A dynamic implicit 3D material point-to-rigid body contact approach for large deformation analysis

Robert E. Bird; Giuliano Pretti; William M. Coombs; Charles Augarde; Michael Brown; Yaseen Sharif; Gareth Carter; Catriona Macdonald; Kirstin Johnson

doi:10.1002/nme.70080

A dynamic implicit 3D material point-to-rigid body contact approach for large deformation analysis

Robert E. Bird
, Giuliano Pretti
, William M. Coombs (Lead / Corresponding author)
, Charles Augarde
, Michael Brown
, Yaseen Sharif
, Gareth Carter
, Catriona Macdonald
, Kirstin Johnson

Civil Engineering

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

1 Citation (Scopus)

78 Downloads (Pure)

Abstract

Accurate and robust modeling of large deformation three-dimensional contact interaction is an important area of engineering, but it is also challenging from a computational mechanics perspective. This is particularly the case when there is significant interpenetration and evolution of the contact surfaces, such as the case of a relatively rigid body interacting with a highly deformable body. This paper provides a new three-dimensional large deformation contact approach where the Material Point Method (MPM) is used to represent the deformable material. A new contact detection approach is introduced that checks the interaction of the vertices of the domains associated with each material point with the discretized rigid body. This provides a general and consistent approach without requiring the reconstruction of an additional boundary representation of the deformable body. A new energy-consistent material point domain updating approach is also introduced that maintains stable simulations under large deformations. The dynamic governing equations allow the trajectory of the rigid body to evolve based on the interaction with the deformable body, and the governing equations are solved within an efficient implicit framework. The performance of the new contact approach is demonstrated on a number of benchmark problems with analytical solutions. The method is also applied to the specific case of soil-structure interaction, using geotechnical centrifuge experimental data that confirms the veracity of the proposed approach.

Original language	English
Article number	e70080
Number of pages	20
Journal	International Journal for Numerical Methods in Engineering
Volume	126
Issue number	14
DOIs	https://doi.org/10.1002/nme.70080
Publication status	Published - 24 Jul 2025

UN SDGs

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

SDG 7 Affordable and Clean Energy
SDG 9 Industry, Innovation, and Infrastructure

Keywords

material point method
Contact mechanics
implicit dynamics
soil-structure interaction
large deformation mechanics
contact mechanics

ASJC Scopus subject areas

Computational Mechanics
Geotechnical Engineering and Engineering Geology
Numerical Analysis
General Engineering
Applied Mathematics

Access to Document

10.1002/nme.70080Licence: CC BY

Final Published VersionFinal published version, 10.8 MBLicence: CC BY

Offshore Cable Burial: How deep is deep enough? (Joint with Durham University and British Geological Survey)
Brown, M. (Investigator)
1/02/22 → 31/03/26
Project: Research
Seabed Ploughing: Modelling for Infrastructure Installation (Joint with Durham University)
Brennan, A. (Investigator) & Brown, M. (Investigator)
1/10/14 → 31/12/17
Project: Research

1 Citations
8 Conference contribution
8 Article
4 Paper

Centrifuge modelling of drag embedment anchors subjected to inclined loading for floating wind
Sharif, Y., Davidson, C., Brown, M., Brennan, A., Coombs, W. M., Bird, R. E., Augarde, C., Carter, G., Macdonald, C. & Johnson, K. R., 9 Jun 2025, Proceedings of the 5TH INTERNATIONAL SYMPOSIUM ON FRONTIERS IN OFFSHORE GEOTECHNICS. Abadie, C. N., Li, Z., Blanc, M. & Thorel, L. (eds.). International Society for Soil Mechanics and Geotechnical Engineering, 7 p.
Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Open Access
File
66 Downloads (Pure)
Regional analysis of layered soils in the shallow subsurface across the North Sea for offshore cable burial
Macdonald, C., Stevens, D., Arnhardt, R., Carter, G., Johnson, K., Coombs, W. M., Bird, R. E., Augarde, C., Sharif, Y. & Brown, M., 9 Jun 2025, Proceedings of the 5TH INTERNATIONAL SYMPOSIUM ON FRONTIERS IN OFFSHORE GEOTECHNICS. Abadie, C. N., Li, Z., Blanc, M. & Thorel, L. (eds.). International Society for Soil Mechanics and Geotechnical Engineering, p. 808-813 7 p.
Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Open Access
File
40 Downloads (Pure)
An implicit material point-to-rigid body contact approach for large deformation soil-structure interaction
Bird, R. E., Pretti, G., Coombs, W. M., Augarde, C., Sharif, Y., Brown, M., Carter, G., Macdonald, C. & Johnson, K., Oct 2024, In: Computers and Geotechnics. 174, 16 p., 106646.
Research output: Contribution to journal › Article › peer-review

Open Access
File
8 Link opens in a new tab Citations (Scopus)

