基于巨电流变液频变阻尼在线调节的高海况无人艇探测装备抗扰控制研究

As the "eyes" of unmanned surface vehicle (USV), the effective detection distance and service precision of detection equipment determine the integrity of many functions such as surveying, reconnaissance, navigation and obstacle avoidance. However, the mechanical vibration and surge disturbance caused of USV in the course of moving will lead to the deterioration of the performance of detection equipment. High-performance vibration control with both shock resistance and vibration suppression can effectively achieve the goal of anti-disturbance stabilization, which has long been an international academic frontier and research difficulty. This project focuses on two scientific issues: the generation mechanism of non-linear frequency-varying damping for high and low frequency synchronous disturbance suppression and the intelligent on-line adaptive control of giant electrorheological fluid frequency-varying damping. The characteristics of vibration source atlas and the mapping model of vibration under high sea conditions are established. The converse thought of high and low frequency synchronous disturbance suppression based on expected transmissibility is put forward. The material characteristics and theoretical model of giant electrorheological fluid are analyzed. The generation mechanism of giant electrorheological fluid damping is explored. A giant electrorheological fluid damper is designed. An intelligent on-line control strategy of frequency-varying damping for giant electrorheological fluids in different frequency and time periods is proposed. Finally, the anti-disturbance control of vibration radiation level attenuation and instantaneous impact energy dissipation of detection equipment is realized. This control strategy also provides a new method and technology for high precision and high resolution analysis of USV detection equipment.

探测装备作为无人艇工作的“眼睛”，其有效探测距离和服役精度决定了测绘、侦查、导航避障等诸多功能的完整性。但无人艇在行进过程中产生的机械振动以及高海况下的浪涌等强冲击干扰，会导致探测装备的性能劣化。兼顾抗冲击和振动抑制的高性能振动控制能够有效实现目标的抗扰増稳，此问题长期以来一直是国际学术前沿和研究难点。本项目围绕高低频同步扰动抑制非线性频变阻尼生成机理和巨电流变液频变阻尼智能在线自适应控制两个科学问题展开研究。建立高海况环境下的振源图谱特征与振动映射模型，提出基于期望传递率反求频变阻尼的高低频同步扰动抑制逆向思路，解析巨电流变液材料特性和理论模型，探寻巨电流变液阻尼生成机理，设计巨电流变液阻尼减振器，提出分频段、分时段的巨电流变液特性的频变阻尼智能在线控制策略，最终实现探测装备振动辐射等级衰减与瞬时冲击能量耗散的抗扰控制，为无人艇探测装备的高精度、高分辨率解析，提供新方法、新技术。