Authors:
Nyrkova Liudmyla Ivanivna — Head of the authoring team. Doctor of Technical Sciences, Senior Researcher, Head of the Gas and Oil Pipeline Welding Department, E.O. Paton Electric Welding Institute of the NAS of Ukraine
Scopus ID: https://www.scopus.com/authid/detail.uri?authorId=57209672063
ORCID ID: https://orcid.org/0000-0003-3917-9063
Research Gate: https://www.researchgate.net/profile/L-Nyrkova
Web of Science: https://www.webofscience.com/wos/author/record/AAF-3187-2020
Google Scholar: https://scholar.google.com.ua/citations?user=bCeO-uIAAAAJ&hl=uk
Labur Tetiana Mykhailivna — Doctor of Technical Sciences, Senior Research Fellow, Chief Research Fellow, Department of physical and metallurgical processes of welding light metals and alloys, E.O. Paton Electric Welding Institute of the NAS of Ukraine
Scopus ID: https://www.scopus.com/authid/detail.uri?authorId=6506343754
ORCID ID: https://orcid.org/0000-0002-4064-2644
Research Gate: https://www.researchgate.net/search.Search.html?query=Labur+T.M.&type=publication
Web of Science: https://www.webofscience.com/wos/woscc/summary/116f48f4-8e59-4e97-a500-19ed6102caea-011551f7b3/relevance/1
Google Scholar: https://scholar.google.com/scholar?hl=en&as_sdt=0%2C5&q=%22%D0%BB%D0%B0%D0%B1%D1%83%D1%80+%D1%82%D0%BC%22&btnG
Osadchuk Svitlana Oleksiivna — Candidate of Technical Sciences, Senior Researcher, Senior Scientific Associate, Department of Gas and Oil Pipeline Welding, E.O. Paton Electric Welding Institute of the NAS of Ukraine
Scopus ID: https://www.scopus.com/authid/detail.uri?authorId=55215010000
ORCID ID: https://orcid.org/0000-0001-9559-0151
Research Gate: https://www.researchgate.net/profile/S-Osadchuk-2
Web of Science: https://www.webofscience.com/wos/woscc/summary/f2ce9ca2-28be-41a9-af02-658c498a6bca-0119ca2be5/relevance/1
Google Scholar: https://scholar.google.com.ua/citations?hl=uk&user=FOG1QRcAAAAJ
E.O. Paton Electric Welding Institute of the NAS of Ukraine, Kiev, Department of physical and metallurgical processes of welding of light metals and alloys
Scopus ID: https://www.scopus.com/authid/detail.uri?authorId=7801687476
ORCID ID: https://orcid.org/0000-0002-3028-2964
Research Gate: https://www.researchgate.net/profile/Iurii-Falchenko
Web of Science: https://www.webofscience.com/wos/author/record/W-2793-2017
Google Scholar: https://scholar.google.com/citations?hl=en&user=wHBCIVwAAAAJ
Scopus ID: https://www.scopus.com/authid/detail.uri?authorId=56182050400
ORCID ID: http://orcid.org/0000-0002-4234-6961
Web of Science: https://www.webofscience.com/wos/author/record/1894647
Google Scholar: https://scholar.google.com.ua/citations?user=6RfjJ2MAAAAJ&hl=uk
The monograph is devoted to the corrosion-mechanical durability of welded structures made of aluminum alloys of Al-Cu-Mn, Al-Mg and Al-Mg-Si-Cu alloying systems and describes a complex of their properties under conditions simulating operational conditions. The method of accelerated corrosion and corrosion-mechanical tests is proposed. Attention is paid to technological problems of welding: structural heterogeneity of welded joints, tendency to hot cracks and porosity. The trends in the use of aluminum alloys in modern welded constructions of the aerospace and transport industries of land and sea basing are analyzed.
For scientists and engineers who research, build and operate welded structures from aluminum alloys.
References:
Frydliander Y.N. Aliumynyevye deformyruemye konstruktsyonnye splavy. M.: Metallurhyia, 1979. 208 s.
Kashchuk N.M. Razrabotka tekhnolohyy yzghotovlenyia yntehralnykh konstruktsyi avyatsyonnoi tekhnyky s prymenenyem metoda kombynyrovannoi fryktsyonnoi svarky: avtoref. dys. … kand. tekh. nauk: 05.07.02. M., 2012. 19 s.
Ponomarev Y.S. Povyshenye mekhanycheskykh y spetsyalnykh svoistv svarnykh shvov aliumynyevykh splavov metodom mykroplazmennoho oksydyrovanyia: dys. … kand. tekh. nauk: 05.02.10. Perm, 164 s.
Kumar P.V., Reddy G.M., Rao K.S. Microstructure and pitting corrosion of armor grade AA7075 aluminum alloy friction stir weld nugget zone-Effect of post weld heat treatment and addition of boron carbide. Defence Technology. Vol. 11, N 2. P. 166-173. https://doi.org/10.1016/j.dt.2015.01.002
King P.C., Cole I.S., Corrigan P.A., Hughes A.E., Muster T.H. FIB/SEM study of AA2024 corrosion under a seawater drop: Part I. Corrosion Science. 2011. Vol. 53, N 3. P. 1086-1096. https://doi.org/10.1016/j.corsci.2010.12.004
Belianov A.H. Vysokoskorostnoe anodnoe rastvorenye y vzaymodeistvye s vneshnymy sredamy metallov s ultramelkozernystoi strukturoi dlia razrabotky tekhnolohycheskykh protsessov elektrokhymycheskoho formoobrazovanyia: avtoref. dys. … kand. tekh. nauk : 05.03.01, 05.16.01. Ufa, 2002. 34 s.
