In a link actuating device, a distal end side link hub is coupled to a proximal end side link hub via three or more link mechanisms. A posture control drive source configured to arbitrarily change the posture of the distal end side link hub is provided to each of two or more link mechanisms. The link actuating device includes a storage unit configured to store therein an operating position of the posture control drive source when the distal end side link hub is in a defined posture. In each of the two or more link mechanisms, a positioning portion is provided to at least one of the proximal side end link member, the distal side end link member, and the intermediate link member. A positioning member configured to position the distal end side link hub in the defined posture is dismountably mounted between a plurality of the positioning portions.

A conveying robot/system configured to: (i) operate within limitations of spaces defined by shelving, (ii) remove or place an object in spaces defined by shelving and (iii) enable an object to be automatically placed at a conveying-in position of a conveying processing system and manipulate the object's posture so that the object's posture changes from the object being conveyed to the object being processed. The system includes one or more of a robot hand with a grasping portion, articulated link mechanism, object placing shelf, box body, key and a lock. In one version, the box body is a bill storage container of the type used to store currency, coupons and tickets in electronic gaming devices located in a casino environment.

A leg assembly for a legged robot includes first through three motors, first through second legs, and a transmission component. The first motor is coupled to the second motor to drive the second motor to rotate, and a rotation axis of the first motor is substantially orthogonal to a rotation axis of the second motor. The second motor is coupled to the third motor to drive the third motor to rotate, and a rotation axis of the third motor substantially coincides with the rotation axis of the second motor. The third motor is arranged at a first end of the first leg, the second leg is pivotably coupled to a second end of the first leg, and the transmission component is coupled to an output shaft of the third motor and the second leg to drive the second leg to rotate relative to the first leg.

An agricultural robot includes a machine body, a wheeled traveling device to support the machine body such that the machine body is capable of traveling, the traveling device including at least three wheels, a manipulator including an arm and a robot hand, the arm being attached to the machine body, the robot hand being attached to the arm and capable of holding an object, and a balance controller to control positions of the at least three wheels, respectively, to achieve a balance between the machine body and the manipulator.

This transfer device is a transfer device which transfers an object to be transferred and includes a pivoting arm supported by a frame and configured to be rotatably driven around a pivot axis, a main arm which is rotatably connected to the pivoting arm and to which a support part which supports the object to be transferred is connected at a distal end portion, and an inclination adjustment part which is slidably connected to the main arm in a longitudinal direction of the main arm and has a parallel link mechanism to adjust an inclination of the main arm.

A manipulator system having a positioner having a primary rail, a first coupling linkage, and a second coupling linkage. The first coupling linkage couples the primary rail to a base and positions the primary rail along a first plane. The system has another positioner having a secondary rail, a third coupling linkage, and a fourth coupling linkage. The third coupling linkage couples the secondary rail to the base and positions the secondary rail along a second plane which is parallel to the first plane. A common link couples to the primary and secondary rails via linkages. Each of the second and fourth coupling linkages includes a joint for linear motion along the respective rail, and a revolute joint for relative pivoting between the respective rail and the common link. A position and orientation of the common link are adjustable by the joints and revolute joints.

The present invention relates to a method and system for optimizing the joint hinge point position of a hydraulic tandem mechanism based on lightweight. The method comprises: determining rotational load characteristics of each joint in the hydraulic tandem mechanism using dynamics simulation software based on said end load characteristics and said structural parameters of the tandem mechanism; establishing a fixed coordinate system between two adjacent rods in each joint and a joint global coordinate system, and determining the relationship between hinge point coordinates, joint rotation angle and joint drive force arm of each joint; calculating linear load characteristics of each joint according to said rotational load characteristics and said joint drive force arm to calculate hydraulic cylinder structural parameters and hydraulic oil source flow rate for each joint; determining a lightweight index for the joint hinge point position of the hydraulic tandem mechanism according to said hydraulic cylinder structural parameters and said hydraulic oil source flow rate; solving the coordinates of each joint hinge point of the tandem mechanism corresponding to the minimum of said lightweight index, using said lightweight index as a fitness function, so that the overall weight of the tandem mechanism is minimized.

An embodiment joint structure for a robot includes an upper plate provided in an upper region, a link part coupled to a lower surface of the upper plate, wherein the link part includes a first link and a second link, and wherein the first link and the second link are provided close to one side of the upper plate with respect to a center of the lower surface of the upper plate, a support part coupled to the lower surface of the upper plate and configured to support the upper plate, wherein the support part is provided to be closer to the center of the lower surface of the upper plate than is the link part, and a motor part configured to provide power to the support part and the link part.

A robot system with a hand-guiding function is disclosed. The robot system selects the hand-guiding function or non-hand-guiding function of an enable device by a mode option mechanism during the operation of a teach mode or an automatic mode. When selecting the hand-guiding function, the enable device has both the enabling and the hand-guiding function to easily hand-guiding the robot to operate.

A powered user interface for a robotic surgical system includes a base, a handle mounted to the base and moveable relative to the base in at least six degrees of freedom, and actuators. The interface operates in accordance with a first mode of operation in which the actuators are operated to constrain predetermined ones of the joints to permit motion of the handle in only 4DOF with respect to the base, and a second mode of operation in which the actuators permit motion of the handle in at least 6DOF with respect to the base.