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Some Basic Issues of Isotropic and Anisotropic Continuum Damage Mechanics Read chapter Read first chapter

2015 | OriginalPaper | Chapter

7. Lattice and Particle Modeling of Damage Phenomena

Authors : Sohan Kale, Martin Ostoja-Starzewski

Published in: Handbook of Damage Mechanics

Publisher: Springer New York

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Abstract

Lattice (spring network) models offer a powerful way of simulating mechanics of materials as a coarse scale cousin to molecular dynamics and, hence, an alternative to finite element models. In general, lattice nodes are endowed with masses, thus resulting in a quasiparticle model. These models, having their origins in spatial trusses and frameworks, work best when the material may naturally be represented by a system of discrete units interacting via springs or, more generally, rheological elements. This chapter begins with basic concepts and applications of spring networks, in particular the anti-plane elasticity, planar classical elasticity, and planar nonclassical elasticity. One can easily map a specific morphology of a composite material onto a particle lattice and conduct a range of parametric studies; these result in the so-called damage maps. Considered next is a generalization from statics to dynamics, with nodes truly acting as quasiparticles, application being the comminution of minerals. The chapter closes with a discussion of scaling and stochastic evolution in damage phenomena as stepping-stone to stochastic continuum damage mechanics.

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previous chapter Fractals and Mechanics of Fracture
next chapter Toughening and Instability Phenomena in Quantized Fracture Process: Euclidean and Fractal Cracks
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Metadata
Title
Lattice and Particle Modeling of Damage Phenomena
Authors
Sohan Kale
Martin Ostoja-Starzewski
Copyright Year
2015
Publisher
Springer New York
Book
Handbook of Damage Mechanics

Print ISBN: 978-1-4614-5588-2

Electronic ISBN: 978-1-4614-5589-9

Copyright Year: 2015

DOI
https://doi.org/10.1007/978-1-4614-5589-9_20

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