Deformation of Electroelastic Materials with Dispersed Microdamageability

Dmytro Babich; O. Bezverkhyi; Tatiana Dorodnykh

doi:10.4028/www.scientific.net/KEM.665.145

Paper Titles

Mechanical and Fatigue Parameters of Two Types of Alkali-Activated Concrete
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Influence of Semi-Circular Cracks on Threaded Connection Fatigue by Means of Kitagawa-Takahashi Diagram and El Haddad Equation
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Predicting Micro-Mechanics Damage Behaviour at a Metal-Ceramic Interface in a Reinforced Alloy
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TEM Study of Microstructure Changes, Formation and Distribution of Slip Bands in Austenitic Steels after Low-Cycle Fatigue (LCF) Deformation - II
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Deformation of Electroelastic Materials with Dispersed Microdamageability
p.145

Investigation on Damage Tolerance of Thick Laminate Composite Structure
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Strength Prediction of Laminated Composites upon Independent Constituent Properties
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Simulation of the Transient Behavior of Matter with Characteristic Geometrical Variations & Defects Irradiated by Nanosecond Laser Pulses Using FEA
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Three-Dimensional Modeling of Single-Lap Joints with Variable Interfacial Crack Length
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 665Deformation of Electroelastic Materials with...

Deformation of Electroelastic Materials with Dispersed Microdamageability

Abstract:

The present paper addresses the continuum model describing deformation electroelastic materials by using the generalized Eshelby principle. The energy method is based on the principle of equivalence of the deformation energy of fractured piezoelectric materials and the energy of medium, which is modeling these materials as a continuous medium. The key point of this approach is to determine the densities of the released elastic and electric energy.

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Periodical:

Key Engineering Materials (Volume 665)

Pages:

145-148

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.665.145

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Online since:

September 2015

Authors:

Dmytro Babich, O. Bezverkhyi, Tatiana Dorodnykh

Keywords:

Damage, Effective Electroelastic Constants, Generalized Eshelby Principle, Piezoelectric Materials

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References

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