面向协作机器人的力操纵规划

Tianyu Zhang, Hongguang Wang, Peng LV, Xin’an Pan, Huiyang Yu
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引用次数: 0

摘要

目的协作机器人(cobot)广泛应用于复杂工业环境中的各种操纵任务。然而,受任务、环境和关节物理限制的影响,协作机器人操纵规划的操纵能力有所下降,尤其是在受力性能方面。现有的运动规划方法需要更有效地解决这些问题。为了克服这些挑战,作者提出了一种新方法,名为面向 cobots 的力可操作性规划(FMMP)。设计/方法/途径该方法将力可操作性集成到双向采样算法中,从而在满足约束条件的同时规划出一系列具有高力可操作性的路径。在本文中,作者利用力可操作性椭球体(FME)的几何特性来确定适当的操纵配置。首先,作者将 FME 的主轴与机器人末端效应器的任务约束相匹配,以确定操纵姿势,确保在所需方向上产生更强的力。接下来,作者使用 FME 的体积作为采样算法的成本函数,提高了力的可操作性,避免了运动学奇异性。研究结果通过与现有算法的实验比较,作者验证了所提方法的有效性和优越性。为了提高操纵规划的受力性能,FMMP 在基于采样的路径规划中引入了 FME,并综合考虑了任务、环境和关节物理约束。所提出的方法在装配和现场测量等实验中表现令人满意。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Force manipulability-oriented manipulation planning for collaborative robot

Purpose

Collaborative robots (cobots) are widely used in various manipulation tasks within complex industrial environments. However, the manipulation capabilities of cobot manipulation planning are reduced by task, environment and joint physical constraints, especially in terms of force performance. Existing motion planning methods need to be more effective in addressing these issues. To overcome these challenges, the authors propose a novel method named force manipulability-oriented manipulation planning (FMMP) for cobots.

Design/methodology/approach

This method integrates force manipulability into a bidirectional sampling algorithm, thus planning a series of paths with high force manipulability while satisfying constraints. In this paper, the authors use the geometric properties of the force manipulability ellipsoid (FME) to determine appropriate manipulation configurations. First, the authors match the principal axes of FME with the task constraints at the robot’s end effector to determine manipulation poses, ensuring enhanced force generation in the desired direction. Next, the authors use the volume of FME as the cost function for the sampling algorithm, increasing force manipulability and avoiding kinematic singularities.

Findings

Through experimental comparisons with existing algorithms, the authors validate the effectiveness and superiority of the proposed method. The results demonstrate that the FMMP significantly improves the force performance of cobots under task, environmental and joint physical constraints.

Originality/value

To improve the force performance of manipulation planning, the FMMP introduces the FME into sampling-based path planning and comprehensively considers task, environment and joint physical constraints. The proposed method performs satisfactorily in experiments, including assembly and in situ measurement.

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