Rabkyn D.M., Yahupolskaia L.N., Nykytyna A.V., Hrabyn V.F. Korrozyonnaia stoikost splava AMh6 y eho svarnykh soedynenyi v zavysymosty ot termoobrabotky. Avtomatycheskaia svarka. 1961. № 2. S. 40-48 https://doi.org/10.1007/BF00603401
Nykolaev H.A. Svarka v mashynostroenyy: Spravochnyk. Tom 2. M.: Mashynostroenye, 1978. 462 s.
Kablov E.N. Avyatsyonnoe materyalovedenye v XXI veke. Perspektyvy y zadachy. Avyatsyonnye materyaly. Yzbrannye trudy. Yubyleinyi nauchno-tekhnycheskyi sbornyk. M.: MYSYS, VYAM. 2002. 21 s.
Semenychev V.V. Korrozyonnaia stoikost y svoistva aliumynyevykh splavov avyatsyonnoho naznachenyia v uslovyiakh morskoho subtropycheskoho klymata: avtoref. dys. … kand. tekh. nauk : 05.02.01. M., 2006. 23 s.
Atroshenko A.A. Analyz konstruktsyonnoi prochnosty sostavnykh tonkostennykh konstruktsyi s boltovym soedynenyem elementov: dys. … kand. tekh. nauk: 05.02.09. Kharkov, 2016. 202 s.
Rao C.V., Reddy G.M., Rao K.S. Influence of tool pin profile on microstructure and corrosion behaviour of AA2219 Al-Cu alloy friction stir weld nuggets. https://doi.org/10.1016/j.dt.2015.04.004
Rambabu G., Naik D.B., Rao C.V., Rao K.S., Reddy G.M. Optimization of friction stir welding parameters for improved corrosion resistance of AA2219 aluminum alloy joints. Defence Technology. Vol. 11, N 4. P. 330-337. https://doi.org/10.1016/j.dt.2015.05.003
Gharavi F., Matoria K.A., Yunusa R., Othmanc N.K., Fadaeifarda F. Corrosion behavior of Al6061 alloy weldment produced by friction stir welding process. Journal of Materials Research and Technology. 2015. Vol. 4, N P. 314-322. https://doi.org/10.1016/j.jmrt.2015.01.007
Kumar P.V., Reddy G.M., Rao K.S. Microstructure, mechanical and corrosion behavior of high strength AA7075 aluminium alloy friction stir welds-Effect of post weld heat treatment. Defence Technology. Vol. 11, N 4. P. 362-369. https://doi.org/10.1016/j.dt.2015.04.003
Medhashree Н., Shetty A.N. Electrochemical corrosion study of Mg-Al-Zn-Mn alloy in aqueous ethylene glycol containing chloride ions. Journal of Materials Research and Technology. Vol. 6, N 1. P. 40-49. https://doi.org/10.1016/j.jmrt.2016.04.003
Davis J.R. Aluminum and Aluminum Alloys. 2001. ASM International. P. 351- https://doi.org/10.31399/asm.tb.aub.t61170351
Rao P.S., Sivadasan K.G., Balasubramanian P.K. Structure-property correlation on AA 2219 aluminium alloy weldments. Bulletin of Materials Science. 1996. Vol. 19, N 3. Р. 549-557. https://doi.org/10.1007/BF02744827
Li H., Zou J., Yao J., Peng H. The effect of TIG welding techniques on microstructure, properties and porosity of the welded joint of 2219 aluminum alloy. Journal of Alloys and Compounds. 2017. Vol. 727. Р. 531-539. https://doi.org/10.1016/j.jallcom.2017.08.157
Zhang D., Wang G., Wu A., Zhao Y., Li Q., Liu X., & et al. Study on the inconsistency in mechanical properties of 2219 aluminium alloy TIG-welded joints. Journal of Alloys and Compounds. Vol. 777. P. 1044-1053. https://doi.org/10.1016/j.jallcom.2018.10.182
Zhang D., Wu A., Zhao Y., Shan J., Wan Z., Wang G., & et al. Effects of the number of welding passes on microstructure and properties of 2219-C10S aluminum alloy TIG-welded joints. Journal of Materials Engineering and Performance. 2021. Vol. 30. P. 3537-3546. https://doi.org/10.1007/s11665-021-05655-x
Wan Z., Meng D., Zhao Y., Zhang D., Wang Q., Shan J., & et al. Improvement on the tensile properties of 2219-T8 aluminum alloy TIG welding joint with weld geometry optimizatio. Journal of Manufacturing Processes. 2021. Vol. 67. Р. 275-285. https://doi.org/10.1016/j.jmapro.2021.04.062
Zhang D., Li Q., Zhao Y., Liu X., Song J., Wang G., & et al. Microstructure and mechanical properties of three-layer TIG-welded 2219 aluminum alloys with dissimilar heat treatments. Journal of Materials Engineering and Performance. 2018. Vol. 27 (6). Р. 2938-2948. https://doi.org/10.1016/j.jmapro.2021.04.062
Niu L.Q., Li X.Y., Zhang L., Liang X.B., LiM. Correlation Between Microstructure and Mechanical Properties of 2219-T8 Aluminum Alloy Joints by VPTIG Welding. Acta Metallurgica Sinica (English Letters). 2017. Vol. 30. P. 438-446. https://doi.org/10.1007/s40195-016-0516-9 .
