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Auteurs principaux: Bennett, Kane C., Stahl, Alyson M., Canfield, Thomas R., Euler, Garrett G.
Format: Preprint
Publié: 2023
Sujets:
Accès en ligne:https://arxiv.org/abs/2312.12577
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author Bennett, Kane C.
Stahl, Alyson M.
Canfield, Thomas R.
Euler, Garrett G.
author_facet Bennett, Kane C.
Stahl, Alyson M.
Canfield, Thomas R.
Euler, Garrett G.
contents An integrated Equation of State (EOS) and strength/pore-crush/damage model framework is provided for modeling near to source (near-field) ground-shock response, where large deformations and pressures necessitate coupling EOS with pressure-dependent plastic yield and damage. Nonlinear pressure-dependence of strength up to high-pressures is combined with a Modified Cam-Clay-like cap-plasticity model in a way to allow degradation of strength from pore-crush damage, what we call the "Yp-Cap" model. Nonlinear hardening under compaction allows modeling the crush-out of pores in combination with a fully saturated EOS, i.e., for modeling partially saturated ground-shock response, where air-filled voids crush. Attention is given to algorithmic clarity and efficiency of the provided model, and the model is employed in example numerical simulations, including finite element simulations of underground explosions to exemplify its robustness and utility.
format Preprint
id arxiv_https___arxiv_org_abs_2312_12577
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle An integrated EOS, pore-crush, strength and damage model framework for near-field ground-shock
Bennett, Kane C.
Stahl, Alyson M.
Canfield, Thomas R.
Euler, Garrett G.
Computational Engineering, Finance, and Science
An integrated Equation of State (EOS) and strength/pore-crush/damage model framework is provided for modeling near to source (near-field) ground-shock response, where large deformations and pressures necessitate coupling EOS with pressure-dependent plastic yield and damage. Nonlinear pressure-dependence of strength up to high-pressures is combined with a Modified Cam-Clay-like cap-plasticity model in a way to allow degradation of strength from pore-crush damage, what we call the "Yp-Cap" model. Nonlinear hardening under compaction allows modeling the crush-out of pores in combination with a fully saturated EOS, i.e., for modeling partially saturated ground-shock response, where air-filled voids crush. Attention is given to algorithmic clarity and efficiency of the provided model, and the model is employed in example numerical simulations, including finite element simulations of underground explosions to exemplify its robustness and utility.
title An integrated EOS, pore-crush, strength and damage model framework for near-field ground-shock
topic Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2312.12577