3D analysis of fracture processes in concrete

G Lilliu

3D analysis of fracture processes in concrete

G Lilliu

Materials and Environment

Research output: Thesis › Dissertation (TU Delft)

71 Downloads (Pure)

Abstract

Concrete fracture is governed by randomly distributed aggregate particles, which make cracks fundamentally not planar. This phenomenon can be captured only by 3D models. Within the 3D framework, material heterogeneity and displacement dis continuity must be incorporated Lattice models allow to consider all these aspects adequately. In this thesis a lattice model is used to analyze the influence of the material structure on the global & structural response and to compare results from 2D and 3D modelling Concrete is schematized as a network of beams with different mechanical properties corresponding to three phases: aggregate, hi matrix, and interfacial transition zone Fracture is mimicked by sequential removal of elements where the stress exceeds the tensile strength Though a purely brittle linear elastic behaviour is assumed for each element, structural softening is modelled successfully.

Original language	English
Qualification	Doctor of Philosophy
Awarding Institution	Delft University of Technology
Supervisors/Advisors	van Mier, JGM, Supervisor
Award date	8 May 2007
Print ISBNs	9789059721845
Publication status	Published - 2007

Keywords

Diss. prom. aan TU Delft

Access to Document

3D Analysis of Fracture Processes in ConcreteFinal published version, 7.73 MB

Cite this

@phdthesis{99bf0095d5924ad19fa97752938cb29d,

title = "3D analysis of fracture processes in concrete",

abstract = "Concrete fracture is governed by randomly distributed aggregate particles, which make cracks fundamentally not planar. This phenomenon can be captured only by 3D models. Within the 3D framework, material heterogeneity and displacement dis continuity must be incorporated Lattice models allow to consider all these aspects adequately. In this thesis a lattice model is used to analyze the influence of the material structure on the global & structural response and to compare results from 2D and 3D modelling Concrete is schematized as a network of beams with different mechanical properties corresponding to three phases: aggregate, hi matrix, and interfacial transition zone Fracture is mimicked by sequential removal of elements where the stress exceeds the tensile strength Though a purely brittle linear elastic behaviour is assumed for each element, structural softening is modelled successfully.",

keywords = "Diss. prom. aan TU Delft",

author = "G Lilliu",

year = "2007",

language = "English",

isbn = "9789059721845",

type = "Dissertation (TU Delft)",

school = "Delft University of Technology",

}

TY - THES

T1 - 3D analysis of fracture processes in concrete

AU - Lilliu, G

PY - 2007

Y1 - 2007

N2 - Concrete fracture is governed by randomly distributed aggregate particles, which make cracks fundamentally not planar. This phenomenon can be captured only by 3D models. Within the 3D framework, material heterogeneity and displacement dis continuity must be incorporated Lattice models allow to consider all these aspects adequately. In this thesis a lattice model is used to analyze the influence of the material structure on the global & structural response and to compare results from 2D and 3D modelling Concrete is schematized as a network of beams with different mechanical properties corresponding to three phases: aggregate, hi matrix, and interfacial transition zone Fracture is mimicked by sequential removal of elements where the stress exceeds the tensile strength Though a purely brittle linear elastic behaviour is assumed for each element, structural softening is modelled successfully.

AB - Concrete fracture is governed by randomly distributed aggregate particles, which make cracks fundamentally not planar. This phenomenon can be captured only by 3D models. Within the 3D framework, material heterogeneity and displacement dis continuity must be incorporated Lattice models allow to consider all these aspects adequately. In this thesis a lattice model is used to analyze the influence of the material structure on the global & structural response and to compare results from 2D and 3D modelling Concrete is schematized as a network of beams with different mechanical properties corresponding to three phases: aggregate, hi matrix, and interfacial transition zone Fracture is mimicked by sequential removal of elements where the stress exceeds the tensile strength Though a purely brittle linear elastic behaviour is assumed for each element, structural softening is modelled successfully.

KW - Diss. prom. aan TU Delft

M3 - Dissertation (TU Delft)

SN - 9789059721845

ER -

3D analysis of fracture processes in concrete

Abstract

Keywords

Access to Document

Fingerprint

Cite this