A robotic tube bending machine is disclosed. The machine includes a tube feeding tray to load tubes. The pneumatic feed separator comprising two jaws to move in a reciprocating motion to separate each tube for sequential operation. The machine includes a robotic arm assembly in communication with a controller and includes a robotic arm and a pneumatic gripper and two gripper fingers to pick each tube from the tray by simultaneous movement of multiple axis of the robotic arm to reach a three-dimensional coordinate. The collision detection module to detect presence of the robotic arm across a non-intended area by measuring force of the robotic arm and deactivate the robotic arm upon detecting a condition of collision. The machine includes a bending die to clamp each tube and a pressure die to apply pressure on the bending die to bend each tube in intricate three dimensional shapes by rotating the tubes at predefined angles by maneuvering the robotic arm.

A handling device is provided. The handling device has a holding unit which has at least one holding element with which the part to be bent which is to be received and is arranged on a loading surface can be gripped on one of its flat sides by forces acting in a pulling manner on one side of the flat side at a plurality of successive locations in the longitudinal direction, that the holding unit for its part can be pivoted relative to a pivoting carrier unit about a first pivot axis parallel to the longitudinal direction, that the pivoting carrier unit can be pivoted relative to a pivoting carrier base about a second pivot axis which extends parallel to the first pivot axis, that the pivoting carrier base can be moved by means of a carrier base moving unit in a direction transverse to the second pivot axis.

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.

A transfer tool includes a substantially strip-shaped frame; a wrist-side slider provided on one side of the frame in a thickness direction in a manner capable of moving along a longitudinal direction of the frame; a workpiece-side slider provided on another side of the frame in the thickness direction in a manner capable of moving along the longitudinal direction; and a distal-end swing shaft attached to the workpiece-side slider. The shaft includes a support section supported by the workpiece-side slider in a manner capable of swinging around an axis line extending in a width direction of the frame and supporting a workpiece, and an actuator attached to the workpiece-side slider and causing the support section to swing. The actuator includes a motor, and a pair of gears that transmits driving force of the motor to the support section. At least one of the gears is formed into a fan shape.

The invention relates to a support device (15) for a press brake, comprising a base frame (24) and a support plate (17) with a bearing surface (18) which can be positioned between a base position (26) and a maximum position (27). The support plate (17) is arranged on a lever linkage system (25) which is connected to a drive unit (32) and which is designed as a parallel kinematics system. The drive unit (32) comprises a crank (35), which is connected to a positioning drive (33) designed as a rotary drive (34), and a rocker (54), which is connected to the crank in an articulated manner. The rocker (54) is connected to the crank (35) by means of an eight rotary joint (55) and to the lever linkage system (25) by means of a ninth rotary joint (56).

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 transfer tool includes a substantially strip-shaped frame; a wrist-side slider provided on one side of the frame in a thickness direction in a manner capable of moving along a longitudinal direction of the frame; a workpiece-side slider provided on another side of the frame in the thickness direction in a manner capable of moving along the longitudinal direction; and a distal-end swing shaft attached to the workpiece-side slider. The shaft includes a support section supported by the workpiece-side slider in a manner capable of swinging around an axis line extending in a width direction of the frame and supporting a workpiece, and an actuator attached to the workpiece-side slider and causing the support section to swing. The actuator includes a motor, and a pair of gears that transmits driving force of the motor to the support section. At least one of the gears is formed into a fan shape.

A hot press device according to the present disclosure includes a first press, a second press, a conveyance device linking the first press and the second press together, and a heating furnace provided within a conveyance range of the conveyance device.

A rack storage unit for use in an automation system for a storage of work pieces and/or work piece pallets and/or tools, which includes a base frame with a rack stand and two rack side parts arranged at a distance from one another, wherein facing surfaces of the rack side parts are provided with interfaces for mounting placement devices. It is provided that the base frame is produced as a one-piece cast body from artificial stone, and that the interfaces are held by adhesive force as separately formed insert parts in the facing surfaces of the rack side parts.

An apparatus for rotating an inner stamped part with respect to an outer stamped part is provided. The inner stamped part is nested within an aperture formed within the outer stamped part. The apparatus includes a plurality of grippers that include at least a first gripper positioned at a first edge of the inner stamped part and a second gripper positioned at a second edge of the inner stamped part opposite to the first edge. The plurality of grippers is configured to grip the inner stamped part at the first edge and the second edge, respectively. The plurality of grippers is further configured to rotate the gripped inner stamped part about an axis of rotation. The axis of rotation intersects the first gripper and the second gripper. The plurality of grippers is also configured to open to release the inner stamped part.