A work apparatus includes a parallel link mechanism, a position control actuator, a linear motion mechanism, and a rotating mechanism. The parallel link mechanism includes three or more link mechanisms that couple a distal end side link hub to a proximal end side link hub such that a position of the distal end side link hub can be changed relative to the proximal end side link hub. The position control actuator operates the parallel link mechanism. The linear motion mechanism moves a working body in an axial direction orthogonal to a central axis of the proximal end side link hub. The rotating mechanism is mounted on the distal end side link hub and rotates a work object about a rotation center axis parallel to a movement direction of the linear motion mechanism when the central axis and a central axis are on the same line.

Disclosed is a two-turn-one-movement parallel mechanism with a large turning angle, comprising a machine frame, a movable platform, a first branch and two second branches, characterized in that the first branch comprises a machine frame turning pair, a first moving pair slider, a first moving pair guide rod and a first universal joint; each one of the second branches comprises a second moving pair guide rail, a second moving pair slider, a second universal joint, a connecting rod and a movable platform turning pair; in the two second branches, the axis of the first turning pair of each one of the second universal joints is superimposed with and parallel to the axis of the machine frame turning pair in the first branch, and the axis of each one of the movable platform turning pairs is parallel to the second turning axis of the first universal joint in the first branch.

Joints for facilitating relative motion between a first part of a machine, such as a robot, and a second part of the machine may include linear actuators connecting the first part to the second part and a shaft member connecting the first part to the second part. Each of the linear actuators may be oriented at an oblique angle relative to the shaft member. The first and second parts of the machine may be parts of a robotic arm, such as other robotic joints or an end-effector, such as a robotic hand. The joints may facilitate simulation of the movement and dexterity of human body parts, such as a human wrist and forearm.

A parallel-type micro robot capable of precise control while minimizing size thereof and a surgical robot system having the same are disclosed. The parallel-type micro robot includes a base plate, a work plate, a main fixing shaft module, a horizontal movement module and at least one angle-controlling module. The base plate includes a base body portion and at least one base connecting portion connected to the base body portion. The work plate includes a work body portion corresponding to the base body portion and at least one work connecting portion connecting to the work body portion to correspond to the base connecting portion. The main fixing shaft module is disposed between the base body portion and the work body portion, and coupled to the work body portion such that the work body portion is rotatable. The horizontal movement module is disposed between the main fixing shaft module and the base body portion, and moves the main fixing shaft module along first and second directions intersecting each other. The angle-controlling module is coupled to the base connecting portion such that the base connecting portion is rotatable, is coupled to the work connecting portion such that the work connecting portion is rotatable, and allows translational motion between the base connecting portion and the work connecting portion. Thus, a size of a robot may be minimized while improving the structural stability and precise control.

A series-parallel movable heavy-load casting robot, includes a four-driving-wheel type moving platform, a rotating device, an upright assembly, a lifting drive device, a parallel working arm, an end actuator and a binocular vision system. The four-driving-wheel type moving platform is driven by adopting four omnidirectional wheels, the platform utilizes rear hydraulic supporting legs and adjustable hydraulic supporting legs to implement stationary point self-balancing supporting, and a robot body has five freedom degrees of motion in space; and the rotating device and the lifting drive device can respectively implement rotating and lifting adjustment, the four-degree-of-freedom parallel working arm can carry out attitude adjustment for the end actuator, different end actuators can be changed according to working requirements.

The present invention introduces a new concept of applying a parallel mechanism in automated fiber placement for aerospace part manufacturing. The proposed system requirements are 4DOF parallel mechanism consisting of two RPS and two UPS limbs with two rotational and two translational motions. Both inverse and forward kinematics models are obtained and solved analytically. Based on the overall Jacobian matrix in screw theory, singularity loci are presented and the singularity-free workspace is correspondingly illustrated. To maximize the singularity-free workspace, locations of the two UPS limbs with the platform and base sizes are used in the optimization which gives a new design of a 4DOF parallel mechanism. A dimensionless Jacobian matrix is also defined and its condition number is used for optimizing the kinematics performance in the optimization process. A numerical example is presented with physical constraint considerations of a test bed design for automated fiber placement.

An industrial robot with parallel kinematics includes a robot base, an effector carrier receiving an effector, a first actuating arm, a second actuating arm, and a third actuating arm, wherein each actuating arm is driven at one end and is received on the robot base and is movably connected with its other end to the effector carrier. The actuating arms are adapted to move the effector carrier translationally in three dimensions in space relative to the robot base. The first actuating arm and the second actuating arm are connected to the effector carrier via lower arm joints. All lower arm joints of the first and second actuator arms lie in an effector carrier plane. The effector carrier is secured against rotation about a z-axis perpendicular to the effector carrier plane by the third actuating arm.

A parallel kinematics robot includes a base and an end effector movable in relation to the base. A first actuator is attached to the base and connected to the end effector via a first kinematic chain including a first drive arm, a first rod, a first joint between the first drive arm and the first rod, and a second joint between the first rod and the end effector. A second actuator is attached to the base and connected to the end effector via a second kinematic chain including a second drive arm, a second rod, a third joint between the second drive arm and the second rod, and a fourth joint between the second rod and the end effector. A third actuator is attached to the base or to the first drive arm, and connected to the end effector via a third kinematic chain including a first gear wheel and a second gear wheel, the first and second gear wheels being journalled in bearings to the end effector and intermeshing with each other. One element of the third kinematic chain constitutes a kinematic pair with at least one element of the first kinematic chain. A kinematic chain responsible for a translational movement of the end effector is utilized as a support structure for a kinematic chain responsible for a rotational movement of the end effector.

A movable hybrid machining robot is provided based on a three-degree-of-freedom force-controlled parallel module. In one example, the robot comprises: an automated guided vehicle (III-11) configured to ensure a large moving stroke of the robot; a linear guide rail (III-12) configured to control movement of the hybrid robot when the automated guided vehicle (III-11) is parked; a planar two-degree-of-freedom hybrid robotic arm configured to control in-plane two-degree-of-freedom motion, wherein the in-plane two-degree-of-freedom motion is driven by a motor on a base (21); and a three-degree-of-freedom, force-controlled parallel machining module (I) configured to control one translational degree of freedom and two rotational degrees of freedom and to control positive pressure on an end effector (564).

Disclosed is a two-turn-one-movement parallel mechanism with a large turning angle, comprising a machine frame, a movable platform, a first branch and two second branches, characterized in that the first branch comprises a machine frame turning pair, a first moving pair slider, a first moving pair guide rod and a first universal joint; each one of the second branches comprises a second moving pair guide rail, a second moving pair slider, a second universal joint, a connecting rod and a movable platform turning pair; in the two second branches, the axis of the first turning pair of each one of the second universal joints is superimposed with and parallel to the axis of the machine frame turning pair in the first branch, and the axis of each one of the movable platform turning pairs is parallel to the second turning axis of the first universal joint in the first branch.