Systems and methods for a telescoping suction gripper assembly are provided. In one embodiment, a robotic system comprises: a robot comprising a robotic actuator and at least one robotic arm mechanically coupled to the robotic actuator; a telescoping suction gripper assembly comprising a telescoping member and a suction gripper mechanism, wherein a first end of the telescoping member is coupled to a vacuum supply conduit via a first flexible conduit member and a second end of the telescoping member is coupled to the suction gripper mechanism by a second flexible conduit member, and wherein the suction gripper mechanism is pivotally coupled to the at least one robotic; wherein the telescoping member is configured to adjust in length in response to the at least one robotic arm relocating the suction gripper mechanism from a first position to a second position.

A parallel link robot includes a plurality of drive units and link units each driven by the corresponding drive unit. Each of the drive units includes a motor, a transmission mechanism that transmits the rotation of the motor to the link unit, and a housing that holds the motor. The housing includes a first connection portion, a second connection portion, and an opening through which the link unit extends. The first connection portion of one of the drive units and the second connection portion of another of the drive units are connected to each other, while the second connection portion of the one of the drive units and the first connection portion of another of the drive units are connected to each other.

A construction system includes an excavator having a hydraulically controlled linkage and a hydraulic robot. The hydraulic robot includes a plurality of arms extending from a base, each arm having a hydraulic motor. The hydraulic robot further includes a robot control system directing movement of the plurality of arms and an end effector platform movable by rotation of the arms.

An article accumulating apparatus that uses a robot to transfer to a predetermined location and accumulate an article conveyed thereto is disclosed. The article accumulating apparatus includes a conveyance unit, an accumulation unit, and a discharge unit. The conveyance unit is configured to convey the article. The accumulation unit is disposed in series with the conveyance unit and is configured to accumulate the article. The discharge unit is configured to discharge the article in the conveyance unit to an area outside the accumulation unit. The discharge unit is disposed in a robot movable range that is a range in which the robot holds and transfers the article to the accumulation unit.

A system for identifying and transferring parcels includes a robot singulator configured to engage and transfer individual parcels in a bulk flow of multiple parcels on a first conveyor to a singulated stream of parcels on a second conveyor. The system further includes a vision and control subsystem, with a first camera for acquiring image data of the bulk flow of multiple parcels, and a computer that receives and processes the image data to identify and segment individual parcels, and then communicates instructions to the robot singulator to engage and transfer each of the individual parcels to the second conveyor. The system may further include a second camera for acquiring image data of the individual parcels to confirm placement on the second conveyor. The system may further include first and second indexing conveyors controlled by the vision and control subsystem for delivering parcels to the robot singulator.

An item sorting system (1) includes a moving belt (1a) and one or more sorting units (2). The sorting unit (2) has an enclosure (3) with a work aperture (4), a suction unit (5) with a suction head (6), and a robot arm unit (7) mounted in the enclosure (3) for moving the suction head (6) within a predetermined operating space within the enclosure (3). The enclosure (3) has one or more shell sections (3a) forming a side wall (3b) of the enclosure (3). In a further aspect, the suction unit (5) has a suction head (6) connected to a suction head channel (11), a low pressure source (12a) connected to the suction head channel (11) via a first valve (13), and a control unit (15) connected to the first valve (13) and arranged to actuate the first valve (13) between a suction position and a release position.

A parallel link robot includes: a base portion; a movable portion; link portions coupling the base and movable portions; and actuators attached to the base portion and driving the respective link portions. Each of the link portions includes drive links swung around axes by the respective actuators, and two each of the passive links parallel to each other and swingably arranged between the drive link and the each of the movable portions. The robot includes a drive unit disposed parallel to the two passive links of at least one of the link portions and between the passive links and drives a mechanical unit attached to the movable portion. The drive unit is attached to the drive link with a joint, swingably coupling the drive unit to the drive link around at least mutually intersecting axes, on a straight-line coupling swinging center points of the passive links and the drive link.

Disclosed is a three-branched six-degree-of-freedom parallel mechanism with curved sliding pairs, which includes a base, a moving platform, and three identical kinetic branches. The kinetic branches are radially and evenly distributed and arranged between the base and the moving platform. Each kinetic branch includes a first curved link assembly, a first motor, and a support link. One end of the support link is hinged to the moving platform. One end of the first curved link assembly is hinged to the support link. The first motor is disposed on the base and is configured for driving the first curved link assembly to rotate, where an arc length of the first curved link assembly is changed as the first curved link assembly is driven to rotate.

A linear delta system includes a frame, rails secured to the frame, linear actuators, each linear actuator coupled to a respective rail and configured to translate along a longitudinal length of the respective rail, pairs of parallel rods each operably coupled to a respective linear actuator, a platform coupled to the pairs of parallel rods, structure configured to movable couple an object to the platform; and at least one degree of freedom imparting assembly including a profiled rod extending in a direction parallel to the rails and a drive unit configured to rotate the profiled rod, wherein the at least one degree of freedom imparting assembly is configured to impart a degree of freedom to the object.

A parallel link robot includes: a base having two or more actuators; a movable part; two or more link parts connected to the actuators; an orientation changing mechanism that changes the orientation of an element attached to the movable part; two or more additional actuators that are provided on the two or more link parts and that change the orientation of the element with the same degree of freedom; and power transmission shafts. The link parts each have a driving link and two parallel driven links. The additional actuators are each disposed between the driven links of the two or more link parts. The power transmission shafts extend from the additional actuators along the driven links and are connected, with universal joints, to shafts extending from the orientation changing mechanism. The universal joints are located on a straight line connecting intersections between the two driven links and the movable part.