Hydrogen diffusion kinetics under different conditions applied to VT6 alloy

Research of hydrogen diffusion in VT6 alloy is carried out considering different types of heat treating and hydrogen charging. The influence of microalloying on the susceptibility to hydride formation and embrittlement of titanium alloys is analyzed, and also effects of an oxide film on hydrogen charging during heat treatment without protective atmosphere, are studied.

titanium alloys, hydrogen charging, alloying, oxide film

1. Geld, P.V., Ryabov, R.A., Vodorod v metallakh i splavakh [Hydrogen in metals and alloys], Moscow: Metallurgiya, 1974.

2. Zwicker, U., Titan und Titanlegierungen, Berlin, 1974.

3. Kolachev, B.A., Vodorodnaya khrupkost metallov [Hydrogen fragility of metals], Moscow: Metallurgiya, 1985.

4. Shmykov, A.A., Khoroshaylov, V.G., Gulikhandanov, E.L., Termodinamika i kinetika protsessov vzaimodeystviya kontroliruemykh atmosfer s poverkhnostyu stali [Thermodynamics and kinetics of the processes of interaction of controlled atmospheres with a steel surface], Moscow: Metallurgiya, 1991.

5. Kolachaev, B.A., Livanov, V.A., Elagin, V.I., Metallovedenie i termicheskaya obrabotka tsvetnykh metallov i splavov [Metallurgy and heat treatment of non-ferrous metals and alloys], 2nd ed., Moscow: Metallurgiya, 1981.

6. Eliezer, D., Tal-Gutelmacher,E., Cross, C.E., Boellinghaus, T., Hydrogen absorption and desorption in a duplex annealed Ti–6Al–4V alloy during exposure to different hydrogen-containing environments, Materials Science and Engineering, 2006, A433, pp. 298–304.

7. Burnyshev, I.N., Kalyuzhny, D.G., O katodnom navodorozhivanii titana [About cathode hydrogen charging of titanium], Khimicheskaya fizika i mezoskopiya, 2014, V. 16, No 2, pp. 250–256.

8. GOST 24956-81State Standard.Titan i splavy titanovye. Metod opredeleniya vodoroda [Titanium and titanium alloys. Method for the determination of hydrogen], Moscow: Standards publishing house, 1997

9. Polyansky, V.A., Polyansky, A.M., Kozlov, E.A., Novy izmeritelny kompleks dlya absolyutnogo opredeleniya soderzhaniya vodoroda v materialakh vodorodnoy energetiki [New measuring complex for absolute determination of hydrogen content in hydrogen energy materials], Proc. of the Third Russian Conference “Physical Problems of Hydrogen Energy”, St Petersburg: Ioffe PhTI, 2006, pp. 110–112.

10. Kudinova, N.R., Polyansky, V.A., Polyansky, A.M., Yakovlev, Yu.A., Opredelenie energii sviazi rastvorennogo vodoroda na osnovnoy modeli mnogokanalnoy diffuzii v tverdom tele [Determination of the binding energies of dissolved hydrogen in the main model of multichannel diffusion in a solid], Fiziko-matematicheskie nauki, 2015, No 4 (230), pp. 9–23.

11. Borisova, E.A., Bochvar, G.A., Brun, M.Ya., et al., Metallografiya titanovykh splavov [Metallography of titanium alloys], Moscow: Metallurgiya, 1980.

12. Li, Z.Z., Ou, P., Sun, N., et al., Face-centered tetragonal titanium hydrides in fine-grained commercial pure (grade 2) titanium, Materials Letters, 2013, No 8, V. 105, pp. 16–19.

13. Merson, E.D., Issledovanie mekhanizma razrusheniya i prirody akusticheskoy emissii pri vodorodnoy khrupkosti nizkouglerodistoy stali [Investigation of the mechanism of destruction and the nature of acoustic emission at hydrogen brittleness of low-carbon steel]: Abstract of the thesis for the degree of candidate of engineering sciences, Togliatti, 2016.

14. Poletaev, D.O., Prognozrastvorimostivodorodaikremniyavα-Timetodomfunktsionalaelektronnoy plotnosti [Prediction of the solubility of hydrogen and silicon in α-Ti by the electron density functional method]: Abstract of the thesis for the degree of candidate of engineering sciences, Belgorod, 2016.

15. Golovin, P.V., Medvedeva, N.A., Skryabina, N.E., Sorbtsionnaya sposobnost splavov sostava TixV1–x po otnosheniyu k vodorodu [Sorption capacity of TixV1–x alloys in comparison with hydrogen], Kondensirovannye sredy i mezhfaznye granitsy, 2013, V. 15, No 2.

16. Zhu, T., Li, M., Effect of 0.77%wt H addition on the microstructure of Ti–6Al–4V alloy and mechanism of δ hydride formation, Journal of Alloys and Compounds, 2009, V. 481, Issues 1–2, pp. 480–485.

17. Tal-Gutelmacher, E., Eliezer, D., Interaction of Hydrogen with Aerospace Titanium Alloys, Negev, 2003.

18. Tal-Gutelmacher, E., Eliezer, D., Hydrogen-Assisted Degradation of Titanium Based Alloys, Materials Transactions, V. 45, No 5, 2004, pp. 1594–1600.

19. Zharkov, A.Yu., Rudskikh, V.V., Levchenkova, O.N., Volkova, T.S., Svetlakov, S.V., Issledovanie protsessa gidrirovaniya drobi titana pri ponizhennom davlenii vodoroda [Study of the process of hydrogenation of titanium fraction under reduced hydrogen pressure], URL:http://www.chmz.net/press/news-chmz/files/2014-04-15/13/14.pdf (reference date 7/07/2020)

20. Tao, S., Notten, P., Van Santen, R., Jansen, A., Density functional theory studies of the hydrogenation properties of Mg and Ti, Physical Review B, 2009, No 4, V. 79 (14), pp. 144–121.

21. Gyulikhandanov, E.L., Kislenkov, V.V., Khaydorov, A.D., Termicheskaya obrabotka metallov [Metal heat treatment], St Petersburg: State Polytechnic University, 2014.

22. Livanov, V.A., Bukhantsev, A.A., Kolachev, B.A., Vodorod v titane [Hydrogen in titanium], Moscow: Metallurgiya, 1962.