To allow necessary movement of a magnet in a magnet insertion hole during a manufacturing process so that a magnet embedded core in which the magnet is positioned as designed can be manufactured efficiently, a lower plate (12) and an upper plate (14) configured to contact against the end surfaces of a rotor core (2) are provided with pin members (37, 39) configured to enter a magnet insertion hole (4) to allow movement of a magnet (5) in a first direction, which is a separation direction of two mutually opposing inner surfaces (4C, 4D) of a magnet insertion hole (4), and to restrict movement of the magnet in a second direction orthogonal to the first direction as viewed in the axial direction of the magnet insertion hole (4), in a state where the magnet insertion hole is not filled with resin.

Provided is a powder supply device for a secondary battery which can always supply a fixed amount of powder with high accuracy without being influenced by a state of the powder. In addition, provided is an apparatus for manufacturing an electrode body, which includes the powder supply device and can efficiently manufacture an electrode body. The powder supply device includes a rotor which makes powder fall into an opening, and a mesh body which covers the lower end of the opening. Uneven portions or projecting portions are formed on the outer circumferential surface of the rotor. The rotor is rotatably supported in a storing portion. The gap is formed between the outer circumferential surface of the rotor and the inner surface of the storing portion so that they are spaced apart. The mesh body is arranged away from the outer circumferential surface of the rotor.

A device for installing a rear cover of an intelligent lamp cap, including a first feeding device for feeding a heat sink base and a second feeding device for feeding a LED lamp bead out to an outlet of the first feeding device and assembling the LED lamp bead with the heat sink base. A lead wire threading device is arranged on a side of a positioning-mounting mechanism, and is configured to guide a lead wire of the LED lamp bead to pass through a mounting hole of the heat sink base. A third feeding device is arranged on a side of the outlet of the first feeding device to mount a bottom cover on the heat sink base.

Described here are devices and methods for crimping self-expanding devices. The crimping devices may be useful for crimping a variety of different self-expanding devices (whether such devices are biodegradable or bio-durable). The crimping devices may have crimping members to engage the self-expanding device to reduce the device from an expanding configuration to an unexpanded configuration. The crimping member may comprise or include a suture, wire, ribbon, guiding hoop, pusher, prong, holding bar, balloon, jaws, combinations thereof, or the like. The crimping devices may also include or comprise a holding structure to hold the self-expanding device in an unexpanded or expanded configuration.

An automated wire feeder assembly to first repetitively receive a wire from a gripper of an automated processing tool and then load the wire into a hollow conduit coupled to the gripper of the automated tool. The wire feeder assembly includes belts that pivot between open and closed positions and each belt rotate to advance a wire into the conduit attached to the gripper of the automated tool. When the belts are in the open position the gripper of the automated tool places a free end of the wire into a wire guide. Pivoting the belts to the closed position engages the belts with the free end of the wire. Once the belt is engaged with the free end of the wire, rotating the belts advances the wire out of the wire feeder and into the gripper conduit.

A self-piercing rivet escapement mechanism for a rivet setting machine includes a self-piercing rivet track in which self-piercing rivets are receivable. A first resiliently biased jaw is biased towards a closed configuration in which the first resiliently biased jaw retains self-piercing rivets in the self-piercing rivet track. The first resiliently biased jaw is moveable to an open configuration in which a self-piercing rivet can escape the self-piercing rivet track. The first resiliently biased jaw is configured to move from the closed configuration to the open configuration upon exertion of a load upon the first resiliently biased jaw.

A separating device separating fastening elements from a container comprises a transfer channel for transferring fastening elements in a transfer direction, the transfer channel having a separating section; a stop element, having a blocking position, in which the stop element projects into the separating section, blocking the channel for the fastening element, such that one fastening element rests against the stop element in a waiting position, and an onward transfer position, in which the stop element allows movement of the fastening element in the transfer direction to a standby position; and a retention element, having a retaining position, in which the retention element projects into the separating section, blocking the channel for the fastening element, such that the fastening element rests against the retention element in the standby position, and a release position, in which the retention element allows fastening element movement in the transfer direction beyond the separating section.

A feed apparatus for feeding fasteners to a fastener installation head includes a chute to support and guide a strip of fasteners from a chute inlet to the fastener installation head. The strip of fasteners includes a plurality of fasteners selectably releasably attached to a carrier ribbon, wherein the feed apparatus is to separate the fasteners from the carrier ribbon and present the fasteners to the fastener installation head for installation. An idler wheel is to peel the carrier ribbon from the fasteners as the fasteners pass through the chute. A tensioner is to advance the carrier ribbon and apply tension to the carrier ribbon to advance the fasteners in the chute. An actuator is to urge the tensioner to advance the carrier ribbon.

A method and apparatus forms an exhaust component that includes first and second substrates. An outer shell surrounds the first and second substrates. At least one sensor hole is formed in the outer shell at a location between the first and second substrates. A first end of the outer shell is surrounded with a plurality fingers to size the first end around the first substrate to a first diameter. The plurality of fingers includes an extended finger that is longer than the other fingers such that the extended finger at least partially covers the sensor hole during sizing of the first end. A second end of the outer shell is then surrounded by the fingers to size the second end around the second substrate to a second diameter. The extended finger at least partially covers the sensor hole during sizing of the second end.

A method and apparatus forms an exhaust component that includes first and second substrates. An outer shell surrounds the first and second substrates. At least one sensor hole is formed in the outer shell at a location between the first and second substrates. A first end of the outer shell is surrounded with a plurality fingers to size the first end around the first substrate to a first diameter. The plurality of fingers includes an extended finger that is longer than the other fingers such that the extended finger at least partially covers the sensor hole during sizing of the first end. A second end of the outer shell is then surrounded by the fingers to size the second end around the second substrate to a second diameter. The extended finger at least partially covers the sensor hole during sizing of the second end.