Raúl Guinovart-Dı́az scite author profile

Numerical unit cell models of 1-3 periodic composites made of piezoceramic unidirectional cylindrical fibers embedded in a soft non-piezoelectric matrix are developed. The unit cell is used for prediction of the effective coefficients of the periodic transversely isotropic piezoelectric cylindrical fiber composite. Special emphasis is placed on a formulation of the boundary conditions that allows the simulation of all modes of the overall deformation arising from any arbitrary combination of mechanical and electrical loading. The numerical approach is based on the finite element method and it allows extension to composites with arbitrary geometrical inclusion configurations, providing a powerful tool for fast calculation of their effective properties. For verification, the effective coefficients are evaluated for square and hexagonal arrangements of unidirectional piezoelectric cylindrical fiber composites. The results obtained from the numerical technique are compared with those obtained by means of the analytical asymptotic homogenization method for different volume fractions. Furthermore, the results are compared with other analytical and numerical methods reported in the literature.

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Closed-form expressions for the effective coefficients of a fiber-reinforced composite with transversely isotropic constituents – I. Elastic and square symmetry

Bravo‐Castillero

Guinovart-Dı́az

Sabina

et al. 2001

Mechanics of Materials

131

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Closed-form expressions for the effective coefficients of a fiber-reinforced composite with transversely isotropic constituents – II. Piezoelectric and square symmetry

Bravo‐Castillero

Guinovart-Dı́az

Sabina

et al. 2001

Mechanics of Materials

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Closed-form expressions for the effective coefficients of fibre-reinforced composite with transversely isotropic constituents. I: Elastic and hexagonal symmetry

Guinovart-Dı́az

Bravo‐Castillero

Rodrı́guez-Ramos

et al. 2001

Journal of the Mechanics and Physics of Solids

105

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On local indentation and impact compliance of isotropic auxetic materials from the continuum mechanics viewpoint

Argatov

Guinovart-Dı́az

Sabina

2012

International Journal of Engineering Science

129

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