Parallel Link Manipulator Research Articles

Development of Hexa type parallel link manipulator for underwater assembly

Development of Hexa type parallel link manipulator for underwater assembly

縦方向運動が簡易自動車模型に及ぼす動的効果

Dynamic effects on the pressure distributions around a sedan-type simplified automobile model were investigated by conducting forced oscillation tests in a wind tunnel. HEXA, an original 6-DOF parallel-link manipulator was used to impose heaving and pitching motions on the model and unsteady pressure distributions over the model surfaces were measured with the effects of the ground plate. The obtained results show that dynamic effects become prominent mainly on the front side of the model underfloor and change depending on the Strouhal number. The effects were mostly consistent to those predicted by the quasi-steady model, but the pressure ports near the far front side of the model showed different behaviors. It is suggested that these observations are related to the local separation regions found in surface-flow visualization tests.

Analysis of a novel lifting mechanism for forging manipulators

In this paper, a hybrid serial–parallel forging manipulator was put forward, which is composed of a planar five-bar mechanism and a two-limb parallel mechanism in series. Forging manipulator’s DOF properties and motion principle were analyzed by means of screw theory. The position solution of the main motion mechanism of manipulator was derived in the grasping stage, which was used to solve input displacements of lifting and pitching hydraulic cylinders depending on the requirements of forged piece’s lifting height and pitching angle. Dimensional optimization of the manipulator’s main motion mechanism is carried out based on position equations, resulting in that the gripper carrier’s lifting motion was decoupled from the horizontal motion. The analytical expression between driving forces of each hydraulic cylinder and external load was derived by solving the first-order derivative of position equations and using principle of virtual work. The results showed that for the parallel-link manipulator, when gripper carrier is horizontal, driving force of lifting hydraulic cylinder is only related to forged piece’s gravity but not to gravitational moment. The mechanism of this phenomenon was also further studied. Experimental model with ratio 1:20 of forging manipulator’s lifting mechanism was developed, and kinematic and static experiments were conducted on it to verify the dimensional optimization results and the conclusion was obtained by the statics.

10705 インパクトドライブ機構を利用した6軸パラレルリンクマニピュレータの制御

10705 インパクトドライブ機構を利用した6軸パラレルリンクマニピュレータの制御

Development and Evaluation of Miniaturized 6-DOF Parallel Link Manipulator

Recently, compact machine tools have witnessed increased demand in the manufacture of small parts with high accuracy. However, miniaturization of these machines poses problems such as decrease in the accuracy and the range of motion. We focused on miniaturizing a parallel link manipulator, which is known to have high rigidity and accuracy. A non-cylindrical link was adopted in the designed manipulator for avoiding collisions among links with an impact drive actuator attached to their side. We confirmed through repeatability measurements that the developed manipulator had sufficient accuracy for handling small electronic parts.

Visual Feedback PID Control for 2DOF Parallel Link Manipulator

This paper investigates the visual feedback control for 2DOF(degrees of freedom) parallel link manipulator with zero steady-state error. Firstly we present the model of visual feedback system of the eye-in-hand configuration. Secondly we consider a novel desired joint angle defined by visual information and joint angles based on the structure of the parallel link, because a desired joint angle cannot be given as a standard robot motion control system. Next we propose the PID control law for the visual feedback system in order to overcome steady-state error with respect to the uncertainty of the position and the orientation for the base frame. For the proposed control law, stability analysis of the closed loop system is discussed in the sense of Lyapunov method with a sufficient condition for the feedback gains. Finally the experimental results are shown in order to confirm the validity of the proposed method by comparing with a previous visual feedback control law.

1101 インパクトドライブ機構を用いた6軸パラレルリンクマニピュレータの製作(機構の開発,一般講演)

1101 インパクトドライブ機構を用いた6軸パラレルリンクマニピュレータの製作(機構の開発,一般講演)

High-Backdrivable Parallel-Link Manipulator with Continuously Variable Transmission Mechanism

High-Backdrivable Parallel-Link Manipulator with Continuously Variable Transmission Mechanism

