An end effector and a light bar assembling device having the end effector are provided. The light bar assembling device is configured to assemble a light bar with a backplane, and includes: an adjusting platform configured to carry the light bar to be assembled and adjust a position of the light bar to be assembled on the adjusting platform; and a robot assembling mechanism configured to obtain a light bar after being adjusted in position from the adjusting platform, and assemble the light bar with the backplane, wherein the robot assembling mechanism includes a mechanical arm and an end effector at a free end of the mechanical arm, and the end effector includes: a first connecting seat, a first frame, a first pick-and-place mechanism including at least two first suction cup groups, and a first positioning mechanism including at least two first positioning pins.

A robot hand is provided and includes a robot hand control unit that has at least three gripping fingers on a base and controls the robot hand, a plurality of drive mechanisms that brings the three gripping fingers independently close to or separate from each other, a plurality of drive control units that individually controls each of a plurality of drive sources of the plurality of drive mechanisms, and a distribution control unit that is disposed on the base and distributes an instruction value from the robot hand control unit to the plurality of drive control units associated with the plurality of gripping fingers. At least one of the gripping fingers includes an integrally formed drive source and drive control unit.

A gripping tool, usable on a manipulator device for picking up and handling items includes a support frame extending along a first axis, provided with an attachment element for connecting to the manipulator device; and a plurality of gripping devices distributed in assemblies. Each assembly is carried by a respective auxiliary frame connected to the support frame by means of respective connecting members configured to be able to adjust the auxiliary frames and the gripping devices in position with respect to the support frame.

A gripping device (2) configured to be detachably attached to a robot (20). The gripping device (2) comprises one or more extremities (10, 10′) provided with one or more suction members (12, 12′) connected to a vacuum source (18). At least two of the extremities (10, 10′) are rotatably arranged with respect to each other.

A method configures a workpiece-related workpiece holding device for press automation. At least one workpiece-specific holding element of the workpiece holding device is configurably secured to a support of the workpiece holding device in at least one degree of configuration freedom. The method has the steps of (a) imaging a real image of the at least one workpiece-specific holding element on a display device and (b) outputting configuration information relating to the at least one workpiece-specific holding element on the display device, the configuration information including at least one piece of reference information relating to a relative reference orientation and/or a relative reference position of at least one region of a workpiece-specific holding element relative to the support.

A gripper may include a plate, a suction manifold, one or more attachment mechanisms, and one or more suction cups. The plate may have a body and one or more extremities and each extremity may have one or more slots formed therethrough. The suction manifold may be connected to the body of the plate. The one or more suction cups may each be attached to the plate via one of the attachment mechanisms and may be fluidly connected to the suction manifold. The attachment mechanisms may each extend through one of the slots of the plate. Each attachment mechanism may be configured to be tightened, loosened, and repositioned by hand.

A computer programmable end of robot arm tool for picking and placing a plurality of objects arranged in a first array from a first pick location to a second place location where the objects are placed in a second array different from said first array where the spacing between the picking arms is programmable between different spacing arrangements including during the pick and place arm movement.

Tooling (100) for picking up two-dimensional workpieces comprises a main body (110) and a plurality of holding elements (131, 132) arranged on the main body (110), wherein the holding elements (131, 132) are movable relative to the main body (110) independently of one another. Each of the holding elements (131, 132) is fastened in an end region of an arm (121.1 . . . 10, 122.1 . . . 10). The arms (121, 122) are movable passively relative to the main body (110) along a linear movement path in a longitudinal extension of each particular arm (121, 122). The tooling (100) comprises, for each of the arms (121, 122) a fixing apparatus, by means of which a position of each particular arm (121, 122) along the movement path is fixable. On account of its passive character, the tooling (100) according to the invention is lightweight and can be produced cost-effectively. Compared with fixedly configured tooling, reduced costs arise on account of the configurability, because different types of tooling do not have to be kept available and provided. The storage area for replacement tooling is saved, and also an automatic tooling changing station or a manual tooling change become superfluous. As a result of the geometry according to the invention, the tooling (100) can be set easily, no complex movements and accordingly no complicated setting devices (for example multiaxial robots) are necessary.

Technology disclosed includes a robotic workstation for unstacking/stacking a multi-layer stack of boards and includes an end effector configured to pick up, move and release a layer of boards. The end effector includes first and second pick up and release members, each being (i) disposed below first and second support members, (ii) transversely arranged with respect to the first and second support members and (iii) attached to both of the first and second support members. The robotic workstation also includes a robotic manipulator connected to an attachment plate of the end effector and capable of moving the end effector. The robotic manipulator is under control of a controller executing stored instructions that perform operations including picking up the layer of boards by orienting the end effector such that each board of the layer of boards is transversely oriented with respect to the first and second pick up and release members.

A gripper for a transport system of a picking device having horizontal storage surfaces for storing and dispensing small piece goods of different shapes and/or surface properties is provided. The gripper comprises a drop table extending in first and a second horizontal directions and having a storage and dispensing end face. Two elongated gripping jaws are arranged above the drop table extending in the first horizontal direction, and are fastened to a gripping jaw guide arrangement. At least one of the gripping jaws is movable in the second horizontal direction and at least one of the gripping jaws has a gripper coupler in its end portion facing away from the gripping jaw guide arrangement, and at least one transport attachment with an attachment coupler. The gripper and attachment couplers interact so that a transport attachment is releasably fixed at an end portion of a gripping jaw.