Zhang D.K., Wang G.Q., Wu A.P., Shan J.G., Zhao Y., Zhao T.Y., & et al. Effects of Post-weld Heat Treatment on Microstructure, Mechanical Properties and the Role of Weld Reinforcement in 2219 Aluminum Alloy TIG-Welded Joints. Acta Metallurgica Sinica (English Letters). 2019. Vol. 32, N 6. Р. 684-694. https://doi.org/10.1007/s40195-018-00869-w
Gupta R.K., Panda R., Mukhopadhyay A.K., Kumar V.A., Sankaravelayutham P., George K.M. Study of aluminum alloy AA2219 after heat treatment. Metal Science and Heat Treatment. 2015. Vol. 57, N 5. Р. 350-353. https://doi.org/10.1007/s11041-015-9888-0
Lu Y., Wang J., Li X., Li W., Li R., Zhou D. Effects of pre-deformation on the microstructures and corrosion behavior of 2219 aluminum alloys. Materials Science and Engineering: A. 2018. Vol. 723. Р. 204-211. https://doi.org/10.1016/j.msea.2018.03.041
Chen S., Li F., Liu Q., Chen K., Huang, L. Effect of Post-aging Heat Treatment on Strength and Local Corrosion Behavior of Ultrafine-Grained 2219 Al Alloy. Journal of Materials Engineering and Performance. 2020. Vol. 29, N 5. Р. 3420-3431. https://doi.org/10.1007/s11665-020-04818-6
Zhu Z. Y., Deng C. Y., Wang Y., Yang Z. W., Ding J. K., Wang D. P. Effect of post weld heat treatment on the microstructure and corrosion behavior of AA2219 aluminum alloy joints welded by variable polarity tungsten inert gas welding. Materials and Design. 2015. Vol. 65. Р. 1075-1082. https://doi.org/10.1016/j.matdes.2014.10.056
Baskutis S., Bendikiene R., Ciuplys A. Effect of weld parameters on mechanical properties and tensile behavior of tungsten inert gas welded AW6082-T6 aluminium alloy. Journal of Mechanical Science and Technology. 2019. Vol. 33, N 2. Р. 765-772. https://doi.org/10.1007/s12206-019-0131-6
Bai J.Y., Yang C.L., Lin S.B., Dong B.L., Fan C.L. Mechanical properties of 2219-Al components produced by additive manufacturing with TIG. The International Journal of Advanced Manufacturing Technology. 2016. Vol. 86, N 1. Р. 479-485. https://doi.org/10.1007/s00170-015-8168-x
Rao S.K., Reddy G.M., Rao K.S., Kamaraj M., Rao K.P. Reasons for superior mechanical and corrosion properties of 2219 aluminum alloy electron beam welds. Materials characterization. 2005. V 55, N 4-5. Р. 345-354. https://doi.org/10.1016/j.matchar.2005.07.006
Peng X.N., Qu W.Q., Zhang G.H. Influence of Welding Processes on Mechanical Properties of Aluminum Alloy 2219. Journal of Aeronautical Materials. 2009. Vol. 29, N 2. P. 57-60.
Syniavskyi V. S., Valkov V. D., Kalynyn V. D. Korrozyia y zashchyta aliumynyevykh splavov. 2 yzd. pererab. y dop. M.: Metallurhyia. 1986. 368 s.
Zhemchuzhnikova D., Mogucheva A., Kaibyshev R. Mechanical properties and fracture behavior of an Al-Mg-Sc-Zr alloy at ambient and subzero temperatures. Materials Science and Engineering. Vol. 565. P. 132-141. https://doi.org/10.1016/j.msea.2012.12.017
Tsaknopoulos K., Walde C., Tsaknopoulos D., Champagne V., Cote D. Characterization of Thermally Treated Gas-Atomized Al 5056 Powder. 2020. Vol. 13(18). Р. 1-11. https://doi.org/10.3390/ma13184051
Kurs M.H., Antypov V.V., Lutsenko A.N. y dr. Yntehralnyi koeffytsyent razrushenyia deformyruemykh aliumynyevykh splavov. Avyatsyonnye materyaly y tekhnolohyy. 2016. № 3(42). S. 24-32.
Morozova L.V., Zhehyna Y.P. Hryhorenko V.B. Osobennosty deformatsyonnoho povedenyia splava V-1469 v uslovyiakh sovmestnoho vozdeistvyia prylozhennoi nahruzky y korrozyonno-aktyvnoi sredy. Trudy VYAM. 2016. № 9(45). S. 85-96
Kurs M.H., Kutyrev A.E., Fomyna M.A. Yssledovanye korrozyonnoho razrushenyia deformyruemykh aliumynyevykh splavov pry laboratornykh y naturnykh yspytanyiakh. Trudy VYAM. 2016. № 8(10). S. 72-82
Chesnokov D.V., Antypov V.V., Kuliushyna N.V. Metod uskorennykh laboratornykh yspytanyi aliumynyevykh splavov s tseliu prohnozyrovanyia ykh korrozyonnoi stoikosty v uslovyiakh morskoi atmosfery. Trudy VYAM. № 5(41). S. 92-99.
Kurs M.H., Karymova S.A. Naturno-uskorennye yspytanyia: osobennosty metodyky y sposoby otsenky korrozyonnykh kharakterystyk aliumynyevykh splavov. Avyatsyonnye materyaly y tekhnolohyy. № 1. S. 51-57.
Frydliander Y.N., Hrushko O.E., Sheveleva L.M. Termychesky uprochniaemyi splav V1341 dlia kholodnoi lystovoi shtampovky. Metallovedenye y termycheskaia obrabotka metallov. 2004. № 9. S. 3-7
Zhemchuzhnykova D.A. Vlyianye deformatsyy na strukturu y mekhanycheskye svoistva Al-Mg-Sc-Zr splava: dys. … kand. tekh. nauk : 05.16.01. Belhorod. 2016. 128 s.
Pokhmurskyi V.I., Khoma M.S. Koroziina vtoma metaliv i splaviv. Lviv: SPOLOM, 2008. 301 s.
Pokliatskyi A.H., Fedorchuk V.E., Yavorskaia M.R. Stoikost k korrozyonnomu rastreskyvanyiu pod napriazhenyem soedynenyi splava AMh5M, poluchennykh arhonoduhovoi svarkoi neplaviashchymsia elektrodom y trenyem s peremeshyvanyem. Fizyko-khimichna mekhanika materialiv. № 51(5). S. 82-89. http://nbuv.gov.ua/UJRN/PHKhMM_2015_51_5_13
Fylatov Yu.A. Razvytye predstavlenyi o lehyrovanyy skandyem splavov Al- Tekhnolohyia lehkykh splavov. 2015. № 2. S. 19-22.
