Towards mechanism-based simulation of impact damage using exascale computing

Anton Shterenlikht; Lee Margetts; S. A. McDonald; Neil Bourne

doi:10.1063/1.4971615

Towards mechanism-based simulation of impact damage using exascale computing

Anton Shterenlikht, Lee Margetts, S. A. McDonald, Neil Bourne

Solid Mechanics

Research output: Chapter in Book/Report/Conference proceeding › Conference Contribution (Conference Proceeding)

2 Citations (Scopus)

448 Downloads (Pure)

Abstract

Over the past 60 years, the finite element method has been very successful in modelling deformation in engineering structures. However the method requires the definition of constitutive models that represent the response of the material to applied loads. There are two issues. Firstly, the models are often difficult to define. Secondly, there is often no physical connection between the models and the mechanisms that accommodate deformation. In this paper, we present a potentially disruptive two-level strategy which couples the finite element method at the macroscale with cellular automata at the mesoscale. The cellular automata are used to simulate mechanisms, such as crack propagation. The stress-strain relationship emerges as a continuum mechanics scale interpretation of changes at the micro- and meso-scales. Iterative two-way updating between the cellular automata and finite elements drives the simulation forward as the material undergoes progressive damage at high strain rates. The strategy is particularly attractive on large-scale computing platforms as both methods scale well on tens of thousands of CPUs.

Original language	English
Title of host publication	SHOCK COMPRESSION OF CONDENSED MATTER
Subtitle of host publication	2015: Proceedings of the Conference of the American Physical Society Topical Group on Shock Compression of Condensed Matter
Publisher	American Institute of Physics (AIP)
Number of pages	4
ISBN (Print)	9780735414570
DOIs	https://doi.org/10.1063/1.4971615
Publication status	Published - 13 Jan 2017

Publication series

Name	AIP Conference Processings
Publisher	AIP Publishing LLC
Number	1
Volume	1793

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An Experimental and Modelling Approach to Engineering the Stability of Mixed Micro- and Nano-Grain Size Polycrystals to Improve Durability
Flewitt, P. E. J. (Principal Investigator)
5/01/10 → 5/10/13
Project: Research
Predicting scatter in the ductile to brittle transitional fracture in steels
Shterenlikht, A. (Principal Investigator)
1/10/09 → 1/10/11
Project: Research

HPC (High Performance Computing) and HTC (High Throughput Computing) Facilities
Alam, S. R. (Manager), Williams, D. A. G. (Manager), Eccleston, P. E. (Manager) & Greene, D. (Manager)
Facility/equipment: Facility

Cite this

Shterenlikht, A., Margetts, L., McDonald, S. A., & Bourne, N. (2017). Towards mechanism-based simulation of impact damage using exascale computing. In SHOCK COMPRESSION OF CONDENSED MATTER: 2015: Proceedings of the Conference of the American Physical Society Topical Group on Shock Compression of Condensed Matter Article 080009 (AIP Conference Processings; Vol. 1793, No. 1). American Institute of Physics (AIP). https://doi.org/10.1063/1.4971615

Shterenlikht, Anton ; Margetts, Lee ; McDonald, S. A. et al. / Towards mechanism-based simulation of impact damage using exascale computing. SHOCK COMPRESSION OF CONDENSED MATTER: 2015: Proceedings of the Conference of the American Physical Society Topical Group on Shock Compression of Condensed Matter. American Institute of Physics (AIP), 2017. (AIP Conference Processings; 1).

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abstract = "Over the past 60 years, the finite element method has been very successful in modelling deformation in engineering structures. However the method requires the definition of constitutive models that represent the response of the material to applied loads. There are two issues. Firstly, the models are often difficult to define. Secondly, there is often no physical connection between the models and the mechanisms that accommodate deformation. In this paper, we present a potentially disruptive two-level strategy which couples the finite element method at the macroscale with cellular automata at the mesoscale. The cellular automata are used to simulate mechanisms, such as crack propagation. The stress-strain relationship emerges as a continuum mechanics scale interpretation of changes at the micro- and meso-scales. Iterative two-way updating between the cellular automata and finite elements drives the simulation forward as the material undergoes progressive damage at high strain rates. The strategy is particularly attractive on large-scale computing platforms as both methods scale well on tens of thousands of CPUs.",

