Skip navigation

putin IS MURDERER

Please use this identifier to cite or link to this item: https://oldena.lpnu.ua/handle/ntb/44114
Full metadata record
DC FieldValueLanguage
dc.contributor.authorCheylyakh, Yan
dc.date.accessioned2019-02-11T13:44:12Z-
dc.date.available2019-02-11T13:44:12Z-
dc.date.created2018-01-29
dc.date.issued2018-01-29
dc.identifier.citationCheylyakh Y. Regulation of the phase-structural composition and metastability of austenite by alloying elements and parameters of tempering for increase wear-resistance of Fe-Cr-Mn deposited steel / Yan Cheylyakh // Ukrainian Journal of Mechanical Engineering and Materials Science. — Lviv : Lviv Politechnic Publishing House, 2018. — Vol 4. — No 1. — P. 1–11.
dc.identifier.urihttps://ena.lpnu.ua/handle/ntb/44114-
dc.description.abstractIt is shown that under the influence of alloying (Cr, Mn, C, Si, Ti, N, V) during electric arc hardfacing with a flux cored wire, as well as technological tempering parameters at temperatures of 300–700 °C, the phase-structural composition of the cost-saving alloyed deposited steel (from 0 to 75 % quenching martensite and austenite), the degree of metastability of austenite are regulated. At optimal parameters of alloying and tempering, an increased wear resistance is achieved due to the development of the deformation induced martensite γ→α' transformation of austenite during the wear process, which causes the effect of self-strengthening during testing and operation. This is an important advantage of the developed metastable deposited steel before the deformation-stable metal.
dc.format.extent1-11
dc.language.isoen
dc.publisherLviv Politechnic Publishing House
dc.relation.ispartofUkrainian Journal of Mechanical Engineering and Materials Science, 1 (4), 2018
dc.subjectdeposited steel
dc.subjectalloying
dc.subjectmetastable austenite
dc.subjectmartensite
dc.subjecttempering
dc.subjectwear resistance
dc.titleRegulation of the phase-structural composition and metastability of austenite by alloying elements and parameters of tempering for increase wear-resistance of Fe-Cr-Mn deposited steel
dc.typeArticle
dc.rights.holder© Національний університет „Львівська політехніка“, 2018
dc.rights.holder© Cheylyakh Y., 2018
dc.contributor.affiliationSHEI "Pryazovskyi State Technical University"
dc.format.pages11
dc.identifier.citationenCheylyakh Y. Regulation of the phase-structural composition and metastability of austenite by alloying elements and parameters of tempering for increase wear-resistance of Fe-Cr-Mn deposited steel / Yan Cheylyakh // Ukrainian Journal of Mechanical Engineering and Materials Science. — Lviv : Lviv Politechnic Publishing House, 2018. — Vol 4. — No 1. — P. 1–11.
dc.relation.references[1] S. Ia. Shekhter and A. M. Reznitckii, Naplavka metallov [Surfacing of metals]. Moscow, Russia: Mashinostroenie Publ., 1982. [in Russian].
dc.relation.references[2] L. S. Livshitc, N. A. Grinberg and E. G. Kurkumelli, Osnovy legirovaniia naplavlennogo metalla [Fundamentals of alloying of weld metal]. Moscow, Russia: Mashinostroenie Publ., 1969. [in Russian].
dc.relation.references[3] I. A. Riabtcev, Naplavka detalei mashin i mekhanizmov [Surfacing of machine parts and mechanisms]. Kyiv, Ukraine: Ekotekhnolohiia Publ., 2004. [in Russian].
dc.relation.references[4] M. I. Razikov and B. A. Kulishenko, “O vybore naplavochnogo materiala, stoikogo pri kavitatcionnom nagruzhenii” [“On the choice of the surfacing material, resistant to cavitation loading”], Svarochnoe proizvodstvo [Welding production], no. 7, pp. 10–12, 1967. [in Russian].
dc.relation.references[5] L. S. Malinov, et al, “Razrabotka i issledovanie novoi poroshkovoi lenty dlia naplavki koles mostovykh kranov” [“Development and research of a new powder tape for surfacing wheels of overhead cranes”], Svarochnoe proizvodstvo [Welding production], no. 10, pp. 22–25, 1995. [in Russian].
dc.relation.references[6] A. I. Kovalchuk, et al., “Povyshenie rabotosposobnosti valkov piligrimovykh stanov naplavkoi novoi poroshkovoi provolokoi ПП–35ЖН” [“Improving the performance of the rolls of pilgrim mills by surfacing with a new flux-cored wire ПП–35ЖН”], Svarochnoe proizvodstvo [Welding production], no. 7, pp. 12–13, 1984. [in Russian].
dc.relation.references[7] E. L. Sheinman, “Zavisimost iznosostoikosti vysokouglerodistykh khromomargantcevykh naplavok ot osobennostei obrazovaniia struktury” [“Dependence of wear resistance of high-carbon chromium-manganese surfacing on the features of structure formation”], Metallovedenie i termicheskaia obrabotka metallov [Metallurgy and heat treatment of metals], no. 2, pp. 45–46, 1992. [in Russian].
