Abstract
This study aimed to develop a novel 3D parallel mechanism robot driven by three vertical-axial pneumatic actuators with a stereo vision system for path tracking control. The mechanical system and the control system are the primary novel parts for developing a 3D parallel mechanism robot. In the mechanical system, a 3D parallel mechanism robot contains three serial chains, a fixed base, a movable platform and a pneumatic servo system. The parallel mechanism are designed and analyzed first for realizing a 3D motion in the X-Y-Z coordinate system of the robot’s end-effector. The inverse kinematics and the forward kinematics of the parallel mechanism robot are investigated by using the Denavit-Hartenberg notation (D-H notation) coordinate system. The pneumatic actuators in the three vertical motion axes are modeled. In the control system, the Fourier series-based adaptive sliding-mode controller with H∞ tracking performance is used to design the path tracking controllers of the three vertical servo pneumatic actuators for realizing 3D path tracking control of the end-effector. Three optical linear scales are used to measure the position of the three pneumatic actuators. The 3D position of the end-effector is then calculated from the measuring position of the three pneumatic actuators by means of the kinematics. However, the calculated 3D position of the end-effector cannot consider the manufacturing and assembly tolerance of the joints and the parallel mechanism so that errors between the actual position and the calculated 3D position of the end-effector exist. In order to improve this situation, sensor collaboration is developed in this paper. A stereo vision system is used to collaborate with the three position sensors of the pneumatic actuators. The stereo vision system combining two CCD serves to measure the actual 3D position of the end-effector and calibrate the error between the actual and the calculated 3D position of the end-effector. Furthermore, to verify the feasibility of the proposed parallel mechanism robot driven by three vertical pneumatic servo actuators, a full-scale test rig of the proposed parallel mechanism pneumatic robot is set up. Thus, simulations and experiments for different complex 3D motion profiles of the robot end-effector can be successfully achieved. The desired, the actual and the calculated 3D position of the end-effector can be compared in the complex 3D motion control.
Highlights
Industrial robots are widely used in automobile, mechanical, semiconductor, electronic, and food and beverage industries, and have gradually replaced the labor force [1]
High response, high accuracy and good stiffness are in demand for robots in many applications so parallel type robots have become more popular in industrial automation due to their serial type robot advantages, i.e., high stiffness, high motion accuracy and high load-structure ratio [6,7]
A novel 3D parallel mechanism robot driven by three vertical pneumatic servo actuators combined with a stereo vision system was developed and implemented experimentally for complex 3D path tracking control in a full-scale test rig
Summary
Industrial robots are widely used in automobile, mechanical, semiconductor, electronic, and food and beverage industries, and have gradually replaced the labor force [1]. Serial type robots have some intrinsic disadvantages such as lower position accuracy affected by the error superposition of each joint and link, slower response due to the series mechanism and poor stiffness for handling heavier loads. Parallel type robots which have the end-effector connected to a fixed base by multiple kinematic chains have high ratios of rigidity to weight, high stiffness, high accuracy, high response and good ability to carry heavier loads. High response, high accuracy and good stiffness are in demand for robots in many applications so parallel type robots have become more popular in industrial automation due to their serial type robot advantages, i.e., high stiffness, high motion accuracy and high load-structure ratio [6,7]. The position of the end-effector of robot is calculated by the position sensors of the actuators through kinematic analysis, but the calculated 3D position of the end-effector cannot consider the manufacturing and assembly tolerance of the joints and the parallel mechanism so that errors exist between the actual position and the calculated 3D position of the end-effector, influencing the position accuracy of the robot end-effector [8]
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