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Archive of Applied Mechanics
Published in: Archive of Applied Mechanics 3/2019

17-09-2018 | SPECIAL

Damage propagation in 2d beam lattices: 1. Uncertainty and assumptions

Authors: Andrej Cherkaev, Michael Ryvkin

Published in: Archive of Applied Mechanics | Issue 3/2019

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Abstract

The paper studies damage propagation in brittle elastic beam lattices, using the quasistatic approach. The lattice is subjected to a remote tensile loading; the beams in the lattice are bent and stretched. An introduced initial flaw in a stressed lattice causes an overstress of neighboring beams. When one of the overstressed beams fails, it is eliminated from the lattice; then, the process repeats. When several beams are overstressed, one has to choose which beam to eliminate. The paper studies and compares damage propagation under various criteria of the elimination of the overstressed beams. These criteria account for the stress level, randomness of beams properties, and decay of strength due to micro-damage accumulation during the loading history. A numerical study is performed using discrete Fourier transform approach. We compare damage patterns in triangular stretch-dominated and hexagonal bending-dominated lattices. We discuss quantitative characterization of the damage pattern for different criteria. We find that the randomness in the beam stiffness increases fault tolerance, and we outline conditions restricting the most dangerous straight linear crack-like pattern.
previous article Non-uniform plastic deformations of crystals undergoing anti-plane constrained shear
next article Damage propagation in 2d beam lattices: 2. Design of an isotropic fault-tolerant lattice

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Appendix
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Metadata
Title
Damage propagation in 2d beam lattices: 1. Uncertainty and assumptions
Authors
Andrej Cherkaev
Michael Ryvkin
Publication date
17-09-2018
Publisher
Springer Berlin Heidelberg
Published in
Archive of Applied Mechanics / Issue 3/2019
Print ISSN: 0939-1533
Electronic ISSN: 1432-0681
DOI
https://doi.org/10.1007/s00419-018-1429-z

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