Numerical modelling of hydraulically bonded mixture with rubber admixture due to applied mechanical loadings

Daniel Pietras¹, Tomasz Sadowski¹

¹Department of Solid Mechanics, Faculty of Civil Engineering and Architecture, Lublin University of Technology

© 2016 Budownictwo i Architektura. Publikacja na licencji Creative Commons Attribution-NonCommercial-ShareAlike 4.0 (CC BY-NC-SA 4.0)

Cytowanie: Budownictwo i Architektura, vol. 16(3) (2017) 095-102, ISSN 1899-0665, DOI: 10.24358/Bud-Arch_17_163_09

Streszczenie:

In this paper the application of the Extended Finite Element Method (XFEM) to anticipate change of the behaviour of composite with complex internal structure after use of the admixtures was presented. The response to mechanical loadings of bent beams made of hydraulically bonded mixture with rubber admixture was considered. The impact of the rubber granulate on the value of fracture energy was analysed. Moreover, the influence of an interfacial transmission zone quality on the achieved effect was assessed. Calculations were conducted by means of the muli-scale numerical model which was built in ABAQUS finite element method environment. The results derived indicate beneficial effect of rubber granulate on fracture energy of hydraulically bonded mixture.

Słowa kluczowe:

virtual test, XFEM, FEM, multi-scale modelling

Numerical modelling of hydraulically bonded mixture with rubber admixture due to applied mechanical loadings

Abstract:

In this paper the application of the Extended Finite Element Method (XFEM) to anticipate change of the behaviour of composite with complex internal structure after use of the admixtures was presented. The response to mechanical loadings of bent beams made of hydraulically bonded mixture with rubber admixture was considered. The impact of the rubber granulate on the value of fracture energy was analysed. Moreover, the influence of an interfacial transmission zone quality on the achieved effect was assessed. Calculations were conducted by means of the muli-scale numerical model which was built in ABAQUS finite element method environment. The results derived indicate beneficial effect of rubber granulate on fracture energy of hydraulically bonded mixture.

virtual test, XFEM, FEM, multi-scale modelling

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