多层级曲梁多稳态超材料的可重用性研究

多稳态超材料凭借其出色的力学性能而广受关注和应用.然而,现有研究主要集中在单曲梁结构,对于由多层级曲梁单胞构建的复杂拓扑结构的可重复吸能特性缺乏深入探讨.此外,与传统材料相比,多稳态超材料在循环加载下的疲劳性能也鲜有研究.文章以两端固支直梁一阶屈曲模态为初始构型构造曲梁单胞,并通过3D打印技术制备双材料双稳态单元.进而建立多层级曲梁结构,并给出预测多层级曲梁正则化的力和势能随位移变化的5次、6次多项式经验公式,相比于以往3次、4次多项式结果更为准确.以双曲梁单胞为基本单元,通过中心旋转的方式设计三维点状多稳态超材料,研究其稳态性能和力学特性.并通过参数化分析研究单元几何参数和模块化拓扑构型对结构力学响应的影响,最后通过疲劳实验验证了该类多稳态超材料的疲劳寿命.该结构能够在小变形和大变形范围内实现正负刚度的转变,同时变形是弹性稳定的,即杨氏模量基本保持不变,且具有多稳态和可重复吸能特性.随着双曲梁几何参数Q(高厚比)的增大,其有效压溃距离和能量吸收效率随之增加.提出的设计策略为制造多稳态多步可逆变形的力学超材料开辟了新路径,并为设计材料-结构-功能一体化的工程材料提供了一种新思路.

多稳态力学超材料带隙特性及调控研究

多稳态力学超材料具有多重稳定状态和几何重构特性,在变形吸能和能带调控等方面有重要的研究价值.本研究提出了一种多稳态力学超材料.该超材料是由具有双稳态特性的曲杆和相关实体支撑结构组成.结合有限单元法和布洛赫定理,计算了结构的能带结构,分析了不同稳态条件下结构的带隙特性,得到了几何参数对结构带隙的影响规律,并研究了由5×5个单胞组成的阵列结构中部分单胞变形时,整体结构的传输率.研究发现,双稳态连杆的变形状态可显著改变结构的带隙,尤其是在低频范围内产生了更宽的带隙.整体结构中局部一行或一列单胞变形即可在该方向对应带隙频率范围内实现弹性波传播的衰减.

Multistable Mechanical Metamaterials:A Brief Review

Over the past decade,multistable mechanical metamaterials have been widely investigated because of their novel shape reconfigurability and programmable energy landscape.The ability to reversibly reshape among diverse stable states with different energy levels represents the most important feature of the multistable mechanical metamaterials.We summarize main design strategies of multistable mechanical metamaterials,including those based on self-assembly scheme,snap-through instability,structured mechanism and geometrical frustration,with a focus on the number and controllability of accessible stable states.Then we concentrate on unusual mechanical properties of these multistable mechanical metamaterials,and present their applications in a wide range of areas,including tunable electromagnetic devices,actuators,robotics,and mechanical logic gates.Finally,we discuss remaining challenges and open opportunities of designs and applications of multistable mechanical metamaterials.