An aligning and feeding device which accommodates a component including a pair of rectangular end surfaces oppositely facing each other and having a longitudinal direction extending between the end surfaces of the component in a cavity formed in an accommodating member. The component is accommodated in the cavity by aligning a direction of the component such that the longitudinal direction of the component extends parallel to a main surface of the accommodating member.

An article feed system for aligning and singulating incoming articles includes a rotatable upper rim surface and an article delivery device that delivers articles received by the article delivery device to the upper rim surface. A drive system is operatively connected to the outer bowl that rotates the outer bowl. A guide wall extends upwardly above the upper rim surface that guides the articles travelling along the upper rim surface toward an exit opening in the guide wall. A vertically oriented article engaging-type conveyor is at the exit opening in the guide wall. The vertically oriented article engaging-type conveyor includes a moving article engaging surface that is exposed to the exit opening in the guide wall for receiving the articles when they exit the exit opening.

An apparatus for arranging and transferring ammunition, includes a slope conveyor, which is configured into an endless track structure so as to lift cartridges placed on a transfer track thereof using magnetic force, a plurality of permanent magnets, which are arranged on the slope conveyor so as to create a magnetic field outside the transfer track, one or more hole sifters, which are disposed near an outer surface of the transfer track and which have cartridge passage holes formed at locations through which the plurality of permanent magnets pass, and magnetizing controllers including electromagnets, which are disposed above and under the hole sifters and are assigned to the plurality of permanent magnets, wherein the magnetizing controllers detect a position of the permanent magnet when the permanent magnet passes through the cartridge passage hole, and controls the electromagnets to create a magnetic field, having polarity, orientation and density at least one of which is controlled, above or under the hole sifters.

A depth of a cavity formed in a storing member is set to a depth which allows a portion of an electronic component to project from the cavity in a state where the electronic component is stored in the cavity. A storing member includes guide portions each of which is a space communicating with the cavity and configured to guide the electronic component into the cavity. A guide portion is formed such that a guide opening portion which is an opening portion of the guide portion is larger than an opening portion of the cavity and the opening portion of the cavity falls within a region of the guide opening portion as viewed in a depth direction of the cavity. A space formed of the cavity and the guide portion is configured to store an entire electronic component in the inside thereof.

Present embodiments relate to a tie plate dispenser which selectively changes the orientation of the tie plates being ejected, if needed. An actuator is used to flip the tie plate as it falls from an ejection location of the dispenser.

Pick-up device (10) configured to selectively pick up and extract at least one bar (B) from a plurality of bars (B) disposed on a feed plane (111) and to position it on a delivery plane (12), said pick-up device (10) comprising a support arm (11) terminally provided with a pick-up head (12). The present invention also concerns an apparatus (100) for feeding bars (B) comprising the device (10) as above and a corresponding method for picking up bars (B).

A bolt feeder includes: a rotating plate (12) arranged adjacent to a hopper (27) storing bolts (10); one or more magnets (15) to attract the bolts (10), from a back surface of the rotating plate (12), onto a front surface of the rotating plate (12); a selection block (13) having a gap space (13a) through which one bolt in a predetermined orientation out of the bolts (10) attracted by the one or more magnets (15) is allowed to pass; a motor (26) to cause the one or more magnets (15) to rotate and move from the hopper (27) toward the selection block (13); and a guide plate (29) extending upstream in a moving direction of the one or more magnets (15) from an entrance of the gap space (13a), and guiding the bolts (10) attracted by the one or more magnets (15) to the gap space (13a).

A part transporting device comprises a face plate, an attracting member that attracts at least one part to a front face of the face plate, a rotary drive that moves the attracting member in a circular motion along a circumferential line so that the part moves in a circular motion to a predetermined position overlapping a top end of the circumferential line on the front face side of the face plate, and a part storage. A part path through which the part travels is provided on the front face side of the face plate downstream of the predetermined position in a transport direction of the part. The part path includes a non-overlapping portion that does not overlap the circumferential line. The non-overlapping portion is provided with a recess that is dented toward the rear face side of the face plate and extends in the transport direction.

A rearranging device for rearranging products is adapted to pick up the products from a supply area where they are randomly arranged and arrange them in a predefined way on a receiving area. The rearranging device includes viewing means to detect the orientation of the product and a control unit for processing the detected data and activating movement means adapted to pick up the product from the supply area. Depending on what is detected by the viewing means, the movement means receive from the control unit a command to deposit the product directly on the receiving area, or to deposit it on an orienting device configured to rotate the product, and release it, once rotated, on the receiving area.