Linearized state‐based peridynamics for 2‐D problems

Sarego, Giulia; Le, Q. V.; Bobaru, Florin; Zaccariotto, Mirco; Galvanetto, Ugo

doi:10.1002/nme.5250

Cited by 107 publications

(46 citation statements)

References 68 publications

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“…One reason for the similar accuracies of the quadrature rules in Table 2 is that the surface effect of peridynamics affects the computation of the Young's modulus using the stress-strain curve. An alternative method that overcomes this issue is presented in Sarego et al (2016) where the authors compute the elastic modulus using the displacement. Nevertheless, for reasons of simplicity we stick to the spacial integration of LAMMPS.…”

Section: Verification Of the Constitutive Lawmentioning

confidence: 99%

Bond-based peridynamics: a quantitative study of Mode I crack opening

Diehl¹,

Franzelin²,

Pflüger³

et al. 2016

Int J Fract

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This paper shows a new approach to estimate the critical traction for Mode I crack opening before crack growth by numerical simulation. For quasi-static loading, Linear Elastic Fracture Mechanics predicts the critical traction before crack growth. To simulate the crack growth, we used bond-based peridynamics, a non-local generalization of continuum mechanics. We discretize the peridynamics equation of motion with a collocation by space approach, the socalled EMU nodal discretization. As the constitutive law, we employ the improved prototype micro brittle material model. This bond-based material model is verified by the Young's modulus from classical theory for a homogeneous deformation for different quadrature rules. For the EMU-ND we studied the behavior for different ratios of the horizon and nodal spacing to gain a robust value for a large variety of materials. To access this wide range of materials, we applied sparse grids, a technique to build high-dimensional surrogate models. Sparse grids significantly reduce the number of simulation runs compared to a full grid approach and keep up a similar approximation accuracy. For the validation of the quasi-static loading process, we show that the critical traction is independent of the material density for most material parameters. The bond-based IPMB model with EMU nodal discretization seems very robust for the ratio δ/ΔX = 3 for a wide range of materials, if an error of 5 % is acceptable.

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Section: Verification Of the Constitutive Lawmentioning

confidence: 99%

Bond-based peridynamics: a quantitative study of Mode I crack opening

Diehl¹,

Franzelin²,

Pflüger³

et al. 2016

Int J Fract

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“…To improve assembly efficiency, the dual assembly algorithm (in Appendix B) is proposed in this paper, and the volume corrections ( η xp , η xq , and η pq ) are defined in Appendix C. It should be noted that this algorithm is very suitable to the OSPD model where nonuniform discretization is used, and more importantly, the double state is only calculated once for each material point, whereas the double state in the work of Sarego et al is calculated twice; from this point, the proposed dual assembly algorithm improves the computational efficiency in double‐state assembly.…”

Section: Linearization Of Dual‐horizon Ospdmentioning

confidence: 99%

“…In the BPD model, the force density vectors are equal in magnitude as well as parallel to the relative position vector in the deformed state, which makes it limited to the constitutive behavior of isotropic materials with a fixed Poisson's ratio (1/3 in plane stress conditions and 1/4 in three‐dimensional [3D] or plane strain conditions). To overcome the restriction, a generalized formulation of PD called state‐based PD is proposed to describe the mechanical and fracturing behavior of more general materials, and subsequently, the linearized theory of the peridynamic states was also studied in the works of Silling and Sarego et al…”

Section: Introductionmentioning

confidence: 99%

An implicit dual‐based approach to couple peridynamics with classical continuum mechanics

Bie

She

et al. 2019

Numerical Meth Engineering

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Summary A general local/nonlocal implicit coupling technique called the dual‐based approach is proposed to couple peridynamics (PD) with classical continuum mechanics. In the present method, physical information is transmitted mutually from local to nonlocal regions through the coupling elements; no transition region is introduced. For different mesh discretizations, two coupling methods are achieved with simplicity and effectivity. To obtain the stiffness matrix of the coupled model, without loss of generality, the implicit dual‐horizon ordinary state‐based peridynamic model is proposed, in which the linearization of dual‐horizon ordinary state‐based PD is derived and the dual assembly algorithm of the peridynamic stiffness matrix is developed. It will be seen that the implicit dual‐based coupling approach provides a new implicit coupling method that is easy to implement and makes full use of the internal connection between PD and classical continuum mechanics. Several numerical examples involving static crack propagation are investigated, and the satisfactory results show both quantitative and qualitative agreement with either the analytic solution or the available experiment.

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“…Similar to the bar element in FEM, the bond force is only related to the relative elongation between the two particles for isotropic material; therefore, the stretch parameter of the bond is solely defined by the elastic modulus. The effect of Poisson's ratio is then cannot be described in BPD model, and the Poisson's ratio is fixed as 1/3 for materials under plane stress condition and 1/4 under plane strain and three‐dimensional (3D) conditions …”

Section: Introductionmentioning

confidence: 99%

“…The effect of Poisson's ratio is then cannot be described in BPD model, and the Poisson's ratio is fixed as 1/3 for materials under plane stress condition and 1/4 under plane strain and three-dimensional (3D) conditions. 9,10 To overcome the limitation of Poisson's ratio in the BPD model, Silling et al 11 proposed a generalization of the PD framework for solid mechanics, which is the so-called state-based peridynamic (SPD) model. In SPD model, the pairwise force of a bond composed of two particles depends not only on the deformation of the bond itself but also on the collective deformation of other bonds within the neighborhoods of the particles.…”

Section: Introductionmentioning

confidence: 99%

A bond‐based peridynamic model considering effects of particle rotation and shear influence coefficient

Zheng

Shen

Xia

et al. 2019

Numerical Meth Engineering

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Summary The classical bond‐based peridynamic (BPD) model is limited with a fixed Poisson's ratio. To overcome this limitation, an improved BPD model is proposed to analyze the deformation and crack propagation of microelastic brittle materials with emphasis on varying Poisson's ratios. In the proposed model, the bond is subjected to axial and transverse pairwise forces, and the particle rotation angle is added to eliminate the additional bending moment caused by transverse forces, which is a key factor to satisfy the balance of angular momentum exactly. As a result, the bond not only has axial displacement but also has transverse displacement and particle rotation. This extension in the displacement mode overcomes the limitation of the fixed Poisson's ratio in the classical BPD model. The simulation results demonstrate the precision of the improved BPD model and prove its ability to predict deformations and crack propagations.

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Linearized state‐based peridynamics for 2‐D problems

Cited by 107 publications

References 68 publications

Bond-based peridynamics: a quantitative study of Mode I crack opening

Bond-based peridynamics: a quantitative study of Mode I crack opening

An implicit dual‐based approach to couple peridynamics with classical continuum mechanics

A bond‐based peridynamic model considering effects of particle rotation and shear influence coefficient

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