Gripper for gripping a thin-walled aerosol can blank, having a base body which is made of a solid material and which has a bore passing through it along a central axis, an inner surface of the bore being provided with a circumferential radial groove extending outwards in the radial direction, and having a rubber-impregnated workpiece which is received in the radial groove, which has a radially inner gripping surface and a radially outer working surface, the working surface, together with mutually opposite axial surfaces of the radial groove and a radially outer circumferential surface of the radial groove, delimiting a fluid working space, wherein an integrally formed circumferential sealing profile is formed on the gripping ring adjacent to the working surface.

Gripper for gripping a thin-walled aerosol can blank, having a base body which is made of a solid material and which has a bore passing through it along a central axis, an inner surface of the bore being provided with a circumferential radial groove extending outwards in the radial direction, and having a rubber-impregnated workpiece which is received in the radial groove, which has a radially inner gripping surface and a radially outer working surface, the working surface, together with mutually opposite axial surfaces of the radial groove and a radially outer circumferential surface of the radial groove, delimiting a fluid working space, wherein an integrally formed circumferential sealing profile is formed on the gripping ring adjacent to the working surface.

A pendular handling system for handling parts in a press line may have two articulated robots arranged on opposite sides with respect to the central vertical plane of the press line, each robot having at least four rotational axes in series between a robot base and a robot wrist, and each robot being mounted with the first axis horizontal and perpendicular to the press line flow direction, a first arm of each robot can swing in a vertical plane in the press line flow direction.

An apparatus (1) for the clocked longitudinal transport of workpieces (11) between processing stations in a transfer press. The apparatus has, at least on one side, a first (2) and a second (3) longitudinally movable control element as a control group (2, 3), wherein two control elements (2, 3) are mounted to be movable relative to each other solely in the longitudinal direction, and the control elements (2, 3) are driven via a common shaft (58). The first control element is a gripper rod (2) for the longitudinal transport of workpieces (11) between the processing stations, and gripper elements (4), offset in the longitudinal direction by the distance between the processing stations, are mounted in the gripper rod (2) and can be moved solely in the transversal direction. The second control element is a thrust rod (3) which forcibly controls the transversal movement of the at least two gripper elements (4).

An apparatus (1) for the clocked longitudinal transport of workpieces (11) between processing stations in a transfer press. The apparatus has, at least on one side, a first (2) and a second (3) longitudinally movable control element as a control group (2, 3), wherein two control elements (2, 3) are mounted to be movable relative to each other solely in the longitudinal direction, and the control elements (2, 3) are driven via a common shaft (58). The first control element is a gripper rod (2) for the longitudinal transport of workpieces (11) between the processing stations, and gripper elements (4), offset in the longitudinal direction by the distance between the processing stations, are mounted in the gripper rod (2) and can be moved solely in the transversal direction. The second control element is a thrust rod (3) which forcibly controls the transversal movement of the at least two gripper elements (4).

The invention relates to a positionable robotic cell for placement at a bending machine. The robotic cell comprises a frame for receiving the robot and a receiving device for a workpiece as well as a positioning device for repositioning the robotic cell. Moreover, a first sensor device is provided for recognizing the position of the robotic cell relative to the manufacturing device. The invention furthermore relates to a production facility with a bending machine and with such a robotic cell as well as a method for operating such a robotic cell at a bending machine.

Methods and systems include ways to synchronize a press machine and tending robots, including a pick robot and a drop robot, where the press machine includes an operating area for pressing a blank into a part. The pick robot and the part are moved out of the operating area while the drop robot carrying the blank is moved into the operating area. At least a portion of the pick robot and/or the part resides within the operating area at the same time at least a portion of the drop robot and/or the blank resides within the operating area. The pick robot is in communication with the drop robot and the movement of the pick robot is synchronized with the movement of the drop robot to prevent the pick robot or part from colliding with the drop robot or the blank.

A bent tubing automation tooling apparatus having a body component made of a rigid piece of material to connect an automation tooling machine to a work-piece manipulating implement, allowing for precision tooling with decreased parts and decreased setup, service, and tuning time to prepare the automation tooling machine for production. The body component may be a single monolithic body that is selectively movable between an operational position and an access position to provide for safer servicing of the automation tooling machine and components by allowing a technician to service the equipment from a safety zone instead of entering a dangerous area of the machine. The bent tubing apparatus provides fine tuning and quick adjustments to positional characteristics of the apparatus to increase precision of the automation tooling process while decreasing service time of the automation tooling machine and components.

A workpiece manipulation device for a swivel bending machine includes a base rack; a manipulation device carrier arranged on the base rack so as to be displaceable by a manipulation device carrier guide in a Y-axis relative to the base rack; a manipulation arm arranged on the manipulation device carrier so as to be displaceable by a manipulation arm guide in a Z-axis relative to the manipulation device carrier; a first rotary punch arranged on the manipulation arm, and a second rotary punch arranged on the manipulation device carrier. The manipulation device carrier is configured in an L-shape and has a first limb, which extends along a Y-axis, and a second limb, which extends along the Z-axis. The manipulation arm guide is formed on the second limb, and a distance between the manipulation arm guide and the rotational axis of the first rotary punch is greater than 1000 mm.

A transfer mechanism includes a rail, first and second tables on the rail, first and second arms each having a base pivotably supported by the first and second tables, respectively, and first and second drive mechanisms that move the first and second tables along the rail, respectively. The first and second arms are pivotaly connected to each other at a position between a tip side and a base side. Tip side portions of the first and second arms than a connected portion of the first and second arms serve as fingers for holding a workpiece. The first and second drive mechanisms independently move the first and second tables, respectively. A relative movement of the first and second tables causes the first and second arms to operate a clamp/unclamp operation. A coordinated movement of the first and second tables causes the first and second arms to perform an advance/return operation.