13th International Conference on Fracture June 16–21, 2013, Beijing, China -10- References [1] H.A. Richard, M. Fulland, M. Sander, Theoretical crack path prediction, in: FFEMS 28 (2005), 3-12. [2] L.P. Pook, Elasto-Plasticity, Thin Sheet and Micromechanism Problems, In: Fracture and Fatigue: Radon, J.C. (Ed.) Pergamon Press, Oxford, 1980, pp. 143-153. [3] L.P. Pook, Multiaxial Fatigues, in: Miller, K.J., Brown, M.W. (Eds.), ASTM STP853, American Society for Testing and Materials, Philadelphia, 1985, pp. 249-263. [4] L.P. Pook, Linear elastic fracture Mechanics for engineers: theory and application, WIT press, Southampton, 2000. [5] M. Schöllmann, G. Kullmer, M. Fulland, H.A. Richard, A New Criterion for 3D Crack Growth under Mixed-Mode (I+II+III) Loading, in: Proc. of 6th Int. Conf. of Biaxial/Multiaxial Fatigue & Fracture, Vol. 2, 2001, 589-596. [6] M. Schöllmann, H.A. Richard, G. Kullmer, M. Fulland, A new criterion for the prediction of crack development in multiaxially loaded structures, in: Int. J. Frac. 117 (2002) 129-141. [7] G. Dhondt, A new Three-Dimensional Fracture Criterion, in: Key Engineering Materials 251-252 (2003), 209-214. [8] H.A. Richard, Bruchvorhersage bei überlagerter Normal- und Schubbeanspruchung von Rissen, VDI-Verlag, Düsseldorf, 1985. [9] F. Erdogan, G.C. Sih, On the crack extension in plates under plane loading and transverse shear, in: Journal of Basic Engineering 85 (1963) 519-527. [10]H.A. Richard, A new compact shear specimen, in: Int. J. Fracture 17 (1981) R105-R107. [11] H.A. Richard, K. Benitz, A loading device for the creation of mixed mode in fracture mechanics, in: Int. J. Fracture 22 (1983) R55-R58. [12]L.P Pook, The fatigue crack direction and threshold behaviour of mild steel under mixed mode I and III loading, in: International Journal of Fatigue 7 (1985) 21-30. [13]B.S.S.C. Rao, M. Srinivas, S.V. Kamat, Effect of temperature on fracture toughness of Timetal 834 titanium alloy under mode I and mixed mode I/III loading, in: Metallurgical and Materials Transactions A 39A (2008) 1340-1349. [14]F.-G. Buchholz, H. Wang, J. Lin, H.A. Richard, 3D finite element analysis of different test specimens for investigations on mixed mode I, II and III fracture, in: S. Idelsohn , E. Onate, E. Dvorkin (Eds.), Computational Mechanics, CIMNE, 1998, pp. 1-21. [15]J.C.W. Davenport, D.J. Smith, A study of superimposed fracture modes I, II and III on PMMA, in: Fatigue and Fracture of Engineering Materials and Structures 16 (1993) 1125-1133. [16] D. Hull, The effect of mixed mode I/III on crack evolution in the brittle solids, in: Int. J. Frac. 70 (1995) 59-79. [17]L.P. Pook, A finite element analysis of the angle crack specimen, in: H.P. Rossmanith, K.J. Miller (Eds.), Mixed-Mode Fatigue and Fracture, ESIS 14, Mechanical Engineering Publications, London, 1993, pp. 285-302. [18]H.A. Richard, Praxisgerechte Simulation des Werkstoff- und Bauteilverhaltens durch überlagerte Zug-, ebene Schub- und nichtebene Schubbelastung von Proben, VDI-Verlag, Düsseldorf, 1983, 269-274. [19]H.A. Richard, M. Kuna, Theoretical and experimental study of superimposed fracture modes I, II and III, in: Eng. Frac. Mech. 35 (1990) 949-960.
RkJQdWJsaXNoZXIy MjM0NDE=