The deformation fracture criterion is introduced and its verification is performed on specimens from ZhS36 single crystal alloy with various crystallographic orientations under thermal fatigue testing with different temperatures and cycle durations.
Similar content being viewed by others
References
L. B. Getsov and V. E. Mikhailov, A. S. Semenov, et al., “Residual life calculation of operating and guiding gas turbine blades. Pt. 2. Single crystal materials,” Gazoturb. Tekhnol., No. 8, 18–25 (2011).
R. Hill, “Generalized constitutive relations for incremental deformation of metal crystals by multislip,” J. Mech. Phys. Solids, 14, 95–102 (1966).
R. Hill and J. R. Rice, “Constitutive analysis of elastic-plastic crystals at arbitrary strains,” J. Mech. Phys. Solids, 20, 401–413 (1972).
R. J. Asaro and J. R. Rice, “Strain localisation in ductile single crystals,” J. Mech. Phys. Solids, 25, 309–338 (1977).
R. J. Asaro, “Crystal plasticity,” J. Appl. Mech., 50, 921–934 (1983).
G. A. Cailletaud, “Micromechanical approach to inelastic behaviour of metals,” Int. J. Plast., 8, 55–73 (1991).
J. Besson, G. Cailletaud, J.-L. Chaboche, and S. Forest, Non-Linear Mechanics of Materials, Springer (2010).
L. B. Getsov, N. I. Dobina, A. I. Rybnikov, et al., “Thermal fatigue resistance of a monocrystalline alloy,” Strength Mater., 40, No. 5, 538–551 (2008).
L. Getsov, A. Semenov, and A. Staroselsky, “A failure criterion for single-crystal superalloys during thermocyclic loading,” Mater. Technol., 42, No. 1, 3–12 (2008).
L. B. Getsov, A. I. Rybnikov, and A. S. Semenov, “Thermal fatigue resistance of heat-resistant alloys,” Teploénergetika, No. 5, 51–58 (2009).
L. B. Getsov, A. I. Rybnikov, A. S. Semenov, et al., “Deformation resistance and fracture toughness of single-crystal alloys under static and termocyclic loading,” Nadezhn. Bezopasn. Énerg., No. 18, 53–62 (2012).
E. N. Kablov and E. R. Golubovskii, Thermal Stability of Nickel Alloys [in Russian], Mashinostroenie, Moscow (1998).
R. E. Shalin, I. L. Svetlov, E. B. Kachanov, et al., Single Crystals of Nickel Superalloys [in Russian], Mashinostroenie, Moscow (1997).
N. K. Arakere and G. Swanson, “Effect of crystal orientation on fatigue failure of single crystal nickel base turbine blade superalloys,” Int. J. Eng. Gas Turbines Power, 124, 161–176 (2002).
A. Garcia de la Yedra, A. Martin-Meizoso, R. Rodriguez Martin, and J. L. Pedrejon, “Thermo-mechanical fatigue behaviour and life prediction of C-1023 nickel based superalloy,” Int. J. Eng. Sci. Technol., 3, No. 6, 88–101 (2011).
L. B. Getsov, “On fracture criterion for complex program loading,” in: Proc. All-Union Workshop on Low-Cycle Fatigue Problems [in Russian], Kaunas (1971).
R. M. Odobai-Fard, A. S. Semenov, and L. B. Getsov, “Modeling of processes of inelastic deformation of specimens from single-crystal materials with account of dislocations’ dynamics,” in: Proc. Int. Conf. “XL Week of Science in St. Petersburg State Polytechnical University” [in Russian], Part V, St. Petersburg (2011), pp. 72–73.
A. S. Semenov, “PANTOCRATOR – a finite-element program specialized on the solution of nonlinear problems of solid-mechanics,” in: Proc. of the 5th Int. Conf. “Scientific and Engineering Problems of Predicting the Reliability and Service Life of Structures and Methods of Their Solution” [in Russian], SPbGPU, St. Petersburg (2003), pp. 466–480.
Author information
Authors and Affiliations
Additional information
Translated from Problemy Prochnosti, No. 1, pp. 50 – 62, January – February, 2014.
Rights and permissions
About this article
Cite this article
Semenov, A.S., Getsov, L.B. Thermal Fatigue Fracture Criteria of Single Crystal Heat-Resistant Alloys and Methods for Identification of Their Parameters. Strength Mater 46, 38–48 (2014). https://doi.org/10.1007/s11223-014-9513-2
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11223-014-9513-2