N. Dourado scite author profile

From load-unloading cycles applied on wood notched specimens subjected to three-point bending, we show that the concept of 'equivalent LEFM', usually used for the quasibrittle materials, can be successfully applied to the fracture behavior of wood in mode I. Within this equivalent linear elastic framework, the quasibrittle fracture behavior of wood leads to an R-curve which is evaluated and discussed. On the other hand, the estimate of the peak load (or maximum load) of a structure as a function of the corresponding R-curve is an important problem for a building material such as wood. After a review of some general results about the connection between the R-curve and the shape of the load-deflection curve, we propose a single equation, i.e., valid for a fracture test under load-control or displacement-control, allowing to estimate the crack length corresponding to every extremum of a load-deflection curve.

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Bilinear softening parameters and equivalent LEFM R-curve in quasibrittle failure

Morel

Lespine

Coureau

et al. 2010

International Journal of Solids and Structures

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a b s t r a c tFor composites and adhesive joints, the determination of the cohesive zone parameters from Double Cantilever Beam specimens loaded with pure moments is now well established and documented. However, for quasibrittle materials used in Civil Engineering such as concrete or wood, the difficulty to apply a pure bending moment lies inappropriated the method used for composites. Nevertheless, the one-to-one correspondence which exists between the R-curve and the softening curve is here revisited and adapted for any kind of specimen geometry and for the bilinear approximation of the softening function, well-known to successfully describe the failure of a wide group of quasibrittle materials. It is shown that even though the connections between the cohesive parameters and the 'equivalent LEFM' R-curve are geometry and material dependent, their trends are preserved whatever the specimen geometry and the material are. The outline of a general estimation procedure of the cohesive zone parameters funded on the equivalent LEFM R-curve is proposed.

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An enhanced formulation to model spatial revolute joints with radial and axial clearances

Marques

Isaac

Dourado

et al. 2017

Mechanism and Machine Theory

118

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Additive manufactured porous biomaterials targeting orthopedic implants: A suitable combination of mechanical, physical and topological properties

Bartolomeu

Dourado

Pereira

et al. 2020

Materials Science and Engineering: C

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The double cantilever beam test applied to mode I fracture characterization of cortical bone tissue

Morais

Moura

Pereira

et al. 2010

Journal of the Mechanical Behavior of Biomedical Materials

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Compliance Fracture toughness Modeling A B S T R A C TThe primary objective of this work was to analyse the adequacy of the Double Cantilever Beam (DCB) test in determining fracture toughness under pure mode I loading of cortical bone tissue. A new data reduction scheme based on specimen compliance and the crack equivalent concept was used to overcome the difficulties inherent in crack monitoring during its growth. It provides a complete resistance curve, which is fundamental in estimating the fracture energy. A cohesive zone model was used to simulate damage initiation and propagation, thus assessing the efficacy of the proposed testing method and data reduction scheme. Subsequently, the DCB test was applied to evaluate the mode I fracture energy of hydrated and thermally dehydrated cortical bone tissue from young bovine femur, in the tangential-longitudinal propagation system. The results obtained demonstrate the efficacy of the DCB test and the proposed data reduction scheme on the bone fracture characterization under mode I loading.

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Preclinical and Translational Studies in Small Ruminants (Sheep and Goat) as Models for Osteoporosis Research

Dias

Camassa

Bordelo

et al. 2018

Curr Osteoporos Rep

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The most frequent osteoporotic sheep model used is the ovariectomized sheep with 12 months post-operatively or more and the combined treatment of ovariectomized sheep associated to calcium/vitamin D-deficient diet and glucocorticoid applications for 6 months, but other methods are also described, like pinealectomy or hypothalamic-pituitary disconnection in ovariectomized sheep. The goat model for osteoporosis research has been used in a very limited number of studies in osteoporosis research relative to sheep. These osteoporotic small ruminant models are applied for biomaterial research, bone augmentation, efficacy of implant fixation, fragility fracture-healing process improvement, or bone-defect repair studies in the osteopenic or osteoporotic bone. Sheep are a recognized large animal model for preclinical and translational studies in osteoporosis research and the goat to a lesser extent. Recently, the pathophysiological mechanism underlying induction of osteoporosis in glucocorticoid-treated ovariectomized aged sheep was clarified, being similar to what occurs in postmenopausal women with glucocorticoid-induced osteoporosis. It was also concluded that the receptor activator of NF-κB ligand was stimulated in the late progressive phase of the osteoporosis induced by steroids in sheep. The knowledge of the pathophysiological mechanisms at the cellular and molecular levels of the induction of osteoporosis in small ruminants, if identical to humans, will allow in the future, the use of these animal models with greater confidence in the preclinical and translational studies for osteoporosis research.

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N. Dourado

A new data reduction scheme for mode I wood fracture characterization using the double cantilever beam test

Comparison of fracture properties of two wood species through cohesive crack simulations

Wood: a quasibrittle material R-curve behavior and peak load evaluation

Bilinear softening parameters and equivalent LEFM R-curve in quasibrittle failure

An enhanced formulation to model spatial revolute joints with radial and axial clearances

Additive manufactured porous biomaterials targeting orthopedic implants: A suitable combination of mechanical, physical and topological properties

The double cantilever beam test applied to mode I fracture characterization of cortical bone tissue

Preclinical and Translational Studies in Small Ruminants (Sheep and Goat) as Models for Osteoporosis Research

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