Development of the Meso-Macro Multiscale Analysis Method with the Use of Discrete Dislocation Mechanics

The multiscale analysis method based on traction-separation law (TSL) and cohesive zone law was used to describe the cross-scale defective process of alpha titanium (α-Ti) material with compounding microdefects in this paper. First, the properties of T-S curve and the reasonable range of T-S area relative to the length of defects were discussed. Next, based on the conclusions above, the molecule dynamics analysis of three models ofα-Ti with compounding microdefects was conducted and cross-scaly simulated. The phenomenon, principles, and mechanisms of different compound microscale defects propagation ofα-Ti were observed and explained at atomic scale, and the effects of different microdefects on macrofracture parameters of materials were studied.

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2017 An Evaluation of Nanoindentation-Induced Displacement Burst and Collective Dislocation Motion Based on Discrete Dislocation Mechanics and Elastic Energy of Dislocations

The proceedings of the JSME annual meeting ◽

10.1299/jsmemecjo.2007.1.0_85 ◽

2007 ◽

Vol 2007.1 (0) ◽

pp. 85-86

Author(s):

Tomohito TSURU ◽

Yoji SHIBUTANI

Keyword(s):

Elastic Energy ◽

Dislocation Motion ◽

Discrete Dislocation ◽

Dislocation Mechanics

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Development of a Decoupled Multiscale Analysis Method for Woven Composites

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.794.89 ◽

2019 ◽

Vol 794 ◽

pp. 89-96

Author(s):

Hiroma Nagaoka ◽

Tetsuya Matsuda ◽

Tsubasa Ogaki

Keyword(s):

Constitutive Model ◽

Multiscale Analysis ◽

Woven Composites ◽

Analysis Method ◽

Element Analysis ◽

Computational Costs ◽

Fiber Reinforced Plastic ◽

Reinforced Plastic ◽

The Finite Element Analysis ◽

Study Development

In this study, development of a decoupled multiscale analysis method for woven composites is conducted. To this end, an elastic-viscoplastic macroscopic constitutive model which is able to express strong anisotropy of composites is introduced, and the material parameters in the constitutive model are determined based on the results of triple-scale homogenization analysis. Moreover, the constitutive model is implemented in the finite element analysis code LS-DYNA. The developed method is applied to 3-point bending analysis of plain-woven carbon fiber-reinforced plastic (CFRP) composites with various types of laminates configurations. It is shown that the present method can analyze their different behavior depending on the laminate configuration with greatly reduced computational costs.

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Size-dependent energy in crystal plasticity and continuum dislocation models

Proceedings of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rspa.2014.0868 ◽

2015 ◽

Vol 471 (2175) ◽

pp. 20140868 ◽

Cited By ~ 16

Author(s):

Sinisa Dj. Mesarovic ◽

Samuel Forest ◽

Jovo P. Jaric

Keyword(s):

Strong Dependence ◽

Negative Answer ◽

Point Of View ◽

Length Scale ◽

Dislocation Interaction ◽

Size Dependent ◽

Discrete Dislocation ◽

Dislocation Mechanics ◽

Dislocation Models ◽

Dislocation Density Tensor

In the light of recent progress in coarsening the discrete dislocation mechanics, we consider two questions relevant for the development of a mesoscale, size-dependent plasticity: (i) can the phenomenological expression for size-dependent energy, as quadratic form of Nye's dislocation density tensor, be justified from the point of view of dislocation mechanics and under what conditions? (ii) how can physical or phenomenological expressions for size-dependent energy be computed from dislocation mechanics in the general case of elastically anisotropic crystal? The analysis based on material and slip system symmetries implies the negative answer to the first question. However, the coarsening method developed in response to the second question, and based on the physical interpretation of the size-dependent energy as the coarsening error in dislocation interaction energy, introduces additional symmetries. The result is that the equivalence between the phenomenological and the physical expressions is possible, but only if the multiplicity of characteristic lengths associated with different slip systems, is sacrificed. Finally, we discuss the consequences of the assumption that a single length scale governs the plasticity of a crystal, and note that the plastic dissipation at interfaces has a strong dependence on the length scale embedded in the energy expression.

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