RESEARCH PAPER
Investigation of Structure Formation and Tribotechnical Properties of Steel Plasma Coatings After Chemical-Heat Treatment and Liquid-Phase Impregnation
1
Fratsevich Institute for Problems in Materials Science NAS of Ukraine, Department of Functional Materials for Medical Application, Krzhizhanovsky Str., 3, 03142, Kyiv, Ukraine
2
Aerospace Faculty, Department of Applied Mechanics and Materials Engineering, National Aviation University, Lubomyr Husar Ave., 1, 03058, Kyiv, Ukraine
Submission date: 2022-06-26
Acceptance date: 2022-09-06
Online publication date: 2022-11-08
Publication date: 2022-12-01
Acta Mechanica et Automatica 2022;16(4):382-387
KEYWORDS
plasma coatingssteel 11Cr18MoWCucomposite electrolytic coatingsimpregnationgalvanic plasma coatingschemical-thermal treatmentstructure formationwear resistance
ABSTRACT
The paper is focused on the studies of the microstructure development and physical and mechanical properties of metal-matrix composite coatings based on steel 11Cr18MoWCu deposited using plasma and galvanoplasma methods. The expediency of combining gas-thermal spraying processes of plasma coatings with open porosity up to 16%–18%, with their subsequent thermodiffusion saturation (chromium plating) or liquid-phase impregnation with eutectic alloys of previously applied Ni–B galvanic layer, is shown. The study of the tribotechnical properties of the proposed coatings showed a significant improvement in their performance under conditions of various types of intensive wear, as well as in corrosive environments.
REFERENCES (28)
1.
Hetmanczyk M, Swadzba L, Mendala B. Advanced Materials and Protective Coatings in Aero-Engines Application. Journal of Achievements in Materials and Manufacturing Engineering. 2007; 24(1):372–81.
2.
Uvarova I, Babutina T, Kostenko V, Cavyak M. From Nanophased Powders to Composite Coatings. Functional Materials. 2001;8(1): 185–8.
3.
Vijayanand P, Kumar A, Vijaya Kumar KR, Vinod A, Kumaran P, Arungalai Vendan S. Characterizations of Plasma Sprayed Composite Coatings Over 1020 Mild Steel. Journal of Mechanical Science and Technology. 2017;31(10):4747–54.
4.
Uvarova I. Ultrafine and Nanophased Powders as the Fillers in Composite Coatings. Journal of Advanced Materials. 2000 Apr; 32(2):26–31.
5.
Rinaldi C, Ferravante L. An Innovative Shrouded Plasma Technique Producing Clean Coatings with Good Hot Corrosion Resistance for Gas Turbine Blades. EUROMAT 2001 Conf. Proc. Rimini. 2001.
6.
Gill BJ, Ridding FL. Argon Shrouded Plasma Spray Technology for Production Applications. Surface Engineering, 1986;2(3):169–76.
7.
Brezinová J, Guzanová A, Draganovská D, Egri M. Assessment Tribological Properties of Coatings Applied by HVOF Technology. Acta Mechanica et Automatica. 2013 Sep 1;7(3):135–9.
8.
Fauchais P, Vardelle M. Understanding the Formation of D.C. Plasma Sprayed Coatings. Materials Science Forum. 2003 Aug;426–432:2459–66.
9.
Coddet C, Verdy C, Dembinski L, Grosdidier T, Cornu D, García JC. High Properties Metallic Alloys Obtained through the Thermal Spray Route. Materials Science Forum. 2003 Aug;426–432:2467–72.
10.
Hardwicke CU, Lau Y-C. Advances in Thermal Spray Coatings for Gas Turbines and Energy Generation: A Review. Journal of Thermal Spray Technology. 2013 Feb 28;22(5):564–76.
11.
Thorpe ML. Thermal Spray, Industry in Transition. Advanced Mat. and Proc. 1993;143(5):50–61.
12.
Bresinova J, Gubanova F, Draganovska D, Marushchak PO, Landova M. Spray Coatings Containing WC and WB Particles. Acta Mechanica et Automatica. 2016;10(4):296–299.
13.
Smagorinski ME, Tsantrizos PG. Sprayed Metals and their Thermal Treatment. EUROMAT 2001 Conf. Proc. Rimini. 2001.
14.
Kabatova M, Medukh R, Kostenko V, Mihalik J, Seveikova J. Improvement of Corrosion and Wear Resistance of Sintered Steels by Coatings. In Vienna; 2004. p. 423–6.
15.
Medyukh RM, Medyukh VK, Uvarova IV. Diffusion Chromizing of Molybdenum-Based Plasma Coatings. Powder Metallurgy and Metal Ceramics. 2018 Jan;56(9–10):535–40.
16.
Staia MH, Ramos E, Carrasquero A, Roman A, Lesage J, Chicot D, et al. Effect of substrate roughness induced by grit blasting upon adhesion of WC-17% Co thermal sprayed coatings. Thin Solid Films. 2000 Dec;377–378:657–64.
17.
GuslienkoYu, MediukhR, TikhonovichT, ChudovskiV, PavlenkoN. Structure and Wear Resistance of Composite Galvanoplasma Coatings. Powder Metallurgy.1989;1:31–4.
18.
Guslienko Yu, Kostenko V, Medukh R, Uvarova I, Kabatova M, Dzubinsky M, Dudrova E. Structure and Properties of Boride Composite Coatings. Functional Materials. 2001;8(1):193–5.
19.
Meidukh R, Kabatova M, Parilak L, Kostenko V, Dzubinsky M, Dudrova E. Microstructure and Properties of Ni-B and Ni-B-WC Coating Layers on Sintered Steels. 11 Int. Symposium of Metallography. Slovak Republic; 2001. p. 536–8.
20.
Medukh R, Kabatova M, Parilak L, Kostenko V, Dzubinsky M, Dudrova E. Microstructure and Properties of Layers Produced on Sintered Steels by Electrolitic Coatings and Diffusion Chroming. Int. Conference “Protective Coating 2002”. Slovak Republic; 2002.
21.
Odhiambo JG, Li W, Zhao Y, Li C. Porosity and Its Significance in Plasma-Sprayed Coatings. Coatings. 2019 Jul 23;9(7):460.
22.
Yang B, Shi C, Li Y, Lei Q, Nie Y. Effect of Cu on the corrosion resistance and electrochemical response of a Ni–Co–Cr–Mo alloy in acidic chloride solution. Journal of Materials Research. 2018 Oct 2;33(22):3801–8.
23.
Hou Y, Li Y, Wang F, Zhang C, Koizumi Y, Chiba A. Influence of Mo concentration on corrosion resistance to HF acid solution of Ni–Co– Cr–Mo alloys with and without Cu. Corrosion Science. 2015 Oct;99:185–93.
24.
Jung S, Jeon C, Jo YH, Choi W-M, Lee B-J, Oh Y-J, et al. Effects of tungsten and molybdenum on high-temperature tensile properties of five heat-resistant austenitic stainless steels. Materials Science and Engineering: A. 2016 Feb;656:190–9.
26.
Pašečko MÌ, Kìndačuk MV, Labunecʹ VF, Dziedzic K, Radʹko OV, Korbut ÊV. Tribologia. Lublin: Politechnika Lubelska; 2017.
27.
Kluk A, Medukh R, Nekoz A, Stetsishin M, Dzub A. Increasing of Cavitation-Erosion Resistance of Carbon Steels by Plasma Spraying and Subsequent Thermal-Diffusion Chromium Plating. Problems of Frictions and Wear. 1987;31:66–8.
| eISSN: | 2300-5319 |
| ISSN: | 1898-4088 |
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