Study of electromechanical metamaterial systems

机电超材料系统研究

• 批准号: RGPIN-2019-05383
• 负责人: Wang, Xiaodong
• 金额: $ 1.97万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=715183
• 关键词: Study; electromechanical; metamaterial; systems

The development of electromechanically coupled smart piezoelectric systems, which can respond to environment stimuli in real time and are compact, sensitive and durable has received considerable attention from research and industrial communities in engineering. Because of their advanced functionalities superior to the convectional structures the applications of these smart piezoelectric structures are widely spread into diverse areas. The race is always on to explore, develop and exploit new products of smart technology, which provides new opportunities for the associated industries, but also impose challenges for keeping to be competitive. The advances in manufacturing techniques have enabled the development of new classes of smart structures that embed sensing, actuation and communication at high densities. This embedding can be so tight that the distinction between structure and materials blur so these smart structures can be considered equivalently as new smart materials. These advances also make it possible to design the detailed local structures of the smart systems. It is the objective of the current project to develop new integrated piezoelectric smart material systems, which consist of periodically arranged specially designed material cells. The electromechanical properties of the smart material will be dominated by both the property of the material cells and also the periodic structure of the material. Different from traditional composite materials for which the desired properties, such as higher stiffness and strength, come from utilizing the best' properties of the individual constituents, the electromechanical properties of the new smart materials are tailored not only by material composition but also, and more importantly, by the detailed geometrical design of the local structure of the material cells. The theoretical study will be focused on (i) the development of mechanical models capable of describing the complicated electromechanical behaviour of the designed local material cells, (ii) the design of local material cell optimized to achieve advanced or exotic electromechanical properties (metamaterials), (iii) the integration of the local cells into periodic structures to form the desired smart materials, (iv) the characterization and evaluation of the electromechanical properties of the new smart materials, and (v) the evaluation of failure conditions of the smart materials. The experimental study will be conducted to build and evaluate the properties of the new smart materials based on traditional manufacturing techniques and/or additive manufacturing. In the short term, the current research will provide new ideas and guidelines on how to design advanced piezoelectric smart materials with new properties not available conventionally. In the long term, the outcome of the current research could be used in the design of the next generation programmable smart materials, which can be easily controlled and communicated with.

机电耦合智能压电系统具有结构紧凑、灵敏度高、经久耐用等特点，能够实时响应环境刺激，已受到工程界和研究界的广泛关注。由于智能压电结构具有优于传统结构的先进功能，其应用已广泛扩展到各个领域。探索、开发和利用智能技术新产品的竞赛一直在进行，这为相关行业提供了新的机遇，但也对保持竞争力提出了挑战。制造技术的进步使新型智能结构的发展成为可能，这些结构嵌入了高密度的传感、驱动和通信。这种嵌入可以非常紧密，以至于结构和材料之间的区别变得模糊，因此这些智能结构可以被视为新的智能材料。这些进步也使得设计智能系统的详细局部结构成为可能。