Lattice structures are promising design solutions for lightweight components in many industrial fields as aeronautics and space. The multifunctional design approach aims to combine in the same component several capabilities, including the ability to absorb impact energy with high efficiency. The additive manufacturing of metals is presently opening to innovative constructive approaches where static strength, lightweight and impact behavior must be considered together in design and simulation. This paper introduces the modeling results of the energy absorbed by different lattice cells topologies under impacts
Lattice structures are excellent candidates for lightweight, energy absorbing applications such as p...
Lattice structures have seen increasing use in several industries including automotive, aerospace, a...
Commonly adopted shock absorbers and, in general, crashworthy structural components, based on sandwi...
Lattice structures offer the potential to relatively easily engineer specific (meso-scale properties...
Lightweight and stiff lattice structures are good energy absorbers. This study evaluates the energy...
In this work, an experimental and numerical analysis of a lattice structure for energy absorption wa...
Innovative additive manufacturing processes open new design opportunities, in the field of periodic ...
Lattice structures are regarded as excellent candidates for use in lightweight energy absorbing appl...
This study is focused on the low-velocity impact response of 3D plate-lattices fabricated via stereo...
Today, variously profiled parts are mainly used for energy absorption. For special cases, precise co...
The design of lattice structures for additive manufacturing processes requires dedicated methods and...
The prediction of damage to structures caused by accidental collision – whether to automobiles, offs...
Aluminum sandwich structures are commonly used in aeronautical and aerospatial applications. Essenti...
In this study, the energy absorption capabilities of a kirigami-inspired auxetic structure under com...
Cellular solids are characteristically excellent energy absorbers due to their capacity to store lar...
Lattice structures are excellent candidates for lightweight, energy absorbing applications such as p...
Lattice structures have seen increasing use in several industries including automotive, aerospace, a...
Commonly adopted shock absorbers and, in general, crashworthy structural components, based on sandwi...
Lattice structures offer the potential to relatively easily engineer specific (meso-scale properties...
Lightweight and stiff lattice structures are good energy absorbers. This study evaluates the energy...
In this work, an experimental and numerical analysis of a lattice structure for energy absorption wa...
Innovative additive manufacturing processes open new design opportunities, in the field of periodic ...
Lattice structures are regarded as excellent candidates for use in lightweight energy absorbing appl...
This study is focused on the low-velocity impact response of 3D plate-lattices fabricated via stereo...
Today, variously profiled parts are mainly used for energy absorption. For special cases, precise co...
The design of lattice structures for additive manufacturing processes requires dedicated methods and...
The prediction of damage to structures caused by accidental collision – whether to automobiles, offs...
Aluminum sandwich structures are commonly used in aeronautical and aerospatial applications. Essenti...
In this study, the energy absorption capabilities of a kirigami-inspired auxetic structure under com...
Cellular solids are characteristically excellent energy absorbers due to their capacity to store lar...
Lattice structures are excellent candidates for lightweight, energy absorbing applications such as p...
Lattice structures have seen increasing use in several industries including automotive, aerospace, a...
Commonly adopted shock absorbers and, in general, crashworthy structural components, based on sandwi...