Modeling and Simulation of Microstructurally Small Crack Formation and Growth in Notched Nickel-base Superalloy Component

doi:10.1016/j.jmst.2013.09.011

Abstract

Abstract:

Studies on microstructurally small fatigue cracks have illustrated that heterogeneous microstructural features such as inclusions, pores, grain size distribution as well as precipitate size distribution and volume fraction create stochasticity in their behavior under cyclic loads. Therefore, to enhance safe-life and damage-tolerance approaches, accurate modeling of the influence of these heterogeneous microstructural features on microstructurally small crack formation and growth from stress raisers is necessary. In this work, computational micromechanics was used to predict the high cycle fatigue of microstructurally small crack formation and growth in notched polycrystalline nickel-base superalloys and to quantify the variability in the driving force for formation and growth of microstructurally small crack from notch root in the matrix with non-metallic inclusions. The framework involves computational modeling to obtain three-dimensional perspectives of microstructural features influencing fatigue crack growth in notched nickel-base superalloys, which accounts for the effects of nonlocal notch root plasticity, loading, microstructural variability, and extrinsic defects on local cyclic plasticity at the microstructure-scale level. This approach can be used to explore sensitivity of minimum fatigue lifetime to microstructures. The simulation results obtained from this framework were calibrated to existing experimental results for polycrystalline nickel-base superalloys.

Key words: Microstructurally small crack, Crystal plasticity, Nickel-base superalloy, Fatigue life

G.M. Owolabi, H.A. Whitworth. Modeling and Simulation of Microstructurally Small Crack Formation and Growth in Notched Nickel-base Superalloy Component[J]. J. Mater. Sci. Technol., DOI: 10.1016/j.jmst.2013.09.011.

References

[1] D.L. McDowell, K. Gall, M.F. Horstemeyer, J. Fan, Eng. Fract.Mech. 70 (2007) 49-80.

[2] D.L. McDowell, Int. J. Fatigue 19 (1997) 127-135.

[3] R.G. Tryon, NASA Contractor Report 202342, 1997.

[4] R.O. Ritchie, J. Lankford (Eds.), Small Fatigue Cracks, Metall. Soc.Inc., Pennsylvania 15086, 1986, pp. 1-5.

[5] B. Lin, L.G. Zhao, J. Tong, Eng. Fract. Mech. 78 (2011) 2174-2192.

[6] J.D. Hochhalter, D.J. Littlewood, M.G. Veilleux, J.E. Bozek, A.M.Maniatty, A.D. Rollett, A.R. Ingraffea, Model. Simul. Mater. Sci.Eng. 19 (2011) 035008.

[7] F. Tancret, Processing for China, Sterling Publications, London,2000, pp. 56-58.

[8] S.A. Padula, A. Shyam, R.O. Ritchie, W.W. Milligan, Int. J. Fatigue21 (1999) 725-731.

[9] M. Shenoy, J. Zhang, D.L. McDowell, Fatigue Fract. Eng. Mater.Struct. 30 (2007) 889-904.

[10] C. Mercer, A.B.O. Soboyejo, W.O. Soboyejo, Mater. Sci. Eng. A270 (1999) 308-322.

[11] M. Goto, D.M. Knowles, Eng. Fract. Mech. 60 (1998) 223e232.

[12] C.P. Przybyla, R. Prasannavenkatesan, N. Salajegheh, D.L.McDowell, Int. J. Fatigue 32 (2010) 512-525.

[13] C.P. Przybyla, D.L. McDowell, Procedia Eng. 2 (2010) 1045-1052.

[14] D. Raabe, F. Roters, F. Barlat, L.Q. Chen, Continuum Scale Simulation of Engineering Materials: FundamentalseMicrostructureseProcess Applications, first ed., Wiley-VCH, Weinheim,2004, p. 500.

[15] L.O. Uhrus, Iron Steel Inst. 77 (1963) 104-109.

[16] S. Nishijima, K. Tanaka, H. Sumiyoshi, Fracture 84, in: Proc. 6th Int. Conf. Fracture (ICF6), Adv. Fracture Res., New Delhi, India,December 4e10, second ed. vol. 3, 1984, pp. 1719-1726.

[17] M.M. Shenoy, Constitutive Modeling and Life Predictions in Nibase Superalloy (Ph.D. thesis), Georgia Institute of Technology,2006.

[18] R.W. Kozar, A. Suzuki, W.W. Milligan, J.J. Schirra, M.F. Savage,T.M. Pollock, Metall. Mater. Trans. A 40 (2009) 1588-1603.

[19] A.M. Wusatowska-Sarnek, M.J. Blackburn, M. Aindow, Mater. Sci.Eng. A 360 (2003) 390-395.

[20] G. Leverant, M. Gell, Trans. Metall. Soc. AIME 245 (1969) 1167-1173.

[21] G.P. Potirniche, S.R. Daniewicz, J.C. Newman Jr., Fatigue Fract.Eng. Mater. Struct. 27 (2004) 59-71.

[22] G.P. Potirniche, S.R. Daniewicz, Eng. Fract. Mech. 70 (2003)1623-1643.

[23] J.R. Rice, D.E. Hawk, R.J. Asaro, Int. J. Fatigue 42 (1990) 301-321.

[24] K. Gall, H. Sehitoglu, Y. Kadioglu, Metall. Mater. Trans. A 27(1996) 3491-3502.

[25] P.R. Dawson, Int. J. Solids Struct. 37 (2000) 115-130.

[26] C.P. Przybyla, D.L. McDowell, Int. J. Plast. 26 (2010) 372-394.

[27] R.J. Asaro, Adv. Appl. Mech. 23 (1983) 1-115.

[28] R. Prasannavenkatesan, Microstructure-sensitive Fatigue Modeling of Heat Treated and Shot Peened Martensitic Gear Steels (Ph.D.thesis), Georgia Institute of Technology, 2009.

[29] Y.Q. Sun, P.M. Hazzledeng, Dislocat. Solids 10 (1996) 27-68.

[30] K. Tanaka, T. Mura, J. Appl. Mech. 48 (1981) 97-103.

[31] A. Fatemi, P. Kurath, J. Eng. Mater. Technol. Trans. ASME 110(1988) 380-388.

[32] A. Fatemi, D.F. Socie, Fatigue Fract. Eng. Mater. Struct. 11 (1988)149-165.

[33] G.M. Owolabi, R. Prasannavenkatesan, D.L. McDowell, Int. J.Fatigue 32 (2010) 1378-1388.

[34] W.D. Muskinski, D.L. McDowell, Int. J. Fatigue 37 (2012) 41-53.

[35] R.A. Smith, K.J. Miller, Int. J. Mech. Sci. 19 (1977) 11-22.

[36] B.A. Cowles, J.R. Warren, F.K. Haake, Evaluation of the Cyclic Behavior of Aircraft Turbine Disk Alloys, Part II, NASA CR-165123, Pratt & Whitney Aircraft, 1980.

[37] C. Bathias, P.C. Paris, Int. J. Fatigue 32 (2010) 894-897.