Computational Homogenization in Masonry Structures

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • G. A. Drosopoulos
  • M. E. Stavroulaki
  • K. Giannis
  • L. Plymakis
  • G. E. Stavroulakis
  • P. Wriggers

Organisationseinheiten

Externe Organisationen

  • Technical University of Crete
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
FachzeitschriftCivil-Comp Proceedings
Jahrgang106
PublikationsstatusVeröffentlicht - 1 Jan. 2014

Abstract

Non-linear homogenization techniques based on the use of the finite element method are tested, in this paper, for the study of heterogeneous materials. The practical steps of a computational homogenization approach and representative examples related to masonry structures and ceramic materials are presented. The non-linear representative volume elements (RVE) of a masonry structure, including parts with elastoplastic material behaviour (mortar), and a ceramic material with a unilateral contact interface (crack), are created and solved. Parametric analysis has been chosen and used for the description of the strain loading. The average stress and strain in the RVE domain are then calculated. In addition, the stiffness is estimated for each loading level. Finally, two databases for the stiffness and the stress are created, a metamodel based on MATLAB interpolation is used, and an overall non-linear homogenization procedure, is considered. The satisfactory results obtained from the comparison between direct heterogeneous macroscopic models created by commercial software show that the proposed method can be used for the simulation of non-linear heterogeneous structures.

ASJC Scopus Sachgebiete

Zitieren

Computational Homogenization in Masonry Structures. / Drosopoulos, G. A.; Stavroulaki, M. E.; Giannis, K. et al.
in: Civil-Comp Proceedings, Jahrgang 106, 01.01.2014.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Drosopoulos, GA, Stavroulaki, ME, Giannis, K, Plymakis, L, Stavroulakis, GE & Wriggers, P 2014, 'Computational Homogenization in Masonry Structures', Civil-Comp Proceedings, Jg. 106.
Drosopoulos, G. A., Stavroulaki, M. E., Giannis, K., Plymakis, L., Stavroulakis, G. E., & Wriggers, P. (2014). Computational Homogenization in Masonry Structures. Civil-Comp Proceedings, 106.
Drosopoulos GA, Stavroulaki ME, Giannis K, Plymakis L, Stavroulakis GE, Wriggers P. Computational Homogenization in Masonry Structures. Civil-Comp Proceedings. 2014 Jan 1;106.
Drosopoulos, G. A. ; Stavroulaki, M. E. ; Giannis, K. et al. / Computational Homogenization in Masonry Structures. in: Civil-Comp Proceedings. 2014 ; Jahrgang 106.
Download
@article{4b4eca00f0ac40ab8684513d694ee351,
title = "Computational Homogenization in Masonry Structures",
abstract = "Non-linear homogenization techniques based on the use of the finite element method are tested, in this paper, for the study of heterogeneous materials. The practical steps of a computational homogenization approach and representative examples related to masonry structures and ceramic materials are presented. The non-linear representative volume elements (RVE) of a masonry structure, including parts with elastoplastic material behaviour (mortar), and a ceramic material with a unilateral contact interface (crack), are created and solved. Parametric analysis has been chosen and used for the description of the strain loading. The average stress and strain in the RVE domain are then calculated. In addition, the stiffness is estimated for each loading level. Finally, two databases for the stiffness and the stress are created, a metamodel based on MATLAB interpolation is used, and an overall non-linear homogenization procedure, is considered. The satisfactory results obtained from the comparison between direct heterogeneous macroscopic models created by commercial software show that the proposed method can be used for the simulation of non-linear heterogeneous structures.",
keywords = "Masonry structures, Non-linear homogenization, Structural analysis",
author = "Drosopoulos, {G. A.} and Stavroulaki, {M. E.} and K. Giannis and L. Plymakis and Stavroulakis, {G. E.} and P. Wriggers",
year = "2014",
month = jan,
day = "1",
language = "English",
volume = "106",

}

Download

TY - JOUR

T1 - Computational Homogenization in Masonry Structures

AU - Drosopoulos, G. A.

AU - Stavroulaki, M. E.

AU - Giannis, K.

AU - Plymakis, L.

AU - Stavroulakis, G. E.

AU - Wriggers, P.

PY - 2014/1/1

Y1 - 2014/1/1

N2 - Non-linear homogenization techniques based on the use of the finite element method are tested, in this paper, for the study of heterogeneous materials. The practical steps of a computational homogenization approach and representative examples related to masonry structures and ceramic materials are presented. The non-linear representative volume elements (RVE) of a masonry structure, including parts with elastoplastic material behaviour (mortar), and a ceramic material with a unilateral contact interface (crack), are created and solved. Parametric analysis has been chosen and used for the description of the strain loading. The average stress and strain in the RVE domain are then calculated. In addition, the stiffness is estimated for each loading level. Finally, two databases for the stiffness and the stress are created, a metamodel based on MATLAB interpolation is used, and an overall non-linear homogenization procedure, is considered. The satisfactory results obtained from the comparison between direct heterogeneous macroscopic models created by commercial software show that the proposed method can be used for the simulation of non-linear heterogeneous structures.

AB - Non-linear homogenization techniques based on the use of the finite element method are tested, in this paper, for the study of heterogeneous materials. The practical steps of a computational homogenization approach and representative examples related to masonry structures and ceramic materials are presented. The non-linear representative volume elements (RVE) of a masonry structure, including parts with elastoplastic material behaviour (mortar), and a ceramic material with a unilateral contact interface (crack), are created and solved. Parametric analysis has been chosen and used for the description of the strain loading. The average stress and strain in the RVE domain are then calculated. In addition, the stiffness is estimated for each loading level. Finally, two databases for the stiffness and the stress are created, a metamodel based on MATLAB interpolation is used, and an overall non-linear homogenization procedure, is considered. The satisfactory results obtained from the comparison between direct heterogeneous macroscopic models created by commercial software show that the proposed method can be used for the simulation of non-linear heterogeneous structures.

KW - Masonry structures

KW - Non-linear homogenization

KW - Structural analysis

UR - http://www.scopus.com/inward/record.url?scp=84963603069&partnerID=8YFLogxK

M3 - Article

AN - SCOPUS:84963603069

VL - 106

JO - Civil-Comp Proceedings

JF - Civil-Comp Proceedings

SN - 1759-3433

ER -

Von denselben Autoren

  1. A general phase-field model for simulating impact-sliding contact failure

    Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

  2. Phase-field modeling of fracture for ferromagnetic materials through Maxwell's equation

    Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

  3. DEM simulations using convex NURBS particles

    Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

  4. Mechano-chemo-biological model of atherosclerosis formation based on the outside-in theory

    Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

  5. 3D concrete fracture simulations using an explicit phase field model

    Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review