C. González scite author profile

A bottom-up, multiscale modeling approach is presented to carry out high-fidelity virtual mechanical tests of composite materials and structures. The strategy begins with the in situ measurement of the matrix and interface mechanical properties at the nanometer-micrometer range to build up a ladder of the numerical simulations, which take into account the relevant deformation and failure mechanisms at different length scales relevant to individual plies, laminates and components. The main features of each simulation step and the information transferred between length scales are described in detail as well as the current limitations and the areas for further development. Finally, the roadmap for the extension of the current strategy to include functional properties and processing into the simulation scheme is delineated.

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A numerical investigation of the effect of particle clustering on the mechanical properties of composites

Segurado

2003

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Computational micromechanics of the transverse and shear behavior of unidirectional fiber reinforced polymers including environmental effects

Naya

González

Lopes

et al. 2017

Composites Part A: Applied Science and Manufacturing

167

129

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Structural composites for multifunctional applications: Current challenges and future trends

González

Vilatela

Molina-Aldareguía

et al. 2017

Progress in Materials Science

219

129

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This review paper summarizes the current state-of-art and challenges for the future developments of fiber-reinforced composites for structural applications with multifunctional capabilities. After a brief analysis of the reasons of the successful incorporation of fiberreinforced composites in many different industrial sectors, the review analyzes three critical factors that will define the future of composites. The first one is the application of novel fiberdeposition and preforming techniques together with innovative liquid moulding strategies, which will be combined by optimization tools based on novel multiscale modelling approaches, so fiber-reinforced composites with optimized properties can be designed and manufactured for each application. In addition, composite applications will be enhanced by the incorporation of multifunctional capabilities. Among them, electrical conductivity, energy storage (structural supercapacitors and batteries) and energy harvesting (piezoelectric and solar energy) seem to be the most promising ones.

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Effect of curing cycle on void distribution and interlaminar shear strength in polymer-matrix composites

Hernández

Sket

González

et al. 2011

Composites Science and Technology

136

119

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Effect of fiber, matrix and interface properties on the in-plane shear deformation of carbon-fiber reinforced composites

Totry

Molina-Aldareguía

González

et al. 2010

Composites Science and Technology

252

120

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Intraply fracture of fiber-reinforced composites: Microscopic mechanisms and modeling

Canal

González

Segurado

et al. 2012

Composites Science and Technology

142

108

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The fracture behavior parallel to the fibers of an E-glass/epoxy unidirectional laminate was studied by means of three-point tests on notched beams. Selected tests were carried out within a scanning electron microscope to ascertain the damage and fracture micromechanisms upon loading. The mechanical behavior of the notched beam was simulated within the framework of the embedded cell model, in which the actual composite microstructure was resolved in front of the notch tip. In addition, matrix and interface properties were independently measured in situ using a nanoindentor. The numerical simulations very accurately predicted the macroscopic response of the composite as well as the damage development and crack growth in front of the notch tip, demonstrating the ability of the embedded cell approach to simulate the fracture behavior of heterogeneous materials. Finally, this methodology was exploited to ascertain the influence of matrix and interface properties on the intraply toughness.

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C. González

Mechanical behavior of unidirectional fiber-reinforced polymers under transverse compression: Microscopic mechanisms and modeling

Multiscale Modeling of Composite Materials: a Roadmap Towards Virtual Testing

A numerical investigation of the effect of particle clustering on the mechanical properties of composites

Computational micromechanics of the transverse and shear behavior of unidirectional fiber reinforced polymers including environmental effects

Structural composites for multifunctional applications: Current challenges and future trends

Effect of curing cycle on void distribution and interlaminar shear strength in polymer-matrix composites

Effect of fiber, matrix and interface properties on the in-plane shear deformation of carbon-fiber reinforced composites

Intraply fracture of fiber-reinforced composites: Microscopic mechanisms and modeling

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