| dc.description.abstract | A porcupine’s quill is an extraordinary natural armor capable of withstanding high compression load. By unraveling the unique properties of the porcupine quill design, the bioinspired structures can be applied in engineering applications. The present work investigates both the mechanical and chemical properties of a porcupine quill. An axial compression test is conducted on the natural material in three states: the entire composite quill structure and the response of shell and foam phases individually. These mechanical responses are reported, and compressive failure modes are quantified by scanning electron microscopy (SEM) and micro-computed tomography (mCT). Fourier-transform infrared (FTIR) spectroscopy is conducted and a slight compositional variation is found between the shell and foam phases of the porcupine quill.
The design of a porcupine quill-inspired structure is achieved through fabrication by stereolithography (SLA) additive manufacturing (AM) technology. Based on these design workflows, the properties of the structures, including struts length and relative density, are analyzed. Random workflow has a higher number of short struts, while longer struts dominate reflected workflow. Relative density increases with the increasing number of seeds. However, it decreases with a growing number of sectors. Qualitative analysis of the numerical simulation presented shows the importance of struts connectivity for efficient stress distribution. | en_US |
