Adaptive Crack Modeling with Interface Solid Elements for Plain and Fiber Reinforced Concrete Structures

Adaptive Crack Modeling with Interface Solid Elements for Plain and Fiber Reinforced Concrete Structures

The effective analysis of the nonlinear behavior of cement-based engineering structures not only demands physically-reliable models, but also computationally-efficient algorithms. Based on a continuum interface element formulation that is suitable to capture complex cracking phenomena in concrete ma...

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Main Authors: Yijian Zhan, Günther Meschke
Format: Article
Language:English
Published: MDPI AG 2017-07-01
Series:Materials
Subjects:
fiber-reinforced concrete
crack model
interface solid element
finite element method
mesh adaptation
computational efficiency
Online Access:https://www.mdpi.com/1996-1944/10/7/771
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spelling doaj-fee01ad12686416b828d3f113f4b5b002020-11-24T23:23:52ZengMDPI AGMaterials1996-19442017-07-0110777110.3390/ma10070771ma10070771Adaptive Crack Modeling with Interface Solid Elements for Plain and Fiber Reinforced Concrete StructuresYijian Zhan0Günther Meschke1Institute for Structural Mechanics, Ruhr University Bochum, Universitätsstraße 150, 44801 Bochum, GermanyInstitute for Structural Mechanics, Ruhr University Bochum, Universitätsstraße 150, 44801 Bochum, GermanyThe effective analysis of the nonlinear behavior of cement-based engineering structures not only demands physically-reliable models, but also computationally-efficient algorithms. Based on a continuum interface element formulation that is suitable to capture complex cracking phenomena in concrete materials and structures, an adaptive mesh processing technique is proposed for computational simulations of plain and fiber-reinforced concrete structures to progressively disintegrate the initial finite element mesh and to add degenerated solid elements into the interfacial gaps. In comparison with the implementation where the entire mesh is processed prior to the computation, the proposed adaptive cracking model allows simulating the failure behavior of plain and fiber-reinforced concrete structures with remarkably reduced computational expense.https://www.mdpi.com/1996-1944/10/7/771fiber-reinforced concretecrack modelinterface solid elementfinite element methodmesh adaptationcomputational efficiency
collection DOAJ
language English
format Article
sources DOAJ
author Yijian Zhan
Günther Meschke
spellingShingle Yijian Zhan
Günther Meschke
Adaptive Crack Modeling with Interface Solid Elements for Plain and Fiber Reinforced Concrete Structures
Materials
fiber-reinforced concrete
crack model
interface solid element
finite element method
mesh adaptation
computational efficiency
author_facet Yijian Zhan
Günther Meschke
author_sort Yijian Zhan
title Adaptive Crack Modeling with Interface Solid Elements for Plain and Fiber Reinforced Concrete Structures
title_short Adaptive Crack Modeling with Interface Solid Elements for Plain and Fiber Reinforced Concrete Structures
title_full Adaptive Crack Modeling with Interface Solid Elements for Plain and Fiber Reinforced Concrete Structures
title_fullStr Adaptive Crack Modeling with Interface Solid Elements for Plain and Fiber Reinforced Concrete Structures
title_full_unstemmed Adaptive Crack Modeling with Interface Solid Elements for Plain and Fiber Reinforced Concrete Structures
title_sort adaptive crack modeling with interface solid elements for plain and fiber reinforced concrete structures
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2017-07-01
description The effective analysis of the nonlinear behavior of cement-based engineering structures not only demands physically-reliable models, but also computationally-efficient algorithms. Based on a continuum interface element formulation that is suitable to capture complex cracking phenomena in concrete materials and structures, an adaptive mesh processing technique is proposed for computational simulations of plain and fiber-reinforced concrete structures to progressively disintegrate the initial finite element mesh and to add degenerated solid elements into the interfacial gaps. In comparison with the implementation where the entire mesh is processed prior to the computation, the proposed adaptive cracking model allows simulating the failure behavior of plain and fiber-reinforced concrete structures with remarkably reduced computational expense.
topic fiber-reinforced concrete
crack model
interface solid element
finite element method
mesh adaptation
computational efficiency
url https://www.mdpi.com/1996-1944/10/7/771
work_keys_str_mv AT yijianzhan adaptivecrackmodelingwithinterfacesolidelementsforplainandfiberreinforcedconcretestructures
AT gunthermeschke adaptivecrackmodelingwithinterfacesolidelementsforplainandfiberreinforcedconcretestructures
_version_ 1725563170777464832

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