Diffraction-Based Investigation Methods in Analysing Plastic Strain Zone Underneath Fracture Surface
| Authors: Naprienko S.A., Medvedev P.N., Raevskikh A.N., Popov M.A. | Published: 05.09.2019 |
| Published in issue: #4(127)/2019 | |
| Category: Aviation and Rocket-Space Engineering | Chapter: Aerodynamics and Heat Transfer Processes in Aircrafts | |
| Keywords: titanium alloy ВТ41, X-ray crystallography, plastic strain zone, texture, EBSD, electron backscatter diffraction | |
We used samples of the ВТ41 two-phase titanium alloy to estimate the relationship between testing temperature, KCV fracture toughness values, width of the plastic strain zone and its formation specifics. We developed an efficient method of estimating the plastic strain zone width, based on a special X-ray imaging geometry enabling a high degree of locality for measuring variations in the X-ray line broadening when moving away from the fracture surface. We studied material texture close to the fracture zone and at a distance from it, which allowed us to detect the specifics of grain reorientation, in particular, texture diffusion and an increase in the concentration of basal and prismatic planes parallel to the fracture surface as a result of plastic strain and dislocation saturation. We hypothesise that pole density in the [0001] region grows due to the [1012]-oriented grain slip, while in the region around [1010] pole density grows due to slip of the grains whose orientation is close to [1120]. We verified our X-ray texture analysis data by texture analysis via electron backscatter diffraction (EBSD)
The study was supported by RFBR as part of the grant NK 13-08-001125/13
References
[1] Kablov E.N. Shestoy tekhnologicheskiy uklad. Nauka i zhizn᾽, 2010, no. 4, pp. 2--7 (in Russ.).
[2] Kablov E.N. On the 80th anniversary of the All-Russian Research Institute of Aviation Materials (VIAM). Zavodskaya laboratoriya. Diagnostika materialov [Industrial Laboratory. Diagnostics of Materials], 2012, vol. 78, no. 5, pp. 79--82 (in Russ.).
[3] Chabina E.B., Alekseev A.A., Filonova E.V., et al. The use of methods of analytical microscopy and Х-ray diffraction analysis for the study of the structural phase state materials. Trudy VIAM [Proceedings of VIAM], 2013, no. 5 (in Russ.). Available at: http://www.viam-works.ru/ru/articles?art_id=37
[4] Naprienko S.A., Zaytsev D.V., Popov M.A., et al. Features of destruction of VT41 titanium alloy in shock (dynamic) loading at different temperatures. Aviatsionnye materialy i tekhnologii [Aviation Materials and Technologies], 2016, no. 2, pp. 60--68 (in Russ.).
[5] Klevtsov G.V., Perlovich Yu.A., Fesenko V.A. On development of X-ray method for identification of cracks with spoiled surface. Zavodskaya laboratoriya, 1993, vol. 59, no. 8, pp. 34--37 (in Russ.).
[6] Botvina L.R., Tyutin M.R., Levin V.P., et al. Special aspects of static, shock and fatigue rupture of 06MBF steel with submicrocrystalline structure. Zavodskaya laboratoriya. Diagnostika materialov [Industrial Laboratory. Diagnostics of Materials], 2008, vol. 74, no. 1, pp. 43--49 (in Russ.).
[7] Klevtsov G.V., Botvina L.R., Klevtsova N.A., et al. Fraktodiagnostika razrusheniya metallicheskikh materialov i konstruktsiy [Fracture diagnostics of metal materials and constructions destruction]. Moscow, MISiS Publ., 2007.
[8] Kablov E.N. Innovative developments of FSUE "VIAM" SSC of RF on realization of "Strategic directions of the development of materials and technologies of their processing for the period until 2030". Aviatsionnye materialy i tekhnologii [Aviation Materials and Technologies], 2015, no. 1, pp. 3--33 (in Russ.).
[9] Kashapov O.S., Novak A.V., Nochovnaya N.A., et al. State, problems and prospects of heat-resistant titanium alloys for GTE parts. Trudy VIAM [Proceedings of VIAM], 2013, no. 3 (in Russ.). Available at: http://viam-works.ru/ru/articles?art_id=20
[10] Kochubey A.Ya., Medvedev P.N. Direct pole figures in the study of structure formation processes during heating of deformed metals and alloys. Novosti materialovedeniya. Nauka i tekhnika [Material Science and Technology News], 2016, no. 5, pp. 12--20 (in Russ.).
[11] Kolachev B.A., Mal’kov A.V. Fizicheskie osnovy razrusheniya titana [Physical fundamentals of titanium rupture]. Moscow, Metallurgiya Publ., 1983.
[12] Agamirov L.V., Alimov M.A., Babichev L.P. Mashinostroenie. T. II-1. Fiziko-mekhanicheskie svoystva. Ispytaniya metallicheskikh materialov [Mechanical engineering. Vol. II-1. Physical-mechanical properties. Tests on metal materials]. Moscow, Mashinostroenie Publ., 2010, pp. 472--521.
[13] Erasov V.S., Oreshko E.I. Deformation and destruction as processes of change of volume, the areas of a surface and the linear sizes in loaded bodies. Trudy VIAM [Proceedings of VIAM], 2016, no. 8 (in Russ.). Available at: http://viam-works.ru/ru/articles?art_id=999
[14] Erasov V.S., Oreshko E.I. Force, deformation and energy criteria of destruction. Trudy VIAM [Proceedings of VIAM], 2017, no. 10 (in Russ.). Available at: http://viam-works.ru/ru/articles?art_id=1169
[15] Klevtsov G.V. Regularities of formation by crack top at different types of weighting and X-ray fractodiagnostics of destruction. Vestnik OGU. Estestvennye i tekhnicheskie nauki [Vestnik of the Orenburg State University], 2006, no. 1--2, pp. 81--88 (in Russ.).
[16] Predvoditelev A.A., Troitskiy O.A. Dislokatsii i tochechnye defekty v geksagonal’nykh metallakh [Dislocation and point defects in hexagonal metals]. Moscow, Atomizdat Publ., 1973.
