Energy conservation during remeshing in the analysis of dynamic fracture

Lin Chen; Bin Li; René de Borst

doi:10.1002/nme.6142

Energy conservation during remeshing in the analysis of dynamic fracture

Lin Chen, Bin Li, René de Borst^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

The analysis of (dynamic) fracture often requires multiple changes to the discretisation during crack propagation. The state vector from the previous time step must then be transferred to provide the initial values of the next time step. A novel methodology based on a least-squares fit is proposed for this mapping. The energy balance is taken as a constraint in the mapping, which results in a complete energy preservation. Apart from capturing the physics better, this also has advantages for numerical stability. To further improve the accuracy, Powell-Sabin B-splines, which are based on triangles, have been used for the discretisation. Since C1 continuity of the displacement field holds at crack tips for Powell-Sabin B-splines, the stresses at and around crack tips are captured much more accurately than when using elements with a standard Lagrangian interpolation, or with NURBS and T-splines. The versatility and accuracy of the approach to simulate dynamic crack propagation are assessed in two case studies, featuring mode-I and mixed-mode crack propagation.

Original language	English
Pages (from-to)	433-446
Number of pages	14
Journal	International Journal for Numerical Methods in Engineering
Volume	120
Issue number	4
DOIs	https://doi.org/10.1002/nme.6142
State	Published - 26 Oct 2019
Externally published	Yes

Keywords

Powell-Sabin B-splines
cohesive zone model
dynamic fracture
energy conservation
remeshing

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/nme.6142

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title = "Energy conservation during remeshing in the analysis of dynamic fracture",

abstract = "The analysis of (dynamic) fracture often requires multiple changes to the discretisation during crack propagation. The state vector from the previous time step must then be transferred to provide the initial values of the next time step. A novel methodology based on a least-squares fit is proposed for this mapping. The energy balance is taken as a constraint in the mapping, which results in a complete energy preservation. Apart from capturing the physics better, this also has advantages for numerical stability. To further improve the accuracy, Powell-Sabin B-splines, which are based on triangles, have been used for the discretisation. Since C1 continuity of the displacement field holds at crack tips for Powell-Sabin B-splines, the stresses at and around crack tips are captured much more accurately than when using elements with a standard Lagrangian interpolation, or with NURBS and T-splines. The versatility and accuracy of the approach to simulate dynamic crack propagation are assessed in two case studies, featuring mode-I and mixed-mode crack propagation.",

keywords = "Powell-Sabin B-splines, cohesive zone model, dynamic fracture, energy conservation, remeshing",

author = "Lin Chen and Bin Li and {de Borst}, Ren{\'e}",

note = "Publisher Copyright: {\textcopyright} 2019 John Wiley & Sons, Ltd.",

year = "2019",

month = oct,

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doi = "10.1002/nme.6142",

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journal = "International Journal for Numerical Methods in Engineering",

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T1 - Energy conservation during remeshing in the analysis of dynamic fracture

AU - Chen, Lin

AU - Li, Bin

AU - de Borst, René

PY - 2019/10/26

Y1 - 2019/10/26

N2 - The analysis of (dynamic) fracture often requires multiple changes to the discretisation during crack propagation. The state vector from the previous time step must then be transferred to provide the initial values of the next time step. A novel methodology based on a least-squares fit is proposed for this mapping. The energy balance is taken as a constraint in the mapping, which results in a complete energy preservation. Apart from capturing the physics better, this also has advantages for numerical stability. To further improve the accuracy, Powell-Sabin B-splines, which are based on triangles, have been used for the discretisation. Since C1 continuity of the displacement field holds at crack tips for Powell-Sabin B-splines, the stresses at and around crack tips are captured much more accurately than when using elements with a standard Lagrangian interpolation, or with NURBS and T-splines. The versatility and accuracy of the approach to simulate dynamic crack propagation are assessed in two case studies, featuring mode-I and mixed-mode crack propagation.

AB - The analysis of (dynamic) fracture often requires multiple changes to the discretisation during crack propagation. The state vector from the previous time step must then be transferred to provide the initial values of the next time step. A novel methodology based on a least-squares fit is proposed for this mapping. The energy balance is taken as a constraint in the mapping, which results in a complete energy preservation. Apart from capturing the physics better, this also has advantages for numerical stability. To further improve the accuracy, Powell-Sabin B-splines, which are based on triangles, have been used for the discretisation. Since C1 continuity of the displacement field holds at crack tips for Powell-Sabin B-splines, the stresses at and around crack tips are captured much more accurately than when using elements with a standard Lagrangian interpolation, or with NURBS and T-splines. The versatility and accuracy of the approach to simulate dynamic crack propagation are assessed in two case studies, featuring mode-I and mixed-mode crack propagation.

KW - Powell-Sabin B-splines

KW - cohesive zone model

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KW - energy conservation

KW - remeshing

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JO - International Journal for Numerical Methods in Engineering

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Energy conservation during remeshing in the analysis of dynamic fracture

Abstract

Keywords

UN SDGs

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