A hand for parallel link robot includes: a holder configured to extract a workpiece from an extraction portion and hold the workpiece; and a swing-up mechanism portion configured to swing the workpiece held by the holder up centering around a turning axis to change a posture of the workpiece. A parallel link robot includes: a link mechanism portion; and the hand mounted to the link mechanism portion.

A device for treating individual sausages, including: a sorting device having an endless conveyor belt traveling around a triangular geometry and having rails or carrier bars, on which belt the sausages, which are loosely deposited onto an ascending run of the belt, are distributed individually into the rails or carrier bars; an endless first conveying device with individual rails or carrier bars to accept the sorted sausages, wherein each individual rail or carrier bar accommodates one sausage; a grouping device, in which the sausages delivered by the first conveying device are combined into groups; a second conveying device with receiving sections, each of which accommodates the sausages of one group, and into which the sausages, lying side by side, are transferred from the grouping device; and a transfer device having a gripper device for gripping a sausage group and for transferring and depositing the sausage group into a receiving container.

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.

A parallel manipulator with six degrees of freedom may include a base that attaches to a unmanned aerial vehicle and a movable gripper element that may be positioned below the UAV. The positioning of the gripper element my reduce impact of the center of gravity of the attached UAV. The gripper element may include a geometric shape that complements objects routinely used in high-throughput screening (HTS) laboratories, such as microplates. The parallel manipulator and gripper element may be used to quickly, safely, and securely move objects in HTS laboratories and/or the like.

An industrial robot with parallel kinematics is proposed which is equipped with a robot base (1), a carrier element (2) for receiving a gripper, a tool or a machine element, at least two moveable actuating units (4), one of which ends is connected to actuating-unit drives (6) arranged on the robot base (1) and the other end is moveably connected to the carrier element (2), a telescope (13) that is moveably arranged between the robot base (1) and the carrier element (2), a first joint (17) with multiple degrees of freedom, by means of which joint the telescope (13) is moveably held on the robot base (1), a second joint (23) with multiple degrees of freedom, by means of which joint the telescope (13) is moveably held on the carrier element (2), whereby the position of the first joint (17) can be displaceably arranged relative to the robot base (1).

A planar actuator device, including a base plate including a first, second, and third pair of planar coils, each pair of planar coils having an inner coil and an outer coil, each pair of planar coils arranged along a first, second, and third linear motion axis, respectively, the first, second, and third linear motion axis arranged in a star configuration, and an actuation mechanism including a first, second, and third planar legs and a centerpiece, the first, second and third planar legs pivotably connected to the centerpiece, the planar legs including a first, second, and third sliding element and a first, second, and third middle section, respectively, a sliding element and middle section of a respective leg pivotably connected to each other, each sliding element including a permanent magnet.

A parallel kinematics robot has a first drive arm and a second drive arm, the two drive arms being crossed when the robot operates within its normal work area. The drive arms thereby occupy less space in a horizontal direction compared with a situation where the two drive arms point away from each other.

A displacement mechanism includes a base, three rails, three arm assemblies, a moving platform, and three parallel linkage assemblies. The rails stand on the base. Each of the arm assemblies has a first end and a second end. The first ends are slidably connected to the rails, respectively. Each of the arm assemblies is configured to swing in a space among the rails. The moving platform is parallel to the base. Two ends of each of the parallel linkage assemblies are connected to the second end of the corresponding arm assembly and the moving platform in a multidirectional rotating way, respectively. Each of the arm assemblies substantially extends away from the base from the corresponding rail, and each of the parallel linkage assemblies substantially extends toward the base from the second end of the corresponding arm assembly.

[Solving Means] A parallel link robot includes a fixation unit, a movable section for operation, a plurality of first links, a plurality of connection sections, a plurality of second links, a plurality of first shaft sections, a plurality of third links, and a plurality of second shaft sections. The fixation unit includes a plurality of driving sources. The plurality of first links are connected to the plurality of driving sources. The plurality of connection sections are rotatably connected to the plurality of first links. The plurality of second links are rotatably connected to the plurality of first links via the plurality of connection sections. The plurality of first shaft sections are rotatably connected to the plurality of second links. The plurality of third links are rotatably connected to the plurality of second links via the plurality of first shaft sections. The plurality of third links are rotatably connected to the movable section through the plurality of second shaft sections, the plurality of second shaft sections extending peripherally outward from the movable section.

Provided is a parallel link robot which has increased rigidity and which can be reduced in size. The parallel link robot includes: a base (1); a movable portion (2); a plurality of link portions (5) connecting the base (1) and the movable portion (2); and a plurality of actuators (6) for driving the plurality of link portions (5), wherein each of the plurality of actuators (6) is a linear actuator (6) supported on the base (1) to be rotatable about a predetermined axis (A1) and has a main body portion (8) and a shaft portion (7) for linearly moving relative to the main body portion (8), and each of the plurality of link portions (5) has a driving link (3) supported on the base (1) to be rotatable about a predetermined axis (A2) and connected to the linear actuator (6) and a driven link (4) connecting the driving link (3) and the movable portion (2). When the linear actuator (6) extends and contracts, the driving link (3) rotates relative to the base (1) about the predetermined axis (A2) of the driving link (3).