Add to ORKGThe finite element method has been used to simulate the properties of panels with Kagomé and tetragonal cores under compressive and shear loading. The simulation has been performed for two different materials: a Cu-alloy with extensive strain hardening and an Al-alloy with minimal hardening. It is shown that the Kagomé core is more resistant to plastic buckling than the tetragonal core under both compression and shear. One consequence is that the Kagomé structure has the greater load capacity and a deferred susceptibility to softening. Another is that the Kagomé core is isotropic in shear: contrasting with the soft orientations exhibited by the tetragonal core
AbstractConstruction of sandwich materials involves a composite material structure of light weight, ...
Additive manufacture of titanium structures allows the realisation of advanced design strategies not...
Theoretical studies have indicated that truss core panels with a tetragonal topology support bending...
The finite element method has been used to simulate the properties of panels with Kagomé and tetrago...
Studying the mechanical behavior of metal cores provides insight into the overall performance of str...
Ultralight weight structures are today’s essential need in aerospace, marine and automotive industri...
A truss-core sandwich panel is a promising load-bearing element of lightweight high-stiffness struct...
The present study aimed at understanding the behavior of tetrahedral lattice truss core structures u...
AbstractWires are great candidates as the raw material for truss periodic cellular metals because th...
International audienceThe present study aimed at understanding the behavior of tetrahedral lattice t...
A finite element study based on 1D beam element model is performed in order to investigate the mecha...
This Final Year Project (FYP) explores compression testing on kagome and Strut-Reinforced Kagome uni...
Lightweight core structures with high strength and high potential for energy absorption are crucial ...
Sandwich panels with multilayer pyramidal truss cores were manufactured by additive manufacturing. T...
In recent studies, selection criteria for lattice materials suitable for active shape-morphing have ...
AbstractConstruction of sandwich materials involves a composite material structure of light weight, ...
Additive manufacture of titanium structures allows the realisation of advanced design strategies not...
Theoretical studies have indicated that truss core panels with a tetragonal topology support bending...
The finite element method has been used to simulate the properties of panels with Kagomé and tetrago...
Studying the mechanical behavior of metal cores provides insight into the overall performance of str...
Ultralight weight structures are today’s essential need in aerospace, marine and automotive industri...
A truss-core sandwich panel is a promising load-bearing element of lightweight high-stiffness struct...
The present study aimed at understanding the behavior of tetrahedral lattice truss core structures u...
AbstractWires are great candidates as the raw material for truss periodic cellular metals because th...
International audienceThe present study aimed at understanding the behavior of tetrahedral lattice t...
A finite element study based on 1D beam element model is performed in order to investigate the mecha...
This Final Year Project (FYP) explores compression testing on kagome and Strut-Reinforced Kagome uni...
Lightweight core structures with high strength and high potential for energy absorption are crucial ...
Sandwich panels with multilayer pyramidal truss cores were manufactured by additive manufacturing. T...
In recent studies, selection criteria for lattice materials suitable for active shape-morphing have ...
AbstractConstruction of sandwich materials involves a composite material structure of light weight, ...
Additive manufacture of titanium structures allows the realisation of advanced design strategies not...
Theoretical studies have indicated that truss core panels with a tetragonal topology support bending...