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Abstract

One of the main objectives of the structural health monitoring community is to continuously monitor the integrity of a structure by embedding sensors and actuators into the structure. A piezoelectrically driven beam is considered in the present work and the effect of the growth of a single crack on the vibratory characteristics of the beam is studied. It is shown that in order to combine the effect of a crack and the piezoceramic (PZT) actuator into the modeling, available formulations of the mode shapes of the cracked beam, such as modeling the beam as a bi-section connected with a rotational spring, are not applicable as they are not twice differentiable. A new formulation of the mode shapes of the cracked beam is introduced here by applying the Rayleigh–Ritz method. The effect of location and depth of the crack on the vibratory response of the beam is modeled through formulating the loss of energy due to the presence of the crack, which is approximated here as a massless rotational spring. It is shown that the proposed crack modeling provides a close approximation of the mode shapes of the cracked beam. This modeling approach is beneficial as it provides twice-differentiable mode shapes for the cracked beam and can be used as trial functions in the assumed mode approximations. Numerical analysis is also provided for various design parameters, such as crack depth and position and the location of the PZT patch.

Keywords

Crack modeling Euler–Bernoulli beam vibration structural health monitoring piezoelectric actuators

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References

Adams

Cawley

Pye

(1978) A vibration technique for non destructively assessing the integrity of structures. ARCHIVE: Journal of Mechanical Engineering Science 1959-1982 (vols 1-23) 20(2): 93–100.

Afshari M, Butrym B and Inman D (2009) On quantifying detectable fatigue crack size in aluminum beams using vibration and impedance-based methods. In: ASME 2009 Conference on Smart Materials, Adaptive Structures and Intelligent Systems (SMASIS2009), Oxnard, CA.

Aydin

(2008) Vibratory characteristics of Euler-Bernoulli beams with an arbitrary number of cracks subjected to axial load. Journal of Vibration and Control 14(4): 485–485.

Bailey

Hubbard

(1985) Distributed piezoelectric-polymer active vibration control of a cantilever beam. Journal of Guidance, Control, and Dynamics 8(5): 605–611.

Barboni

Mannini

Fantini

(2000) Optimal placement of PZT actuators for the control of beam dynamics. Smart Materials and Structures 9(1): 110–110.

Chatterjee

(2010) Structural damage assessment in a cantilever beam with a breathing crack using higher order frequency response functions. Journal of Sound and Vibration 329(16): 3325–3334.

Chaudhry

Rogers

(1994) The pin-force model revisited. Journal of Intelligent Material Systems and Structures 5(3)347–347.

Chondros

Dimarogonas

(1998) Vibration of a cracked cantilever beam. Journal of Vibration and Acoustics 120(3): 742–742.

Chondros

Dimarogonas

Yao

(1998) A continuous cracked beam vibration theory. Journal of Sound and Vibration 215(1): 17–34.

10.

Christides

Barr

(1984) One-dimensional theory of cracked Bernoulli-Euler beams. International Journal of Mechanical Sciences 26(11–12): 639–648.

11.

Crawley

De Luis

(1987) Use of piezoelectric actuators as elements of intelligent structures. AIAA Journal 25(10): 1373–1385.

12.

Dilena

Morassi

(2004) The use of antiresonances for crack detection in beams. Journal of Sound and Vibration 276(1–2): 195–214.

13.

Dimarogonas

(1996) Vibration of cracked structures: a state of the art review. Engineering Fracture Mechanics 55(5): 831–857.

14.

Erturk A and Inman DJ (2011). Piezoelectric Energy Harvesting. Chichester: Wiley.

15.

Faverjon

Sinou

(2009) Identification of an open crack in a beam using an a posteriori error estimator of the frequency response functions with noisy measurements. European Journal of Mechanics-A/Solids 28(1): 75–85.

16.

Fernandez-Saez

Navarro

(2002) Fundamental frequency of cracked beams in bending vibrations: an analytical approach. Journal of Sound and Vibration 256(1): 17–31.

17.

Fernandez-Saez

Rubio

Navarro

(1999) Approximate calculation of the fundamental frequency for bending vibrations of cracked beams. Journal of Sound and Vibration 225(2): 345–352.

18.

Freund

Herrmann

(1976) Dynamic fracture of a beam or plate in plane bending. Journal of Applied Mechanics 43(1): 112–112.

19.

Hasan

(1995) Crack detection from the variation of the eigenfrequencies of a beam on elastic foundation. Engineering Fracture Mechanics 52(3): 409–421.

20.

Khiem

Lien

(2001) A simplified method for natural frequency analysis of a multiple cracked beam. Journal of Sound and Vibration 245(4): 737–751.

21.

Leo DJ (2007). Engineering Analysis of Smart Material Systems. Hoboken, NJ: John Wiley & Sons Inc.

22.

(2003) Vibratory characteristics of Timoshenko beams with arbitrary number of cracks. Journal of Engineering Mechanics 129(11): 1355–1359.

23.

Meirovitch

(1967) Analytical Methods in Vibration, London: Macmillan Company.

24.

Morassi

(1993) Crack-induced changes in eigenparameters of beam structures. Journal of Engineering Mechanics 119(9): 1798–1803.

25.

Narkis

(1994) Identification of crack location in vibrating simply supported beams. Journal of Sound and Vibration 172(4): 549–558.

26.

Ostachowicz

Krawczuk

(1991) Analysis of the effect of cracks on the natural frequencies of a cantilever beam. Journal of Sound and Vibration 150(2): 191–201.

27.

Prasad

Roy

Tyagi

(2010) Effect of crack position along vibrating cantilever beam on crack growth rate. Work 2(5): 837–839.

28.

Rezaee

Hassannejad

(2011) A new approach to free vibration analysis of a beam with a breathing crack based on mechanical energy balance method. Acta Mechanica Solida Sinica 24(2): 185–194.

29.

Rubio

Fernández-Sáez

(2010) A note on the use of approximate solutions for the bending vibrations of simply supported cracked beams. Journal of Vibration and Acoustics 132(2): 024504–024504.

30.

Shigley

Mischke

Budynas

(2004) Mechanical Engineering Design, New York: McGraw-Hill.

31.

Strambi

Barboni

Gaudenzi

(1995) Pin-force and Euler-Bernoulli models for analysis of intelligent structures. AIAA Journal 33(9): 1746–1749.

32.

Tada H, Paris P and Irwin G (2000). The Stress Analysis of Cracks Handbook. New York: ASME Press, Professional Engineering Pub., ASM International.

Continuous crack modeling in piezoelectrically driven vibrations of an Euler–Bernoulli beam

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