A pipette tip supply mechanism includes: a pipette tip storage unit for storing a plurality of tapered shaped pipette tips; a belt for transporting a pipette tip supplied from an opening of the pipette tip storage unit; and a belt drive unit that drives the belt in a transport direction. The belt is inclined upwards toward the transport direction so that the pipette tip is rotatable around a longitudinal axis of the pipette tip on a surface of the belt and the pipette tip is rolled to orient the longitudinal axis of the pipette tip along the transport direction in conjunction with the drive of the belt in the transport direction.

A feeder system for item feeding is presented. The feeder system may include a container having a plurality of walls, an actuator, a selector, and a chute. The container receives a plurality of items. An opening is formed in the container. The items flow through the opening towards the selector by a gravitational force. The selector singulates the plurality of items into one item. The chute receives the singulated item one at a time from the selector. The actuator is attached to the container and agitates the container to maintain a flow of the plurality of items passing through the opening.

An apparatus for equipping a basket welding machine, the apparatus having an insertion device. The apparatus is characterized in that the insertion device has a plurality of receiving positions for all the longitudinal wires of a basket to be produced using the basket welding machine, the insertion device having a receiving element for receiving the longitudinal wires of a basket, the receiving positions being spaced apart in the radial direction from an axis of rotation of the insertion device, wherein the insertion device is designed to feed at least two longitudinal wires arranged on the insertion device to the basket welding machine simultaneously in one insertion operation, the insertion operation of the longitudinal wires into the basket welding machine being effected by a movement of the insertion device in the axial direction of the axis of rotation of the insertion device. The invention further relates to a basket welding machine.

A feeding system comprises a hopper having a discharge port at a bottom of the hopper, a flow control gate disposed at the discharge port of the hopper, a sliding rail obliquely disposed below the hopper, and a vibration excitation unit. The hopper accommodates a plurality of different types of product components and each of the product components flows out from the discharge port of the hopper. A flow rate of the product components flowing out from the discharge port is adjustable by adjusting an opening degree of the flow control gate. The sliding rail is configured to receive the product components flowing out from the discharge port. The vibration excitation unit receives the product components from the sliding rail and is configured to separate the product components and to change a posture of the product components by virtue of vibration.

This article supply method comprises: a step for introducing, using a movable block capable of reciprocating between a first position and a second position, a single object to be conveyed into a housing portion formed on the movable block when the movable block is in the first position; a forward step for pressing the movable block from the first position in a range of motion of the movable block while vacuum-sucking the movable block from the second position in the range of motion of the movable block, and then continuing the vacuum-sucking from the second position and moving the movable block to the second position; a step for discharging the object to be conveyed from the housing portion when the movable block is in the second position; and a return step for vacuum-sucking the movable block from the first position and moving the movable block to the first position.

A component depositing device in which components P stored inside storage container 140 in a bulk state are consecutively conveyed above depositing path 154 by rotating multiple magnets 142 in a first direction, the conveyed components are stopped by stopping wall 156 provided above the depositing path so as to fall onto the depositing path, thereby depositing a specified amount of the components into a case, wherein, when the specified amount of components has been deposited, the multiple magnets are stopped at a position such that the magnets currently pulling a component are not positioned above the depositing path. For example, the multiple magnets are stopped after being reverse rotated by a set angle. Because a magnet currently conveying a component is not above the depositing path when component depositing is completed, components are prevented from falling into the depositing path after component depositing is complete, thus preventing component blockages at the depositing path.

Fastener delivery apparatus for automatically selecting and delivering fasteners such as rivets to a setting tool. The fasteners are pre-loaded in a package and dispense via at least one fastener delivery tube that interconnects the setting tool to a fastener feeder device. The fastener feeder device releases selected fasteners from the package into the delivery tube. The fasteners are transportable individually or in groups in the tube from the feeder device to the tool. A transfer station attached to the tool or the delivery tube transfers a fastener from the delivery apparatus into the tool, transfer station is adjacent to the tool so that a delivered fastener may be inserted by the transfer station into the tool and a second position in which it is clear of the tool so as to permit the tool or a portion thereof to move towards a workpiece to insert a smooth, rapid and reliable delivery of fasteners of various sizes and types to the nose of a setting tool in any particular order and provides all the fastener types for any particular work cycle.

An article supply device has: a transport part that transports transported objects, and a movable block. The movable block is provided with a storage part that can store one of the transported objects in a reception position that communicates with a downstream end of the transport part. The movable block is capable of reciprocal movement in a direction that intersects the reception direction of the transported object. At one end of the reciprocal movement, the storage part is in the reception position. At the other end of the reciprocal movement, the storage part is in a dispensation or retrieval position from which the transported object can be dispensed or retrieved.

A parts organizer receives small parts such as mechanical fasteners in bulk form and organizes a plurality of the parts in a common desired orientation. Unoriented parts are received on top of a parts holder and subsequently moved along an upper side of the parts holder by an agitator. A plurality of receptacles are formed in the parts holder and open on its upper side. Each receptacle is configured to hold one of the parts in the desired orientation and may include a lead-in feature to help reorient the parts as they encounter the receptacles during movement. A retaining wall operates to contain unheld parts at the upper side of the parts holder during a parts organizing step and to allow the agitator to clear unheld parts away from the upper side of the parts holder during a purge step.

An unload stacking assembly includes a discharge hopper for receiving container closures from a conveyance assembly. A deflector deflects the container closures into the discharge hopper in a desired orientation, and a control system detects the container closures and operates a pusher assembly to control movement of the container closers. The conveyance assembly is disposed in a horizontal plane and the discharge hopper is disposed at a discharge angle with respect to the horizontal plane.