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Characteristics of the deformation diagram of AMg6 alloy

НазваCharacteristics of the deformation diagram of AMg6 alloy
Назва англійськоюCharacteristics of the deformation diagram of AMg6 alloy
АвториSerhii Fedak, Oleg Yasnii, Iryna Didych, Nadiya Kryva
ПринадлежністьTernopil Ivan Puluj National Technical University, Ternopil, Ukraine
Бібліографічний описCharacteristics of the deformation diagram of AMg6 alloy / Serhii Fedak, Oleg Yasnii, Iryna Didych, Nadiya Kryva // Scientific Journal of TNTU. — Tern.: TNTU, 2023. — Vol 110. — No 2. — P. 33–39.
Bibliographic description:Fedak S., Yasnii O., Didych I., Kryva N. (2023) Characteristics of the deformation diagram of AMg6 alloy. Scientific Journal of TNTU (Tern.), vol 110, no 2, pp. 33–39.
DOI: https://doi.org/10.33108/visnyk_tntu2023.02.033
УДК

539.3

Ключові слова

mechanical characteristics, aluminium alloys, jump-like deformation, deformation diagram.

The parameters of the deformation of AMg6 alloy diagram under conditions of uniaxial tension were studied, taking into account the areas of material strengthening. The dependence of the change in magnitude of deformation occurring after jump-like increments in deformation caused by the destruction of dispersed phases in this alloy was revealed. A method of taking into account the revealed regularities in predicting the general deformation of AMg6 alloy based on the histogram of distribution of dispersed particles in the material is proposed.

ISSN:2522-4433
Перелік літератури

1.    Strizhalo V. A., Vorobev E. V., 1999. Standardization of the strength of metals under conditions of low-temperature instability of plastic deformation and the action of strong magnetic fields. Strength of material 31, 459–466.
2.    Vorobiov Ie., Anpilohova T. Nyzkotemperaturna strybkopodibna deformatsiia metaliv: lokalizovane poshkodzhennia ta vtrata mitsnosti. Visnyk Ternopilskoho natsionalnoho tekhnichnoho universytetu. 2013. No. 3. Р. 113–123. [In Ukrainian].
3.    Hryhorova T. V., Shumilin S. E., Shapovalov Yu. O., Semerenko Yu. O., Tabachnikova O. D., Tykhonovskyi M. A., Tortika O. S., Tsekhetbauer M. I., Shafler E. Nyzkotemperaturni mekhanichni vlastyvosti vysokoentropiinoho splavu Fe40Mn40Co10Cr10, plastychnist yakoho indukovana dviinykuvanniam Visnyk KhNU imeni V. N. Karazina, seriia “Fizyka”. Vyp. 32. 2020. Р. 41–48. [In Ukrainian].
4.    Iasnii P., Halushchak M. Metodyka i deiaki rezultaty doslidzhennia vplyvu tsyklichnoho navantazhuvannia na diahramy deformuvannia splavu AMh-6. Visnyk Ternopilskoho derzhavnoho tekhnichnoho universytetu. 1998. Tom 3. Chyslo 4. Р. 62–66. [In Ukrainian].
5.    Stryzhalo V. A. Tsyklycheskaia prochnost y polzuchest metallov pry malotsyklovom nahruzhenyy v uslovyiakh nyzkykh y vыsokykh temperatur. K.: Nauk. dumka, 1978. 238 р. [In Russian].
6.    Iasnii P. V., Hlado V. B. Vplyv tsyklichnoi roztiahovoi skladovoi navantazhennia na dyslokatsiinu strukturu splavu Amh6. Fizyko-khimichna mekhanika materialiv. 2002. No. 3. Р. 63–68. [In Ukrainian]
7.    Yasnii P. V., Fedak S. I., Glado V. B., Galushchak M. P., 2004. Jumplike deformation in AMg6 aluminum alloy in tension. Strength of Materials 36. Р. 113–118.
8.    Karpynos D. M., Tuchynskyi L. Y., Sapozhnykova A. B. y dr. Kompozytsyonnыe materyalы v tekhnyke.  K.: Tekhnika, 1985. 152 р. [In Russian].
9.    Fedak S., 2003. Jumplike deformation of the AMg6 alloy during creep. Visn. Ternopil. Derzh. Tekhn. Univ. 8. Р. 16–23. [In Ukrainian].
10.    Iasnii P. V., Halushchak M. P., Stoianova O. M., Fedak S. I. Mikrostrukturni osoblyvosti deformuvannia splavu AMh6 pry povzuchosti ta roztiahu. Fizyko-khimichna mekhanika materialiv. 2001. No. 5. Р. 64–68. [In Ukrainian].
11.    Smola A., Vishwanathan S. V. N., 2010. Introduction to Machine Learning, Cambridge University Press, P. 234.
12.    Hastie T., Tibshirani R., Friedman J., 2009. The Elements of Statistical Learning: Data Mining, Inference, and Prediction. In: New York, Springer. P. 764.
13.    Yasniy O., Didych I., Fedak S., Lapusta Yu. Modeling of AMg6 aluminum alloy jump-like deformation properties by machine learning methods. Procedia Structural Integrity. Vol. 28. 2020. P. 1392–1398.
14.    Didych I., Yasniy O., Fedak S., Lapusta Yu. Prediction of jump-like creep using preliminary plastic strain.  Procedia Structural Integrity. Vol. 36. 2022. P. 166–170.
15. Yasnii O. P., Fedak S. I., Didych I. S. Modeliuvannia kharakterystyk pereryvchastoi tekuchosti splavu AMh6 neironnymy merezhamy. Pratsi VI Mizhnarodnoi naukovo-tekhnichnoi konferentsii „Poshkodzhennia materialiv pid chas ekspluatatsii, metody yoho diahnostuvannia i prohnozuvannia“, 24–27 veresnia 2019 r. T.: TNTU, 2019. P. 124–127. [In Ukrainian]

