorthy R, Babu S. Application of Response Surface Methodolody to Prediction of Dilution in Plasma Transferred Arc Hardfacing of Stainless Steel on Carbon Steel, J Iron Steel Res Int. 2009; 16: 44-53.
Deuis RL, Yellup JM, Subramanian C. Metal-matrix composite coatings by PTA surfacing. Compos Sci Technol. 1998; 58: 299-309.
Harris P, Smith BL. Factorial techniques for weld quality prediction. Met Constr-Brit Weld. 1983; 15: 661-666.
Badisch E, Ilo S, Polak R. Multivariable Modeling of Impact-Abrasion Wear Rates in Metal Matrix-Carbide Composite Materials. Trib Lett. 2009; 36: 55-62.
Maslarević A, Rajičić B, Bakić GM, Djukic MB, Djordjević A. Metalizacija veliim brzinama u struji produkata sagorevanja (HVOF). In: Book of Proceedings of International scientific conference of IT and Business-related research, Synthesis, Belgrade, Serbia, 2015, pp. 262-267. (in Srbian)
Veinthal R, Sergejev F, Zikin A, Tarbe R, Hornung J. Abrasive impact wear and surface fatigue wear behaviour of Fe–Cr–C PTA overlays. Wear. 2013; 301: 102–108.
D'Oliveira ASCM, Paredes RSC, Santos RLC. Pulsed current plasma transferred arc hardfacing. J Mater Process Tech. 2006; 171: 167-174.
Sudha C, Shankar P, Rao RVS, Thirumurugesan R, Vijayalakshmi M, Raj B. Microchemical and microstructural studies in a PTA weld overlay of Ni–Cr–Si–B alloy on AISI 304L stainless steel. Surf Coat Tech. 2008; 202: 2103–2112.
Hállen H, Lugscheider E, Ait-Mekideche A. Plasma Transferred Arc Surfacing with High Deposition Rates. In: Fourth National Thermal Spray conference. Pittsburg, PA, USA, 1991.
Abosrra L, Ashour A.F, Mitchell S.C, Zouseffi M. Corrosion of mild steel and 316L austenitic stainless steel with different surface roughness in sodium chloride saline solutions. WIT Trans Eng Sci. 2009; 65: 161-172.
Xu C, Zhang Y, Cheng G, Zhu W. Corrosion and electrochemical behavior of 316L stainless steel in sulfate-reducing anf iron-oxidizing bacteria solutions. Chinese J. Chem. Eng. 2006; 14: 829-834.
Xu J, Zhuo C, Tao J, Jiang S, Liu L. Improving the corrosion wear resistance of AISI 316L stainless steel by particulate reinforced Ni matrix composite alloying layer. J Phys D: Appl Phys. 2009; 42.
Mathiesen T, Rau J, Frantsen J.E, Terävä J, Björnstedt P-Å, Henkel B. Using exposure tests to examine rouging of stainless steel. Pharm Eng. 2002; 21.
Kurgan N, Sun Y, Cicek B, Ahlatci H. Production of 316L stainless steel implant materials by powder metallurgy and investigation of their wear properties. Cninese Sci Bull. 2012; 57: 1873-1878.
Mihailović DM, Patarić SA, Gulišija PZ, Janjušević VZ, Sokić DM. Mogućnost primene atmosferskog plazma-sprej postupka za dobijanje prevlaka hidroksiapatita na uzorcima od nerđajućeg čelika. Hem Ind. 2013; 67: 753-757. (in Serbian)
Malik AU, Mayan Kutty PC, Siddiqi NA, Andijani N, Ahmed S. The influence of pH and chloride concentration on the corrosion behaviour of AISI 316L steel in aqueous solutions. Corros Sci. 1992; 33: 1809-1827.
Datasheet Metal powder, EuTroLoy 16316, Castolin Ges.m.b.H, Vienna, 2005.
Peat T, Galloway A, Toumpis A, Harvey D, Yang WH. Performace evaluation of HVOF deposited cermet coatings under dry and slurry erosion. Surf Coat Tech. 2016; 300: 118–127.
Vieira RE, Mansouri A, McLaury BS, Shirazi A. Experimental and computational study of erosion in elbows due to sand particles in air folw. Powder Technol. 2016; 288: 339-353.
Cernuschi F, Guardamanga, Capelli S, Lorenzoni L, Mack DE, Moscatelli. Solid partice erosion of standard and advanced thermal barrier coatings. Wear. 2016; 348-349: 43-51.
Ruff AW, Ives LK. Measurement of solid particle velocity in erosive wear. Wear. 1975; 35: 195-199.
Okonkwo PC, Mohamed AMA, Ahmed E. Influence of particle velocities and impact angles on the erosion mechanisms of AISI 1018 steel. Adv Mater Lett. 2015; 6: 653-659.
Pinkerton A.J, Li L. The effect of laser pulse width on multiple-layer 316L steel clad microstructure and surface finish, Appl Surf Sci. 2003; 208-209: 411-416.
Maslarevic A, Bakic G, Sijacki Zeravcic V, Rajicic B, Lukic U. Plasma transferred arc hardfacing with 316L. In: Proceedings of the 3rd IIW South-East European welding congress. Timisoara, Romania, 2015, pp 283-288.
Kell J, Tyrer JR, Higginson RL, Thomson RC. Microstzructural characterization of autogenous laser welds on 316L stainless steel using EBSD and EDS. J Microsc. 2005; 21: 167-173.
Miller IH. The many facets and complexities of 316L ant the effect on properties. In: ITSC 2015, Internatiojnal thermal spray conference, California, USA, 2015.
Diaz VV, Duatra JC, D`Oliveira ASC. Hardfacing bay Plasma Transferred Arc Process. in: Wladislav S, ed. Arc Welding. chapter 1. InTech; 2011:3-20.
Finnie I. The Mechanism of Erosion in Ductile Materials. Proc. of the Third US National Congress of Applied Mechanics, Hagthormthwaite, R. M., Ed., ASME, New York, 1958, pp.7082
Nguyen QB, Nguyen VB, Lim CYH, Trinh QT, Sankaranarayanan S, Zhang YW, Gupta M. Effect of impact angle and testing time on erosion of stainless steel at higher velocities. Wear. 2014; 321: 87-93.
Hutchings IM. Ductile-brittle transitions wear maps for the erosion and abrasion of brittle materials. J Phys D: Appl Phys. 1992; 25: A212-A221.