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Purpose: In the present paper a crack arrest model is proposed for an infinitely long narrow poled piezoelectric strip embedded with a centrally situated finite hairline straight crack. Design/methodology/approach: The ceramic of the strip is assumed to be mechanically brittle and electrically ductile. Combined mechanical and electrical loads applied at the edge of the strip open the rims of the crack in mode-I deformations. Consequently a yield zone protrudes ahead of each tip of the crack. Under small scale yielding the yield zone are assumed to lie on the line segment along the axis of the crack. To arrest the crack from further opening the rims of the yield zones are subjected to normal, cohesive quadratically varying yield point stress. Two cases are considered: Case-I the edges of the strip are subjected to in-plane normal and in-plane electrical displacement and in Case-II the in-plane stresses and in-plane electrical field are applied on the edges of the strip. In each case problem is solved using Fourier transform method which finally reduces to the solution of integral equation. Findings: Analytic expressions are derived for stress intensity factor, yield zone, crack opening displacement, crack growth rate, variation of these quantities with respect to affecting parameters viz. width of the strip, yield zone length, crack length, material constants for different ceramics have been plotted. Research limitations/implications: The material of the strip is assumed mechanically brittle and electrically ductile consequently mechanically singularity is encountered first. The investigations in this paper are carried at this level. Also the crack yielding under the loads is considered small scale hence the yield zone is assumed to be lying on the line segment ahead of the crack. Practical implications: Piezoelectric ceramics are widely used as sensors and actuators, this necessity prompts the fracture study on such ceramics under different loading conditions. Originality/value: The paper gives an assessment of the quadratically varying load required to be prescribed on yield zones so as to arrest the opening of the crack. The investigations are useful to smart material design technology where sensors and actuators are manufactured.
Wydawca
Rocznik
Tom
Strony
5--12
Opis fizyczny
Bibliogr. 21 poz., rys., tab., wykr.
Twórcy
autor
autor
- Department of Mathematics, Indian Institute of Technology, Roorkee-247667, India, rajrbfma@iitr.ernet.in
Bibliografia
- [1] Y. Shindo, E. Ozawa, Singular stresses and electric fields of a cracked piezoelectric strip, International Journal of Applied Electromagnetic Materials 1 (1990) 77-87.
- [2] Y. Shindo, E. Ozawa, Dynamic analysis of a cracked piezoelectric material, Mechanical model of new electromagnetic materials, Proceedings of the IUTAM Symposium, 1990, 297-304.
- [3] V.V. Belyaev, Spall damage modeling and dynamic fracture specificities of ceramics, Journal of Materials Processing Technology 32 (1992) 135-144.
- [4] Y. Shindo, K. Tanaka, F. Narita, Singular stress and electric fields of a piezoelectric ceramic strip with a finite crack under longitudinal shear, Acta Mechanica 120 (1997) 31-45.
- [5] Y. Shindo, K. Tanaka, F. Narita, Electroelastic intensification near antiplane shear crack in orthotropic piezoelectric ceramic strip, Theoretical and Applied Fracture Mechanics 25 (1996) 65-71.
- [6] Z.T. Chen, Crack tip field of an infinite piezoelectric strip under anti-plane impact, Mechanics Research Communications 25 (1998) 313-319.
- [7] M.T. Hayajneh, V.P. Astakhov, M.O.M. Osman, An analytical evaluation of the cutting forces in orthogonal cutting using a dynamic model of shear zones with parallel boundaries, Journal of Materials Processing Technology 82 (1998) 61-67.
- [8] F. Narita, Y. Shindo, Fatigue crack propagation in a piezoelectric ceramic strip subjected to mode III loading, Acta Mechanica 137 (1999) 55-63.
- [9] Z.T. Chen, S.A. Meguid, The transient response of a piezoelectric strip with a vertical crack under electromechanical impact load, International Journal of Solids and Structures 37 (2000) 6051-6062.
- [10] F. Narita, Y. Shindo, Mode I crack growth rate for yield strip model of a narrow piezoelectric ceramic body, Theoretical and Applied Fracture Mechanics 36 (2001) 73-85.
- [11] X. Wang, S. Yu, Transient response of a crack in a piezoelectric strip subjected to the mechanical and electrical impacts: mode-III problem, International Journal of Solids and Structures 37 (2000) 5795-5808.
- [12] B.L. Wang, Y.W. Mai, A piezoelectric material strip with a crack perpendicular to its boundary surfaces, International Journal of Solids and Structures 39 (2002) 4501-4524.
- [13] S. Li, On saturation-strip model of a permeable crack in a piezoelectric ceramic, Acta Mechanica 165 (2003) 47-71.
- [14] J. Chen, Z. Liu, Z. Zou, The central crack problem for a functionally graded piezoelectric strip, International Journal of Fracture 121 (2003) 81-94.
- [15] R.R. Bhargava, S. Hasan, Generalized Dugdale model solution for a piezoelectric plate weakened by two straight cracks, Proceedings of the International Conference “Advances in Materials and Processing Technologies”, 2003, vol. 1, 647-650.
- [16] M. Szutkowska, Fracture resistance behavior of Alumina-Zirconia composites, Proceedings of the International Conference “Advances in Materials and Processing Technologies”, 2003, vol. 1, 1251-1254.
- [17] V. Govorukha, M. Kamlah, D. Munz, The interface crack problem for a piezoelectric semi-infinite strip under concentrated electromechanical loading, Engineering Fracture Mechanics 71 (2004) 1853-1871.
- [18] L. Ma, L.Z. Wu, Z.G. Zhou, L.C. Guo, Fracture analysis of a functionally graded piezoelectric strip, Composite structures 69 (2005) 294-300.
- [19] R.R. Bhargava, N. Saxena, Solution for a cracked piezoelectric plate subjected to variable load on plastic zones under mode-I deformation, Journal of Materials Processing Technology 164-165 (2005) 1495-1499.
- [20] S. Ueda, A finite crack in a semi-infinite strip of a graded piezoelectric material under electric loading, European Journal of Mechanics A25 (2006) 250-259.
- [21] R.R. Bhargava, A. Setia, Crack arrest model for a piezoelectric strip subjected to Mode-I loadings, Journal of Achievements in Materials and Manufacturing Engineering 22/2 (2007) 9-22.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-PWA9-0042-0001