高柔性离子聚合物金属复合材料的动态响应建模及其传递函数优化OA
Dynamic response modeling and transfer function optimization of high-flexibility ionic polymer-metal composites
离子聚合物金属复合材料作为一种高柔性大变形的新型智能材料,凭借其独特的电致变形特性,在柔性机器人、微机电系统和生物医学工程等领域展现出广阔的应用潜力.然而,其固有的非线性动态响应特性以及复杂的动力学行为,给精确控制带来了重大挑战,极大地限制了其在高性能系统中的应用范围.为突破这一瓶颈,本工作基于等效理论开展了高柔性大变形离子聚合物金属复合材料动态响应模型的构建及其传递函数优化研究.通过对材料非线性特性的深入分析,建立了物理系统与数值模型之间的精确本构关系.进一步地,为实现从无限维模型到有限维模型的降阶转化,定义了适用于该材料大变形特性的辨识准则,并采用3种不同的辨识方法对其电致变形行为进行系统辨识.结果表明,改进的加权迭代算法在辨识性能上表现出显著优势,辨识准确率超过98%.研究还发现,在电致变形过程中,材料的动态响应幅度和相位角随电阻增大而减小,而随电容增大而增大.本工作提出的优化模型能够有效指导离子聚合物金属复合材料的设计与制备,并实现对其大变形行为的高精度控制,为该材料控制系统的开发提供了坚实的理论基础,对推动其在高性能领域中的柔性应用具有重要的科学意义和工程价值.
As a novel class of smart materials with high flexibility and large deformation,ionic polymer-metal composites(IPMCs)exhibit exceptional electro-actuated deformation characteristics,demonstrating significant potential in flexible robotics,micro-electro-mechanical systems,and biomedical engineering.Nevertheless,their inherent nonlinear dynamic responses and complex kinetic behaviors pose substantial challenges to precise control,severely limiting their deployment in high-performance systems.To overcome this bottleneck,the present study establishes a dynamic response model for high-flexibility,large-deformation IPMCs and optimizes their transfer function based on equivalent-circuit theory.Through an in-depth analysis of the material's nonlinear properties,a precise constitutive relationship between the physical system and the numerical model is established.To achieve model-order reduction from an infinite-dimensional to a finite-dimensional representation,identification criteria tailored to the large-deformation characteristics of the material are formulated,and three distinct identification methods are employed for systematic identification of its electro-actuated deformation behavior.Results indicate that the refined weighted-iterative algorithm offers markedly superior identification performance,achieving an accuracy exceeding 98%.Additionally,the study reveals that during electro-actuated deformation,the amplitude and phase angle of the material's dynamic response decrease with increasing resistance but increase with increasing capacitance.The optimized model proposed herein can effectively guide the design and fabrication of IPMCs while enabling high-precision control of their large-deformation behavior.This work provides a solid theoretical foundation for the development of control systems for such materials and holds significant scientific and engineering value for advancing their flexible applications in high-performance domains.
王红;杨亮;杨延宁
延安大学 物理与电子信息学院,陕西 延安 716000延安大学 物理与电子信息学院,陕西 延安 716000延安大学 物理与电子信息学院,陕西 延安 716000
通用工业技术
离子聚合物金属复合材料动态响应驱动特性传递函数软体机器人
ionic polymer-metal compositedynamic responseactuation characteristictransfer functionsoft robot
《材料工程》 2026 (6)
105-114,10
国家自然科学基金项目(52365069)陕西省重点研发计划项目(2025CY-YBXM-099)陕西省自然科学基础研究计划项目(2024JC-YBQN-0472)延安大学科研专项项目(2023JBZR-005,2023HBZ-013)
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