The porous structure in pomelo peel is believed to be responsible for the protection of its fruit from damage during the free falling from a tree. The quantitative understanding of the relationship between the deformation behavior and the porous structure could pave the way for the design of porous structures for efficient energy absorption. Here, a universal feature of pore distribution in pomelo peels along the radial direction is extracted from three varieties of pomelos, which shows strong correlation to the deformation behavior of the peels under compression. Guided by the porous design found in pomelo peels, porous polyether-ether-ketone (PEEK) cube is additively manufactured and possesses the highest ability to absorb energy during compression as compared to the non-pomelo-inspired geometries, which is further confirmed by the finite element simulation. The nature-optimized porous structure revealed here could guide the design of lightweight and high-energy-dissipating materials/devices.
Programmable
nonuniform deformation is of great significance for
self-shape-morphing systems that are commonly seen in biological systems
and also has practical applications in drug delivery, biomedical devices
and robotics, etc. Here, we present a novel gradient four-dimensional
(4D) printing method toward biomimetic nonuniform, dual-stimuli self-morphing.
By modeling and printing graded active materials with water swelling
properties, we can configure continuously smooth gradients of volume
fraction of the active material in bilayer structures. The variation
of swelling ratio mismatch between the two layers can be delicately
regulated, which results in the programmable nonuniform shape transformation.
The shape-shifting results can be predicted by the established mathematical
model and computational simulations. Furthermore, we demonstrate dual-stimuli
self-morphing structures by printing the graded water-responsive elastomer
materials onto a heat-shrinkable shape memory polymer, which could
produce different shape changes in response to humidity and different
temperatures. This method pioneers a versatile approach to broaden
the design space for 4D printing and will be compatible with a wide
range of active materials meeting various requirements in diverse
potential applications.
Many materials in nature exhibit excellent mechanical properties. In this study, we evaluated the bionic bumper structure models by using nonlinear finite element (FE) simulations for their crashworthiness under full-size impact loading. The structure contained the structural characteristics of cattail and bamboo. The results indicated that the bionic design enhances the specific energy absorption (SEA) of the bumper. The numerical results showed that the bionic cross-beam and bionic box of the bionic bumper have a significant effect on the crashworthiness of the structure. The crush deformation of bionic cross-beam and box bumper model was reduced by 33.33%, and the total weight was reduced by 44.44%. As the energy absorption capacity under lateral impact, the bionic design can be used in the future bumper body.
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