Dai Mouhui, Wu Ruien, Ye Mingxuan, Gao Kai, Chen Bin, Tao Xinwang, Fan Zhijie
College of Mechanical and Vehicle Engineering, Changsha University of Science & Technology, Changsha 410114, China.
College of International Engineering, Changsha University of Science & Technology, Changsha 410114, China.
Biomimetics (Basel). 2025 Jun 13;10(6):401. doi: 10.3390/biomimetics10060401.
To address the limitations of traditional single-motor bionic ornithopters in terms of environmental adaptability and lift capacity, this study proposes a dual-motor independently driven system utilizing a cross-shaft single-gear crank mechanism to achieve adjustable flap speed and wing frequency, thereby enabling asymmetric flapping for enhanced environmental adaptability. The design integrates a two-stage reduction gear group to optimize torque transmission and an S1223 high-lift airfoil to improve aerodynamic efficiency. Multiphysics simulations combining computational fluid dynamics (CFD) and finite element analysis (FEA) demonstrate that, under flapping frequencies of 1-3.45 Hz and wind speeds of 1.2-3 m/s, the optimized model achieves 50% and 60% improvements in lift and thrust coefficients, respectively, compared to the baseline. Concurrently, peak stress in critical components (e.g., cam disks and wing rods) is reduced by 37% to 41 MPa, with significantly improved stress uniformity. These results validate the dual-motor system's capability to dynamically adapt to turbulent airflow through the precise control of wing kinematics, offering innovative solutions for applications such as aerial inspection and precision agriculture.
为解决传统单电机仿生扑翼飞行器在环境适应性和升力能力方面的局限性,本研究提出一种双电机独立驱动系统,该系统采用横轴单齿轮曲柄机构来实现襟翼速度和机翼频率的可调,从而实现不对称扑动以增强环境适应性。该设计集成了两级减速齿轮组以优化扭矩传递,并采用S1223高升力翼型以提高空气动力学效率。结合计算流体动力学(CFD)和有限元分析(FEA)的多物理场模拟表明,在1 - 3.45Hz的扑动频率和1.2 - 3m/s的风速下,优化后的模型与基线相比,升力系数和推力系数分别提高了50%和60%。同时,关键部件(如凸轮盘和机翼杆)的峰值应力降低至37%,达到41MPa,应力均匀性显著提高。这些结果验证了双电机系统通过精确控制机翼运动学动态适应湍流气流的能力,为航空巡检和精准农业等应用提供了创新解决方案。
