An aligning and conveying apparatus includes a rotating disk having a bottom wall, a first ring having a first circumferential wall, a second ring having a second circumferential wall. First and second conveying parts are respectively provided in upper parts of the first and second circumferential walls. In the rotating disk and the first ring, the bottom wall is positioned lower than the first conveying part to form a retaining space for retaining preparations inside the first ring. The respective rotational axes are relatively inclined such that the preparations move from the bottom wall to the first conveying part at a first delivery position. In the first and second rings, the first conveying part is positioned lower than the second conveying part, and the respective rotational axes are relatively inclined such that the preparations move from the first conveying part to the second conveying part at a second delivery position.

Disclosed is a method for unblocking the movement of hollow bodies travelling in a line in a conveyor, including: a guiding chute in which each hollow body is intended to take up a freely suspended position; a component for continuously driving hollow bodies into the chute in a direction of movement; a hollow body being likely to take up a position in which it is stuck against a stationary surface of a member that complements the chute and thus to block the movement of the hollow bodies that build up behind same. The method includes an unblocking step which consists of applying an unblocking pulse to the hollow bodies of the blocked line against the direction of movement in order to move the blocking hollow body away from the stationary surface and to allow the blocking hollow body to swivel into the freely suspended position thereof in the chute.

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 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.

An object of the present invention is to provide a stepped pin loading mechanism which can be used for loading stepped pins, comprising a vibrator bowl. A spirally rising discharge track is connected to an outer side of a hopper of the vibrator bowl, and a swivel plate is provided on the discharge track, and several receiving slots are provided on the swivel plate. The strip-shaped receiving slot consists of an inner segment and an outer segment, and the width of the outer segment is greater than that of the inner segment. A front baffle and a rear baffle, both of which are provided with a through opening, are provided on the discharge track, an arc-shaped side baffle, which is located between the front baffle and the rear baffle to form a semi-enclosed structure, is provided on an outer circumferential side of the swivel plate. One end of the side baffle deviates from the through opening of the rear baffle, and the height of an upper edge of the side baffle gradually increases from the rear baffle to the front baffle so that an upper edge at the other end of the side baffle is as high as an upper side of the through opening of the front baffle.

Disclosed is a method for unblocking the movement of hollow bodies travelling in a line in a conveyor, including: a guiding chute in which each hollow body is intended to take up a freely suspended position; a component for continuously driving hollow bodies into the chute in a direction of movement; a hollow body being likely to take up a position in which it is stuck against a stationary surface of a member that complements the chute and thus to block the movement of the hollow bodies that build up behind same. The method includes an unblocking step which consists of applying an unblocking pulse to the hollow bodies of the blocked line against the direction of movement in order to move the blocking hollow body away from the stationary surface and to allow the blocking hollow body to swivel into the freely suspended position thereof in the chute.

A turntable is divided into an inner part (50) and an outer part (40). The angular speed of a large-diameter turntable 40 is made higher than the angular speed of a small-diameter turntable 50, and a tablet transfer path 32 of a straightening guide 30 is configured to be a spiral path extending from an inner end portion 32a to an outer end portion 32b. A tablet contact portion (64) of a tablet holding mechanism is reciprocated with respect to a temporary holding area (62) located before the outer end portion 32b. A tablet is temporarily held in the temporary holding area and when a long narrow blade insertion slit 43 in the large-diameter turntable 40 reaches the temporary holding area, a tablet cutting blade of a tablet cutting mechanism is reciprocated with respect to the temporary holding area and a blade insertion notch (62, 63) to split the tablet.

Various embodiments relate to a rivet element supply unit for providing rivet elements, wherein the rivet element supply unit comprises a rivet element provision unit and a handling unit, wherein the rivet element provision unit for conveying the rivet elements comprises a spiral conveyor having a longitudinal axis and a spiral, which extends around the longitudinal axis, wherein the longitudinal axis is inclined to the direction of gravity, wherein the rivet element provision unit has a pick-up region to which the spiral conveyor supplies rivet elements and from which the handling unit picks up the rivet elements for transporting to a rivet element receptacle.

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.

The supply device includes a rotating table. The supply device includes a plate-shaped member configured to move bolts placed on the table and a plate-shaped member configured to discharge bolts to the outside of the table. A replenishment region to which bolts are replenished is set in a first rotation region of the table. A discharge region from which the bolts are discharged is defined in a second rotation region. The plate-shaped member is configured to move bolts from the first rotation region to the second rotation region.