Abstract
The results of the acoustic monitoring of the damage that accumulated in an austenitic steel sample tube during thermal pulsation are presented.
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Sudakov, A.V. and Trofimov, A.S., Pul’satsii temperatur i dolgovechnost' elementov energooborudovaniya (Temperature Pulsations and Life of Power Equipment Components), Leningrad: Energoatomizdat, 1989.
Sudakov, A.V., Power equipment life under temperature pulsations, Nadezhnost’ i Bezopasnost’ Energetiki, 2008, no. 9, pp. 10–18.
Khlybov, A.A., Assessing the stress condition of guillotine knives subjected to heat treatment, Zavod. Lab, Diagn. Mater., 2009, vol. 75, no. 4, pp. 54–57.
Uglov, A.L., Erofeev, V.I., and Smirnov, A.N., Akusticheskii kontrol' oborudovaniya pri izgotovlenii i ekspluatatsii., (Acoustic Control of Equipment during Its Manufacture and Operation), Mitenkov, F.M, Ed., Moscow: Nauka, 2009.
Volkov, I.A. and Korotkikh, Yu.G., Uravneniya sostoyaniya vyazkouprugoplasticheskikh sred s povrezhdeniyami (Equations of State of Damaged Elasto-Viscoplastic Media), Moscow: Fizmatlit, 2008.
Ereev, M.N., Zakharov, D.A., Panov, V.A., Pichkov, S.N., Sidorov, A.Yu., and Shishulin, D.N., A study of kinetics of fatigue damage accumulation in the material of pipelines of primary systems of ship nuclear power plants during thermal pulsations, Proc. All-Russian Conf. on Probl. Sci. Techn.), Moscow: RAN, 2014, pp. 120–140.
Bol’shukhin, M.A., Lebedev, V.V., Kozin, A.V., Korotkikh, Yu.G., Panov, V.A., and Pakhomov, V.A., Simulation of processes of damage accumulation during thermal pulsations, Probl. Prochn. Plast.: Mezhvuz. Sb. Nizhegorod. Univ., 2014, no. 76(2), pp. 134–143.
Khlybov, A.A., Pichkov, S.N., and Uglov, A.L., Investigation of accumulation of dispersed microdamages in specimens of 08Kh18N10T steel at low-cycle fatigue, Kontrol’. Diagnostika, 2011, no. 4, pp. 55–61.
MVI Standartnye obraztsy vremeni prokhozhdeniya ul’trazvukovykh signalov. Opredelenie osnovnykh metrologicheskikh kharakteristik (Management Procedure. Standard Patterns of Propagation of Ultrasonic Signals. Determination of Basic Metrological Characteristics), Yekaterinburg: IFM UrO RAN, 2007.
Mitenkov, F.M., et al., Metody obosnovaniya resursa yadernykh energeticheskikh ustanovok (Methods of Justification of the Life of Nuclear Power Plants), Moscow: Mashinostroenie, 2007.
Volkov, I.A., Korotkikh, Yu.G., and Tarasov, I.S., Numerical simulation of fatigue damage accumulation under complex plastic deformation, Vychisl. Mekh. Sploshnykh Sred, 2009, vol. 2, no. 1, pp. 5–18.
Korotkikh, Yu.G., Volkov, I.A., Tarasov, I.S., and Fomin, M.N., The validation of the applicability of the evolution equation of damage accumulation for assessing low-cycle fatigue of metals, Probl. Prochn. Plast., 2010, no. 72, pp. 46–56.
Uglov, A.L., On a model of accumulation of dispersed damages, Prikl. Mekh., 1991, no. 1, pp. 77–84.
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Original Russian Text © A.L. Uglov, A.A. Khlybov, S.N. Pichkov, D.N. Shishulin, 2016, published in Defektoskopiya, 2016, Vol. 52, No. 2, pp. 3–10.
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Uglov, A.L., Khlybov, A.A., Pichkov, S.N. et al. An acoustic method for estimating the thermal-pulsation-induced damage in austenitic steel. Russ J Nondestruct Test 52, 53–59 (2016). https://doi.org/10.1134/S106183091602008X
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DOI: https://doi.org/10.1134/S106183091602008X