Abstract
The demand for redundant hydraulic manipulators that can implement complex heavy-duty tasks in unstructured areas is increasing; however, current manipulator layouts that remarkably differ from human arms make intuitive kinematic operation challenging to achieve. This study proposes a seven-degree-of-freedom (7-DOF) redundant anthropomorphic hydraulically actuated manipulator with a novel roll-pitch-yaw spherical wrist. A hybrid series-parallel mechanism is presented to achieve the spherical wrist design, which consists of two parallel linear hydraulic cylinders to drive the yaw/pitch 2-DOF wrist plate connected serially to the roll structure. Designed as a 1RPRRR-1SPU mechanism (“R”, “P”, “S”, and “U” denote revolute, prismatic, spherical, and universal joints, respectively; the underlined letter indicates the active joint), the 2-DOF parallel structure is partially decoupled to obtain simple forward/inverse kinematic solutions in which a closed-loop subchain “RPRR” is included. The 7-DOF manipulator is then designed, and its third joint axis goes through the spherical center to obtain closed-form inverse kinematic computation. The analytical inverse kinematic solution is drawn by constructing self-motion manifolds. Finally, a physical prototype is developed, and the kinematic analysis is validated via numerical simulation and test results.
Highlights
1.1 BackgroundMulti-degree-of-freedom robotic manipulators have been widely adopted to replace humans and perform dangerous tasks in hazardous environments
Given the existence of numerous heavy-duty tasks, hydraulic robotic manipulators (HRMs) with complex DOFs have been widely used in mobile areas [2], such as in construction, rescue, and exploration [3,4,5]
Li et al [9] developed a 7-DOF HRM for industrial manufacturing; this HRM consisted of five revolute joints and two prismatic ones
Summary
Multi-degree-of-freedom (multi-DOF) robotic manipulators have been widely adopted to replace humans and perform dangerous tasks in hazardous environments. Given the existence of numerous heavy-duty tasks, hydraulic robotic manipulators (HRMs) with complex DOFs have been widely used in mobile areas [2], such as in construction, rescue, and exploration [3,4,5]. Kivelä et al [7] from Tampere University in Finland designed an 8-DOF hydraulic manipulator for the International Thermonuclear Experimental Reactor and found that its redundancy feature was beneficial for optimizing the execution of remote handling tasks. Liang et al [8] designed a 7-DOF HRM with seven revolute joints for rescue areas during natural disasters. On the basis of the aforementioned literature, HRM redundancy contributes to solving constraint problems due to complex surrounding environments
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