Engineering Journal: Science and InnovationELECTRONIC SCIENCE AND ENGINEERING PUBLICATION
Certificate of Registration Media number Эл #ФС77-53688 of 17 April 2013. ISSN 2308-6033. DOI 10.18698/2308-6033
  • Русский
  • Английский
Article

Formation of welded solid-state wire bonds in the manufacture of 12Kh18N10T steel porous mesh materials

Published: 19.05.2022

Authors: Tretyakov A.F.

Published in issue: #5(125)/2022

DOI: 10.18698/2308-6033-2022-5-2181

Category: Metallurgy and Science of Materials | Chapter: Powder Metallurgy and Composite Materials

The experience of using turbine blade shells based on porous mesh materials in aerospace products and high-temperature gas turbines has shown that they are subject to destruction when under the influence of pressure fluctuations. So, first of all, fatigue failure occurs, in those permeable shells where there are no high-quality connections of structure-forming elements. It has been established that in diffusion welding and rolling welding, the strength of welded bonds increases with an increase in the process temperature, as well as in the vacuum depth and deformation time in diffusion welding. Research findings show that at strain rates of 10–2…1.0 s–1, the low quality of welded joints is explained by the high deformation resistance of microroughnesses on the contact surfaces of the wires and the low rate of diffusion mass transfer in the connection zone. The study establishes that under the conditions of diffusion and impact welding in vacuum, the formation of a solid-phase joint is possible on the entire surface of the macrocontact. At the same time, in percussion welding, the influence of the temperature value in the investigated interval on the quality of welded bonds is much lower than that for processes with lower loading rates. Practical recommendations are given for determining the optimal modes of wire mesh welding in the manufacture of porous mesh materials made of 12Kh18N10T steel.


References
[1] Belov S.V., ed. Poristye pronitsaemye materialy: spravochnik [Porous permeable materials: reference book]. Moscow, Metallurgiya Publ., 1987, 338 p.
[2] Sinelnikov Yu.I., Tretyakov A.F., Maturin N.I., Kolesnikov A.G., Panov A.D., Makarochkin V.I. Poristye setchatye materialy [Porous mesh materials]. Moscow, Metallurgiya Publ., 1983, 64 p.
[3] Zeygarnik Yu.A., Polyakov A.F., Stratev V.K., et al. Preprint OIVT RAN (Preprint of Joint Institute for High Temperatures of the Russian Academy of Sciences), no. 2–502. Moscow, 2010, 64 p.
[4] Pelevin F.V., Avramov N.I., Orlin S.A., Sintsov A.L. Inzhenerny zhurnal: nauka i innovatsii — Engineering Journal: Science and Innovation, 2013, iss. 4. http://dx.doi.org/10.18698/2308-6033-2013-4-698
[5] Novikov Yu.M. Bolshakov V.A. Bezopasnost zhiznedeyatelnosti — Life safety, 2015, no. 11, pp. 53–56.
[6] Krasulin Yu.L. Vzaimodeystvie metalla s poluprovodnikom v tverdoy faze [Interaction of a metal with a solid-state semiconductor]. Moscow, Nauka Publ., 1971, 119 p.
[7] Mazur A.M., Alekhin V.P., Shorshorov M.Kh. Protsessy svarki i payki v proizvodstve poluprovodnikovykh priborov [Processes of welding and soldering in the production of semiconductor devices]. Moscow, Radio i svyaz Publ., 1981, 224 p.
[8] Karakozov E.S. Svarka metallov davleniem [Pressure welding of metals]. Moscow, Mashinostroenie Publ., 1986, 280 p.
[9] Shorshorov M.Kh., Kolesnichenko V.A., Alekhin V.P. Klinopressovaya svarka raznorodnykh metallov [Clinopress welding of dissimilar metals]. Moscow, Metallurgiya Publ., 1982, 112 p.
[10] Epshteyn G.N. Stroenie metallov, deformirovannykh vzryvom [The structure of metals deformed by an explosion]. Moscow, Metallurgiya Publ., 1980, 256 p.
[11] Larikov L.N., Ryabov V.R., Falchenko V.M. Diffuzionnye protsessy v tverdoy faze pri svarke [Diffusion processes in the solid phase during welding]. Moscow, Mashinostroenie Publ., 1975, 192 p.
[12] Larikov L.N., Mazenko V.F., Falchenko V.M., et al. Doklady AN SSSR (Proceedings of the USSR Academy of Sciences), 1975, no. 7, pp. 637–640.
[13] Larikov L.N., Falchenko V.M., Mazenko V.F., et al. Avtomaticheskaya svarka — Automatic Welding, 1974, no. 5, pp. 19–21.
[14] Falchenko V.M. Podvizhnost atomov v usloviyakh skorostnoy plasticheskoy deformatsii metallov i splavov [Mobility of atoms under conditions of high-speed plastic deformation of metals and alloys]. Vliyanie defektov kristallicheskoy struktury na diffuziyu metallov i splavov na massoperenos pri impulsnom vozdeystviy [Influence of crystal structure defects on the diffusion of metals and alloys on mass transfer under pulsed action]. Kiev, 1980, pp. 6–7.
[15] Kharchenko G.K., Gurevich S.M., Ignatenko A.I. Avtomaticheskaya svarka — Automatic Welding, 1983, no. 10, pp. 73–74.
[16] Musin R.A., Antsiferov V.N., Kvasnitskiy V.F. Diffuzionnaya svarka zharoprochnykh splavov [Diffusion welding of heat-resistant alloys]. Moscow, Metallurgiya Publ., 1979, 208 p.
[17] Tretyakov A.F. Proizvodstvo prokata (Rolled products production), 2013, no. 6, pp. 29–34.
[18] Tretyakov A.F. Problemy chernoy metallurgii i materialovedeniya (Problems of ferrous metallurgy and materials science), 2016, no. 1, pp. 5–10.
[19] Spiridonov A.A., Vasilev I.G. Planirovanie eksperimenta pri issledovanii i optimizatsii tekhnologicheskikh protsessov [Planning an experiment in the study and optimization of technological processes]. Sverdlovsk, URFU Publ., 1975, 140 p.
[20] Kharchenko G.K., Ignatenko A.I. Novy sposob svarki davleniem. Dostizheniya i perspektivy razvitiya diffuzionnoy svarki: materialy konferentsii [A new way of pressure welding. Achievements and prospects for the development of diffusion welding: conference proceedings]. Moscow, Dzerzhinsky MDNTP Publ., 1987, pp. 97–100.