An apparatus for coupling a robot arm to a tool that is suspended by an ergonomic arm capable of supporting 3D motion of the tool within a working volume. The apparatus includes a tool sleeve configured to accept the tool, a freely rotating rotary fitting coupled to the tool sleeve, and a coupling that couples a distal end of the robot arm to the rotary fitting. When the tool is inserted into the tool sleeve, the tool is free to rotate around the rotational axis with respect to the robot arm, such that a motion of the distal end of the robot arm does not impose a torque between the robot arm and the tool around the rotational axis, and such that motion of the distal end of the robot arm repositions or reorients the tool within at least a portion of the working volume.

A first driving device includes a motor including a rotating shaft, a speed reducer, and a supporting member. The speed reducer includes a rigid gear, a flexible gear configured to partially mesh with the rigid gear, and a wave motion generator coupled to the rotating shaft and configured to come into contact with the inner circumferential surface of the flexible gear, bend the flexible gear, and move a meshing position of the rigid gear and the flexible gear in the circumferential direction. The wave motion generator includes a projecting section projecting along the rotating shaft. The rotating shaft is supported by the supporting member via a bearing including an inner ring and an outer ring. The outer ring of the bearing is supported by the supporting member. The rotating shaft and the projecting section are coupled to the inner ring of the bearing by tight fitting.

In the link operating device, a distal-end-side link hub is connected to a proximal-end-side link hub so as to be changeable in position relative thereto via at least three link mechanisms. Each link mechanism includes a proximal-side end link member, a distal-side end link member, and a center link member. Position-controlling actuators and speed reduction mechanisms are provided to two or more of the link mechanisms. The proximal-side end link member includes a bent portion and a pair of rotational connection bodies disposed at one end of the bent portion. The speed reduction mechanism is disposed between the pair of rotational connection bodies, and includes an output shaft fixed to one of the rotational connection bodies, and an input shaft rotatably supported by the other one of the rotational connection bodies.

An apparatus for coupling a robot arm to a tool that is suspended by an ergonomic arm capable of supporting 3D motion of the tool within a working volume. The apparatus includes a tool sleeve configured to accept the tool, a freely rotating rotary fitting coupled to the tool sleeve, and a coupling that couples a distal end of the robot arm to the rotary fitting. When the tool is inserted into the tool sleeve, the tool is free to rotate around the rotational axis with respect to the robot arm, such that a motion of the distal end of the robot arm does not impose a torque between the robot arm and the tool around the rotational axis, and such that motion of the distal end of the robot arm repositions or reorients the tool within at least a portion of the working volume.

A workpiece transferring tool including a base mounted on a distal end of a wrist of a robot, a workpiece holder releasably holding a workpiece, and a movable connection unit connecting the workpiece holder to the base so that the workpiece holder is displaceable in an escape direction of an external force acting on the workpiece. This can prevent an excessively large external force from acting on the robot due to the workpiece and can prevent frequent accidental stop of the robot.

A leg structure of a quadruped robot includes a body and four separate leg modules. Each leg module includes a thigh motor assembly, a calf motor assembly, a hip joint motor assembly and an associated linkage and fixing base of the hip joint motor assembly. The hip joint motor drives the thigh and calf assembly through a parallelogram mechanism, the thigh motor assembly directly drives the thigh rod assembly, and the calf motor assembly drives the calf assembly through an anti-parallelogram mechanism. The joint motor assemblies are independent of each other and all the motor assemblies are modularized; the thigh and calf motor assemblies have a good ability to prevent external impact, and the joints on the robot body, formed by using the motor assemblies, have a large working space, thus ensuring the movement flexibility of the robot.

The disclosure discloses an electric-pneumatic hybrid-driving flexible manipulator with spring framework from plates of special-shaped thickness, including a screw shaft motor, an upper seat plate, guide coupling rods, linear bearings, a driving plate, a push plate, short push rods, connecting rods, a bottom seat plate, flexible fingers, a rotating finger holder, a long push rod, a small support, tension springs, single-head bellows muscles and a ridged push plate. The framework of the flexible fingers is a thickness special-shaped plate spring designed according to the principle of equal strength. In the disclosure, through the control of a motor, an angle between a finger knuckle and a grasped object can be adjusted to realize the adjustment of the position of a contact point. To adjust the position of the contact point of the grasped object, the acting point of the contact force and the direction of the acting force can be selected according to situations, so that the grasping is more accurate and reliable. At the same time, the angle between the finger knuckle and the grasped object can be adjusted to adapt to a larger change in size of the grasped object. In the disclosure, a pneumatic system is large in gain and the pneumatic bellows muscles are light, so that the response is quick and the buffering effect is good.

The present invention relates to the field of intelligent robots, and more particularly to a subunit module for constructing a modular robot. The subunit module includes a first housing and a second housing which are disposed oppositely. The first housing and the second housing are rotatable relative to each other. Each of the two housings is provided with a docking part. The docking part is used to mechanically and electrically connect other robot modules adjacent to it. The subunit module further includes a control circuit. The control circuit is used for communicating with other robot modules. The subunit module receives control signals from other robot modules to control the relative rotation of the first and second housings of the subunit module; and/or the subunit module receives an external force so that the first and second housings rotate relative to each other.

The invention relates to a joint unit that is reduced in size while being provided with a plurality of angle detection mechanisms. The joint unit includes an input-side support member that supports a rotationally driven input shaft, a decelerator that decelerates the input shaft to provide a deceleration output shaft, an output rotating body that is coupled to the deceleration output shaft, and includes a strain generating portion that generates strain due to rotation transmitted by the deceleration output shaft, and an associated rotating body that is coupled to a output-side portion of the strain generating portion of the output rotating body to rotate together with the output rotating body, and is disposed in a space between the input-side support member and an input-side portion of the strain generating portion of the output rotating body.

A robot includes a first joint and a second joint positioned on a base end side from the first joint. A first speed reducer is incorporated in the first joint. A second speed reducer is incorporated in the second joint. A volume proportion of a resin occupying a constituent member of the first speed reducer is larger than a volume proportion of a resin occupying a constituent member of the second speed reducer.