多地形四足轮式机器人机构:设计、建模与分析

E. Gratton, M. Benyeogor, K. Nnoli, O. Olakanmi, Liam Wolf, Zavier Berti, Sushant Kumar, P. Saha
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引用次数: 2

摘要

为了使机器人在崎岖不平的地形中导航,其驱动器和控制器必须产生并精确控制大的机械动力。本文旨在研制一种具有主动悬架的自主机器人,其形式为混合四足驱动机构。这涉及到在不影响系统性能的情况下优化开发成本的计算方法。利用Solidworks CAD工具对辅助部件进行设计,并与床身结构集成,形成主动悬挂式机器人驱动机构。此外,利用S-Math计算工具,对机器人的悬挂系统进行了优化,采用了四杆机构。为了提高该设计与预期控制器的兼容性,建立并求解了一些数学方程和数值验证。其中包括倾覆稳定性和滑移转向的建模,用于计算悬架伺服电机角位置的趋势线方程,以及用于确定这些趋势线方程精度的R2值的计算。采用有限元分析(FEA),模拟了最终结构关键子部件的结构完整性。结果表明,我们的机械设计适合于开发一种能够在不同地面位置和地形上有效导航的主动悬浮机器人。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Multi-terrain Quadrupedal-wheeled Robot Mechanism: Design, Modeling, and Analysis
For a robot to navigate in terrains of rough and uneven topographies, its drives and controllers must generate and control large mechanical power with great precision. This paper is aimed at developing an autonomous robot with active-suspensions in form of a hybrid quadrupedal-wheel drive mechanism. This involves a computational approach to optimizing the development cost without compromising the system’s performance. Using the Solidworks CAD tool, auxiliary components were designed and integrated with the bed structure to form an actively suspended robot drive mechanism. Also, using the S-Math Computing tool, the robot’s suspension system was optimized, employing a four-bar mechanism. To enhance the compatibility of this design with the intended controller, some mathematical equations and numerical validations were formulated and solved. These included the modeling of tip-over stability and skid steering, the trendline equations for computing the angular positions of the suspension servomotors, and the computation of R2– values for determining the accuracy of these trendline equations. Using finite element analysis (FEA), we simulated the structural integrity of key sub-components of the final structure. The results show that our mechanical design is appropriate for developing an actively suspended robot that can efficiently navigate in different terrestrial sites and topographies.
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