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Abstract

Delaminations in laminated composite structures are usually invisible or difficult to detect by visual inspection, and thus, cost-effective and reliable non-destructive techniques and approaches need to be developed to detect such failures for structural health monitoring. In this study, a dynamic analytical model is developed to detect a through-the-width delamination embedded in a cantilever laminated composite beam. This beam is surface-bonded with an isolated piezoelectric lead-zirconate-titanate (PZT) sensor and a PZT actuator. The PZT actuator located near the fixed end of the composite beam is used to excite the beam system using a sinusoidal input voltage. The PZT sensor with a striped electrode pattern is bonded on the top surface of the beam section embedded with a delamination and is used to monitor the output voltages recorded from the electrode strips. To study the feasibility of the present model for delamination identification, an experimental investigation is conducted to detect an embedded delamination using this PZT sensor and actuator setup. A comparison of the first three frequencies and the output voltage distribution for the case of the first frequency between the predicted and measured results is carried out, and good agreement between them is noted. Numerical study using the present analytical model reveals that the output voltage distribution along the PZT sensor is closely related to the magnitude and frequency of the sinusoidal input voltage.

Keywords

dynamic analytical model delamination identification composite beam output voltage distribution piezoelectric lead-zirconate-titanate (PZT) sensor and actuator

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References

Keilers, C. H. and Chang, F. K. (1993). Damage Detection and Diagnosis of Composites using Built-in Piezoceramics, In: Proceedings of the 1993 North American Conference on Smart Structures and Materials, Vol. 1917, pp. 1009-1019.

Keilers, C. H. and Chang, F. K. (1995). Identifying Delamination in Composite Beam using Built-in Piezoelectrics: Part I-Experiments and Analysis, Journal of Intelligent Material Systems and Structures, 6(5): 649-663.

Keilers, C. H. and Chang, F. K. (1995). Identifying Delamination in Composite Beam using Built-in Piezoelectrics: Part II-An Identification Method, Journal of Intelligent Material Systems and Structures, 6(5): 664-672.

Okafor, A. C. , Chandrashekhara, K. and Jiang, Y. P. (1996). Delamination Prediction in Composite Beams with Built-in Piezoelectric Devices using Modal Analysis and Neural Network, Smart Materials & Structures, 5(3): 338-347.

Valdes, S. H. D. and Soutis, C. (1999). Application of the Rapid Frequency Sweep Technique for Delamination Detection in Composite Laminates, Advanced Composites Letters, 8(1): 19-23.

Valdes, S. H. D. and Soutis, C. (1999). Delamination Detection in Composite Laminates from Variations of their Modal Characteristics, Journal of Sound and Vibration, 228(1): 1-9.

Valdes, S. H. D. and Soutis, C. (2000). Delamination Detection in Composite Laminates from Variations of their Modal Characteristics, Journal of Low Frequency Noise Vibration and Active Control, 19(1): 27-33.

Chattopadhyay, A. , Nam, C. and Dragomir-Daescu, D. (1999). Delamination Modeling and Detection in Smart Composite Plates, Journal of Reinforced Plastics & Composites, 18 (17): 1557-1572.

Chattopadhyay, A. , Nam, C. and Kim Y. (2000). Damage Detection and Vibration Control of a Delaminated Smart Composite Plate, Advanced Composites Letters, 9(1): 7-15.

10.

Chattopadhyay, A. , Kim, H. S. and Ghoshal, A. (2004). Non-linear Vibration Analysis of Smart Composite Structures with Discrete Delamination using a Refined Layerwise Theory, Journal of Sound and Vibration, 273(1-2): 387-407.

11.

Watkins, S. E. , Sanders, G. W. , Akhavan, F. and Chandrashekhara, K. (2002). Modal Analysis using Fiber Optic Sensors and Neural Networks for Prediction of Composite Beam Delamiation, Smart Materials and Structures, 11(4): 489-495.

12.

Tan, P. and Tong, L. (2004). Delamination Detection of Composite Beams using Piezoelectric Sensors with Evenly Distributed Electrode Strips, Journal of Composite Materials, 38(4): 321-352.

13.

Tan, P. and Tong, L. (2004). A Delamination Detection Model for Composite Beams using PFRC Sensor/Actuator, Composites, Part A: Applied Science and Manufacturing, 35(2): 231-247.

14.

Tan, P. and Tong, L. (2004). Identification of Delamination in a Composite Beam using Integrated Piezoelectric Sensor/Actuator Layer, Composite Structures, 66(1-4): 391-398.

15.

Tong, L. and Steven, G. P. (1999). Analysis and Design of Structural Bonded Joints, Dordrecht, Kluwer.

16.

A Data Sheet from Boeing HDH, Australia, 2004.

17.

A Data Sheet from TRS, USA, 2002.

Experimental and Analytical Identification of a Delamination Using Isolated PZT Sensor and Actuator Patches

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