准静态压缩载荷下结构稳定性提高的3d打印分层可重入蜂窝

Chi Zhan, Mingzhe Li, R. Mccoy, Linda Zhao, Weiyi Lu
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摘要

负泊松比重入式蜂窝作为一种轻型吸能器在各种应用中显示出巨大的潜力。然而,由于其弯曲为主的特性,重入式蜂窝的结构稳定性和吸能能力还有待进一步提高。研究表明,分层结构具有轻量化和优异的机械性能。我们假设,通过在常规细胞壁中引入三角形层次子结构,可以将蜂窝式再入蜂窝的弯曲主导行为转化为拉伸主导行为。因此,可以通过分层结构的局部变形来促进分层重入蜂窝结构的整体稳定性,从而潜在地提高结构的能量吸收能力。为了验证我们的假设,我们首先使用Polyjet 3d打印技术制造了长度范围从微米到厘米的分层可重入蜂巢。带实心支柱的常规可重返蜂巢已被制成基准结构。通过单轴准静态压缩试验对蜂窝的力学性能进行了表征。此外,利用数字图像相关(DIC)揭示了分层结构的局部变形机制。与常规重入蜂窝相比,分层重入蜂窝的整体破坏应变提高了36%。这是由于局部断裂和三角层致密化提高了结构稳定性。规则型和分层型蜂窝均表现出相同的比能量吸收能力。根据现有的尺度规律预测,通过优化结构的相对密度,分层重入蜂窝具有超越常规蜂窝的巨大潜力。利用商业软件Abaqus/CAE 2020建立了分层再入蜂窝的有限元模型。用实验数据对模型进行了校正。在弹性区域内,模拟的变形模式与实验结果吻合较好。当规则重入蜂巢的相对密度等于分层重入蜂巢时,该模型预测分层重入蜂巢的吸能性能优于规则重入蜂巢,其刚度和屈服强度均有所提高。综上所述,本研究表明,将分层结构引入再入式蜂窝结构中,可以提高结构稳定性。此外,层次化的结构赋予了可重入式蜂窝轻量化且具有竞争力的能量吸收能力。
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3D-Printed Hierarchical Re-Entrant Honeycomb With Improved Structural Stability Under Quasi-Static Compressive Loading
Re-entrant honeycombs with negative Poisson’s ratio have shown great potential as lightweight energy absorbers for various applications. However, due to its bending-dominated behavior, the structural stability and energy absorption capacity of reentrant honeycombs are yet to be further improved. It has been demonstrated that hierarchical structures exhibit a combination of lightweight and superior mechanical properties. We hypothesize that by introducing the triangular hierarchical substructures into the conventional cell walls, the bending-dominated behavior of re-entrant honeycombs can be converted into the stretching-dominated one. Consequently, the overall structural stability of the hierarchical re-entrant honeycombs can be promoted through local deformation of hierarchy, which can potentially benefit the energy absorption capacity of the resulted structure. To test our hypothesis, we first fabricate the hierarchical reentrant honeycombs with length scale ranging from micrometer to centimeter using Polyjet 3D-printing technique. Regular reentrant honeycombs with solid struts have been fabricated as baseline structures. The mechanical performance of the honeycombs has been characterized through uniaxial quasi-static compression tests. Besides, the local deformation mechanisms of the hierarchical structure have been revealed by the Digital Image Correlation (DIC). In comparison to the regular re-entrant honeycomb, the global failure strain of hierarchical re-entrant honeycomb is enhanced by 36%. This is due to the improved structural stability from local fracture and densification of the triangular hierarchy. Both the regular and hierarchical honeycombs exhibit the same specific energy absorption capacity. As predicted by the existing scaling laws, the hierarchical re-entrant honeycomb has great potential to outperform regular one by optimizing the relative density of the structure. A finite element model of the hierarchical re-entrant honeycomb has been developed by using commercial software Abaqus/CAE 2020. The model has been calibrated by the experimental data. Within the elastic region, the simulated deformation modes show good agreement with experimental observations. When the relative density of the regular re-entrant honeycombs equals to the hierarchical ones, the model predicts that the hierarchical re-entrant honeycombs have superior energy absorption performance with enhanced stiffness and yield strength in comparison to the regular ones. In conclusion, this study has demonstrated that by introducing hierarchical structure into re-entrant honeycomb, the structural stability has been improved. Furthermore, the hierarchical structure endows re-entrant honeycomb with lightweight yet competitive energy absorption capacity.
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