216 Downloads (Pure)

Invited presentation: NEXANS Lunch & Learn, Cable Protection Teams European Subsea Cables Association, Cable Burial Risk Assessment (CBRA) Modelling.
Brown, M. (Speaker) & Coombs, W. M. (Speaker)
27 Jan 2026
Activity: Talk or presentation types › Invited talk
Keynote Lecture: 2nd Offshore Wind Symposium: Cables, pipelines and shallow infrastructure installation, Geological Society Energy Group: Physical and numerical modelling of drag anchor penetration: assessing seabed penetration factors to inform depth of lowering of subsea cables
Coombs, W. M. (Speaker) & Brown, M. (Speaker)
19 Sept 2025
Activity: Talk or presentation types › Keynote
Invited presentation: Society of Underwater Technology (SUT) Offshore Site Investigation Group (OSIG), Northeast OSIG Geoforum, Newcastle, Centrifuge modelling of drag embedment anchors subjected to inclined loading for floating wind
Brown, M. (Speaker)
16 Oct 2025
Activity: Talk or presentation types › Invited talk

A CPT approach to cable plough performance prediction based upon centrifuge model testing - Measured Data
Robinson, S. (Creator), Brown, M. (Creator), Matsui, H. (Creator), Brennan, A. (Creator), Augarde, C. (Creator), Coombs, W. M. (Creator) & Cortis, M. (Creator), University of Dundee, 30 Nov 2020
DOI: 10.15132/10000161
Dataset

File
On Lagrangian mechanics and the material point method for large deformation elasto-plasticity [dataset]
Coombs, W. M. (Creator), Augarde, C. E. (Creator), Brennan, A. J. (Creator), Brown, M. (Creator), Charlton, T. J. (Creator), Knappett, J. A. (Creator), Ghaffari Motlagh, Y. (Creator) & Wang, L. (Creator), Durham University, 11 Jul 2019
DOI: 10.15128/r2pk02c977f, http://collections.durham.ac.uk/files/r2pk02c977f
Dataset

Cite this

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title = "A dynamic implicit 3D material point-to-rigid body contact approach for large deformation analysis",

abstract = "Accurate and robust modeling of large deformation three-dimensional contact interaction is an important area of engineering, but it is also challenging from a computational mechanics perspective. This is particularly the case when there is significant interpenetration and evolution of the contact surfaces, such as the case of a relatively rigid body interacting with a highly deformable body. This paper provides a new three-dimensional large deformation contact approach where the Material Point Method (MPM) is used to represent the deformable material. A new contact detection approach is introduced that checks the interaction of the vertices of the domains associated with each material point with the discretized rigid body. This provides a general and consistent approach without requiring the reconstruction of an additional boundary representation of the deformable body. A new energy-consistent material point domain updating approach is also introduced that maintains stable simulations under large deformations. The dynamic governing equations allow the trajectory of the rigid body to evolve based on the interaction with the deformable body, and the governing equations are solved within an efficient implicit framework. The performance of the new contact approach is demonstrated on a number of benchmark problems with analytical solutions. The method is also applied to the specific case of soil-structure interaction, using geotechnical centrifuge experimental data that confirms the veracity of the proposed approach.",

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AU - Pretti, Giuliano

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AU - Augarde, Charles

AU - Brown, Michael

AU - Sharif, Yaseen

AU - Carter, Gareth

AU - Macdonald, Catriona

AU - Johnson, Kirstin

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N2 - Accurate and robust modeling of large deformation three-dimensional contact interaction is an important area of engineering, but it is also challenging from a computational mechanics perspective. This is particularly the case when there is significant interpenetration and evolution of the contact surfaces, such as the case of a relatively rigid body interacting with a highly deformable body. This paper provides a new three-dimensional large deformation contact approach where the Material Point Method (MPM) is used to represent the deformable material. A new contact detection approach is introduced that checks the interaction of the vertices of the domains associated with each material point with the discretized rigid body. This provides a general and consistent approach without requiring the reconstruction of an additional boundary representation of the deformable body. A new energy-consistent material point domain updating approach is also introduced that maintains stable simulations under large deformations. The dynamic governing equations allow the trajectory of the rigid body to evolve based on the interaction with the deformable body, and the governing equations are solved within an efficient implicit framework. The performance of the new contact approach is demonstrated on a number of benchmark problems with analytical solutions. The method is also applied to the specific case of soil-structure interaction, using geotechnical centrifuge experimental data that confirms the veracity of the proposed approach.

AB - Accurate and robust modeling of large deformation three-dimensional contact interaction is an important area of engineering, but it is also challenging from a computational mechanics perspective. This is particularly the case when there is significant interpenetration and evolution of the contact surfaces, such as the case of a relatively rigid body interacting with a highly deformable body. This paper provides a new three-dimensional large deformation contact approach where the Material Point Method (MPM) is used to represent the deformable material. A new contact detection approach is introduced that checks the interaction of the vertices of the domains associated with each material point with the discretized rigid body. This provides a general and consistent approach without requiring the reconstruction of an additional boundary representation of the deformable body. A new energy-consistent material point domain updating approach is also introduced that maintains stable simulations under large deformations. The dynamic governing equations allow the trajectory of the rigid body to evolve based on the interaction with the deformable body, and the governing equations are solved within an efficient implicit framework. The performance of the new contact approach is demonstrated on a number of benchmark problems with analytical solutions. The method is also applied to the specific case of soil-structure interaction, using geotechnical centrifuge experimental data that confirms the veracity of the proposed approach.

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A dynamic implicit 3D material point-to-rigid body contact approach for large deformation analysis

Abstract

UN SDGs

Keywords

ASJC Scopus subject areas

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