Detail publikace

Generalized linear elastic fracture mechanics: an application to a crack touching the bimaterial interface

NÁHLÍK, L. ŠESTÁKOVÁ, L. HUTAŘ, P. KNÉSL, Z.

Originální název

Generalized linear elastic fracture mechanics: an application to a crack touching the bimaterial interface

Typ

článek v časopise - ostatní, Jost

Jazyk

angličtina

Originální abstrakt

In the contribution the limits of the validity of classical linear elastic fracture mechanics are extended to problems connected with failure of composite structures. The work is focused mainly on the case of a crack touching the interface between two different materials, two different constituents. The approach suggested in the paper facilitates the answer to the question what is the influence of particle (in particulate composite) or layer (in laminates) on crack propagation through bimaterial interface. Different composite (bimaterial) structures are considered: layered composites and composites reinforced by particles. The presented approach follows the basic idea of linearelastic fracture mechanics, i.e. the validity of small scale yielding conditions is assumed, and has a phenomenological character.

Klíčová slova

generalized stress intensity factor, bimaterial interface, composite materials, strain energy density factor, fracture criterion, generalized linear elastic fracture mechanics.

Autoři

NÁHLÍK, L.; ŠESTÁKOVÁ, L.; HUTAŘ, P.; KNÉSL, Z.

Rok RIV

2011

Vydáno

4. 1. 2011

Nakladatel

TTP

Místo

Švýcarsko

ISSN

1013-9826

Periodikum

Key Engineering Materials (print)

Ročník

452-453

Číslo

XXX

Stát

Švýcarská konfederace

Strany od

445

Strany do

448

Strany počet

4

BibTex

@article{BUT50939,
  author="Luboš {Náhlík} and Lucie {Malíková} and Pavel {Hutař} and Zdeněk {Knésl}",
  title="Generalized linear elastic fracture mechanics: an application to a crack touching the bimaterial interface",
  journal="Key Engineering Materials (print)",
  year="2011",
  volume="452-453",
  number="XXX",
  pages="445--448",
  issn="1013-9826"
}