Modeling of dynamic fracture problems using AL finite element formulation

The problem of dynamic crack propagation is widely addressed in the literature. The few available analytical solutions are limited to simple and idealized geometries and loading conditions. On the other hand, major approximations and inconsistent assumptions exist in published numerical models....

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Main Author: Abdelgalil, Abdelgader I.
Language:English
Published: 2009
Online Access:http://hdl.handle.net/2429/13320
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spelling ndltd-LACETR-oai-collectionscanada.gc.ca-BVAU.2429-133202014-03-14T15:46:53Z Modeling of dynamic fracture problems using AL finite element formulation Abdelgalil, Abdelgader I. The problem of dynamic crack propagation is widely addressed in the literature. The few available analytical solutions are limited to simple and idealized geometries and loading conditions. On the other hand, major approximations and inconsistent assumptions exist in published numerical models. In this thesis, the problem of dynamic crack propagation is modeled using a fully coupled Arbitrary Lagrangian Eulerian (ALE) formulation. The ALE equilibrium equations are derived, discretized using isoparametric finite elements and implemented into an ALE dynamic fracture program (ALEFR), based on an implicit solution scheme. The advantage of the ALE formulation is that the computational grid (finite element mesh) may have an arbitrary motion with respect to the domain of the deformed body. Therefore, the complex nature of the developed boundary condition due to a propagating crack may now be modeled in a continuous and accurate manner. The process of creating new surfaces due to crack propagation is modeled by splitting material points. This allows for a more realistic representation of the actual physical process. The ALE boundary constraint is enforced on the free boundaries, including the continuously changing free crack surfaces, using a newly developed technique. The dynamic energy release rate is evaluated through the integration of material properties of Lagrangian grid material points. The developed formulations and techniques are then discretized and implemented into a finite element code. The developed code is tested by modeling dynamic stationary and propagating fracture problems. 2009-09-29T20:15:47Z 2009-09-29T20:15:47Z 2002 2009-09-29T20:15:47Z 2002-11 Electronic Thesis or Dissertation http://hdl.handle.net/2429/13320 eng UBC Retrospective Theses Digitization Project [http://www.library.ubc.ca/archives/retro_theses/]
collection NDLTD
language English
sources NDLTD
description The problem of dynamic crack propagation is widely addressed in the literature. The few available analytical solutions are limited to simple and idealized geometries and loading conditions. On the other hand, major approximations and inconsistent assumptions exist in published numerical models. In this thesis, the problem of dynamic crack propagation is modeled using a fully coupled Arbitrary Lagrangian Eulerian (ALE) formulation. The ALE equilibrium equations are derived, discretized using isoparametric finite elements and implemented into an ALE dynamic fracture program (ALEFR), based on an implicit solution scheme. The advantage of the ALE formulation is that the computational grid (finite element mesh) may have an arbitrary motion with respect to the domain of the deformed body. Therefore, the complex nature of the developed boundary condition due to a propagating crack may now be modeled in a continuous and accurate manner. The process of creating new surfaces due to crack propagation is modeled by splitting material points. This allows for a more realistic representation of the actual physical process. The ALE boundary constraint is enforced on the free boundaries, including the continuously changing free crack surfaces, using a newly developed technique. The dynamic energy release rate is evaluated through the integration of material properties of Lagrangian grid material points. The developed formulations and techniques are then discretized and implemented into a finite element code. The developed code is tested by modeling dynamic stationary and propagating fracture problems.
author Abdelgalil, Abdelgader I.
spellingShingle Abdelgalil, Abdelgader I.
Modeling of dynamic fracture problems using AL finite element formulation
author_facet Abdelgalil, Abdelgader I.
author_sort Abdelgalil, Abdelgader I.
title Modeling of dynamic fracture problems using AL finite element formulation
title_short Modeling of dynamic fracture problems using AL finite element formulation
title_full Modeling of dynamic fracture problems using AL finite element formulation
title_fullStr Modeling of dynamic fracture problems using AL finite element formulation
title_full_unstemmed Modeling of dynamic fracture problems using AL finite element formulation
title_sort modeling of dynamic fracture problems using al finite element formulation
publishDate 2009
url http://hdl.handle.net/2429/13320
work_keys_str_mv AT abdelgalilabdelgaderi modelingofdynamicfractureproblemsusingalfiniteelementformulation
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