Micromechanical analysis of periodic composites by prescribing the average stress

Caporale, Andrea

doi:10.1007/s12356-010-0010-4

Cited by 14 publications

(2 citation statements)

References 26 publications

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“…The following analyses are performed on the representative volume element. Instead of modelling the masonry as a random composite material (see, e.g., [31][32][33][34][35][36]), it is assumed that the constituents are arranged in a periodic way [37][38][39][40][41][42][43][44][45] and a unit cell is adopted as the representative volume element. The masonry considered in this work is shown in Figure 1, where a wall is depicted.…”

Section: Micromechanical Analysis and Materials Modelmentioning

confidence: 99%

Initiation of Failure for Masonry Subject to In-Plane Loads through Micromechanics

Berardi

2016

Modelling and Simulation in Engineering

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A micromechanical procedure is used in order to evaluate the initiation of damage and failure of masonry with in-plane loads. Masonry material is viewed as a composite with periodic microstructure and, therefore, a unit cell with suitable boundary conditions is assumed as a representative volume element of the masonry. The finite element method is used to determine the average stress on the unit cell corresponding to a given average strain prescribed on the unit cell. Finally, critical curves representing the initiation of damage and failure in both clay brick masonry and adobe masonry are provided.

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Section: Micromechanical Analysis and Materials Modelmentioning

confidence: 99%

Initiation of Failure for Masonry Subject to In-Plane Loads through Micromechanics

Berardi

2016

Modelling and Simulation in Engineering

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“…icromechanical methods [1][2][3] have been widely used to homogenize fiber reinforced composites such as FRP, frequently employed to strengthen existing structures made of concrete [4][5][6][7][8]. Micromechanics has also been adopted for the analysis of different types of heterogeneous materials such as masonry arrangements [9,10] and cement concrete [11][12][13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

A micromechanical four-phase model to predict the compressive failure surface of cement concrete

Caporale

2014

Frattura Ed Integrità Strutturale

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In this work, a micromechanical model is used in order to predict the failure surface of cement concrete subject to multi-axial compression. In the adopted model, the concrete material is schematised as a composite with the following constituents: coarse aggregate (gravel), fine aggregate (sand) and cement paste. The cement paste contains some voids which grow during the loading process. In fact, the non-linear behavior of the concrete is attributed to the creation of cracks in the cement paste; the effect of the cracks is taken into account by introducing equivalent voids (inclusions with zero stiffness) in the cement paste. The three types of inclusions (namely gravel, sand and voids) have different scales, so that the overall behavior of the concrete is obtained by the composition of three different homogenizations; in the sense that the concrete is regarded as the homogenized material of the two-phase composite constituted of the gravel and the mortar; in turn, the mortar is the homogenized material of the two-phase composite constituted of the sand inclusions and a (porous) cement paste matrix; finally, the (porous) cement paste is the homogenized material of the two-phase composite constituted of voids and the pure paste. The pure paste represents the cement paste before the loading process, so that it does not contain voids or other defects due to the loading process. The abovementioned three homogenizations are realized with the predictive scheme of Mori-Tanaka in conjunction with the Eshelby method. The adopted model can be considered an attempt to find micromechanical tools able to capture peculiar aspects of the cement concrete in load cases of uni-axial and multi-axial compression. Attributing the non-linear behavior of concrete to the creation of equivalent voids in the cement paste provides correspondence with many phenomenological aspects of concrete behavior. Trying to improve this correspondence, the influence of the parameters of the evolution law of the equivalent voids in the cement paste is investigated, showing how the parameters affect the uni-axial stress-strain curve and the failure surfaces in bi-axial and tri-axial compression.

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Numerical collapse load of multi-span masonry arch structures with FRP reinforcement

Caporale

Feo

Luciano

et al. 2013

Composites Part B: Engineering

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Micromechanical analysis of periodic composites by prescribing the average stress

Cited by 14 publications

References 26 publications

Initiation of Failure for Masonry Subject to In-Plane Loads through Micromechanics

Initiation of Failure for Masonry Subject to In-Plane Loads through Micromechanics

A micromechanical four-phase model to predict the compressive failure surface of cement concrete

Numerical collapse load of multi-span masonry arch structures with FRP reinforcement

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