References:

1.    Strizhalo V. A., Vorobev E. V., 1999. Standardization of the strength of metals under conditions of low-temperature instability of plastic deformation and the action of strong magnetic fields. Strength of material 31, 459–466.
2.    Vorobiov Ie., Anpilohova T. Nyzkotemperaturna strybkopodibna deformatsiia metaliv: lokalizovane poshkodzhennia ta vtrata mitsnosti. Visnyk Ternopilskoho natsionalnoho tekhnichnoho universytetu. 2013. No. 3. Р. 113–123. [In Ukrainian].
3.    Hryhorova T. V., Shumilin S. E., Shapovalov Yu. O., Semerenko Yu. O., Tabachnikova O. D., Tykhonovskyi M. A., Tortika O. S., Tsekhetbauer M. I., Shafler E. Nyzkotemperaturni mekhanichni vlastyvosti vysokoentropiinoho splavu Fe40Mn40Co10Cr10, plastychnist yakoho indukovana dviinykuvanniam Visnyk KhNU imeni V. N. Karazina, seriia “Fizyka”. Vyp. 32. 2020. Р. 41–48. [In Ukrainian].
4.    Iasnii P., Halushchak M. Metodyka i deiaki rezultaty doslidzhennia vplyvu tsyklichnoho navantazhuvannia na diahramy deformuvannia splavu AMh-6. Visnyk Ternopilskoho derzhavnoho tekhnichnoho universytetu. 1998. Tom 3. Chyslo 4. Р. 62–66. [In Ukrainian].
5.    Stryzhalo V. A. Tsyklycheskaia prochnost y polzuchest metallov pry malotsyklovom nahruzhenyy v uslovyiakh nyzkykh y vыsokykh temperatur. K.: Nauk. dumka, 1978. 238 р. [In Russian].
6.    Iasnii P. V., Hlado V. B. Vplyv tsyklichnoi roztiahovoi skladovoi navantazhennia na dyslokatsiinu strukturu splavu Amh6. Fizyko-khimichna mekhanika materialiv. 2002. No. 3. Р. 63–68. [In Ukrainian]
7.    Yasnii P. V., Fedak S. I., Glado V. B., Galushchak M. P., 2004. Jumplike deformation in AMg6 aluminum alloy in tension. Strength of Materials 36. Р. 113–118.
8.    Karpynos D. M., Tuchynskyi L. Y., Sapozhnykova A. B. y dr. Kompozytsyonnыe materyalы v tekhnyke.  K.: Tekhnika, 1985. 152 р. [In Russian].
9.    Fedak S., 2003. Jumplike deformation of the AMg6 alloy during creep. Visn. Ternopil. Derzh. Tekhn. Univ. 8. Р. 16–23. [In Ukrainian].
10.    Iasnii P. V., Halushchak M. P., Stoianova O. M., Fedak S. I. Mikrostrukturni osoblyvosti deformuvannia splavu AMh6 pry povzuchosti ta roztiahu. Fizyko-khimichna mekhanika materialiv. 2001. No. 5. Р. 64–68. [In Ukrainian].
11.    Smola A., Vishwanathan S. V. N., 2010. Introduction to Machine Learning, Cambridge University Press, P. 234.
12.    Hastie T., Tibshirani R., Friedman J., 2009. The Elements of Statistical Learning: Data Mining, Inference, and Prediction. In: New York, Springer. P. 764.
13.    Yasniy O., Didych I., Fedak S., Lapusta Yu. Modeling of AMg6 aluminum alloy jump-like deformation properties by machine learning methods. Procedia Structural Integrity. Vol. 28. 2020. P. 1392–1398.
14.    Didych I., Yasniy O., Fedak S., Lapusta Yu. Prediction of jump-like creep using preliminary plastic strain.  Procedia Structural Integrity. Vol. 36. 2022. P. 166–170.
15. Yasnii O. P., Fedak S. I., Didych I. S. Modeliuvannia kharakterystyk pereryvchastoi tekuchosti splavu AMh6 neironnymy merezhamy. Pratsi VI Mizhnarodnoi naukovo-tekhnichnoi konferentsii „Poshkodzhennia materialiv pid chas ekspluatatsii, metody yoho diahnostuvannia i prohnozuvannia“, 24–27 veresnia 2019 r. T.: TNTU, 2019. P. 124–127. [In Ukrainian]

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