Bio-mimetic walking with distributed controlled wave gait

This paper describes a multi-agent mobile system that walks. In particular, the gate of the system can be considered as an expansion of the ordinary wave gate, since the class of system configuration is not restricted in a line shape. The system consists of a number of identical units with distributed controllers. The homogeneous units are mechanically connected to construct a mobile platform. Every unit has its local controller that communicates only with its adjacent units. This basic configuration of supervisor-less structure affirmatively confines the dependence of each unit to a local area, and therefore any unit can be removed from/add into any part of a system regardless of the timing without disturbing the performance of the whole system. This flexibility of configuration significantly contributes to easy maintenance of units, such as battery charging or hot-replacing for faulty units. Utilizing the flexibility as well, the system is capable of adapting to a variety of tasks including transportation application and to target objects having various kinds of shape and/or a wide range of mass. A proposed example unit contains a Gough-Stewart Platform, a symmetrical type of parallel link manipulator, as its leg. The whole mobile system is aimed at transportation platform, with high system flexibility, i.e., the system is able to adapt to wide range of target objects. The “digital actuation (D-actuation)” concept is applied to the local unit controller. D-actuation is a concept to drive a mechatronic system with numbers of “digital actuator (D-actuator)” that has only discrete stable states, such as pneumatic cylinders or solenoids. D-actuation yields great benefits: high repeatability, system simplicity, and low cost. Because of the simplicity of the communication data, the control strategy, and the concept of D-actuation, the controlling framework can be implemented as distributed and localized one on every unit. The Schlafli symbol is applied to denote the system configurations. For example, two-dimensional honeycomb like connection of the units is denoted as {3,6}. A simple, but effective, coordinate system, HC/P (HoneyComb by Projection), is introduced to denote the connecting relations among the units in the {3,6} system. In short, HC/P utilizes three-axes to describe 2D system, and the redundant triplet notation enables direct and clear computation regarding unit coordinates. The basic architecture of the unit mechanism and gait controller are justified with simulation results. The performed simulation shows the feasibility of the whole mobile system.

1215 マルチ駆動リニアモータを用いたパラレルメカニズムの機構解析(GS-13・15 パラレルメカニズムの機構と制御)

1215 マルチ駆動リニアモータを用いたパラレルメカニズムの機構解析(GS-13・15 パラレルメカニズムの機構と制御)

1A1-G20 非円形プーリーバネ系による自重補償機構 : パラレルリンクマニピュレータへの適用(映像,作業をするロボット)

We propose a new weight compensation mechanism with a non-circular pulley and a spring. We show the basic principle and numerical design method to derive the shape of the non-circular pulley. After demonstration of the weight compensation for an inverted/ordinary pendulum system, we extend the same mechanism to a parallel link manipulator, analyzing the required torques with Jacobian matrices. Finally, we carry out hardware experiments.

A fingertip guiding manipulator for mental image creation of multi-stroke drawings

Authors developed an improved fingertip guiding manipulator that helps visually handicapped persons create mental images of relief sculptures. The manipulator has three functions: (1) an indicating function of knob-moving-direction by a stepping-motor attached at the arm end, (2) a fingertip traction function by a quadrilateral parallel link manipulator, and (3) a fingertip up-down motion function by a linear motion actuator. The former two functions are utilized to represent planer 2D figures, and the last one is to represent the relief sculpture representation together with the former two. Some preliminary experiments were carried out, and the human perceptual thresholds with the up-down motion and the fingertip rotation, and the human kinesthetic following performance were clarified. These thresholds shall be used as the back data for designing mechanical specifications of the proposed fingertip guiding manipulator.

Networked Telemicromanipulation Systems “Haptic Loupe”

In this paper, "Haptic Loupe" telemicromanipulation systems are proposed. We have developed telemicromanipulation systems that enable human operators to perform micro tasks, such as assembly or manufacturing without stress . These systems are based on a scaled bilateral teleoperation system between different structures. The systems are composed of an original six-degrees-of-freedom (6-DOF) parallel link manipulator to carry out micromanipulation and a 6-DOF haptic interface with force feedback. A parallel mechanism is adopted as a slave micromanipulator because of its good features of accuracy and stiffness. The haptic master interface is developed for micromanipulation systems. Haptic device system modeling and a model reference adaptive controller are implemented to compensate for friction forces, which spoil the free motion performance and force response isotropy of the system. Total system performance as a telemicromanipulator system is evaluated by performing some primitive manipulation tasks in a teleoperation experiment. Experimental results are presented and discussed.

