A three-dimensional plasticity-damage constitutive model for timber under cyclic loads

Sirumbal-Zapata, Luis F.; Mariotti, C.; Elghazouli, A.Y.

doi:10.1016/j.compstruc.2017.09.010

Cited by 37 publications

(26 citation statements)

References 33 publications

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“…Degradation of mechanical properties of wood samples subjected to symmetrical cyclic stresses accompanied by microstructure degradation of wood. If the structural damage in tension does not affect the stiffness degradation or the strength of the wood when a reversed load is applied in compression (stiffness recovery) as was shown in Figure 4 , in contrary, the constitutive damage does reduce the tensile capacity of the material when a reverse loading from compression to tension is applied as Sirumbal-Zapata et al [ 27 ] demonstrate in their study. In Figure 10 b–d, all effects of mechanical phenomena as tensile softening brittle failure, stiffness cyclic degradation, and recovery after load-reversal, as well as compressive permanent plastic deformation due to ductile failure can be observed at microscopic levels.…”

Section: Resultsmentioning

confidence: 80%

“…At compression parallel to the fibers, the structural changes begin with the increase of the stress level, and the instability of the fibers is observed by the appearance of some macroscopic kinks [ 6 , 21 , 25 ]. The yielding of a material represents the transition from the initial state of a volume element from an elastic material to a different and irreversible state [ 12 , 26 , 27 ]. In the case of the specimen made of material with predominantly ductile behavior that is subjected to traction, the rupture occurs in successive stages ( Figure 10 ): The peripheral areas yield under the action of tangential stresses, and the central area yields under the action of normal stresses.…”

Section: Resultsmentioning

confidence: 99%

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Degradation of Mechanical Properties of Pine Wood Under Symmetric Axial Cyclic Loading Parallel to Grain

2020

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The mechanical properties of wood, respectively the elastic, plastic, and strength properties, depend on a large number of factors, due both to its structural and physical characteristics, as well as to the size, direction, nature, and speed of application of forces. Wood, generally considered to be a viscous-elastic material, has creep deformations over time under the effect of a constant load. In this study the behavior of pine wood samples was investigated due to its large utilization in different finished products, such as roof construction, furniture, outdoor applications, garden furniture, and toys. The paper aims to analyze the viscoelastic behavior of pine wood subjected to cyclically loading to traction-compression with different loads (1 kN; 1.5 kN; 2 kN), applied at different speeds (1 mm/min; 10 mm/min). It was observed that, at low speeds (1 mm/min) and low intensities of the applied force, it was possible to distinguish the three creep regions specific to wood: the primary area (primary flow), the secondary area, and finally the tertiary creep. As the force increases, the law of variation of the wood flow changes. The degradation of longitudinal elasticity modulus occurs with the increase of the number of cycles, so after 20 alternating symmetrical cycles of traction-compression of the pine wood samples, there is a decrease of its values by 35%.

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Section: Resultsmentioning

confidence: 80%

Section: Resultsmentioning

confidence: 99%

Degradation of Mechanical Properties of Pine Wood Under Symmetric Axial Cyclic Loading Parallel to Grain

2020

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“…Nevertheless, the load and sti↵ness of the laminated veneer lumber (LVL) specimens was slightly overestimated. More recently, Sirumbal-Zapata et al [27] developed a 3D model coupling orthotropic plasticity in compression with isotropic damage in both tension and compression stress states. The model was able to reproduce the response of timber-to-steel connections subjected to load reversals.…”

Section: Numerical Modelling Of Timbermentioning

confidence: 99%

“…This section introduces the numerical strategies followed to model the test specimens described above. The DIANA FE software [41] incorporating a purposely defined damage-plasticity model [27,42] is employed. First, the wood plasticity-damage constitutive model is employed.…”

Section: Finite Element Modellingmentioning

confidence: 99%

“…However, there is a lack of three-dimensional wood constitutive models aimed at reporducing the nonlinear cyclic response of timber dowelled connections. The constitutive model employed in this paper was developed by Sirumbal et al [27] and consists on a plasticity-damage model able to simulate the complex behaviour of wood under three-dimensional stress conditions, within a continuum mechanics approach and with a good level of precision for a natural material such as wood. This model is based on the most relevant characteristics of timber inelastic behaviour when subjected to reversed cyclic loading, allowing to monitor the evolution of damage, to identify potential rupture zones through a smeared continuous approach, and to reproduce the di↵erent inelastic responses of wood in tension and compression.…”

Section: Wood Plasticity-damage Constitutive Modelmentioning

confidence: 99%

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Experimental assessment and damage modelling of hybrid timber beam-to-steel column connections under cyclic loads

Sirumbal-Zapata

Mariotti

Elghazouli

2019

Engineering Structures

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Strong‐motion duration and response scaling of yielding and degrading eccentric structures

Mariotti

2020

Earthq Engng Struct Dyn

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Plan irregular structures, whose complex response represents a generalisation of the simpler de-coupled motion ascribed to symmetric buildings, make up a large proportion of the failures during major earthquakes. This paper examines the seismic response scaling of degrading and no-degrading eccentric structures subjected to bidirectional earthquake action and its relationship with the duration of the ground motion by means of dimensional and orientational analyses. Structures with reflectionally symmetric stiffness distribution and mass eccentricity subjected to orthogonal pairs of ideal pulses are considered as the fundamental case. The application of Vaschy-Buckingham's Π-theorem reduces the number of variables governing the peak orthogonal displacements leading to the emergence of remarkable order in the structural response. If orientationally consistent dimensionless parameters are selected, the response becomes self-similar. By contrast, when degradation is introduced, peak inelastic displacements are dramatically affected and the self-similarity in the response is lost immediately after the onset of inelastic deformations. Conversely, if the uniform duration, instead of the period, of the strong motion is adopted as a timescale, a practically self-similar response is observed. This offers unequivocal proof of the fundamental role played by the ground-motion duration in defining the peak displacement response of degrading structures even at small inelastic demands, although its importance increases with increasing deformation levels. Finally, the existence of complete similarities, or similarities of the first kind, are explored and the practical implications of these findings are briefly outlined in the context of real pulse-like ground motions with varying degrees of coherency.

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A three-dimensional plasticity-damage constitutive model for timber under cyclic loads

Cited by 37 publications

References 33 publications

Degradation of Mechanical Properties of Pine Wood Under Symmetric Axial Cyclic Loading Parallel to Grain

Degradation of Mechanical Properties of Pine Wood Under Symmetric Axial Cyclic Loading Parallel to Grain

Experimental assessment and damage modelling of hybrid timber beam-to-steel column connections under cyclic loads

Strong‐motion duration and response scaling of yielding and degrading eccentric structures

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