A machine for producing sanitary articles includes a plurality of processing stations including automated apparatus for forming sanitary articles which advance along a machine direction. The machine includes a multi-axis industrial robot arranged to automatically clean and/or inspect the automated apparatus of the processing stations. The machine has a positive impact on sustainability.

An end effector is disclosed for an articulated arm. The end effector includes a valve assembly including a plurality of supply channels, each supply channel including a supply conduit, a pressure sensor in fluid communication with the supply conduit, and a supply conduit plug. The supply conduit is in fluid communication with a vacuum source. During use, each supply conduit is either at vacuum such that the pressure within the supply conduit is substantially at a vacuum pressure, or is at a pressure that is substantially higher than vacuum pressure because the supply conduit plug has moved to block a portion of the supply conduit. The pressure sensor of each supply conduit provides a pressure sensor signal responsive to whether the pressure in the conduit is either substantially at vacuum or is at a pressure that is substantially higher than vacuum.

A waste sorting robot can include a manipulator comprising a suction gripper for interacting with one or more waste objects to be sorted within a working area, and wherein the manipulator is moveable within the working area. There is a controller configured to send control instructions to the manipulator. At least one pressure sensor is in fluid communication with the suction gripper and configured to generate a pressure signal in dependence on a fluid pressure in the suction gripper. The controller is configured to receive the pressure signal and to determine manipulator instructions in dependence on the pressure signal.

There is provided a conveying device that reliably discharges only scrap when simultaneously conveying the scrap and a pressed product without sacrificing cycle time. A conveying device for use in press forming includes: a conveying part that holds a product part and a scrap part of a workpiece after a cutting process, and conveys the product part and the scrap part to a next process; a nozzle part that is provided in the conveying part, and discharges compressed fluid toward the scrap part; and a controller that performs a control to release holding of the scrap part during conveyance of the workpiece and to blow compressed fluid toward the scrap part.

A method for controlling a vacuum generator (3) in a vacuum system (10) for transportation of objects, which vacuum system (10) comprises a vacuum generator (3) driven by a compressed air flow via a first on/off valve (1), wherein the vacuum generator (3) is arranged to be brought in flow connection with the vacuum gripper means (6) comprised in the vacuum system (10), in order to supply vacuum to the vacuum gripper means (6) in result of the compressed air flow, wherein the vacuum system (10) comprises a second valve (2), which is arranged to supply compressed air into the vacuum system (10); one centralized pressure sensor (4) used for monitoring a system pressure (P) inside the vacuum system (10) and for adaptive blow-off; and a vacuum system controller (5), wherein if the on/off valve (1) is not flowing air to the vacuum generator (3), the vacuum system controller (5) indicates a state of no vacuum generation, and the second valve (2) is activated, allowing an amount of compressed air to flow into the vacuum-system (10) for blow-off, using vacuum system properties being characterized with respect to volume and flow-restriction in relation to the blow-off capacity of the blow-off function and for every release cycle wherein blow-off is terminated and excessive air injected into the system is released through the vacuum gripper means, analyzing pressure propagation following blow-off for calculating a duration of when the vacuum system (10) is being fully pressure-equalized (E) in parts of the vacuum gripper means by using a compensation factor (k), wherein the compensation factor (k) is stored and used for the next release cycle.

The invention relates to grasping system comprising a grasping head (15) for a sheet transporting device, in particular for transporting an insert sheet to be inserted between rows of folding boxes in a receptacle, the grasping head (15) having at least one support frame (80) and a plurality of aspiration elements (17, 18). The aspiration elements (17, 18) are mounted on holding elements (50) which are received on the support frame (80) so as to be displaceable with respect to the support frame (80).

A tray stabilizer system for delivery robots includes a base having an upper end and a lower end; a shock absorbing outer shell assembly, the shock absorbing outer shell assembly having an upper end and a lower end and configured to slidingly house in the space inside the base; a shock-absorbing inner shell assembly, the shock absorbing inner shell assembly having an upper end and a lower end and configured to slidingly house in the space inside the shock absorbing outer shell assembly; a suction cup assembly; and a shock absorbent pad. A method of using the tray stabilizer system for delivery robots includes the steps of preparing a surface onto which the tray stabilizer system is mounted; mounting the system to the prepared surface; placing a tray on the shock absorbing upper pad; and placing an item to be delivered onto the tray.

An end effector is disclosed for an articulated arm. The end effector includes a valve assembly including a plurality of supply channels, each supply channel including a supply conduit, a pressure sensor in fluid communication with the supply conduit, and a supply conduit plug. The supply conduit is in fluid communication with a vacuum source. During use, each supply conduit is either at vacuum such that the pressure within the supply conduit is substantially at a vacuum pressure, or is at a pressure that is substantially higher than vacuum pressure because the supply conduit plug has moved to block a portion of the supply conduit. The pressure sensor of each supply conduit provides a pressure sensor signal responsive to whether the pressure in the conduit is either substantially at vacuum or is at a pressure that is substantially higher than vacuum.

Systems and methods of a robotic arm coupling for connecting a tool with a robotic arm are disclosed. In an embodiment, the robotic arm coupling includes: a mounting interface for mounting the robotic arm coupling on a robotic arm; a coupler interface on which differently actuated tools are releasably and interchangeably coupled; a fluid inlet port connected to an external fluid source to receive a pneumatic fluid; a plurality of interface fluid ports; at least one valve in fluid a communication with the fluid inlet port and settable to at least a first and a second operating state; and a suction device configured to apply a fluid suction pressure to an interface fluid port when a fluid pressure is provided to the suction device.

A gripper head assembly is for a robotic gripping system and includes an actuator. The actuator includes: an actuator body having an attachment region configured to attach the actuator body to the gripper head; a drive element having a mounting section for a tool; a drive having a connector configured to receive an input; the drive being configured to move the drive element upon receiving the input; the drive element defining a through passage; the through passage having a first port for receiving at least one of negative pressure and positive pressure; and, the through passage having an outlet at the mounting section configured to supply the tool with the at least one of negative and positive pressure.