パラレルマニピュレータのヤコビ行列の特性を活かした順運動学計算法と制御系の提案および安定性解析

In this paper, we propose a design method of task coordinated feedback control law for parallel link manipulators (PLMs) . In general, since it is the last purpose to control the coordinates of an End-effector by a manipulator's control, a task coofdinated feedback control suits the purpose rather than a joint coordinated one. However, control with a parallel link manipulator's work coordinates has the following two problems which should be solved. First, it is difficult for PLMs to have the information of task coordinate from joint infomation, though it is easy for serial link manipulators to do this. Second, it is necessary to calculate the Inverse Matrix of Jacobian for calculating Driving force of a joint. In this paper, we propose a novel solving method of forward kinematics problem for PLMs and construct a task coordinated feedback control which used the character of Jacobian and made calculation easy. Then we prove the stability of this control system and verify the validity by the simulation and experiment.

指先誘導マニピュレータによるメンタルイメージ生成支援(J22-1 センサ・アクチュエータシステムとその知能化(1),J22 センサ・アクチュエータシステムとその知能化-実環境で活躍するメカトロニクスを目指して)

A mental image creation support system was developed. The mechanical device of the system is a 3-DOF manipulator that is*composed of a 2-DOF quadrilateral parallel-link manipulator and an arm-end actuator. A couple of servomotors of the 2-DOF manipulator control the arm-end position. The arm-end actuator controls the orientation of a knob attached to the servomotor axis. The person is assumed to pinch the knob by his/her fingertips. The position of the knob axis traces the strokes of the presented figures sequentially, and the orientation of the knob is .controlled to indicate the orientation of the currently tracing point on the stroke. A couple of preeminent functions are embedded to the process: one is the indicating function, and the other is the leading function. That is, the knob indicates to the person with its orientation to which direction the arm end moves: the direction reflects the orientation of the ongoing stroke. And the translation of the knob leads the person along the strokes. The indicating/leading functions play complementary role.

2A1-3F-E5 パラレルリンクマニピュレータの作業座標フィードバック制御

パラレルリンクマニピュレータの作業座標での制御は順運動学計算と関節駆動力を求める際のヤコビ逆行列の計算のため煩雑となる。本論文では計算効率を改善した作業座標制御系の設計法を提案し, 実験により有効性を示す。

Implementing Fuzzy Learning Algorithms in a 6 DOF Hydraulic Parallel Link Manipulator: Control with Actuators’ Forces Fuzzy Compensation

This paper proposes fuzzy compensation for actuators’ motion forces, (dynamics, gravity and friction) in a force/motion control algorithm for the assembly of segments of a shield tunnel excavation applying a 6 DOF hydraulic parallel link manipulator. First, we introduce the feedback force/motion control algorithm with fuzzy forces compensation. Then, we introduce a rule-base fuzzy compensating model and its real-time implementation for every hydraulic actuator of a Stewart Platform so that we can reduce the effect of friction forces and hence improve the quality of force control and assembly. The experimental results of the control system with and without fuzzy compensation are presented, which show a good achievement in contact force estimation and manipulator motion utilizing the proposed fuzzy compensation.

Implementing Fuzzy Learning Algorithms in a 6 DOF Hydraulic Parallel Link Manipulator: Actuators' Fuzzy Modeling

A fuzzy-logic-based model, suitable for force control, for each hydraulic actuator of a parallel link manipulator is presented. Constructing the fuzzy model rule base mainly consists of 2 stages: (1) learning rules from examples for the known acquired input/output data of the hydraulic actuators and (2) completing unknown fuzzy rules from heuristics and experience based on the logic of actuators' behavior. We first present the algorithm of fuzzy-rule base modeling and its application for one actuator. We then present fuzzy rule base results characterizing each hydraulic actuator, differing from one to another, of a 6 DOF parallel link manipulator. Simulation output results from fuzzy models show good agreement with experimental results.

1026 3 リンク 6 自由度パラレルリンクロボットの PTP (Point to Point) 制御

1026 3 リンク 6 自由度パラレルリンクロボットの PTP (Point to Point) 制御

Observer-Based Optimal Control of Flexible Stewart Parallel Robots

The design and simulation of two optimal control schemes for a parallel flexible link manipulator of the Stewart type is presented. The first control scheme combines a nonlinear rigid model of the flexible manipulator with a linear rigid observer, whereas the second scheme uses a nonlinear flexible manipulator model with a linear flexible observer. The majority of the results available in the literature do not address the optimal control problem through the use of observers, as it is done in this paper, for the control of parallel robots. The simulation results have shown in both cases that indeed optimal state-obscrver-based control is a good candidate for controlling parallel-link manipulators in practice. As expected, the second scheme (flexible model plus flexible observer) gives better results than the first one, achieving faster trajectory tracking. The effects of white noises, applied forces, and zero gravity environment were taken under consideration.