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1. Built Env. Research Lab., Department of Structures and Materials, Civil Eng. Faculty, University of Sciences and Technology
Houari Boumediene, B.P. 32 El Alia Bab Ezzouar, 16111 Algiers, Algeria
2. Department of Structures and Materials, Civil Eng. Faculty, University of Sciences and Technology Houari Boumediene, B.P. 32 El Alia Bab Ezzouar, 16111Algiers, Algeria
Received: October 03, 2011 / Accepted: November 12, 2011 / Published: February 25, 2012.
Abstract: In this study, kinematics of the Damage Zone (DZ) or the so-called Fracture Process Zone (FPZ) which often precedes the crack during its propagation and characterized by few degrees of freedom (elementary movements) such as translation, rotation, isotropic expansion and distortion are considered. On the basis of a stress field distribution obtained by the use of a Semi-Empirical Approach (SEA), which relies on the Green’s functions, these driving forces corresponding to the mentioned degrees of freedom are formulated within the framework of the plane problem of elastostatics. Thus, expressions for translation (J), isotropic expansion (M), distorsion (N) and interactions effects representing the active parts of crack driving forces known as energy release rates are formulated in a purely theoretical context.
Key words: Displacement, stress, green’s functions, stress intensity factors, energy release rates.
Consider a Single Edge Notch (SEN) specimen as shown in Fig. 4 in which a crack propagates surrounded by a layer of damage. Experimental measurements of the crack opening displacement and the concentration of damage in the vicinity of the crack are needed for evaluating the different energy release rates.
The work W done by an applied force F at the grips(x2 = H) is given as follows:
Theoretical expressions for translation (J), isotropic expansion (M), distorsion (N) representing the active parts of crack driving forces are formulated. It is also shown in a number of cases that J has a significant statistical distribution. It is the expenditure of energy into various modes of crack propagation meaning the translational motion of the crack with the process zone unchanging on one hand and the expansion as well as the distorsion of the DZ on the other hand. These latest along with the change in concentration and interaction effects constitute an important percentage of the total energy release rate. Besides, the distribution of energy into modes varies size from one experiment
to the other as being a loading history dependant quantity.
References
[1] J. Botsis, A. Chudnovsky, A. Moet, Fatigue crack layer propagation in Polystyrene, International Journal of Fracture Parts I and II 33 (1987) 263-284.
[2] M.T.K. Takemori, Fatigue fracture of polycarbonate, Polymer Engineering and Science 22 (1982) 637-645.
[3] M. Chabaat, Comparison of minimal principal stress trajectories with crazes Distribution, International Journal of Fracture 37 (1988) 47-54.
[4] R.W. Hertzberg, J.A. Manson, Fatigue of engineering plastics, Academic Press, New York, 1980.
[5] L.R.F. Rose, Microcrack interaction with a main crack, International Journal of Fracture 31 (1986) 233-242.
[6] M. Chabaat, S. Djouder, Crack-microcracks interactions using a semi-empirical Approach, International Journal of Materials Sciences and Engineering A (2004) 387-389, 361-369.
[7] M. Chabaat, S. Djouder, M. Touati, Semi-empirical stress analysis of a brittle material in a vicinity of a stress concentrator, International Journal of Applied Mechanics and Materials 3-4 (2005) 243-252.
[8] B. Budiansky, R. Rice, Conservation laws and energy release rates, ASME Journal of Applied Mechanics 40(1973) 201-203.
[9] Y.H. Chen, M-integral analysis for 2-D solids with strongly interacting microcracks: Part 1. In an infinite brittle solid, International Journal of Solids and Structures 38 (2001) 3193-3212.
Houari Boumediene, B.P. 32 El Alia Bab Ezzouar, 16111 Algiers, Algeria
2. Department of Structures and Materials, Civil Eng. Faculty, University of Sciences and Technology Houari Boumediene, B.P. 32 El Alia Bab Ezzouar, 16111Algiers, Algeria
Received: October 03, 2011 / Accepted: November 12, 2011 / Published: February 25, 2012.
Abstract: In this study, kinematics of the Damage Zone (DZ) or the so-called Fracture Process Zone (FPZ) which often precedes the crack during its propagation and characterized by few degrees of freedom (elementary movements) such as translation, rotation, isotropic expansion and distortion are considered. On the basis of a stress field distribution obtained by the use of a Semi-Empirical Approach (SEA), which relies on the Green’s functions, these driving forces corresponding to the mentioned degrees of freedom are formulated within the framework of the plane problem of elastostatics. Thus, expressions for translation (J), isotropic expansion (M), distorsion (N) and interactions effects representing the active parts of crack driving forces known as energy release rates are formulated in a purely theoretical context.
Key words: Displacement, stress, green’s functions, stress intensity factors, energy release rates.
Consider a Single Edge Notch (SEN) specimen as shown in Fig. 4 in which a crack propagates surrounded by a layer of damage. Experimental measurements of the crack opening displacement and the concentration of damage in the vicinity of the crack are needed for evaluating the different energy release rates.
The work W done by an applied force F at the grips(x2 = H) is given as follows:
Theoretical expressions for translation (J), isotropic expansion (M), distorsion (N) representing the active parts of crack driving forces are formulated. It is also shown in a number of cases that J has a significant statistical distribution. It is the expenditure of energy into various modes of crack propagation meaning the translational motion of the crack with the process zone unchanging on one hand and the expansion as well as the distorsion of the DZ on the other hand. These latest along with the change in concentration and interaction effects constitute an important percentage of the total energy release rate. Besides, the distribution of energy into modes varies size from one experiment
to the other as being a loading history dependant quantity.
References
[1] J. Botsis, A. Chudnovsky, A. Moet, Fatigue crack layer propagation in Polystyrene, International Journal of Fracture Parts I and II 33 (1987) 263-284.
[2] M.T.K. Takemori, Fatigue fracture of polycarbonate, Polymer Engineering and Science 22 (1982) 637-645.
[3] M. Chabaat, Comparison of minimal principal stress trajectories with crazes Distribution, International Journal of Fracture 37 (1988) 47-54.
[4] R.W. Hertzberg, J.A. Manson, Fatigue of engineering plastics, Academic Press, New York, 1980.
[5] L.R.F. Rose, Microcrack interaction with a main crack, International Journal of Fracture 31 (1986) 233-242.
[6] M. Chabaat, S. Djouder, Crack-microcracks interactions using a semi-empirical Approach, International Journal of Materials Sciences and Engineering A (2004) 387-389, 361-369.
[7] M. Chabaat, S. Djouder, M. Touati, Semi-empirical stress analysis of a brittle material in a vicinity of a stress concentrator, International Journal of Applied Mechanics and Materials 3-4 (2005) 243-252.
[8] B. Budiansky, R. Rice, Conservation laws and energy release rates, ASME Journal of Applied Mechanics 40(1973) 201-203.
[9] Y.H. Chen, M-integral analysis for 2-D solids with strongly interacting microcracks: Part 1. In an infinite brittle solid, International Journal of Solids and Structures 38 (2001) 3193-3212.