An automatic processing system includes a base or platform, on which a loading station is mounted, adapted to house one or more trolleys having workpieces to be processed, a magazine adapted to pick up at least one work piece at a time from the loading station and to transport it to a centering device adapted to receive the workpiece and to place it in pick-up position by a robot, and a unloading station where the processed pieces are positioned.

An automated transforming tooling system apparatus and method for shuttling a workpiece to and from an industrial operation. The system includes a workstation for complementarily engaging and securing the workpiece, and at least one holder removably secures at least on end effector tool to the workstation. At least one transfer bar is movably positioned with respect to the workstation. At least one automated transforming tooling assembly is connected to the transfer bar and has a plurality of links adjustably connected by motorized joints to automatically position the automated transforming tooling assembly. An automated tool changer is connected to the automated transforming tooling assembly and releasably engages the end effector tool between a disengaged position, wherein the end effector tool is disengaged from the automated tool changer, and an engaged position, wherein the end effector tool is engaged by the automated tool changer.

A high-speed stamping transfer robot, including a Y-axis portion, a Z1-axis portion, a Z2-axis portion (upper arm), a mechanical lower arm portion and a tooling portion, wherein the Z1-axis portion is fixedly connected to the Y-axis portion; the Z2-axis portion (upper arm) is in rotational connection with the Z1-axis portion and the Y-axis portion and is capable of moving vertically relative to the Z1-axis portion while moving horizontally relative to the Y-axis portion; the mechanical lower arm portion is in rotational connection with the Z2-axis portion (upper arm) and is capable of rotating relative to the Z2-axis portion (upper arm); and the tooling portion is fixedly connected to the mechanical lower arm portion. Through linkage among the respective axis portions, high-speed and high-load stable transfer of sheets between presses can be realized.

A device comprises a frame, a traversing unit with a first drive unit for moving the traversing unit with respect to the frame and a telescopic unit. The telescopic unit is equipped with a base movable along a first travel path with respect to the traversing unit, a support beam movable along a second travel path with respect to the base and a sliding carriage for transferring the component, the sliding carriage being movable along a third travel path with respect to the support beam, a second drive unit and a transmission. The transmission is at least formed to transmit a driving motion of the second drive unit to the base at a first transmission ratio, to support beam at a second transmission ratio and to the sliding carriage at a third transmission ratio.

A workpiece conveyance device is used for a press device. The workpiece conveyance device includes a support component, first and second moving members, a driver, and a transmission mechanism. The support component supports a holder that detachably holds a workpiece. The first moving member pivotably supports the support component. The first and second moving members are movable in the up and down direction. The driver moves the second moving member in the up and down direction. The transmission mechanism transmits an up and down movement of the second moving member to the first moving member so as to move the first moving member in the up and down direction in conjunction with the up and down movement of the second moving member. The transmission mechanism causes an amount of movement of the first moving member to be greater than an amount of movement of the second moving member.

A manipulator for components, in particular sheet metal parts, includes a base body mountable stationarily or movable along a guide arrangement, a first pivot arm pivotally coupled to the base body via a horizontal first pivot axis, a second pivot arm pivotally coupled to the first pivot arm via a horizontal second pivot axis and a third pivot arm pivotally coupled to the second pivot arm via a horizontal third pivot axis. A first axis of rotation extending radially to the third pivot axis is formed on the third pivot arm. A gripper support arm is rotatably coupled to the third pivot arm via the first axis of rotation and extends radially to the first axis of rotation. A gripping arrangement is rotatably coupled to the gripper support arm via a second axis of rotation spaced from the first axis of rotation. A bending installation includes the manipulator.

A method transports and/or handles components, in particular sheet metal parts, and a production plant includes a manipulator arrangement having a first manipulator arm and at least one second manipulator, wherein the first manipulator and the at least one second manipulator are designed to pick up, transport, hold and/or deposit a component, at least one processing device for carrying out processing steps on the component, wherein the component is transferred from the first manipulator to the at least one second manipulator after a first processing cycle at a predetermined re-gripping time, the re-gripping time being between the first processing cycle and at least one second processing cycle, wherein the component at least in portions rests on the processing device during the re-gripping time and is supported in a load-dissipating manner solely by the processing device.

The method for processing bars provides for feeding a predefined number of bars (2) into a feeding station (3). The method further provides for transferring said fed bars to an operating assembly (4) by means of a transfer assembly (5) comprising at least one transfer device (50).

The invention relates to a gripping device (1) and a method for the monitored movement of objects (2), preferably sheet metals, comprising a system control (3) configured for processing object data (31) and controlling a gripping module (4), wherein the gripping module (4) has at least two gripping jaws (5) formed to cooperate with one another, which form an intermediate receiving space (6) for receiving at least parts of an object (2) to be monitored and transported, and the gripping jaws (5) are formed such that, by applying a pre-definable clamping force (7), at least a friction-type connection between the gripping jaws (5) and at least parts of the object (2) is made possible, whereby the object (2) is movable, and at least one sensor element (8) for collecting object data (31) of the object (2) to be moved and monitored, wherein the at least one sensor element (8) is arranged on at least one gripping jaw (5) with its sensor region (9) facing the receiving space (6), and is formed such that it detects, by means of at least temporary collection of the object data (31), a relative movement and/or relative velocity (26) of the object (2) with respect to at least one of the gripping jaws (5).

A transport system (10) for transporting workpieces (12) on a transport path between two production process stations, includes a set of drones (18, 20), each of which includes at least one gripper (26), which is designed to releasably couple to a surface (28) of a workpiece, and a control device for the simultaneous coordinated control of the drones (18, 20) of the set in such a way that the grippers (26) of the drones (18, 20) couple to different coupling positions on the surface (28) of the workpiece (12) and the orientation of the workpiece (12) can be changed on a transport path between the production process stations by changing the relative positions of the drones (18, 20) while maintaining the relative distances of the coupling positions from one another.