Numerical investigation, experimental validation and macroscopic yield criterion of Al5056 honeycombs under mixed shear-compression loading

•Yield behaviour of Al5056 aluminium alloy honeycombs is investigated under mixed shear-compression.•Numerical simulations allow to overcome a limitation of the experimental measurements.•Numerical and experimental investigations allow to investigate the normal and shear behaviours separately.•A mac...

Full description

Saved in:
Bibliographic Details
Published in:International journal of impact engineering 2017-10, Vol.108, p.348-360
Main Authors: Tounsi, R., Markiewicz, E., Zouari, B., Chaari, F., Haugou, G.
Format: Article
Language:English
Subjects:
Aluminum alloys
Collapse
Compression loads
Computer simulation
Engineering Sciences
Experimental validation
FE model
Finite element analysis
Honeycomb
Honeycomb construction
Impact velocity
Macroscopic yield criterion
Mathematical models
Mechanics
Mixed shear-compression
Numerical analysis
Parameter identification
Shear
Shear strength
Studies
Yield criteria
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Yield behaviour of Al5056 aluminium alloy honeycombs is investigated under mixed shear-compression.•Numerical simulations allow to overcome a limitation of the experimental measurements.•Numerical and experimental investigations allow to investigate the normal and shear behaviours separately.•A macroscopic yield criterion expressed as a function of the impact velocity, the loading angle Ψ and the in-plane orientation angle β. Numerical simulations of honeycomb behaviour under mixed shear-compression loading are performed to overcome a limitation of the experimental measurements and to investigate the normal and the shear honeycomb behaviours separately. A detailed FE model allowing to simulate the mixed shear-compression honeycomb behaviour is presented. A validation between numerical and experimental results in terms of crushing responses and collapse mechanisms allows to dissociate the normal and shear forces components. They are used to identify the parameters of a macroscopic yield criterion expressed as a function of the impact velocity, the loading angle and the in-plane orientation angle. A well known dynamic enhancement phenomenon is confirmed by this macroscopic yield criterion. However, as a new result, this dynamic enhancement is reversed when the loading angle reaches a critical value. An analysis of the collapse mechanisms is carried out under both quasi-static and dynamic loading conditions in order to explain this inversion.
ISSN:0734-743X
1879-3509
DOI:10.1016/j.ijimpeng.2017.05.001