Numerical modeling of microcrack behavior in encapsulation-based self-healing concrete under uniaxial tension

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Luthfi Muhammad Mauludin
  • Bentang Arief Budiman
  • Sigit Puji Santosa
  • Xiaoying Zhuang
  • Timon Rabczuk

Externe Organisationen

  • Bauhaus-Universität Weimar
  • Politeknik Negeri Bandung
  • Institut Teknologi Bandung (ITB)
  • National Center for Sustainable Transportation Technology (NCSTT)
  • Tongji University
  • Ton Duc Thang University
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Details

OriginalspracheEnglisch
Seiten (von - bis)1847-1853
Seitenumfang7
FachzeitschriftJournal of Mechanical Science and Technology
Jahrgang34
Ausgabenummer5
PublikationsstatusVeröffentlicht - 30 Apr. 2020
Extern publiziertJa

Abstract

We investigated microcrack behavior in encapsulation-based self-healing concrete subjected to uniaxial tension by using finite element analysis. 3D circular capsule with particular shell thickness embedded in the mortar matrix samples was modeled. To represent potential cracks, zero thickness cohesive elements with bi-linear traction-separation law were pre-inserted into the initially generated meshes. Effects of fracture strength variation among the mortar matrix, the capsule, and the interface between them on crack nucleation, initiation, and propagation were investigated. The results showed that the mismatch among fracture strengths of the capsule, the mortar matrix, and the interface of them has a significant influence on crack nucleation, initiation, and propagation. Using similar fracture strength between capsule and mortar matrix, together with high fracture strength of their interface, will initiate a crack from the mortar matrix and then propagate directly into the capsule. This condition is the most favorable case in the capsule-based self-healing concrete since a capsule contained with a healing agent will likely fracture. Thus, the self-healing process in the concrete can be achieved effectively. In addition, the interface with lower fracture strength than the mortar matrix and the capsule strengths will initiate a crack from the interface and then leave the capsule intact. Hence, the self-healing mechanism could not be achieved. These results will become some valuable assets for the experimentalists to assist in their experimental works.

ASJC Scopus Sachgebiete

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Numerical modeling of microcrack behavior in encapsulation-based self-healing concrete under uniaxial tension. / Mauludin, Luthfi Muhammad; Budiman, Bentang Arief; Santosa, Sigit Puji et al.
in: Journal of Mechanical Science and Technology, Jahrgang 34, Nr. 5, 30.04.2020, S. 1847-1853.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Mauludin LM, Budiman BA, Santosa SP, Zhuang X, Rabczuk T. Numerical modeling of microcrack behavior in encapsulation-based self-healing concrete under uniaxial tension. Journal of Mechanical Science and Technology. 2020 Apr 30;34(5):1847-1853. doi: 10.1007/s12206-020-0405-z
Mauludin, Luthfi Muhammad ; Budiman, Bentang Arief ; Santosa, Sigit Puji et al. / Numerical modeling of microcrack behavior in encapsulation-based self-healing concrete under uniaxial tension. in: Journal of Mechanical Science and Technology. 2020 ; Jahrgang 34, Nr. 5. S. 1847-1853.
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title = "Numerical modeling of microcrack behavior in encapsulation-based self-healing concrete under uniaxial tension",
abstract = "We investigated microcrack behavior in encapsulation-based self-healing concrete subjected to uniaxial tension by using finite element analysis. 3D circular capsule with particular shell thickness embedded in the mortar matrix samples was modeled. To represent potential cracks, zero thickness cohesive elements with bi-linear traction-separation law were pre-inserted into the initially generated meshes. Effects of fracture strength variation among the mortar matrix, the capsule, and the interface between them on crack nucleation, initiation, and propagation were investigated. The results showed that the mismatch among fracture strengths of the capsule, the mortar matrix, and the interface of them has a significant influence on crack nucleation, initiation, and propagation. Using similar fracture strength between capsule and mortar matrix, together with high fracture strength of their interface, will initiate a crack from the mortar matrix and then propagate directly into the capsule. This condition is the most favorable case in the capsule-based self-healing concrete since a capsule contained with a healing agent will likely fracture. Thus, the self-healing process in the concrete can be achieved effectively. In addition, the interface with lower fracture strength than the mortar matrix and the capsule strengths will initiate a crack from the interface and then leave the capsule intact. Hence, the self-healing mechanism could not be achieved. These results will become some valuable assets for the experimentalists to assist in their experimental works.",
keywords = "3D circular capsule, Cohesive elements, Crack initiation, Finite element, Fracture strength",
author = "Mauludin, {Luthfi Muhammad} and Budiman, {Bentang Arief} and Santosa, {Sigit Puji} and Xiaoying Zhuang and Timon Rabczuk",
note = "Funding information: This work is supported and financed by RISTEKDIKTI (Directorate General of Resources for Science, Technology and Higher Education, Ministry of Research, Technology and Higher Education of Indonesia) under funding agreement No. 153.39/E4.4/2014, and International Promovieren in Deutschland-for all (IPID4all) Frung von Forschungs- und Praxisaufenthalten im Ausland - Bauhaus Research School, Bau-haus University of Weimar, Germany. This work is also partially funded by USAID through Sustainable Higher Education Research Alliance (SHERA) program with grant number IIE00000078-ITB-1. The supports are gratefully acknowledged.",
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Download

