A fastener feeding system and method for automatically delivering fasteners to a plurality of different manufacturing cells in a manufacturing line from a single load point. The fastener feeding system includes a fastener distribution assembly and a transport assembly for selecting and delivering fasteners to the manufacturing cells. Individual fasteners are selected from a fastener reservoir by a robotic manipulator of the fastener distribution assembly, and are placed on a fastener carrier supported on conveying structure extending between the fastener distribution assembly and the manufacturing cells for movement therealong. The fastener carrier is controlled to move along the track to deliver one or more fasteners to a manufacturing cell.

A manufacturing machine includes a feeding system that has first and second processing conveyors arranged in series along the processing path, and a transfer unit interposed between there-between that cyclically transfers the products from the first processing conveyor to the second processing conveyor, picking up the products in a pick-up station arranged in the area of the first processing conveyor and releasing the products in a release station arranged in the area of the second processing conveyor. The transfer unit has a plurality of trays, each having a series of seats designed to house a product, a moving system, which cyclically moves the trays between the pick-up and release stations, a first transferring and second transfer devices arranged in the pick-up station and release stations, respectively to transfer the products from the first processing conveyor to a tray, and from a tray to the second processing conveyor, respectively.

A flexible assembly system includes an industrial personal computer, a data collection card, a motion control card, a six-degree-of-freedom assembly platform, a first visual platform, a second visual platform and a supporting platform. The six-degree-of-freedom assembly platform includes a four-degree-of-freedom motion platform and a two-degree-of-freedom adjustment device, the two-degree-of-freedom adjustment device includes a two-degree-of-freedom motion platform and a clamping mechanism, and the clamping mechanism includes an outer frame, a flexible wrist rotatably connected in the outer frame, two clamping sheets mounted on the flexible wrist, two driving parts corresponding to the two clamping sheets, two first force sensors provided on the outer frame and two second force sensors provided on the flexible wrist; a first image collection apparatus is mounted on the first visual platform, and a second image collection apparatus is mounted on the second visual platform. A flexible assembly method is also disclosed.

A flexible assembly system includes an industrial personal computer, a data collection card, a motion control card, a six-degree-of-freedom assembly platform, a first visual platform, a second visual platform and a supporting platform. The six-degree-of-freedom assembly platform includes a four-degree-of-freedom motion platform and a two-degree-of-freedom adjustment device, the two-degree-of-freedom adjustment device includes a two-degree-of-freedom motion platform and a clamping mechanism, and the clamping mechanism includes an outer frame, a flexible wrist rotatably connected in the outer frame, two clamping sheets mounted on the flexible wrist, two driving parts corresponding to the two clamping sheets, two first force sensors provided on the outer frame and two second force sensors provided on the flexible wrist; a first image collection apparatus is mounted on the first visual platform, and a second image collection apparatus is mounted on the second visual platform. A flexible assembly method is also disclosed.

An exemplary method and system are disclosed to flexibly and adaptably manufacture and assemble a workpiece by using recordings of a user in machine learning/artificial intelligence algorithms to train a robot for subsequent automated manufacture. Machine learning and artificial intelligence learning can generate libraries of generalized dynamic motion primitives that can be subsequently combined for any type of manufacturing or assembling activity. The exemplary method and system can flexibly generate a model of an existing workpiece as a template or primer workpiece that can then be used in conjunction with the DMP operations to fabricate subsequent workpieces.

The present disclosure relates to systems, apparatuses, and methods for assembling cartridges for aerosol delivery devices. The cartridges may be assembled by coupling a base of the cartridge to a carriage that is transported via a track. The track transports the carriages between various substations at which one or more parts are added to the base. The carriage may be lifted from the track by a lifter mechanism at each substation in order to perform assembly operations on the base. An inspection system may inspect the cartridges at various stages of completion at or between the various substations.

Disclosed are a full-automatic storage shelf assembly production line and an operation method thereof. The production line includes a logistics channel, a stand column-based feeding area, a supporting beam-based feeding area, an in-line logistics system, a shelf assembly area, a finished product area, and a control system. The stand column-based feeding area, the supporting beam-based feeding area, the shelf assembly area, and the finished product area are connected in series by means of the in-line logistics system to form an integrated production line.

A method for an assemble system that assembles insulation plates and mounting bars to a stack, includes moving the stack pressed by a stack pressing device to an outside thereof; attaching, a insulation plate attaching device, the insulation plates to the stack; attaching, by a mounting bar attaching device, the mounting bars that is configured to fix the insulation plates to the stack; and assembling, by a bolt assembling device, bolts configured to fix the mounting bars to the stack.

A smart factory system for an electrified vehicle includes a components supplying section in which a drive-motor and a one-kit module of speed reducer component parts for forming a speed reducer to be assembled to the drive-motor are supplied to an upper portion of an autonomous mobile robot, a stator assembling section in which a stator to be assembled to the drive-motor is assembled, a speed reducer assembling section configured to sequentially assemble the speed reducer component parts to the drive-motor, a sub-assembling section in which the drive-motor, the stator, and the speed reducer component parts are electrically interconnected, and a test section in which an assembly quality of the drive-motor, the stator, and the speed reducer component parts is checked.

Systems and methods are provided for fabricating a preform for a fuselage section of an aircraft. The method includes advancing a series of arcuate mandrel sections in a process direction through an assembly line, laying up fiber reinforced material onto the arcuate mandrel sections via layup stations, uniting the series of arcuate mandrel sections into a combined mandrel; and splicing the fiber reinforced material laid-up onto the arcuate mandrel sections.