dc.relation.references[8] Y. A. Cheiliakh and V. V. Chigarev, “Structure and properties of deposited wear-resistant Fe-Cr-Mn steel with controllable content of metastable austenite”, The Paton welding Journal, no. 8, pp. 17–21, 2011.
dc.relation.references[9] L. S. Malinov and V. L. Malinov, Resursosbeoegaiushchie ekonomnolegirovannye splavy i uprochniaiushchie tekhnologii, obespechivaiushchie effekt samozakalk [Resource-saving economically alloyed alloys and reinforcing technologies that provide the effect of self-enrichment]. Mariupol, Ukraine: Renata Publ., 2009. [in Russian].
dc.relation.references[10] A. P. Cheiliakh, Y. A. Cheylyakh and Yu. S. Samotugina, Strengthening technologies of materials treatment. Mariupol, Ukraine: Ltd “PPNS” Publ., 2016. [in Russian].
dc.relation.references[11] A. Cheiliakh, et al., “Design of surface metastable phase-structural modifications for wear-resistant steels by methods of surfacing and plasma and electron-beam treatments”, Bulletin of Tabbin Insititute of Metallurgical Studies, vol. 102, pp. 53–65, 2013.
dc.relation.references[12] Y. Cheiliakh, V. Chidgarev and G. Shevchenko, “The creation of a new economical (nickel free) powder– like wire for surfacing made of metastable metal, self–strengthened during wear”, in Proc. 1st Mediterranean Conf. Heat Treatment and Surface Engineering in the Manufacturing of Metallic Engineering Components, Sharm El Sheikh, Egypt, December 1–3, 2009, pp. 74–75.
dc.relation.references[13] Y. A. Cheiliakh, V. V. Chidgarev and G. V. Shevchenko, “Naplavlena znosostiika stal” [“Deposited wear-resistant steel”], UA Patent 95559, August 10, 2011. [in Ukrainian].
dc.relation.references[14] Y. A. Cheiliakh and V. V. Chidgarev, “Razrabotka sostava ekonomnolegirovannoi Fe–Cr–Mn naplavlennoi iznosostoikoi stali s regulirovaniem soderzhaniia i metastabilnosti austenita” [“The creation of composition of new economical alloyed Fe-Cr-Mn surfacing wear resistant steel with regulate of maintenance and metastable austenite”], Visnyk Pryazovskoho derzhavnoho tekhnichnoho universytetu [Reporter of the Priazovskyi state technical university], vol. 22, pp. 103–108, 2011. [in Russian].
dc.relation.references[15] A. P. Cheiliakh, Ekonomnolegirovannye metastabilnye splavy i uprochniaiushchie tekhnologii [Economically alloyed metastable alloys and reinforcing technologies]. Mariupol, Ukraine: Priazovskyi state technical university Publ., 2009. [in Russian].
dc.relation.references[16] A. P. Cheiliakh, et al., “Surface modifications for wear resistant steels by methods of induced metastable austenite structures”, Visnyk Pryazovskoho derzhavnoho tekhnichnoho universytetu [Reporter of the Priazovskyi state technical university], vol. 26, pp. 62–70, 2013.
dc.relation.references[17] O. Cheiliakh, et al., “Development of science intensive resource-saving methods for surface strengthening of steel products by designing metastable phase-structural modifications”, in Proc. 2nd Mediterranean Conf. on heat treatment and surface engineering and the challenges for heat treatment and surface engineering, Dubrovnik – Cavtat, Croatia, June 11–14, 2013, pp. 375–384.
dc.relation.referencesen[1] S. Ia. Shekhter and A. M. Reznitckii, Naplavka metallov [Surfacing of metals]. Moscow, Russia: Mashinostroenie Publ., 1982. [in Russian].
dc.relation.referencesen[2] L. S. Livshitc, N. A. Grinberg and E. G. Kurkumelli, Osnovy legirovaniia naplavlennogo metalla [Fundamentals of alloying of weld metal]. Moscow, Russia: Mashinostroenie Publ., 1969. [in Russian].
dc.relation.referencesen[3] I. A. Riabtcev, Naplavka detalei mashin i mekhanizmov [Surfacing of machine parts and mechanisms]. Kyiv, Ukraine: Ekotekhnolohiia Publ., 2004. [in Russian].
dc.relation.referencesen[4] M. I. Razikov and B. A. Kulishenko, "O vybore naplavochnogo materiala, stoikogo pri kavitatcionnom nagruzhenii" ["On the choice of the surfacing material, resistant to cavitation loading"], Svarochnoe proizvodstvo [Welding production], no. 7, pp. 10–12, 1967. [in Russian].
dc.relation.referencesen[5] L. S. Malinov, et al, "Razrabotka i issledovanie novoi poroshkovoi lenty dlia naplavki koles mostovykh kranov" ["Development and research of a new powder tape for surfacing wheels of overhead cranes"], Svarochnoe proizvodstvo [Welding production], no. 10, pp. 22–25, 1995. [in Russian].
