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Deformation of a beam with partially debonded piezoelectric actuators
A linear and a non-linear mathematical models for analyzing the deformation behavior of a beam with a pair of partially debonded piezoelectric actuators are developed on the basis of the Timoshenko beam theory. Effect of buckling is considered in the linear model, where the debonded actuator region is assumed to generate the Euler buckling load when the axial force in the region is larger than the load. The static behavior of the beam is investigated for extension and bending deformation. When the actuator debonds from its edge, the performance deteriorates; in contrast, the debonding in the middle of the actuator does not show any performance degradation until the debonded region buckles. The deformation behavior obtained from the linear model has been found to have good agreement with that from the non-linear model. The non-linear analysis shows that after the buckling the debonded actuator region maintains an axial force of the order of the Euler buckling load of a fix-fix column for the extending actuation, although for the bending actuation, it retains nearly 75% of the Euler buckling load. Further, the strain distribution in the debonded region shows that the buckling may occur before cracks begin in the actuator.
Deformation of a beam with partially debonded piezoelectric actuators
A linear and a non-linear mathematical models for analyzing the deformation behavior of a beam with a pair of partially debonded piezoelectric actuators are developed on the basis of the Timoshenko beam theory. Effect of buckling is considered in the linear model, where the debonded actuator region is assumed to generate the Euler buckling load when the axial force in the region is larger than the load. The static behavior of the beam is investigated for extension and bending deformation. When the actuator debonds from its edge, the performance deteriorates; in contrast, the debonding in the middle of the actuator does not show any performance degradation until the debonded region buckles. The deformation behavior obtained from the linear model has been found to have good agreement with that from the non-linear model. The non-linear analysis shows that after the buckling the debonded actuator region maintains an axial force of the order of the Euler buckling load of a fix-fix column for the extending actuation, although for the bending actuation, it retains nearly 75% of the Euler buckling load. Further, the strain distribution in the debonded region shows that the buckling may occur before cracks begin in the actuator.
Deformation of a beam with partially debonded piezoelectric actuators
Ikeda, Tadashige (author) / Raja, Samikkannu (author) / Ueda, Tetsuhiko (author)
Journal of Intelligent Material Systems and Structures ; 21 ; 453-468
2010
16 Seiten, 23 Quellen
Article (Journal)
English
axiale Verschiebung , Axialkraft , Biegen , Bindefestigkeit , Festigkeitsverlust , intelligenter Sensor , Knickbeanspruchung , Knicken , Leistungsminderung , mathematisches Modell , mechanische Spannungsverteilung , numerisches Verfahren , piezoelektrischer Aktor , Piezoelektrizität , Rissbildung , statisches Verhalten , Träger (Bauwesen) , Verformungsverhalten
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