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Odonnell, Matthew Philip
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Topics
Publications (12/12 displayed)
- 2023Stiffness tailoring in sinusoidal lattice structures through passive topology morphing using contact connectionscitations
- 2020Reconsidering laminate nonsymmetrycitations
- 2019Thermal prestress in composite compliant shell mechanismscitations
- 2019Comparing the effect of geometry and stiffness on the effective load paths in non-symmetric laminates
- 2018Thermal Prestress in Composite Compliant Shell Mechanisms
- 2016Can tailored non-linearity of hierarchical structures inform future material development?citations
- 2016Efficient Analysis of Variable Stiffness Composite Plates
- 2016Coupling of helical lattice structures for tunable non-linear elasticity
- 2016Can Non-symmetry Improve Composite Performance?
- 2014Rapid Analysis of Variable Stiffness Plates
- 2012Debond resisting composite stringers
- 2010Approximations for Warp Free Laminate Configurations
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article
Stiffness tailoring in sinusoidal lattice structures through passive topology morphing using contact connections
Abstract
Structures with adaptive stiffness characteristics present an opportunity to meet competing design requirements, thus achieving greater efficiency by the reconfiguration of their topology. Here, the potential of using changes in the topology of planar lattice structures is explored to achieve this desired adaptivity and observe that lattice structures with rectangle-like unit-cells may undergo elastic buckling or bending of cell walls when subject to longitudinal compression. Under sufficient load intensity, cell walls can deform and contact neighbouring cells. This self-contact is harnessed to change the topology of the structure to that of a kagome-like lattice, thereby establishing new load paths, thus enabling enhancement, in a tailored manner, of the effective compressive and shear stiffness of the lattice. Whilst this phenomenon is independent of characteristic length scale, we focus on macroscopic behaviour (lattices of scale200 mm). Experimentally observed responses of 3D-printed lattices correlate excellently with finite element analysis and analytical stiffness predictions for pre- and post-contact topologies. The role of key geometric and stiffness parameters in critical regions of the design space is explored through a parametric study. The non-linear responses demonstrated by this topology morphing lattice structure may offer designers a new route to tailor elastic characteristics.