Coupled Layerwise Analysis of Composite Beams with Embedded Piezoelectric Sensors and Actuators

Abstract

Unified mechanics are developed with the capability to model both sensory and active composite laminates with embedded piezoelectric layers. Two discretelayer (or layerwise) formulations enable analysis of both global and local electromechanical response. The first assumes constant through-the-thickness displacement, while the second permits piecewise continuous variation. The mechanics include the contributions from elastic, piezoelectric and dielectric components. The incorporation of electric potential into the state variables permits representation of general electromechanical boundary conditions. Approximate finite element solutions for the static and freevibration analysis of beams are presented. Applications on composite beams demonstrate the capability to represent either sensory or active structures, and to model the complicated stressstrain fields, the interactions between passive/active layers and interfacial phenomena between sensors and composite plies. The capability to predict the dynamic characteristics under various electrical boundary conditions is demonstrated. Some advantages of the variable transverse displacement formulation on the freevibration response of sensory structures are also shown.

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References

Bailey, T. and J. E. Hubbard . 1985. "Distributed Piezoelectric Polymer Active Vibration Control of Cantilever Beam', AIAA Journal of Guidance and Control 8:606-610.

Crawley, E. F. and J. de Luis . 1987. "Use of Piezoelectric Actuators as Elements of Intelligent Structures", AIAA Journal 25:1373-1385.

Dimitriadis, E. K. , C. R. Fuller and C. A. Rogers . 1989. "Piezoelectric Actuators for Distributed Noise and Vibration Excitation of Thin Plates", Proceedings of ASME Failure Prevention and Reliability Conference Montreal, pp. 223-233.

Fanson, J. L. and J. C. Chen . 1986. "Structural Control by the Use of Piezoelectric Active Members", Proceedings of NASA/DOD Control-Structures Interaction Conference NASA CP-2447, Part II.

Ha, S. H. , C. Keilers and F. K. Chang . 1992. "Finite Element Analysis of Composite Structures Containing Distributed Piezoceramic Sensors and Actuators"' AIAA Journal 30(3):772-780.

Hwang, W. S. and H. C. Park . 1993. "Finite Element Modelling of Piezoelectric Sensors and Actuators", AIAA Journal 31(5):930-937.

Lammering, R. 1991. "The Application of a Finite Shell Element for Composites Containing Piezoelectric Polymers in Vibration Control". Computers and Structures 41:1101-1109.

Lazarus, K. B. and E. F Crawley. 1989. "Induced Strain Actuation of Composite Plates", GTL Report No. 197, Massachusetts Institute of Technology, Cambridge, Massachusetts.

Lee, C.-K. and F C. Moon . 1990. "Modal Sensors/Actuators", ASME Journal of Applied Mechanics, 57:434-441.

10.

Lee, C.-K. and F. C. Moon . 1989. "Laminated Piezopolymer Plates for Torsional Bending Sensors and Actuators", Journal of the Acoustical Society of America 85:2432-2439.

11.

Lee, C.-K. 1990. "Theory of Laminated Piezoelectric Plates for the Design of Distributed Sensors/Actuators. Part I: Governing Equations and Reciprocal Relationships", Journal of the Acoustical Society of America 87:1144-1158.

12.

Liebowitz, M. and J. R. Vinson . 1991. "Intelligent Composites: Design and Analysis of Composite Material Structures Involving Piezoelectric Material Layers. Part A-Basic Formulation", Technical Report CCM 91-54, University of Delaware Center for Composite Materials.

13.

Mason, W. P. 1950. Piezoelectric Crystals and Their Applications to Ultrasonics. New York: D. Van Nostrand Co.

14.

Nye, J. F. 1964. "Piezoelectricity", Physical Properties of Crystals. Oxford: The Clarendon Press.

15.

Reddy, J. N. 1987. "A Generalization of Displacement-Based Laminate Theories", Communication in Applied Numerical Methods 3:173-181.

16.

Robbins, D. H. and J. N. Reddy . 1991. "Analysis of Piezoelectrically Actuated Beams Using a Layer-Wise Displacement Theory", Computers and Structures 41:265-279.

17.

Saravanos, D. A. 1993. "Analysis of Passive Damping in Thick Composite Structures", AIAA Journal 31(8):1503-1510.

18.

Saravanos, D. A. and J. M. Pereira . 1992. "Effects of Interply Damping Layers on the Dynamic Response of Composites Plates", AIAA Jourrnal 30(12):2906-2913.

19.

Tiersten, H. F. 1969. Linear Piezoelectric Plate Vibrations. New York: Plenum Press.

20.

Tzou, H. S. and M. Gadre . 1989a. "Theoretical Analysis of a Multi-Layered Thin Shell Coupled with Piezoelectric Shell Actuators for Distributed Vibration Controls', Journal of Sound and Vibration 132:433-450.

21.

Tzou, H. S. 1989b. "Distributed Sensing and Controls of Flexible Plates and Shells Using Distributed Piezoelectric Element", Journal of Wave-Material Interaction 4:11-29.

22.

Tzou, H. S. and C. I. Tseng . 1990. "Distributed Piezoelectric Sensor/Actuator Design for Dynamic Measurement/Control of Distributed Parametric Systems: A Piezoelectric Finite Element Approach", Journal of Sound and Vibration 138:17-34.

23.

Venneri, S. L. and A. K. Noor . 1992. "Overview and Major Characteristics of Future Aeronautical and Space Systems", AIAA-92-2441-CP, Proceedings, 33rd AIMAIASME/ASCEIAHS/ASC Structures, Structural Dynamics, and Materials Conference Dallas, TX, pp. 1924-1934.

24.

Wang, B. T. , E. K. Dimitriadis and C.R. Fuller . 1989. 'Active Control of Panel Related Noise Using Multiple Piezoelectric Actuators", Journal of the Acoustical Society of America 86(S1):S84-S84.

25.

Wang, B.-T. and C. A. Rogers . 1991. "Laminate Plate Theory for Spatially Distributed Induced Strain Actuators"' Journal of Composite Materials 25:433-452. 363