A robotic grommet installer includes a robotic arm and an installation unit. The installation unit includes a rotary grommet holder rotatively coupled to the robotic arm and an installer coupled to the robotic arm. The rotary grommet holder includes a plurality of grommet chambers spaced circumferentially about a rotational axis of the rotary grommet holder. Each grommet chamber of the plurality of grommet chambers is configured to hold a plurality of grommets. The installer is configured to retrieve a grommet from the rotary grommet holder, wherein the rotary grommet holder is configured to rotate to align the installer with an available grommet positioned within one of the plurality of grommet chambers.

An example system includes a moveable arm, a pick tool connected to the arm, and a controller. The pick tool includes a first finger, a second finger disposed opposite the first finger, a first handler disposed at a first end of the first finger, and a second handler disposed at a first end of the second finger. Rotation of the first and second handlers while first and second forces are applied to an item by the first and second handlers, respectively, causes movement of the item.

An electronic apparatus production system is disclosed. The electronic apparatus production system comprises a transmission rail in the form of a substantially closed loop, a plurality of storage trays circulating on the transmission rail, each of the storage trays comprising a plurality of holding portions to hold a plurality of components with different shapes, an automatic distributor configured to mount the components with different shapes on respective holding portions, and an automatic assembler configured to grip the components on the storage tray.

An insertion station of a component (2), for example a clevis, in a component seat (12) formed in an assembly (3) to be assembled, for example a hinge assembly for doors, includes a component ordering device (14) to order the loose components coming from a component feed hopper. A component support seat (16) receives the component and is configured in such a way as to guide the component in the horizontal insertion direction. A manipulator (20) picks a component (2) from the component ordering device (14) and deposit the component in the component support seat (16). An insertion actuator (30) has a pusher member (32) operable to push the component (2) in the component seat (12), and a positioning unit (40), including an abutment (42) operable to block the assembly (3) in a component insertion position.

A system for controlled distribution of components, the system including a vibrating bowl provided with an enclosure having a wall extending right around an axis of revolution of the bowl and in which the components are placed in bulk, and an articulated gripping arm provided to distribute the components to the automatic assembly installation, the vibrating bowl including an ascending helical ramp extending along an internal face of the wall between a base and an upper edge of the vibrating bowl constituting an exit of the ramp, the components being able to travel along this ramp towards a supply platform, particularly a slide, on which at least one component is arranged in advance of its seizure by the articulated gripping arm, the supply platform being connected to the exit and extending above or in the enclosure of the vibrating bowl.

An orientation device for objects (O) provided with a stem (S) and with a head (H) that has a minimum width (R), characterised in that it comprises: a slot (3) which has two edges separated by a predetermined distance (D), less than the minimum width (R) and greater than the maximum width of the stem (G); an uncoupling device (4), movable between an active configuration, in which it is able to retain an object (O) with respect to lifting, and an inactive configuration, in which it is not able to interact with an object (O); a magnetic gripping element (2), movable along at least a vertical direction between an upper position and a lower position, in which an object (O) associated with the gripping element (2) is in a position such as to be retained by the uncoupling device (4) so as to be detached from the gripping element (2).

A loading workstation comprises a docking station including a first transmission device adapted to transmit a carrier for loading components, and a mobile vehicle. The mobile vehicle includes a second transmission device, a feeding device and a loading device. The second transmission device is adapted to dock with the first transmission device to allow the carrier to be continuously transmitted on the first transmission device and the second transmission device. The feeding device is adapted to supply components to be loaded. The loading device is adapted to load the supplied components onto the carrier that has been transferred to the second transmission device.

Provided is apart stopping/passing unit for apart including a unit main body having a part passage, an opening/closing member configured to open and close the part passage, and an attracting mechanism. The opening/closing member includes a stopper surface for stopping a part and a passing hole for allowing the part to pass therethrough. The attracting mechanism is configured to position the part by an attracting force when the stopper surface takes a part stopping position, and to allow the part to pass by elimination of an attraction force when the passing hole takes a part passing position.

Techniques are disclosed for remotely switching screw color or screw type feeding into a door assembly machine with an auto-hinge applicator. An apparatus having a turntable is supported on bearings and a framework. Each side of the turntable includes a screw hopper accessible via a rotary index. The screw hoppers receive a user input to make a screw selection. Upon receiving a selection, one of the hoppers indexes into position, allowing the correct screw to feed to the hinge applicator. Screw feed-hoses from screwdrivers on the hinge applicator are arranged to connect to a manifold below the screw hoppers. Screws drop from the hoppers into a manifold, at which point the screws are blown with compressed air through the feed-hoses to the screwdrivers on the hinge applicator. Screws can be reloaded into the screw hoppers when rotated in alignment with the hinge side of the door assembly machine.

Systems, apparatus, and methods of manufacturing an article using electroadhesion technology for the pick-up and release of materials, respectively.