References
- [1] Chan S.K, Tuba I.S. (1971). A finite element method for contact problems of solid bodies - Part II: Applications to turbine blade fastenings. International Journal of Mechanical Scientist; 13:627-39.
- [2] Masataka, M. (1992). Root and groove contact analysis for steam turbine blades. Japan SocietyMech. Eng. Int. J., 35:508-14.
- [3] Meguid S.A, Kanth P.S, Czekanski A. (2000). Finite element analysis of fir-tree region in turbine disc. Finite Element in Analysis and Design, 35:305-17.
- [4] Papanikos P, Meguid S.A, Stjepanovic Z. (1998). Three-dimensional nonlinear finite element analysis of dovetail joints in aero-engine discs. Finite Element in Analysis and Design, 29:173-86.
- [5] Zboinski, G. (1995). Physical and geometrical non-linearities in contact problems of elastic turbine blade attachments. J Mech. Eng. Sci., 209:273-86.
- [6] McEvily, A. (2004). Failures in inspection procedures: case studies. Engineering FailureAnalysis, 11:167-76.
- [7] Barlow K.W., Chandra R. (2005). Fatigue crack propagation simulation in an aircraft engine fan blade attachment. International Journal of Fatigue, 27:1661-1668.
- [8] Slavik D., McClain R., Levis K. (2000). Stress intensity predictions with ANSYS for use in Aircraft engine component life prediction. Fatigue and Fracture Mechanics, Vol. 31(2000), 371-390.
- [9] Zhuang, W. Z. (2000). Prediction of crack growth from bolt holes in a disc. InternationalJournal of Fatigue, Vol. 22(2000), p. 241-250.
- [10] Shlyannikov V., Iltchenko B., Stepanov N. (2001) Fracture analysis of turbine disks and computational-experimental background of the operational decisions. Engineering FailureAnalysis, Vol. 8(2001), p. 461-475.
- [11] Witek, L., Failure analysis of turbine disc of an aero engine, Engineering Failure Analysis, Vol: 13 Issue: 1, Elsevier, 2006.
- [12] Witek, L. Experimental crack propagation and failure analysis of the first stage compressor blade subjected to vibration, Engineering Failure Analysis Vol. 16, Issue: 7, Elsevier, 2009.
- [13] Witek, L. Experimental crack propagation and failure analysis of the first stage compressor blade subjected to vibration, Engineering Failure Analysis Vol. 16, Issue: 7, Elsevier, 2009.
- [14] Witek, L. (2011) Crack propagation analysis of mechanically damaged compressor blades subjected to high cycle fatigue. Engineering Failure Analysis, Vol. 18(4), Elsevier Science.
- [15] Witek L., Orkisz, M.. Wygonik P., Musili D. N., Kowalski T. (2011). Fracture analysis of a turbine casing. Engineering Failure Analysis, Vol. 18(3), Elsevier Science.
- [16] Witek L., Numerical stress and crack initiation analysis of the compressor blades after foreign object damage subjected to high-cycle fatigue, Engineering Failure Analysis, Volume: 11, Issue: 8, Elsevier Science, 2011.
- [17] Witek, L. (2011). Stress intensity factor calculations for the compressor blade with half-elliptical surface crack using Raju-Newman solution. Fatigue of Aircraft Structures, Issue 2011. Institute of Aviation Scientific Publications, Warsaw, Poland.
- [18] MSC-PATRAN User’s manual, MSC Corporation, Los Angeles; 2009.
- [19] ABAQUS User’s Manual, ver. 6.8, Abaqus Inc.; 2009.
- [20] Anderson T. L., Fracture mechanics. Fundamentals and applications, CRC Press Inc, Boca Raton, Florida, 1991.
- [21] Aerospace Structural Metals Handbook, US Air Force CRDA/Purdue University, 37th Edition, vol. 5, 2004.