The present invention relates to a joint assembly (1) for a robot (100), comprising a housing (26) connected with an output part (8), the housing comprising a housing wall (26A), a strain wave gearing system (90) comprising a wave generator (7), a flexspline (13), and a circular spline (36) connected to the output part (8), wherein the wave generator (7) is rotated by a rotor shaft (3), the rotor shaft being driven by an electric motor (140) comprising a stator (15) and a rotor magnet (16), the rotor magnet (16) being affixed to the rotor shaft (3), and wherein the joint assembly (1) further comprises a rotor brake (30) configured to stop/prevent relative movement between the rotor shaft (3) and the flexspline (13), and sensors arranged to measure the position of the housing (26) in relation to the output part (8). Furthermore, the present invention also relates to a robotic arm (100) comprising a joint assembly according to the present invention and to the use of the joint assembly according to the present invention.

Joint coupling links of robot arm to each other includes: plurality of plate-shaped segments lined up in plate thickness direction; and operating wires extending through plurality of segments in plate thickness direction. Groove extending in second direction and having partially circular cross section is provided at first-direction middle portion of main surface out of two main surfaces of adjacent segments, two main surfaces facing each other in plate thickness direction. Projection extending in second direction and having partially circular cross section is provided at first-direction middle portion of main surface. Curvature of projection is larger than curvature of groove. Projection is fitted in groove, and bottom portion of groove and top portion of projection contact each other. Dimension of projection in plate thickness direction is larger than dimension of groove in plate thickness direction and smaller than length of line connecting bottom portion of groove and edge portion of groove.

A vertical articulated robot has a base installed on a mounting surface, a first axis supported parallel to the mounting surface by the base, a pivot frame rotatable by the first axis, a second axis supported orthogonal to the first axis by the pivot frame, a lower arm rotatable by the second axis, a third axis supported parallel to the second axis by an end of the lower arm opposite to the second axis, a connecting arm rotatable by the third axis, a fourth axis supported orthogonal to the second axis and third axis by the connecting arm, and an upper arm including a holding arm rotatable by the fourth axis, and the first axis enables the second axis, the lower arm, the third axis, and the upper arm to make a substantially vertical circular motion relative to the mounting surface.

Assembly equipment comprises a base, a first holding hand provided in a first robot arm set on the base, a second holding hand provided in a second robot arm set on the base, and a control device configured to control the first and second robot arms and the first and second holding hands. The first holding hand comprises an attachment connected to the first robot arm and having a rotation shaft, and an aligning holding mechanism provided in a rotation mechanism having a rotation shaft located to intersect the rotation shaft of the attachment or located in a skewed positional relationship with the rotation shaft of the attachment. A cooperative working area of the first and second holding hands is provided in an overlapping area where working areas of the first and second holding hands overlap with each other.

The present invention relates to a joint unit for an articulated connection of at least one first component and one second component. The joint unit comprises a joint body, in particular a sleeve-like joint body, connectable to the first component. A first joint element is arranged rotatably supported about a first axis of rotation in the joint body. The first joint element has at least one bearing section that receives a second joint element that is rotatably supported about a second axis of rotation and that is connectable to the second component.

Provided is a multi-joint robot which is capable of performing motion control and includes a part for easily setting a moving path, an angle, and the like of a take-out device in a process of taking out an injection-molded object. To this end, the present disclosure includes a molding part configured to mold an object, a multi-joint robot configured to move close to the molding part and take out the object, a first controller connected to the above work components and configured to control driving of the work components, a marker connected to the first controller and provided on each of joints of the multi-joint robot, and a camera part configured to photograph movement of the marker, and transmit movement information of the multi-joint robot according to the movement of the marker to the first controller, and an overrun detector is provided on at least one of the joints of the multi-joint robot to detect an overrun operation exceeding an operation range of a joint movement and transmit a warning signal about the overrun operation to the first controller. According to the present disclosure, even a low-skilled worker can easily set access and work of a worker at an injection molding site without performing coding, thus reducing a difficulty level of work and maximizing process efficiency, control whether to perform injection according to whether a door is open or not, thereby securing safety, and control quality and a take-out environment using environmental information received by the molding part.

The present disclosure provides a collaborative robot arm and a joint module. The joint module includes a housing, a driving assembly, and a multi-turn absolute encoder. The joint module detects the angular position of the output shaft and records a number of rotating revolutions of the output shaft only by means of the multi-turn absolute encoder. The multi-turn absolute encoder includes a base, a bearing, a rotating shaft, an encoding disk, and a circuit board, the encoding disk is rotatably connected with the base by the rotating shaft and the bearing, the circuit board is fixedly connected with the base, and the reading head on the circuit board detects the angular position of the output shaft cooperatively with the encoding disk, making the multi-turn absolute encoder be an integrated structure. The base and the rotating shaft are detachably connected with the housing and the output shaft respectively.

A bidirectional pivoting joint comprises pivoting elements which are rotatable relative to one another, specifically in a coaxial arrangement, a cylindrical outer body and a cylindrical inner body and a locking device optionally locking and releasing the rotational movement. The locking device has an annular space between the outer body and the inner body. Provided between annular space surfaces, specifically an inner surface of the outer body and an outer surface of the inner body are radially narrowing and, on the other hand, radially wider, peripheral regions in alternating arrangement. Arranged in the annular space are at least two clamping members which are each adjustable in cross-section in the peripheral direction (u) of the annular space. In a holding state, each clamping member has a first said cross-section and lies in the narrowing peripheral regions against the outer body and the inner body. By this means, a self-holding clamping connection is established which blocks the relative rotational movement between the outer body and the inner body in each rotation direction (d). In a releasing state, each clamping member has a second said cross-section by means of which the clamping connection is released in order to free the rotational movement. An actuating device of the pivoting joint is equipped with an actuating means which acts on the clamping members to establish, firstly, the holding state and, secondly, the releasing state. A holding and positioning device comprises a plurality of said pivoting joints.

The subject matter of this specification can be embodied in, among other things, a multi-axis rotary actuator that includes a first rotary piston actuator configured to controllably actuate a first pivotal joint between a first linkage to a second linkage about a first axis, and a second rotary piston actuator configured to controllably actuate a second pivotal joint connecting the second linkage to a third linkage about a second axis.

The subject matter of this specification can be embodied in, among other things, a fluid actuator including a housing defining a first chamber having a first cavity and a first open end, a first piston assembly including a tubular first piston defining a second chamber having a second cavity and a second open end, disposed in said first housing for reciprocal movement in the first chamber through the first open end, wherein a first seal, the first cavity, and the first piston define a first pressure chamber, and a second piston assembly having an second piston disposed in said first piston assembly for reciprocal movement in the second chamber through the second open end, wherein a second seal, the second cavity, and the second piston define a second pressure chamber, and a first portion of the second piston contacts a first end effector.