Scaling of structural failure

This article attempts to review the progress achieved in the understanding of scaling and size effect in the failure of structures. Particular emphasis is placed on quasibrittle materials for which the size effect is complicated. Attention is focused on three main types of size effects, namely the s...

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Bibliographic Details
Main Authors: Bazant, Zdenek P., Chen, Er-Ping
Other Authors: United States. Department of Energy.
Format: Report
Language:English
Published: Sandia National Laboratories 1997
Subjects:
Crack Propagation
Brittleness
36 Materials Science
Rocks
Icebergs
Composite Materials
Compression Strength
Deformation
Fracture Properties
Ceramics
Scaling Laws
Sea ice
Online Access:https://doi.org/10.2172/420364
https://digital.library.unt.edu/ark:/67531/metadc686246/
Description
Summary:This article attempts to review the progress achieved in the understanding of scaling and size effect in the failure of structures. Particular emphasis is placed on quasibrittle materials for which the size effect is complicated. Attention is focused on three main types of size effects, namely the statistical size effect due to randomness of strength, the energy release size effect, and the possible size effect due to fractality of fracture or microcracks. Definitive conclusions on the applicability of these theories are drawn. Subsequently, the article discusses the application of the known size effect law for the measurement of material fracture properties, and the modeling of the size effect by the cohesive crack model, nonlocal finite element models and discrete element models. Extensions to compression failure and to the rate-dependent material behavior are also outlined. The damage constitutive law needed for describing a microcracked material in the fracture process zone is discussed. Various applications to quasibrittle materials, including concrete, sea ice, fiber composites, rocks and ceramics are presented.

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