Study on the structural function and motion performance of pneumatic flexible tree-climbing robot.

To enhance the adaptability of tree-climbing robots to changes in tree diameter and load capacity, an "I-shaped" pneumatic flexible tree - climbing robot was designed using self-developed pneumatic flexible joints and retractable needle anchors. The robot consists of an upper waist, a lower waist, a front leg, a rear leg, a load plate, and anchors. Through pneumatic driving, it can achieve efficient and stable driving during tree - climbing and stable grasping trees of varying diameters. Static mechanical models of waist and leg joints were established, the deformation characteristics of joints under different pressures were obtained, and relevant experimental verification was carried out. The kinematic analysis of the robot was performed using a 3D motion capture system, and the motion performance of the robot was obtained under different air pressures, tree diameters, tree inclination angles, and load conditions. The experimental results show that, according to the gait planning and its control sequence for climbing trees, the robot can carry loads to complete functions of climbing upwards, climbing downwards, and crossing obstacles at different inclination angles by alternately coordinating waist deformation and leg clamping through the air pressure control system. The robot can adapt to climbing different types of trees with diameters ranging from 146.4 mm to 292.8 mm, and its maximum load capacity is 2.0 kg. When encircling a tree with a diameter of 290 mm, the maximum horizontal climbing speed in the no-load state is 43.8 mm/min, and the maximum upward climbing speed when climbing vertically is 27 mm/min, while the maximum downward climbing speed is 63 mm/min.