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Shterenlikht, A, Margetts, L, McDonald, SA & Bourne, N 2017, Towards mechanism-based simulation of impact damage using exascale computing. in SHOCK COMPRESSION OF CONDENSED MATTER: 2015: Proceedings of the Conference of the American Physical Society Topical Group on Shock Compression of Condensed Matter., 080009, AIP Conference Processings, no. 1, vol. 1793, American Institute of Physics (AIP). https://doi.org/10.1063/1.4971615

Towards mechanism-based simulation of impact damage using exascale computing. / Shterenlikht, Anton; Margetts, Lee; McDonald, S. A. et al.
SHOCK COMPRESSION OF CONDENSED MATTER: 2015: Proceedings of the Conference of the American Physical Society Topical Group on Shock Compression of Condensed Matter. American Institute of Physics (AIP), 2017. 080009 (AIP Conference Processings; Vol. 1793, No. 1).

Research output: Chapter in Book/Report/Conference proceeding › Conference Contribution (Conference Proceeding)

TY - GEN

T1 - Towards mechanism-based simulation of impact damage using exascale computing

AU - Shterenlikht, Anton

AU - Margetts, Lee

AU - McDonald, S. A.

AU - Bourne, Neil

PY - 2017/1/13

Y1 - 2017/1/13

N2 - Over the past 60 years, the finite element method has been very successful in modelling deformation in engineering structures. However the method requires the definition of constitutive models that represent the response of the material to applied loads. There are two issues. Firstly, the models are often difficult to define. Secondly, there is often no physical connection between the models and the mechanisms that accommodate deformation. In this paper, we present a potentially disruptive two-level strategy which couples the finite element method at the macroscale with cellular automata at the mesoscale. The cellular automata are used to simulate mechanisms, such as crack propagation. The stress-strain relationship emerges as a continuum mechanics scale interpretation of changes at the micro- and meso-scales. Iterative two-way updating between the cellular automata and finite elements drives the simulation forward as the material undergoes progressive damage at high strain rates. The strategy is particularly attractive on large-scale computing platforms as both methods scale well on tens of thousands of CPUs.

AB - Over the past 60 years, the finite element method has been very successful in modelling deformation in engineering structures. However the method requires the definition of constitutive models that represent the response of the material to applied loads. There are two issues. Firstly, the models are often difficult to define. Secondly, there is often no physical connection between the models and the mechanisms that accommodate deformation. In this paper, we present a potentially disruptive two-level strategy which couples the finite element method at the macroscale with cellular automata at the mesoscale. The cellular automata are used to simulate mechanisms, such as crack propagation. The stress-strain relationship emerges as a continuum mechanics scale interpretation of changes at the micro- and meso-scales. Iterative two-way updating between the cellular automata and finite elements drives the simulation forward as the material undergoes progressive damage at high strain rates. The strategy is particularly attractive on large-scale computing platforms as both methods scale well on tens of thousands of CPUs.

U2 - 10.1063/1.4971615

DO - 10.1063/1.4971615

M3 - Conference Contribution (Conference Proceeding)

SN - 9780735414570

T3 - AIP Conference Processings

BT - SHOCK COMPRESSION OF CONDENSED MATTER

PB - American Institute of Physics (AIP)

ER -

Shterenlikht A, Margetts L, McDonald SA, Bourne N. Towards mechanism-based simulation of impact damage using exascale computing. In SHOCK COMPRESSION OF CONDENSED MATTER: 2015: Proceedings of the Conference of the American Physical Society Topical Group on Shock Compression of Condensed Matter. American Institute of Physics (AIP). 2017. 080009. (AIP Conference Processings; 1). doi: 10.1063/1.4971615

Towards mechanism-based simulation of impact damage using exascale computing

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Projects

An Experimental and Modelling Approach to Engineering the Stability of Mixed Micro- and Nano-Grain Size Polycrystals to Improve Durability

Predicting scatter in the ductile to brittle transitional fracture in steels

Equipment

HPC (High Performance Computing) and HTC (High Throughput Computing) Facilities

Cite this