Zakharov V.V., Elahyn V.Y., Rostova T.D., Fylatov Yu.A. Metallovedcheskye pryntsypy lehyrovanyia aliumynyevykh splavov skandyem. Tekhnolohyia lehkykh splavov. 2010. № 1. S. 67-73.
Filatov Yu.A., Yelagin V.I., Zakharov V.V. New Al-Mg-Sc alloys. Materials Science and Engineering: А. 2000. Vol. 280, N 1. P. 97-101. https://doi.org/10.1016/S0921-5093(99)00673-5
Bondarev B.Y., Chuiko V.M., Kuznetsov A.N., Syhalov Yu.M., Frydliander Y.N. Perspektyvnye tekhnolohyy lehkykh y spetsyalnykh splavov. M.: Fyzmatlyt, 432 s. ISBN 5-9221-0716-Kh.
Mardarevych R., Vynar V., Katoda O. ta in. Trybokhimichni osoblyvosti aliuminiievoho splavu v korozyvnykh seredovyshchakh. Fizyko-khimichna mekhanika materialiv. № 3(10). S. 63-68.
Gureeva М.А., Grushko О.Ye. Scientific publications of VIAM staff 9. 2011. [Online]. Available: https://www.viam.ru/public/index.php?year=2011
Мondolfo L.F. Al uminum Alloys: Structure and Properties. London; Boston: Butterworths. 1979. 971 p. https://books.google.com.ua/books?id=Xf4kBQAAQBAJ&pg=PR3&source=gbs_selected_pages&cad=1#v=onepage&q&f=false
Archakova Z.N., Balakhontsev H.A., Basova Y.H. y dr. Aliumynyevye splavy : Struktura y svoistva polufabry-katov yz aliumynyevykh splavov : Spravochnyk. M.: Metallurhyia. 1974. 432 s.
Hatch J.E. Aluminium: properties and physical metallurgy. ASM International. 422 p.
Ando M., Suzuki Y. Effects of Cu Addition on Aging Behavior of Al-5%Si-0.3%Mg Alloy. In: Proceedings of the 12th International Conference on Aluminium Alloys. 2010. Р. 1045-1050. http://www.icaa-conference.net/ICAA12/pdf/3B-07.pdf
Wang S., Matsuda K., Kawabata T., Ikeno S. Variation of Aging Behavior for Al-Mg-Si Alloys with Different TMs Addition. In: Proceedings of the 12th International Conference on Aluminium Alloys. Р. 2008-2011. http://www.icaa-conference.net/ICAA12/pdf/P072.pdf
Fam Khonh Fu. Sovershenstvovanye tekhnolohyy termycheskoi obrabotky yzdelyi yz deformyruemykh aliumynyevykh slavov systemy Al-Mg-Si na osnove vybora rezhymov okhlazhdenyia pry zakalke: dys. … kand. tekh. nauk: 05.16.09. M., 2016. 143 s.
Kovářík Т., Zrník J. Microstructure Behavior of Al-Mg-Si Alloy Processed by ECAP And Its Thermal Stability. In: Proceedings of the 12th International Conference on Aluminium Alloys. 2010. Р. 1720-1725. http://www.icaa-conference.net/ICAA12/pdf/P014.pdf
Holder A.E., McMurray H.N., Williams G., Scamans G. Following the Kinetics of Localised Corrosion on AA6111 Using SVET. In: Proceedings of the 12th International Conference on Aluminium Alloys. 2010. P. 1475- http://www.icaa-conference.net/ICAA12/pdf/3E-08.pdf
Ichitani K., Kоуama K. Effect of Experimental Humidity on Fatigue Fracture of 6XXX-series Aluminum Alloys. In: Proceedings of the 12th International Conference on Aluminium Alloys. 2010. Р. 363- http://www.icaa-conference.net/ICAA12/pdf/IL-20.pdf
Frydliander Y. N., Hrushko O. E., Sheveleva L. M. y dr. Svoistva lystov yz vysokotekhnolohychnoho splava V1341. Metallovedenye y termycheskaia obrabotka metallov. № 12. S. 3-6.
Kurs M.H., Antypov V.V., Lutsenko A.N., Kutyrev A.E. Yntehralnyi koeffytsyent korrozyonnoho razrushenyia deformyruemykh aliumynyevykh splavov. Avyatsyonnye materyaly y tekhnolohyy. 2016. №3 (42). S. 24-32.
Kurs M.H. Prohnozyrovanye prochnostnykh svoistv obshyvky LA yz deformyruemoho aliumynyevoho splava V95o.ch.-T2 s prymenenyem yntehralnoho koeffytsyenta korrozyonnoho razrushenyia. Trudy VYAM. 2018. № 6. R. 101-109. https://doi.org/10.18577/2307-6046-2018-0-5-101-109
Tupytsyn A.M., Hladkov E.A., Hryhorenko V.B. Analyz tekhnolohycheskykh vozmozhnostei sovremennykh sposobov avtomatycheskoi svarky krupnohabarytnykh tonkostennykh yzdelyi estvetstvennoho naznachenyia yz aliumynyevykh splavov. Hlobalnaia yadernaia bezopasnost. 2016. № 1(18). S. 66-75. https://doi.org/10.26583/gns-2016-01-08
Klochkov H.H., Klochkova Yu.Yu., Romanenko V.A. Novyi splav systemy Al-Su-Mn dlia yzdelyi kosmycheskoi tekhnyky. Trudy VYAM. 2015. № 4 (01). S. 3-9.
