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Title of the article

EFFECT OF AIR ATOMIZATION PRESSURE AT HIGH-SPEED SPRAYING OF GAS-THERMAL COATING FROM HIGH-CHROMIUM STEEL ON ITS CONSTRUCTION AND WEAR RESISTANCE

Authors

ASTRASHAB Evgeniy V., Technical Expert of the Center of Structural Research and Tribo-Mechanical Testing of Materials and Mechanical Engineering Products, Joint Institute of Mechanical Engineering of the NAS of Belarus, Minsk, Republic of Belarus

BELOTSERKOVSKY Marat А., D. Sc. in Eng., Assoc. Prof., Head of the Laboratory of Gas-Thermal Methods of Machine Components Hardening, Joint Institute of Mechanical Engineering of the NAS of Belarus, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

GRIGORCHIK Alexander N., Ph. D. in Eng., Senior Researcher of the Center of Structural Research and Tribo-Mechanical Testing of Materials and Mechanical Engineering Products, Joint Institute of Mechanical Engineering of the NAS of Belarus, Minsk, Republic of Belarus

KUKAREKO Vladimir A., D. Sc. in Phys. and Math., Prof., Chief of the Center of Structural Research and Tribo-Mechanical Testing of Materials and Mechanical Engineering Products, Joint Institute of Mechanical Engineering of the NAS of Belarus, Minsk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

SOSNOVSKIY Aleksey V., Ph. D. in Eng., Leading Researcher of the Laboratory of Gas-Thermal Methods of Machine Components Hardening, Joint Institute of Mechanical Engineering of the NAS of Belarus, Minsk, Republic of Belarus

In the section TECHNOLOGICAL MECHANICS
Year 2018 Issue 4 Pages 51–57
Type of article RAR Index UDK 621.723 Index BBK  
Abstract

The influence of the pressure of the atomizing air at high-speed spraying of the gas-thermal coating from high-chromium steel 20Kh13 on the structure and wear resistance of the coating is studied. It is shown that sprayed gas-thermal coatings from 20Kh13 steel in the phase composition contain α-Fe and Fe3O4 and FeO oxides. It is established that with an increase in the pressure of air supply used to burn the MPS gas from 0.1 to 0.3 MPa, with gas-thermal spraying, the amount of oxides increases from ≈8 to ≈15 vol.%, and the porosity of coatings decreases from 5.0 to 2.5 vol.%. The hardness of sprayed coatings from 20Kh13 steel increases with air pressure from 220 to 320 HV 10. The increase in hardness of coatings with increasing air pressure is associated with an increase in the volume fraction of Fe3O4 and FeO oxides contained in the coatings. The intensity of mass wear under conditions of dry friction of a gas-thermal coating of 20Kh13 steel sprayed with a minimum air pressure of 0.1 MPa, under conditions of dry friction is 20.2 ∙ 10–3 mg/m. The increase in air pressure up to 0.3 MPa leads to the decrease in wear resistance of coatings by 1.4 times, which is associated with the increase in the number of brittle oxides in coatings. The intensity of linear wear in the I-20 lubricant of coatings obtained at a minimum pressure of spraying air of 0.1 MPa is 0.255 ∙ 10–9. With the increase in air pressure during spraying up to 0.3 MPa, the wear resistance of coatings under conditions of boundary friction increases by ≈1.3 times, which is caused by the increase in the durometric properties of coatings.

Keywords

high-speed metallization, air pressure, structure, phase composition, oxide content, porosity, microhardness, wear resistance

   
Bibliography
  • Belotserkovsky M.A., Pryadko A.S. Aktivirovannoe gazoplamennoe i elektrodugovoe napylenie pokrytiy provolochnymi materialami [Activated gas-flame and electric arc spraying of coatings with wire materials]. Uprochnyayushchie tekhnologii i  pokrytiya [Hardening technologies and coatings], 2006, no. 12, pp. 17–23.
  • Belotserkovsky M.A. Tekhnologii aktivirovannogo gazoplamennogo napyleniya antifriktsionnykh pokrytiy [Technologies of activated gas-flame spraying of anti-friction coatings]. Minsk, Tekhnoprint Publ., 2004. 200 p.
  • Belotserkovsky M.A., Pryadko A.S., Cherepko A.E. Metody i oborudovanie dlya formirovaniya vysokoenergeticheskikh dvukhfaznykh potokov [Methods and equipment for the formation of high-energy two-phase flows]. Fizika plazmy i plazmennye tekhnologii [Plasma physics and plasma technologies], 1997, vol. 4, pp. 670–673.
  • Grigorchik A.N., Astrashab E.V. Strukturno-fazovoe sostoyanie i tribomekhanicheskie svoystva gazotermicheskogo pokrytiya iz vysokokhromistoy stali 40Kh13, napylennogo s ispolzovaniem vysokoentalpiynogo gaza MAF [Structural-phase
    state and tribomechanical properties of gas-thermal coating of high-chromium steel 40Kh13, sprayed using high-enthalpy MPS gas]. Metallurgiya: resp. mezhved. sb. nauch. tr. [Metallurgy: republican interdepartmental collection of scientific works], 2017, no. 38, pp. 157–166.
  • Vityaz P.A., Ilyushchenko A.F., Shevtsov A.I. Osnovy naneseniya iznosostoykikh, korrozionno-stoykikh i teplozashchitnykh pokrytiy [Fundamentals of application of wear-, corrosion-and heat-resistant coatings], Minsk, Belorusskaya nauka Publ., 2006. 361 p.
  • Vityaz P.A., Ivashko V.S., Ilyushchenko A.F. Teoriya i praktika naneseniya zashchitnykh pokrytiy [Theory and practice of application of protective coatings]. Minsk, Belaruskaya navuka Publ, 1998. 583 p.
  • Kukareko V.A., Grigorchik A.N., Belotserkovsky M.A., Sosnovskiy A.V. Zakonomernosti formirovaniya strukturno-fazovogo sostoyaniya gazotermicheskogo pokrytiya iz stali martensitnogo klassa [The regularities of structure formation of thermal sprayed coating of martensitic steel]. Sovremennye metody i tekhnologii sozdaniya i obrabotki materialov [Advanced methods and technologies of materials development and processing], 2017, vol. 2, pp. 54–62.
  • Kukareko V.A., Grigorchik A.N., Belotserkovsky M.A., Sosnovskiy A.V. O prirode formirovaniya metastabilnoy austenitnoy struktury pri gazotermicheskom napylenii vysokokhromistoy stali martensitnogo klassa 95Kh18 [About the nature of formation of metastable austenitic structure at gas-thermal spraying of high-chromium steel of martensitic class 95Kh18]. Uprochnyayushchie tekhnologii i pokrytiya [Hardening technologies and coatings]. 2017, vol. 13, no. 7(151),
    pp. 318–322.
  • Kukareko V.A., Belotserkovsky M.A., Grigorchik A.N. Deformatsionno-aktivirovannoe martensitnoe prevrashchenie v gazotermicheskikh pokrytiyakh iz vysokokhromistykh staley pri sukhom trenii [Deformation-activated martensitic transformation in gas-thermal coatings of high-chromium steels under dry friction]. Tezisy dokladov Mezhdunarodnoy nauchno-teknicheskoy konferentsii “Polimernye kompozity i tribologiya “POLIKOMTRIB-2015” [Abstracts of papers of International Scientific and Technical Conference “Polymer Composites and Tribology “POLYCOMTRIB-2015”]. Gomel, 2015, p. 75.