An automated screw driving machine may include a hopper adapted to hold associated fasteners, a chuck assembly adapted to hold an individual fastener in position with respect to an associated component part, a feeder assembly adapted to convey the fasteners from the hopper to the chuck assembly; and, a driver assembly that takes fasteners from the chuck assembly and attaches them to the associated component part.

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 device for separating and aligning pin-shaped piece goods exhibiting a head and a shank includes a funnel-shaped receptacle for receiving the piece goods. The receptacle has two wall sections which delimit the receptacle in a front area, and a rear wall, which are arranged in sections opposite one another and in each case inclined outwards at an angle to the central transversal plane of the receptacle. An endlessly circulating conveying means is arranged underneath a recess which spaces apart the two wall sections and which is arranged at a same angle () as the wall sections inclined relative to the central transversal plane and conveys the piece goods from a receiving plane to a higher discharge plane. The conveying means has a conveying plane provided with drivers. The recess is delimited by parallel front edges of the wall sections which are arranged in a V-shape tapering towards the conveying means and terminate above the conveying means or in a plane with the conveying means. The drivers are in the form of cylindrical pins which are arranged at a distance from one another in the direction of circulation of the conveying means and extend essentially perpendicular to the conveying plane of the conveying means.

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.

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.

A linear conveyor device includes a slider having a linear motor mover; a straight-line conveyance part formed of a connected body of modules each having a linear motor stator and first and second guide rails for guiding movement of the slider on an upper surface of the module; and a cover member. The cover member covers the upper surface of the module so as to cover and conceal the linear motor stator and the first and second guide rails from above. The slider has a shape which allows the slider to be fitted on the cover member in a movable manner in an extending direction of the straight-line conveyance part.

A device for separating and aligning pin-shaped piece goods exhibiting a head and a shank includes a funnel-shaped receptacle for receiving the piece goods. The receptacle has two wall sections which delimit the receptacle in a front area, and a rear wall, which are arranged in sections opposite one another and in each case inclined outwards at an angle to the central transversal plane of the receptacle. An endlessly circulating conveying means is arranged underneath a recess which spaces apart the two wall sections and which is arranged at a same angle () as the wall sections inclined relative to the central transversal plane and conveys the piece goods from a receiving plane to a higher discharge plane. The conveying means has a conveying plane provided with drivers. The recess is delimited by parallel front edges of the wall sections which are arranged in a V-shape tapering towards the conveying means and terminate above the conveying means or in a plane with the conveying means. The drivers are in the form of cylindrical pins which are arranged at a distance from one another in the direction of circulation of the conveying means and extend essentially perpendicular to the conveying plane of the conveying means.

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.

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.

An automatic feeding system adapted to arrange a variety of components having different shapes comprises a storage apparatus and a first conveying device. The storage apparatus includes loaded storage devices loaded with the components and unloaded storage devices unloaded with the components. The first conveying apparatus includes a pair of first support frames disposed opposite to each other, a loading conveying apparatus mounted between the first support frames and configured to convey the unloaded storage devices to a loading position to load the components thereon and change the unloaded storage devices to loaded storage devices, and an unloading conveying apparatus mounted between the first support frames and configured to receive the loaded storage devices conveyed from the loading position. The unloading conveying apparatus conveys the unloaded storage devices to the loading conveying apparatus after the components on the loaded storage devices are picked up by a pick-up apparatus.