Ovchynnykov V.V., Hrushko O.E. Vysokotekhnolohychnyi svaryvaemyi aliumynyevyi splav V1341 systemy Al-Mg-Si. Tekhnolohyy mashynostroenyia. 2005. S. 2-11. https://old.mospolytech.ru/mio/iblock/651/ovch.pdf
Klochkov H.H., Klochkova Yu.Yu., Romanenko V.A. Vlyianye temperatury deformatsyy na strukturu y svoistva pressovannykh profylei splava V-1341 systemy Al-Mg-Si. Trudy VYAM. T. 45, № 9. S. 3-11.
Morozova L.V., Zhehyna Y.P., Hryhorenko V.B. Osobennosty deformatsyonnoho povedenyia splava V-1469 v uslovyiakh sovmestnoho vozdeistvyia prylozhennoi nahruzky y korrozyonno-aktyvnoi sredy. Trudy VYAM. 2016. T. 45, № 9. S. 85-96.
Hryhorenko V.B., Morozova L.V., Zhehyna Y.P., Fomyna N.A. Osobennosty nakoplenyia povrezhdenyi v poverkhnostnykh sloiakh aliumynyi-lytyevykh splavov 1441 y V-1469 pry vozdeistvyy korrozyonnoi sredy y prylozhennoi zahruzky. Trudy VYAM. 2016. T. 45, № 7. S. 3-12.
Semenychev V.V. Korrozyonnaia stoikost lystov splava D16ch.-t v morskykh subtropykakh. Trudy VYAM. 2014. T. 11, № 7. S. 17-34.
Karymova S.A., Zhylykov V.P., Lapaev A.V. y dr. Naturno-uskorennye yspytanyia aliumynyevykh splavov v uslovyiakh vozdeistvyia morskoi atmosfery. Korrozyia: materyaly, zashchyta. 2012. № 10. S. 3-7.
ASTM G112-92. Standard Guide for Conducting Exfoliation Corrosion Tests in Aluminum Alloys.
Kurs M.H., Karymova S.A., Makhsydov V.V. Sravnenye korrozyonnoi stoikosty deformyruemykh aliumynyevykh splavov po rezultatam naturnykh y naturno-uskorennykh yspytanyi pod navesom. Voprosy materyalovedenyia. T. 73, № 1. S. 182-195.
Q-Lab Corporation. Technical Bulletin LL-9025.2. 2011. Р.1-8.
ASTM G7-05. Standard Practice for Atmospheric Environmental Exposure Testing of Nonmetallic
ASTM D1435-20. Standard Practice for Outdoor Weathering of Plastics.
SAE J 1976-2012 (SAE J1976-2012). Outdoor Weathering Of Exterior Materials.
ASTM D4141-01. Standard Practice For Conducting Black Box And Solar Concentrating Exposures Of Coatings.
Pavlovskaia T.H., Deshevaia E.A., Zaitsev S.N. y dr. Korrozyonnaia stoikost aliumynyevykh splavov v uslovyiakh, ymytyruiushchykh faktory kosmycheskoho poleta. Trudy VYAM. 2016. T. 39, № 3. S. 85-94.
Khokhlatova L.B., Kolobnev N.I., Antipov V.V., Karimova S.A., Rudakov A.G., Oglodkov M.S. Effect Of Corrosion Medium On The Fatigue Crack Growth Rate In Aluminium Alloys. Труды ВИАМ. 2013. № 3 (05).
Frydliander Y.N., Hrushko O.E., Shamrai V.F., Klochkov H.H. Vysokoprochnyi konstruktsyonnyi Ai-Su-Li-Mg-splav ponyzhennoi plotnosty, lehyrovannyi serebrom. Metallovedenye y termycheskaia obrabotka metallov. T. 624, № 6. S. 3-7.
Yvanova A.O., Vakhromov R.O., Hryhorev M.V., Senatorova O.H. Yssledovanye vlyianyia malykh dobavok serebra na strukturu y svoistva resursnykh splavov systemy Al-Cu-Mg. Trudy VYAM. 2014. № 10 (01). S. 3-11.
Riabov D.K., Kolobnev N.Y., Kochubei A.Ya., Zavodov A.V. Yzmenenye mekhanycheskykh svoistv lystov yz splava 1913 pry vvedenyy skandyia. Avyatsyonnye materyaly y tekhnolohyy. 2014. № 4. S. 3-8.
Morozova L.V., Yskhodzhanova Y.V. Yssledovanye zakonomernostei yzmenenyia relefa poverkhnosty obraztsov yz aliumynyilytyevykh splavov metodom lazernoi mykroskopyy. Nauchnyi vestnyk MHTU HA. 2014. T. 8, № 10. S. 11-25.
Baikov V.M., Lapaev A.V., Shapkyn V.S. Yssledovanye kharakterystyk ustalostnoi dolhovechnosty y treshchynostoikosty pry korrozyonnom porazhenyy aliumynyevoho splava 1163, prymeniaemoho v konstruktsyiakh sovremennykh samoletov. Nauchnyi vestnyk MHTU HA. 2011. № 163. S. 110-116.
AMS-QQ-A-250/30A. Tekhnichni vymohy. Aliuminiievyi splav 2219. Lyst i plastyna
DSTU HOST 10157:2019. Arhon hazopodibnyi ta ridkyi. Tekhnichni umovy (HOST 10157-2016, IDT)
Labur T.M., Dehtiarev M.A., Malyshko V.Y. y dr. Tekhnolohyia remonta svarnykh shvov aliumynyevoho splava 2219. Mizhnarodna konferentsiia «Kosmycheskye tekhnolohy: nastoiashchee y budushchee» (21-24 travnia 2019 r., DP «KB “Pivdenne” im. M.K. Yanhelia»): Tezy dopovidei. 2019. S. 82.
