An operating device for a handling device, with a gripping section and a coupling for a gripping device, with at least a part of the coupling being at or in the gripping section, so that it is rotatable about an axis of rotation, with a reading device for reading out an information carrier with coded data being placed on the side of the griping section facing the coupling, where the reading device is designed to read out an information carrier of a gripping device coupled to the coupling regardless of the rotational position of the coupling.

An apparatus for installing and removing glass panels and methods of using the apparatus includes a base portion, a back support structure secured to the base portion, and a glass adjustment system moveably coupled to the back support structure. The glass adjustment system couples to the glass panels. The apparatus is used to install and remove glass panels from, for example, ice rink boards.

An apparatus for installing and removing glass panels and methods of using the apparatus are disclosed. The apparatus includes a base portion, a back support structure secured to the base portion, and a glass adjustment system moveably coupled to the back support structure. Methods for using the apparatus to install and remove glass panels from, for example, ice rink boards, are also disclosed.

Embodiments of a solar panel trailer (10) of this disclosure include a fixed frame (20) having a pair of tilt hinges (55) at a forward end (21); a tilting frame (70) having forks (83) and connected to the pair of tilt hinges; a pair of lifting cylinders (140) having a piston end (141) and a rod end (143), the piston end connected to the fixed frame, the rod end connected to a corresponding one of the pair of tilt hinges, and a pair of vertically oriented clamps (120) located at a rearward end (31) of the trailer, an open end (121) of each clamp facing away from the rearward end; the tilting frame tilting the pair of lifting cylinders extend and retract. The trailer may be accompanied by a vacuum lifter (150) including a slewing bearing (151); at least two spring-loaded, disc-shaped vacuum pads (153); and vacuum pump (155).

An end effector device and system for suction-based grasping of bagged objects that can include a body structure with a vacuum line opening and an object engagement region, the vacuum line opening being configured to couple at least one pressure line of a vacuum pressure system to a defined internal channel of the body structure; the body structure comprising an internal structure that defines a concave inner chamber with a chamber opening at the object engagement region; and the internal structure comprising an array of inlets positioned along at least one wall of the concave inner chamber, wherein each inlet defines an opening in the body to the defined internal channel. The body structure may additionally include a suction cup system that comprises a flexible sealing lip at the object engagement region; wherein the chamber opening being positioned within a grasping region of the sealing lip.

An end effector device and system for suction-based grasping of bagged objects that can include a body structure with a vacuum line opening and an object engagement region, the vacuum line opening being configured to couple at least one pressure line of a vacuum pressure system to a defined internal channel of the body structure; the body structure comprising an internal structure that defines a concave inner chamber with a chamber opening at the object engagement region; and the internal structure comprising an array of inlets positioned along at least one wall of the concave inner chamber, wherein each inlet defines an opening in the body to the defined internal channel.

A gripping device for a part stacking system that according to one embodiment includes a plurality of supporting arms and a plurality of gripping elements attached to the supporting arms, at least some of the gripping elements being movable with respect to the respective supporting arm. Each supporting arm comprises at least one guiderail and each movable gripping element comprises a carriage movable in the corresponding guiderail. The static friction force between each carriage and the respective guiderail is such that the movable gripping elements are kept immobile with respect to the supporting arms by the static friction force during the part stacking process, and the movable gripping elements are positioned with respect to the respective supporting arm overcoming the static friction force.

The invention relates to a method for conveying components and to an automated vacuum gripper (1) for components (3), in particular sheet metal parts, comprising a plurality of suction elements (4), which are arranged at a preferably movable support part (5), a first vacuum generator (8) for forming a first vacuum circuit (9), a second vacuum generator (10) for forming a second vacuum circuit (11), at least one switching element connected to a system controller (14) for automated switching of the first vacuum circuit (9) to the second vacuum circuit (11), at least one compressed air supply (15) connected to at least the first and the second vacuum generators (8), at least one sensor device (16, 17), wherein the first vacuum generator (8) is associated with a first predeterminable group (12) of suction elements (4), and the second vacuum generator (10) is connected to a vacuum tank (18) for forming a second vacuum circuit (11), which may be activated in case of emergency and is redundant to the first vacuum circuit (9), and wherein at least one first sensor device is (16) is formed for monitoring the vacuum at least at the first vacuum circuit (9), and at least one second sensor device (17) has an optical sensor for detecting a relative movement of the component (3) during a conveying operation.

A sucker includes: a main body having a bottom face formed with an annular abutment; a disc body made of a flexible material having a tapered annular wall, the disc body being disposed under the bottom face of the main body, an outer circumference of the annular wall being formed with a lip edge positioned below the annular contact area; an air chamber being formed in the disc body; an air-sucking passage and a fast flow way; the air-sucking passage having a first end in communication with the air chamber of the disc body and a second end passing through the disc body and the main body to communicate with the fast flow way. When the sucker sucks a surface of an object, the air in the air-sucking passage is sucked into the fast flow way.

An apparatus for installing and removing glass panels and methods of using the apparatus are disclosed. The apparatus includes a base portion, a back support structure secured to the base portion, and a glass adjustment system moveably coupled to the back support structure. Methods for using the apparatus to install and remove glass panels from, for example, ice rink boards, are also disclosed.