A stamping strip manufacturing system comprises a stamping machine forming terminals in a strip by stamping. A supply reel around which a strip to be stamped is wound supplies the strip to be stamped to the stamping machine, and a recovery reel around which the stamped strip is wound recovers the stamped strip. A strip cutting and welding device of the system cuts off an unqualified strip segment of the strip having an unqualified terminal and welds two cut ends of the cut strip to each other.

A stamping strip manufacturing system comprises a stamping machine forming terminals in a strip by stamping, a supply reel around which the strip to be stamped is wound for supplying the strip to be stamped to the stamping machine, and a recovery reel around which the stamped strip is wound for recovering the stamped strip. The system further includes an autonomous mobile robot on which a cutting tool and a welding tool are mounted. The autonomous mobile robot is adapted to cut off an unqualified strip segment of the stamped strip having an unqualified terminal by operating the cutting tool, and to weld two cut ends of the cut strip to each other by operating the welding tool.

A stamping strip manufacturing system comprises a stamping machine forming terminals in a strip by stamping, a supply reel around which the strip to be stamped is wound for supplying the strip to be stamped to the stamping machine, and a recovery reel around which the stamped strip is wound for recovering the stamped strip. The system further includes an autonomous mobile robot on which a cutting tool and a welding tool are mounted. The autonomous mobile robot is adapted to cut off an unqualified strip segment of the stamped strip having an unqualified terminal by operating the cutting tool, and to weld two cut ends of the cut strip to each other by operating the welding tool.

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.

Proposed is a transfer system for presses, having at least two fastening units arranged opposite one another, wherein each of the fastening units in each case has a first fastening region. The transfer system further has a press transfer unit, consisting of two movement arms arranged opposite one another, as well as a crossbar connected thereto for receiving and for transporting, i.e. including setting down, a workpiece. Each of the movement arms has a first drive unit connected to the first fastening region, a first lever arm, a second drive unit, and a second lever arm. The first lever arm is connected at a first end thereof or between the first and a second end to the first drive unit, and at the second end thereof to the second drive unit. The second lever arm is rotatably connected at a first end thereof to the second drive unit, and is movably connected with a second end thereof to the crossbar. In addition, at least one energy-storing element is provided for each movement arm, which energy-storing element is formed and arranged in such a way that its force or a force component thereof points in the acceleration direction of the crossbar with or without workpiece. In an embodiment c1, a second fastening region is provided on the fastening unit, and the energy-storing element is connected directly or indirectly with a first end thereof to the second fastening region, and is fastened on a second end thereof at a specified region of the movement arm. In an additional or alternative embodiment c2, the energy-storing element is fastened with a first end to the first lever arm and with a second end thereof to the second lever arm.

A method and system for handling beam-cut parts (202) cut out of a piece of material, the method comprising the steps of: receiving the beam-cut piece of material from beam-cutting equipment (102), the beam-cut piece of material being situated on a supporting structure (116); and gripping at least one part of the beam-cut piece of material, or gripping the beam-cut piece of material, or gripping a section of the beam-cut piece of material including at least one part of the beam-cut piece of material or gripping a remainder of the beam-cut piece of material with the at least one part removed, by means of at least one gripper (110, 112) controlled by a gripping robot (106, 108).

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.

The current invention relates to a system for accurately punching holes in a profile comprising at least one clamp, slideable in a first direction, and at least one punch unit for punching holes in the profile, wherein the at least one clamp comprises a linear encoder, configured for measuring a displacement in the first direction of the at least one clamp. The invention also relates to a method for accurately punching holes in a profile comprising clamping a profile in a clamp, displacing the profile by sliding the clamp in a first direction in a punch unit, and punching at least one hole in the profile by the punch unit, wherein the displacement of the profile in the first direction is measured with a linear encoder, coupled to the clamp.

A method of manufacturing a press-formed product includes: a heating step; a transportation step; and a pressing step. The transportation step includes: using claws of a pair of first arms to support the lower surface, at both ends, of a first heated workpiece and lift the workpiece; using claws of a pair of second arms to support the lower surface, at both ends, of a second heated workpiece and lift the workpiece; transporting the first heated workpiece with the lower surface supported, at both ends, by the claws of the pair of first arms and the second heated workpiece with the lower surface supported, at both ends, by the claws of the pair of second arms, where the first and second heated workpieces overlap each other in the direction normal to the sheet surfaces; driving the pair of first arms to lower the first heated workpiece to a pressing location on a press machine; and driving the pair of second arms to lower the second heated workpiece to a pressing location on the press machine.

Proposed is a transfer system for presses, having at least two fastening units arranged opposite one another, wherein each of the fastening units in each case has a first fastening region. The transfer system further has a press transfer unit, consisting of two movement arms arranged opposite one another, as well as a crossbar connected thereto for receiving and for transporting, i.e. including setting down, a workpiece. Each of the movement arms has a first drive unit connected to the first fastening region, a first lever arm, a second drive unit, and a second lever arm. The first lever arm is connected at a first end thereof or between the first and a second end to the first drive unit, and at the second end thereof to the second drive unit. The second lever arm is rotatably connected at a first end thereof to the second drive unit, and is movably connected with a second end thereof to the crossbar. In addition, at least one energy-storing element is provided for each movement arm, which energy-storing element is formed and arranged in such a way that its force or a force component thereof points in the acceleration direction of the crossbar with or without. In an embodiment c1, a second fastening region is provided on the fastening unit, and the energy-storing element is connected directly or indirectly with a first end thereof to the second fastening region, and is fastened on a second end thereof at a specified region of the movement arm. In an additional or alternative embodiment c2, the energy-storing element is fastened with a first end to the first lever arm and with a second end thereof to the second lever arm.