Labur T. M., Dehtiarev M.A., Malyshko V. Y. y dr. Vlyianye tekhnolohy duhovoi svarky na strukturu y mekhanycheskye svoistva soedynenyi splava 2219. Mizhnarodna konferentsiia «Kosmycheskye tekhnolohy: nastoiashchee y budushchee» ( 21-24 travnia 2019 r., DP «KB “Pivdenne” im. M.K. Yanhelia»): Tezy dopovidei. 2019. S. 82-83.
Nyrkova L. I., Labur T. M., Shevtsov Ye. I., Nazarenko O. P., Dorofieiev A. V. Koroziino-mekhanichna stiikist zvarnykh ziednan splavu 2219 v umovakh, modeliuiuchykh ekspluatatsiini. Avtomatychne zvariuvannia. 2021. № 10. C. 19-28. https://doi.org/10.37434/as2021.10.03
Nyrkova L.I., Labur T.M., Shevtsov E.I., Nazarenko O.P., Dorofeev A.V. Osadchuk S.O., & et al. Complex of properties of 2219 alloy weld joint in T62 state under modeling operating conditions. Space Science and Technology. 2022. Vol. 28, N 2. P. 14-29. https://doi.org/10.15407/knit2022.02.014
DSTU EN ISO 10042:2019. Zvariuvannia. Ziednannia z aliuminiiu ta yoho splaviv, vykonani duhovym zvariuvanniam. Rivni yakosti zalezhno vid defektiv (EN ISO 10042:2018, IDT; ISO 10042:2018, IDT)
Nyrkova L I. , Osadchuk S.O., Labur T.M., Shevtsov E.I., Nazarenko O.P., Dorofeev A.V. Comparative Studies of the Properties of Heat-Treated Welded Joints of AA2219 Alloy. Metallofizika I Noveishie Tekhnologii. 2023. Vol. 45, N 5. P. 615-630. https://doi.org/10.15407/mfint.45.05.0615
Beletskyi V.M., Kryvov H.A. Aliumynyevye splavy (sostav, svoistva, tekhnolohyia, prymenenye): Spravochnyk ; Pod red. akad. Y.N. Frydliandera. Kyev: Komyntekh, 2005. 365 s.
Yshchenko A.Ya., Labur T.M., Bernadskyi V.N., Makovetskaia O.K. Aliumynyi y eho splavy v sovremennykh svarnykh konstruktsyiakh. Kyev: Ekotekhnolohyia, 2006. 112 s.
Svarka v samolёtostroenyy; Pod redaktsyei akademyka B.E. Patona. Kyev: MYYVTs, 1998. 695 s.
Іrving B. Welding the four most popular aluminum alloys. Welding Journal. 1994. Vol.73, N 2. P.51-55. ISSN 0043-2296
Ishchenko A.Ya., Labur T.M. Svarka sovremennykh konstruktsyi yz aliumynyevykh splavov. Kyev: Naukova dumka, 2013. 415 s.
Rabkyn D.M. Metallurhyia svarky plavlenyem aliumynyia y eho splavov. Kyev: Naukova dumka, 1986. 256 s.
Rabkyn D.M., Yhnatev V.H., Dovbyshchenko Y.V. Duhovaia svarka aliumynyia y eho splavov. M: Mashynostroenye, 1982. 95 s.
Lebedev V.A. Nekotorye osobenosty duhovoi mekhanyzyrovanoi svarky aliumynyia s upravliaemoi ympulsnoi podachei elektrodnoi provoloky. Svarochnoe proyzvodstvo. 2007. №11. S. 26-30.
Zhernosekov A.M., Andreev V.V. Ympulsno-duhovaia svarka plaviashchymsia elektrodom (obzor). Avtomatycheskaia svarka. 2007. № 10. S. 48-52.
Labur T.M., Zhernosekov A.M., Yavorskaia M.R., Pashulia M.P. Ympulsno-duhovaia svarka plaviashchymsia elektrodom aliumynyevykh splavov s rehulyruemoi formoi ympulsov. Svarochnoe proyzvodstvo. 2013. №11. S.3-7.
Colchem D. Application des calculs aux éléments finis pour définir et valider des modèles analytiques de calcul de contrainte sur un assemblage bout À bout en alliage d’aluminium. Soudage et techniques connexes. 2000. Vol. 54, N 3-4. P. 3-16.
Labur T.M., Bunchuk Yu.P., Malyshko V.I., Yavorskaia M.R., Koval V.A., Shynkarenko V.S. Metod remonta svarnykh shvov plaviashchymsia elektrodom. Materyaly shestoi mezhdunarodnoi konferentsyy «Kosmycheskye tekhnolohyy: nastoiashchee y budushchee» (23-26 Maia, 2017 h., h. Dnepr): Tezysy dokladov. Dnepr, 2017. 76 s.
Labur T. M., Ostash O. P., Pashulia M. P. y dr. Osobennosty formyrovanyia struktury y mekhanycheskykh svoistv svarnykh soedynenyi aliumynyevoho splava AMh5M, vypolnennykh plaviashchymsia elektrodom pry raznykh skorostiakh svarky y prostranstvennoho polozhenyia stykov. Svarochnoe proyzvodstvo. 2018. №4. S.3-11. https://doi.org/10.37434/as2021.04.05
Labur T.M., Yavorska M.R., Koval V.A. Vplyv shvydkosti impulsno-duhovoho zvariuvannia na strukturu ta vlastyvosti ziednan aliuminiievoho splavu AMh5M, otrymanykh u riznykh prostorovykh polozhenniakh stykiv. Avtomatychne zvariuvannia. 2021. № 9. S. 31-37. https://doi.org/10.37434/as2021.09.05
Nyrkova L.I., Labur T.M., Osadchuk S.O. ta in. Elektrokhimichni vlastyvosti zvarnykh ziednan splavu systemy Al-Mg, otrymanykh plavkym elektrodom u riznykh prostorovykh polozhenniakh. Naukovo-tekhnichna konferentsiia Problemy zvariuvannia ta sporidnenni tekhnolohii: Materialy
Vseukrainskoi konferentsii z mizhnarodnoiu uchastiu, shcho prysviachena 60 richchiu kafedry zvariuvalnoho vyrobnytstva NUK( 17-19 veresnia 2019 r., m. Mykolaiv). Mykolaiv, 2019. S. 18.