TY - JOUR

T1 - Numerical modeling of microcrack behavior in encapsulation-based self-healing concrete under uniaxial tension

AU - Mauludin, Luthfi Muhammad

AU - Budiman, Bentang Arief

AU - Santosa, Sigit Puji

AU - Zhuang, Xiaoying

AU - Rabczuk, Timon

N1 - Funding information: This work is supported and financed by RISTEKDIKTI (Directorate General of Resources for Science, Technology and Higher Education, Ministry of Research, Technology and Higher Education of Indonesia) under funding agreement No. 153.39/E4.4/2014, and International Promovieren in Deutschland-for all (IPID4all) Frung von Forschungs- und Praxisaufenthalten im Ausland - Bauhaus Research School, Bau-haus University of Weimar, Germany. This work is also partially funded by USAID through Sustainable Higher Education Research Alliance (SHERA) program with grant number IIE00000078-ITB-1. The supports are gratefully acknowledged.

PY - 2020/4/30

Y1 - 2020/4/30

N2 - We investigated microcrack behavior in encapsulation-based self-healing concrete subjected to uniaxial tension by using finite element analysis. 3D circular capsule with particular shell thickness embedded in the mortar matrix samples was modeled. To represent potential cracks, zero thickness cohesive elements with bi-linear traction-separation law were pre-inserted into the initially generated meshes. Effects of fracture strength variation among the mortar matrix, the capsule, and the interface between them on crack nucleation, initiation, and propagation were investigated. The results showed that the mismatch among fracture strengths of the capsule, the mortar matrix, and the interface of them has a significant influence on crack nucleation, initiation, and propagation. Using similar fracture strength between capsule and mortar matrix, together with high fracture strength of their interface, will initiate a crack from the mortar matrix and then propagate directly into the capsule. This condition is the most favorable case in the capsule-based self-healing concrete since a capsule contained with a healing agent will likely fracture. Thus, the self-healing process in the concrete can be achieved effectively. In addition, the interface with lower fracture strength than the mortar matrix and the capsule strengths will initiate a crack from the interface and then leave the capsule intact. Hence, the self-healing mechanism could not be achieved. These results will become some valuable assets for the experimentalists to assist in their experimental works.

AB - We investigated microcrack behavior in encapsulation-based self-healing concrete subjected to uniaxial tension by using finite element analysis. 3D circular capsule with particular shell thickness embedded in the mortar matrix samples was modeled. To represent potential cracks, zero thickness cohesive elements with bi-linear traction-separation law were pre-inserted into the initially generated meshes. Effects of fracture strength variation among the mortar matrix, the capsule, and the interface between them on crack nucleation, initiation, and propagation were investigated. The results showed that the mismatch among fracture strengths of the capsule, the mortar matrix, and the interface of them has a significant influence on crack nucleation, initiation, and propagation. Using similar fracture strength between capsule and mortar matrix, together with high fracture strength of their interface, will initiate a crack from the mortar matrix and then propagate directly into the capsule. This condition is the most favorable case in the capsule-based self-healing concrete since a capsule contained with a healing agent will likely fracture. Thus, the self-healing process in the concrete can be achieved effectively. In addition, the interface with lower fracture strength than the mortar matrix and the capsule strengths will initiate a crack from the interface and then leave the capsule intact. Hence, the self-healing mechanism could not be achieved. These results will become some valuable assets for the experimentalists to assist in their experimental works.

KW - 3D circular capsule

KW - Cohesive elements

KW - Crack initiation

KW - Finite element

KW - Fracture strength

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M3 - Article

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VL - 34

SP - 1847

EP - 1853

JO - Journal of Mechanical Science and Technology

JF - Journal of Mechanical Science and Technology

SN - 1738-494X

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