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http://dx.doi.org/10.12989/sss.2015.15.5.1233

Crack identification in post-buckled beam-type structures  

Moradi, Shapour (Department of Mechanical Engineering, Shahid Chamran University)
Moghadam, Peyman Jamshidi (M.Sc. in Mechanical Engineering, Department of Mechanical Engineering)
Publication Information
Smart Structures and Systems / v.15, no.5, 2015 , pp. 1233-1252 More about this Journal
Abstract
This study investigates the problem of crack detection in post-buckled beam-type structures. The beam under the axial compressive force has a crack, assumed to be open and through the width. The crack, which is modeled by a massless rotational spring, divides the beam into two segments. The crack detection is considered as an optimization problem, and the weighted sum of the squared errors between the measured and computed natural frequencies is minimized by the bees algorithm. To find the natural frequencies, the governing nonlinear equations of motion for the post-buckled state are first derived. The solution of the nonlinear differential equations of the two segments consists of static and dynamic parts. The differential quadrature method along with an arc length strategy is used to solve the static part, while the same method is utilized for the solution of the linearized dynamic part and the extraction of the natural frequencies of the cracked beam. The investigation includes several numerical as well as experimental case studies on the post-buckled simply supported and clamped-clamped beams having open cracks. The results show that several parameters such as the amount of applied compressive force and boundary conditions influences the outcome of the crack detection scheme. The identification results also show that the crack position and depth can be predicted well by the presented method.
Keywords
crack detection; beam vibration; postbuckling; differential quadrature method; bees algorithm;
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1 Hua, Y.J, Zhu, Y.Y. and Cheng, C.J. (2008), "DQEM for large deformation analysis of structures with discontinuity conditions and initial displacements", Eng. Struct., 30(5), 1473-1487.   DOI
2 Huh, Y.C, Chung, T.Y, Moon, S.J, Kil, H.G. and Kim, J.K. (2011), "Damage detection in beams using vibratory power estimated from the measured accelerations", J. Sound Vib., 330(15), 3645-3665.   DOI
3 Karaagac, C., Ozturk, H. and Sabuncu, M. (2009), "Free vibration and lateral buckling of a cantilever slender beam with an edge crack: Experimental and numerical studies", J. Sound Vib., 326(1-2), 235-250.   DOI
4 Ke, L.L, Yang, J. and Kitipornchai, K. (2009), "Postbuckling analysis of edge cracked functionally graded timoshenko beams under end shortening", Compos. Struct., 90(2), 152-160.   DOI
5 Khorram, A., Bakhtiari-Nejad, F. and Rezaeian, M. (2012), "Comparison studies between two wavelet based crack detection methods of a beam subjected to a moving load", Int. J. Eng. Sci., 51, 204-215.   DOI
6 Moradi, S., Razi, P. and Fatahi, L. (2011), "On the application of bees algorithm to the problem of crack detection of beam-type structures", Comput. Struct., 89(23-24), 2169-2175.   DOI
7 Nayfeh, A.H., Kreider, W. and Anderson, T.J. (1995), "Investigation of natural frequencies and mode shapes of buckled beams", AIAA J., 33(6), 1121-1126.   DOI
8 Neukirch, S, Frelat, J., Goriely, A. and Maurini, C. (2012), "Vibrations of post-buckled rods: the singular inextensible limit", J. Sound Vib., 331(3), 704-720.   DOI   ScienceOn
9 Razi, P, Esmaeel, R.A. and Taheri, F. (2011), "Application of a robust vibration-based non-destructive method for detection of fatigue cracks in structures", Smart Mater. Struct., 20(11), 1-12.
10 Wu, N. and Wang, Q. (2011), "Experimental studies on damage detection of beam structures with wavelet transform", J. Eng. Sci., 49(3), 253-261.   DOI
11 Yazdchi, K. and GowhariAnaraki, A.R. (2008), "Carrying capacity of edge-cracked columns under concentric vertical loads", Acta Mech., 198(1-2), 1-19.   DOI
12 Zhong, S. and Oyadiji, O. (2007), "Crack detection in simply supported beams without baseline modal parameters by stationary wavelet transform", Mech. Syst. Signal Pr., 21(4), 1853-1884.   DOI
13 Ashlock, D. (2006), Evolutionary computation for modeling and optimization, Springer, NY, USA.
14 Addessi, D., Lacarbonara, W. and Paolone, A. (2005a), "Free in-plane vibrations of highly buckled beams carrying a lumped mass", Acta Mech., 180(1-4), 133-156.   DOI
15 Addessi, D., Lacarbonara, W. and Paolone, A. (2005b), "On the linear normal modes of planar pre-stressed curved beams", J. Sound Vib., 284(3-5), 1075-1097.   DOI
16 Al-rasby, S.N. (1991), "Solution techniques in nonlinear structural analysis", Comput. Struct., 40(4), 985-993.   DOI
17 Buezas, F.S., Rosales, M.B. and Filipich, C.P. (2011), "Damage detection with genetic algorithms taking into account a crack contact model", Eng. Fract. Mech., 78(4), 695-712.   DOI
18 Emam, S.A. (2009), "A static and dynamic analysis of the postbuckling of geometrically imperfect composite beams", Compos. Struct., 90(2), 247-253.   DOI
19 Forde, B.W.R. and Stiemer, S.F. (1987), "Improved arc length orthogonality methods for nonlinear finite element analysis", Comput. Struct., 27(5), 625-630.   DOI
20 Reissner, E. (1972), "On one-dimensional finite-strain beam theory: The plane problem", J. Appl. Math. Phys., 23(5), 795-804.   DOI
21 Rosales, M.B, Filipich, C.P. and Buezas, F.S. (2009), "Crack detection in beam-like structures", Eng. Struct., 31(10), 2257-2264.   DOI
22 Roveri, N. and Carcaterra, A. (2012), "Damage detection in structures under traveling loads by Hilbert-Huang transform", Mech. Syst. Signal Pr., 28, 128-144.   DOI   ScienceOn
23 Saavedra, P.N. and Cuitino, L.A. (2001), "Crack detection and vibration behavior of cracked beams", Comput. Struct., 79(16), 1451-1459.   DOI
24 Santillan, S.T, Virgin, L.N. and Plaut, R.H. (2006), "Post-buckling and vibration of heavy beam on horizontal or inclined rigid foundation", J. Appl. Mech., 73(4), 664-671.   DOI
25 Shu, C. and Richards, B.E. (1992), "Application of generalized differential quadrature to solve two-dimensional incompressible navier-stokes equations", Int. J. Numer. Meth. Fl., 15(7), 791-798.   DOI
26 Sinha, J., Friswell, M. and Edwards, S. (2002) "Simplified models for the location of cracks in beam structures using measured vibration data", J. Sound Vib., 251(1), 13-38.   DOI
27 Umesha, P.K, Ravichandran, R. and Sivasubramanian, K. (2009), "Crack detection and quantification in beams using wavelets", Comput. -Aided Civil Infrastruct. Eng., 24(8), 593-607.   DOI
28 VakilBaghmisheh, M.T., Peimani, M., Sadeghi, M.H., Ettefagh, M.M. and FakheriTabrizi, A. (2012), "A hybrid particle swarm-nelder-mead optimization method for crack detection in cantilever beams", Appl. Soft Comput., 12(8), 2217-2226.   DOI