Feihenbaum Yu.M., Dubynskyi S.V. Vlyianye sluchainykh ekspluatatsyonnykh povrezhdenyi na prochnost y resurs konstruktsyi vozdushnykh sudov. Nauchnyi vestnyk MHTU HA. 2013. № 187.S. 83-91.
Wang Wang S., Matsuda K., Kawabata T., Ikeno S. Variation of aging behavior for Al-Mg-Si alloys with different TMs addition. In: Proceedings 12th International Conference on Aluminium Alloys. 2010. P. 2008-2011. http://icaa-conference.net/ICAA12/pdf/P072.pdf
Frydliander Y. N., Hrushko O. E., Shamrai V. F., Klochkov H. H. Vysokoprochnyi konstruktsyonnyi Al-Cu-Li-Mg splav ponyzhennoi plotnosty, lehyrovannyi serebrom. Trudy VYAM. 2007. T. 6 (3).
Holder A. E., McMurray H. N., Williams G., Scamans G. Following the kinetics of localised corrosion on AA6111 using SVET. In: Proceedings 12th International Conference on Aluminium Alloys. 2010. P. 1475-1480. http://www.icaa-conference.net/ICAA12/pdf/3E-08.pdf
Koval V.A., Labur T.M., Yavorska M.R. Vlastyvosti ziednan aliuminiievoho splavu marky V1341T v umovakh TIG zvariuvannia. Avtomatychne zvariuvannia. 2020. № 2. S.38-43. https://doi.org/10.37434/as2020.02.07
Ostash О.P., Labur T.М., Holovatyuk Y.V., & et al. Structural Strength of Welded Joints of Thermally Hardened Alloy of the Al-Cu-Mg System. Materiasls Science. 2020. Vol. 55. P. 548-554. https://doi.org/10.1007/s11003-020-00337-w
Koval V.A., Labur T.M., Yavorska M.R. Vplyv termichnoi obrobky na strukturu i mekhanichni vlastyvosti tonkolystovoho aliuminiievoho splavu V1341 ta yoho zvarnykh ziednan, vykonanykh TIG zvariuvanniam. Avtomatychne zvariuvannia. 2020. №7. S. 25-31. https://doi.org/10.37434/as2020.07.03
Labur Т.М., Ostash O.P., Holovatyuk Y.V., Koval V. А., Shynkarenko V. S. Influence of Alloying and Thermal Treatment on the Strength and Cyclic Crack Resistance of Welded Joints of Alloys of the Al-Cu-Mg System. Part 1. Materiasls Science. 2017. Vol. 53. Р. 131-140. https://doi.org/10.1007/s11003-017-0054-2
Labur Т.М., Ostash O.P., Holovatyuk Y.V., Koval V. А., Shynkarenko V. S. Influence of Alloying and Thermal Treatment on the Strength and Cyclic Crack Resistance of Welded Joints of Alloys of the Al-Cu-Mg System. Part 2. Materiasls Science. 2018. Vol. 53. P. 453-459. https://doi.org/10.1007/s11003-018-0094-2
Holovatyuk Y.V., Poklyats’kyi A.H., Ostash O.P., Labur Т.М. Elevation of the Structural Strength of Welded Joints of Sheets Made of Alloys of the Al-Cu-Mg System. Materiasls Science. 2018. Vol. 54. P. 412-420. https://doi.org/10.1007/s11003-018-0200-5
Nyrkova L.I., Labur T.M., Riabyko O.M., Borysenko Yu.V. Koreliatsiia mizh elektrokhimichnymy vlastyvostiamy zvarnoho ziednannia aliuminiievoho splavu systemy Al-Mg-Cu-Si ta yoho stiikistiu proty lokalnoi korozii. Visnyk Kyivskoho natsionalnoho universytetu tekhnolohii ta dyzainu. Seriia: Tekhnichni nauky. 2018. № 6. S. 71-77. http://nbuv.gov.ua/UJRN/vknutdtn_2018_6_10 https://doi.org/10.30857/1813-6796.2018.6.8
Lyudmila Nyrkova, Svetlana Osadchuk, Tetiana Labur, Yulia Borisenko. Сorrosion resistance of the welded junction of aluminum alloy of the Al-Mg-Si-Cu system. Mechanics and Advanced Technologies. 2020. N 3(90). P. 64-72. https://doi.org/10.20535/2521-1943.2020.0.207069
Nyrkova L.І., Osadchuk S.О., Kovalenko S.Y., Klymenko A.V., Labur T.М. Influence of Heat Treatment on the Corrosion Resistance of Welded Joints of Aluminum Alloys of the Al-Mg-Si-Сu System. Materials Science. 2021. Vol. 56, N 5. P. 642-648. https://doi.org/10.1007/s11003-021-00476-8
Nyrkova L.I., Labur T.M., Osadchuk S.O., Yavorska M.R. Koroziino-mekhanichna tryvkist zvarnykh ziednan aliuminiievoho splavu V1341, otrymanykh arhonoduhovym zvariuvanniam vilnoiu ta stysnutoiu duhoiu. Avtomatychne zvariuvannia. 2020. № 12. C. 44-51. https://doi.org/10.37434/as2020.12.06
Nyrkova L.I., Osadchuk S.O., Labur T.M., Yavorska M.R. Effect of microstructure on corrosion-mechanical endurance of welded joints of aluminium alloy V1341T produced by manual argon-arc welding. FME Transactions. 2021. Vol. 49, N 2. Р. 374-383. https://doi.org/10.5937/fme2102374N
Nyrkova L., Osadchuk S., Kovalenko S., Klymenko A., Labur T. The influence of heat treatment on the corrosion resistance of the welded joints of aluminum alloy of the system Al-Mg-Si-Сu. Problems of corrosion and corrosion protection of materials (Corrosion-2020). Lviv, 2020. P.27.
