There is disclosed a separator drum (13) for tobacco industry product assembly apparatus. The separator drum has a plurality of segments (29, 30) arranged to form at least a part of a peripheral surface of the separator drum. Each segment has at least one flute (31) and at most four flutes (31). Each flute (31) is adapted to carry a rod of aerosolisable material (2) as the separator drum rotates during use. Each segment (29, 30) is slidably mounted to the separator drum (13) for axial movement.

An operating group for a cartoning machine is arranged to move a blank that is intended to form a carton adapted to contain one or more products, and includes a magazine suitable for housing a plurality of blanks folded in a planar manner; gripping arrangement that is configured for retaining the blank and is movable at least between a removing position in which the gripping arrangement removes the blank arranged in the magazine in a planar configuration, which is horizontal, and a delivery position in which the gripping arrangement delivers the blank arranged in a tridimensional unfolded configuration, which is vertical with respect to the planar configuration; in which the gripping arrangement is rotated around a rotation axis such as to travel along a closed loop path; the removing position from the magazine being arranged above the closed loop transfer path travelled by the gripping arrangement, such that the gripping arrangement can remove directly from the magazine said blank in the horizontal folded planar configuration.

Provided is an aligning and conveying apparatus 1 comprising a rotating disk 10 having a disk-shaped bottom wall 11 and supported so as to be rotatable, a first ring 20 having a first circumferential wall 21 surrounding the bottom wall 11 and supported so as to be rotatable, and a second ring 30 having a second circumferential wall 31 surrounding the first circumferential wall 21 and supported so as to be rotatable, wherein a first conveying part 91 and a second conveying part 92 are respectively provided in upper parts of the first circumferential wall 21 and the second circumferential wall 31, in the rotating disk 10 and the first ring 20, the bottom wall 11 is positioned lower than the first conveying part 91 so as to form a retaining space S for retaining preparations P inside the first ring 10, and the respective rotational axes are relatively inclined such that the preparations P move from the bottom wall 11 to the first conveying part 91 at a first delivery position P1, and in the first ring 20 and the second ring 30, the first conveying part 91 is positioned lower than the second conveying part 92, and the respective rotational axes are relatively inclined such that the preparations P move from the first conveying part 91 to the second conveying part 92 at a second delivery position P2.

A method and a kit for adjusting a machine for wrapping or packing articles, including a conveyor associated with an electric motor where, in an operating condition, the motor drives the conveyor in rotation about its axis of rotation. The method includes associating the conveyor with a reference integral with the conveyor and disposed at an angular position about its axis of rotation; detecting the angular position of the conveyor relative to the force of gravity by measuring the angle between a radial line passing through the reference and the force of gravity; detecting the angular position of the axis of the motor relative to a zero reference associated with an angular position transducer of the motor; calculating and storing the angular displacement between the angular positions of the motor and the conveyor corresponding to the angular displacement between the zero reference and the force of gravity.

A quick-change starwheel guide assembly is structured to be coupled to a starwheel guide assembly mounting base. The quick-change starwheel guide assembly includes a starwheel guide assembly mounting assembly, a starwheel guide assembly support assembly, a number of starwheel guide assembly guiderails and a starwheel guide assembly can body height adjustment assembly. The starwheel guide assembly mounting assembly is coupled to the starwheel guide assembly support assembly. The starwheel guide assembly guiderails are coupled to the starwheel guide assembly mounting assembly. The starwheel guide assembly can body height adjustment assembly is coupled to at least one the starwheel guide assembly guiderail. At least one of the starwheel guide assembly mounting assembly or the can body height adjustment assembly is a quick-change assembly.

A bead feeder serially delivering beads to a downstream location comprises a bead supply wheel connected to rotate about a vertical axis. The bead supply wheel includes a bead supply bowl and a plurality of radially and outwardly extending bead passageway connected to rotate with the bowl and dimensioned to receive a single line of beads. A plurality of openings in the bead supply bowl is spaced around a lower portion thereof with the openings in alignment with the radially and outwardly extending passageways each of which has an outer exit end. A metering plate is connected to rotate about the same vertical axis as the bead supply wheel, and metering plate has a plurality of equally spaced apart openings directly below the outer ends of the passageways for receiving the lowermost beads in the passageways. The metering plate rotates at a slightly slower or slightly faster speed than the bead supply wheel so that vertical alignment of an outer exit end of a particular passageway and an opening in the metering plate only occurs once for each revolution of the bead supply wheel. A drop off is provided for the removal of beads away from the metering plate.

A bottle neck gripper includes first and second jaw components, each pivotally mounted for rotation about a respective pivot axis, the first jaw component including a first permanent magnet mounted thereon, the second jaw component including a second permanent magnet mounted thereon. The first permanent magnet and second permanent magnet are positioned to be attracted to each other. An attractive force of the magnets urges grip ends of the first and second jaw components toward each other. The pivot axis of the first jaw component is located between the first permanent magnet and the grip end, and the pivot axis of the second jaw component is located between the second permanent magnet and the grip end.

Transfer wheel (1) for transferring objects (40, 41) comprises at least a seat module (3). The seat module comprises a seat (2) located at the peripheral face of the transfer wheel and adapted for accommodating an object on the seat. The at least one seat module is a resilient seat module, wherein a position of the seat of the seat module is adaptable in radial direction of the transfer wheel. Also provided is a method for transferring objects.

Transfer system for removing sleeve-shaped workpieces from a first conveyor and for pushing the sleeve-shaped workpieces onto a second conveyor, with a linearly movable coupling rod, with which a gear unit is associated, which includes a swivel body mounted so as to be pivotable about an axis of movement, on which a first workpiece gripper mounted so as to be rotatable about a first axis of rotation and a second workpiece gripper are arranged, wherein the gear unit has an adjuster for initiating an actuating movement for setting a distance between a first gripping region of the first workpiece gripper, which is arranged at a radial distance from the axis of movement, and a second gripping region of the second workpiece gripper, which is arranged at a radial distance from the axis of movement, as well as with a swivel drive for actuating the adjuster for initiating a forced swivel movement connected to the swivel movement of the swivel body onto the first workpiece gripper.

An apparatus and method for manufacturing an absorptive article are capable of suppressing the occurrence of wrinkles in a constituent element of the absorbing article when transferring the constituent element to a downstream conveying device. A main suction pad that moves along a cylindrical or conical first virtual path surface receives a constituent element from an upstream conveying device, changes the orientation by 90 and conveys the constituent element to a second position. Sub-suction surfaces of the first and second sub-suction pads move around a second reference center line along a cylindrical or conical second virtual path surface centered on the second reference center line, while being aligned with each other with a space therebetween, suction end portions of the constituent element at the second position, and transfer the constituent element to the downstream conveying device at a third position.