Macro- and micro-modeling of crack propagation in encapsulation-based self-healing materials: Application of XFEM and cohesive surface techniques

Gilabert, F.A.; Garoz, D.; Paepegem, Wim Van

doi:10.1016/j.matdes.2017.05.050

Cited by 59 publications

(62 citation statements)

References 66 publications

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“…Gilabert et al developed a finite element model that used a combination of extended finite element method (XFEM) and the cohesive surfaces (CS) technique to simulate the mechanical behavior of self‐healing material systems with encapsulated healing agents. Two scenarios were explored: one was a microscale model that comprised a microcapsule embedded in a cementitious matrix and the other was a macroscale model that considered the effect of adding tubular glass capsules on the overall bending response of a cementitious beam.…”

Section: The Simulation Of Mechanical Self‐healingmentioning

confidence: 99%

Research Progress on Numerical Models for Self‐Healing Cementitious Materials

Jefferson

Javierre

Freeman

et al. 2018

Adv Materials Inter

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In this paper, research progress on numerical models for self‐healing cementitious materials (SHCMs) is discussed. Models developed specifically for SHCMs, as well as other relevant work, are considered. A summary of current self‐healing (SH) techniques is provided along with descriptions of the processes that govern their behavior. Models for mechanical self‐healing, transport processes in materials with embedded healing systems, fully coupled models, and other modeling techniques used to simulate SH behavior are discussed. The mechanics models discussed include those based on continuum–damage–healing mechanics (CDHM), micromechanics, as well as models that use discrete elements and particle methods. A considerable section is devoted to the simulation of carbonation in concrete since the essential mechanisms that govern this process are applicable to SH systems that employ calcite as a healing material. A number of transport models for simulating early‐age self‐healing are also considered. This highlights the fact that there are currently very few papers that describe fully coupled models, although a number of approaches that couple some aspects of transport and mechanical healing behavior are discussed. This article closes with a discussion that highlights the fact that many models are presented with limited or no experimental validation.

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Section: The Simulation Of Mechanical Self‐healingmentioning

confidence: 99%

Research Progress on Numerical Models for Self‐Healing Cementitious Materials

Jefferson

Javierre

Freeman

et al. 2018

Adv Materials Inter

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“…Gilabert et al combined eXtended Finite Element Method (XFEM) elements and cohesive surface (CS) techniqus to predict crack propagation and brekage of the capsules. They simulated the response of a beam with encapsulated systems in a three‐point bending test, concluding that when using capsules with t/R less than 0.12, a minimum interface strength of 2.0 MPa has to be ensured to break the capsuels and liberate the healing agent.…”

Section: Encapsulation‐based Self‐healing Concretementioning

confidence: 99%

A review study on encapsulation‐based self‐healing for cementitious materials

Xue

et al. 2018

Structural Concrete

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Inspired by the self-repair polymeric materials, most of healing agents in encapsulation-based self-healing concrete are FIGURE 1 Self-healing schematic concept for cementitious materials 10 : (a) crack forming; (b) healing agent releasing; (c) polymerization with catalysts FIGURE 2 Configuration of encapsulation-based self-healing concrete 61 : (a) crack breaking capsule; (b) healing agent filling; (c) healing agent curing XUE ET AL.

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“…() For instance, efforts are taken to estimate the effective elastic properties of self‐healing particulate composites, whereby the effect of dispersed healing particles on the elastic moduli of the host matrix material is quantified. () Crack propagation studies were conducted in an idealised healing capsule(s)‐matrix system, and the effects of geometric and material parameters were analysed using cohesive zone model and extended finite element method (XFEM) . In particular, a self‐healing concrete in a three‐point bending test set‐up was utilised to evaluate the influence of parameters such as number, size, and position of capsules on the mechanical behaviour of the concrete.…”

Section: Introductionmentioning

confidence: 99%

“…In the context of self-healing particulate composite systems, a limited number of modelling studies have been conducted in terms of quantifying the effective mechanical properties and crack path predictions. [28][29][30][31][32][33] For instance, efforts are taken to estimate the effective elastic properties of self-healing particulate composites, whereby the effect of dispersed healing particles on the elastic moduli of the host matrix material is quantified. 30,31 Crack propagation studies were conducted in an idealised healing capsule(s)-matrix system, and the effects of geometric and material parameters were analysed using cohesive zone model and extended finite element method (XFEM).…”

Section: Introductionmentioning

confidence: 99%

“…30,31 Crack propagation studies were conducted in an idealised healing capsule(s)-matrix system, and the effects of geometric and material parameters were analysed using cohesive zone model and extended finite element method (XFEM). 28 In particular, a self-healing concrete in a three-point bending test set-up was utilised to evaluate the influence of parameters such as number, size, and position of capsules on the mechanical behaviour of the concrete. This was then followed by modelling an idealised single healing capsule-matrix volume element, whereby the influence of interface properties and capsule volume fraction on the effective strength was reported.…”

Section: Introductionmentioning

confidence: 99%

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A micromechanical fracture analysis to investigate the effect of healing particles on the overall mechanical response of a self‐healing particulate composite

Ponnusami

Krishnasamy

Turteltaub

et al. 2018

Fatigue Fract Eng Mat Struct

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A computational fracture analysis is conducted on a self‐healing particulate composite employing a finite element model of an actual microstructure. The key objective is to quantify the effects of the actual morphology and the fracture properties of the healing particles on the overall mechanical behaviour of the (MoSi2) particle‐dispersed Yttria Stabilised Zirconia (YSZ) composite. To simulate fracture, a cohesive zone approach is utilised whereby cohesive elements are embedded throughout the finite element mesh allowing for arbitrary crack initiation and propagation in the microstructure. The fracture behaviour in terms of the composite strength and the percentage of fractured particles is reported as a function of the mismatch in fracture properties between the healing particles and the matrix as well as a function of particle/matrix interface strength and fracture energy. The study can be used as a guiding tool for designing an extrinsic self‐healing material and understanding the effect of the healing particles on the overall mechanical properties of the material.

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Macro- and micro-modeling of crack propagation in encapsulation-based self-healing materials: Application of XFEM and cohesive surface techniques

Cited by 59 publications

References 66 publications

Research Progress on Numerical Models for Self‐Healing Cementitious Materials

Research Progress on Numerical Models for Self‐Healing Cementitious Materials

A review study on encapsulation‐based self‐healing for cementitious materials

A micromechanical fracture analysis to investigate the effect of healing particles on the overall mechanical response of a self‐healing particulate composite

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