Nyrkova L., Goncharenko L., Osadchuk S., Labur T., Yavorska M. Influence of the time factor and heat treatment on mechanical properties of Al-Mg-Si-Сu alloy welded joints in corrosive environment. 6th International Conference on Structural Integrity and Durability (2022, September 19-23, Dubrovnik). Croatia. Book of Abstracts. Р.65.
Nyrkova L., Goncharenko L., Osadchuk S., Labur T. Influence of the time factor on corrosion-mechanical properties of Al-Mg-Si-Сu alloy welded joint. https://www.ipm.lviv.ua/corrosion2022/Book_abstract_Corrosion2022-site.pdf
Nyrkova L., Goncharenko L., Osadchuk S., Labur T., Yavorska M. Influence of exposure in a corrosive environment on ultimate stress of heat-treated welded joints of Al-Mg-Si-Сu alloy. Corrosion Reviews. 2023. Vol. 41, N 4. P. 485-496 https://doi.org/10.1515/corrrev-2022-0076
Albert D. Aluminum alloys in arc welded constructions. Weld. World. 1993. Vol. 32, N 3. P. 97-114.
Wemah K. Equipment for Aluminium Welding. Svetsaren. 2000. №2. P.11-13. https://infosolda.com.br/wp-content/uploads/Downloads/Artigos/equipamentos/equipament-for-aluminium-welding.pdf
Norlin A. A century of aluminium — a product of the future. Svetsaren. 2000. N 2. P.31—33. https://infosolda.com.br/wp-content/uploads/Downloads/Artigos/processos_solda/EN-001-A-century-of-aluminium.pdf
Araya M. Spacial Constitution and Expression in the Aluminum Structure) The Future and the Past of the Aluminum Structure. Kei Kinzoku Yosetsu (Journal of Light Metal Welding and Construction). 2003.
TWI team is match for aerospace challenge. TWI Connect. 1995. N 73. P. 12.
Hibben M. Tailored Blanks aus Aluminium. ATZ. Automobiltechnische Zeitschrift. P. 14-18.
Colchen D. Application des calculs aux éléments finis pour définir et valider des modèles analytiques de calcul de contrainte sur un assemblage bout À bout en alliage d’aluminium. Soudage et techniques connexes. 2000. Vol. 54, N 3-4. P. 3-16.
Yasuda K., Isizawa Y., Kitaura I. Study on hybrid joining method using TIG arc welding. I. Kei Kinzoku Yosetsu (Journal of Light Metal Welding and Construction)(Japan). 1996. Vol. 34, N 11. P. 1-7.
Tempus G. New aluminium alloys and fuselage structures in aircraft design. Wekstoffe Für Transport und Verkehr. 2001.
Wada J. Application of Pre-ribbed Aluminum Alloy Plate in Architectural Structure. Kei Kinzoku Yosetsu. Journal of Light Metal Welding and Construction. 2003. Vol. 41, N 10. P. 472-476.
Vollertsen F. Innovative welding strategies for the manufacture of large aircraft. In: Proceedings IIW international Conference. 2004. P. 237- 253.
Teh N.J. Small joints make a big difference. TWI Connect. 2006. Vol. 143, N 4. P. 1-7.
Mueler S., Volpone L. Сurrent status of joining processes of Aluminium Structure: a critical review. of the International «Joining of Aluminium Structure» (December 03-05, 2007). M., 2007. Р. 1-15.
Larquer R., Reis R.P. Gas tungsten arc welding with synchronized magnetic oscillation. Joining technologies. 2016. P. 53-76. https://doi.org/10.5772/64158
Dreher M. , Füssel U., Rose S., Häßler M., Hertel M., Schnick M. Methods and results concerning the shielding gas flow in GMAW. Welding in the World. 2013. Vol. 57. P. 391-410. https://doi.org/10.1007/s40194-013-0038-2
Kanemaru S., Sasaki T., Sato T., Mishima H., Tashiro S., Tanaka M. Study for TIG-MIG hybrid welding process. Welding in the World. 2014. Vol. 58. P. 11-18. https://doi.org/10.1007/s40194-013-0090-y
Thomy C., Vollertsen F.. Laser-MIG hybrid welding of aluminium to steel-effect of process parameters on joint properties. Welding in the World. 2012. Vol. 56. P. 124-132. https://doi.org/10.1007/BF03321356
Mokrov O., Simon M., SharmaR., Reisgen U. Effects of evaporation-determined model of arc-cathode coupling on weld pool formation in GMAW process simulation. Welding in the World. 2020. Vol. 64. P. 847-856. https://doi.org/10.1007/s40194-020-00878-3
Dutra J.C., Gonçalvese Silva R.H., Riffel K.C., MarquesC. High-performance GMAW process for deep penetration applications. Welding in the World. 2020. Vol. 64. P. 999-1009. https://doi.org/10.1007/s40194-020-00889-0
Babych O. A., Korzhyk V. M., Grynyuk А. А., Khaskin V. Y., Dong C., Han S. (2020). Hybrid welding of aluminium 1561 and 5083 alloys using plasma-arc and consumable electrode arc (Plasma-MIG). The Paton Welding Journal. 2020. Vol.7, N11-22. https://doi.org/10.37434/tpwj2020.07.02
Portalnyi stend zi zvariuvalnym robotom vyrobliaie aliuminiievi vahony dlia zaliznychnoho transportu. Avtomatychne zvariuvannia. 2021. № 4. S. 53-54. https://patonpublishinghouse.com/as/pdf/2021/as202104part.pdf