dc.relation.referencesen[6] A. I. Kovalchuk, et al., "Povyshenie rabotosposobnosti valkov piligrimovykh stanov naplavkoi novoi poroshkovoi provolokoi PP–35ZhN" ["Improving the performance of the rolls of pilgrim mills by surfacing with a new flux-cored wire PP–35ZhN"], Svarochnoe proizvodstvo [Welding production], no. 7, pp. 12–13, 1984. [in Russian].
dc.relation.referencesen[7] E. L. Sheinman, "Zavisimost iznosostoikosti vysokouglerodistykh khromomargantcevykh naplavok ot osobennostei obrazovaniia struktury" ["Dependence of wear resistance of high-carbon chromium-manganese surfacing on the features of structure formation"], Metallovedenie i termicheskaia obrabotka metallov [Metallurgy and heat treatment of metals], no. 2, pp. 45–46, 1992. [in Russian].
dc.relation.referencesen[8] Y. A. Cheiliakh and V. V. Chigarev, "Structure and properties of deposited wear-resistant Fe-Cr-Mn steel with controllable content of metastable austenite", The Paton welding Journal, no. 8, pp. 17–21, 2011.
dc.relation.referencesen[9] L. S. Malinov and V. L. Malinov, Resursosbeoegaiushchie ekonomnolegirovannye splavy i uprochniaiushchie tekhnologii, obespechivaiushchie effekt samozakalk [Resource-saving economically alloyed alloys and reinforcing technologies that provide the effect of self-enrichment]. Mariupol, Ukraine: Renata Publ., 2009. [in Russian].
dc.relation.referencesen[10] A. P. Cheiliakh, Y. A. Cheylyakh and Yu. S. Samotugina, Strengthening technologies of materials treatment. Mariupol, Ukraine: Ltd "PPNS" Publ., 2016. [in Russian].
dc.relation.referencesen[11] A. Cheiliakh, et al., "Design of surface metastable phase-structural modifications for wear-resistant steels by methods of surfacing and plasma and electron-beam treatments", Bulletin of Tabbin Insititute of Metallurgical Studies, vol. 102, pp. 53–65, 2013.
dc.relation.referencesen[12] Y. Cheiliakh, V. Chidgarev and G. Shevchenko, "The creation of a new economical (nickel free) powder– like wire for surfacing made of metastable metal, self–strengthened during wear", in Proc. 1st Mediterranean Conf. Heat Treatment and Surface Engineering in the Manufacturing of Metallic Engineering Components, Sharm El Sheikh, Egypt, December 1–3, 2009, pp. 74–75.
dc.relation.referencesen[13] Y. A. Cheiliakh, V. V. Chidgarev and G. V. Shevchenko, "Naplavlena znosostiika stal" ["Deposited wear-resistant steel"], UA Patent 95559, August 10, 2011. [in Ukrainian].
dc.relation.referencesen[14] Y. A. Cheiliakh and V. V. Chidgarev, "Razrabotka sostava ekonomnolegirovannoi Fe–Cr–Mn naplavlennoi iznosostoikoi stali s regulirovaniem soderzhaniia i metastabilnosti austenita" ["The creation of composition of new economical alloyed Fe-Cr-Mn surfacing wear resistant steel with regulate of maintenance and metastable austenite"], Visnyk Pryazovskoho derzhavnoho tekhnichnoho universytetu [Reporter of the Priazovskyi state technical university], vol. 22, pp. 103–108, 2011. [in Russian].
dc.relation.referencesen[15] A. P. Cheiliakh, Ekonomnolegirovannye metastabilnye splavy i uprochniaiushchie tekhnologii [Economically alloyed metastable alloys and reinforcing technologies]. Mariupol, Ukraine: Priazovskyi state technical university Publ., 2009. [in Russian].
dc.relation.referencesen[16] A. P. Cheiliakh, et al., "Surface modifications for wear resistant steels by methods of induced metastable austenite structures", Visnyk Pryazovskoho derzhavnoho tekhnichnoho universytetu [Reporter of the Priazovskyi state technical university], vol. 26, pp. 62–70, 2013.
dc.relation.referencesen[17] O. Cheiliakh, et al., "Development of science intensive resource-saving methods for surface strengthening of steel products by designing metastable phase-structural modifications", in Proc. 2nd Mediterranean Conf. on heat treatment and surface engineering and the challenges for heat treatment and surface engineering, Dubrovnik – Cavtat, Croatia, June 11–14, 2013, pp. 375–384.
dc.citation.journalTitleUkrainian Journal of Mechanical Engineering and Materials Science
dc.citation.volume4
dc.citation.issue1
dc.citation.spage1
dc.citation.epage11
dc.coverage.placenameLviv
Appears in Collections:Ukrainian Journal of Mechanical Engineering And Materials Science. – 2018. – Vol. 4, No. 1

Files in This Item:
File Description SizeFormat 
2018v4n1_Cheylyakh_Y-Regulation_of_the_phase_1-11.pdf1.03 MBAdobe PDFView/Open
2018v4n1_Cheylyakh_Y-Regulation_of_the_phase_1-11__COVER.png458.11 kBimage/pngView/Open
Show simple item record


Items in DSpace are protected by copyright, with all rights reserved, unless otherwise indicated.