A system, and associated method, for launching and delivering separated food product in organized groups to a robotized packaging station for the product. The system initiates the delivery via a metered hopper of food product delivering the product to a launch V-belt that aligns the product end to end. A successive singulator belt, positioned adjacent to and receiving product from the launch belt, further organizes the product into a single file alignment. An optional separator belt may follow the singulator belt to create gaps between successive product units. The product is then delivered to a pick belt for product to be provided to the packaging robot. The system product information is from a single (per product delivery line) sensor, enabling intergrated end-to-end control from hopper to robot, and a nearly continuous motion of said pick belt.

A material handling system includes a conveyor, an actuation unit, and a chute. The chute is mechanically coupled to the conveyor at a defined angle with respect to a surface of the conveyor. The chute includes an inlet defining a first end and a second end, where the first end of the inlet is mechanically coupled to the surface of the conveyor. Further, the chute includes at least one tube configured to be rotated by the actuation unit at a defined rotational speed. The chute also includes an outlet mechanically coupled to the at least one tube. In this aspect, the defined angle and the defined rotational speed is based on at least one of: physical characteristic of an item to be passed through the chute, a rate of inflow of the item through the inlet, and a rate of outflow of the item through the outlet.

The food inputting apparatus according to the present invention comprises: a supply unit provided so as to supply food downwardly; a chute unit comprising a chute body through which food discharged from the supply unit falls and passes due to gravity; a shutter unit provided so as to be opened or closed in accordance with whether the food discharged from the chute unit is to be discharged into packaging material, and comprising a shutter body which, when closed, is positioned between the upper part of an upwardly opened opening of the packaging material and a chute outlet provided at the bottom end of the chute unit; and a suction unit for suctioning liquid that collects inside the shutter body when closed.

A weigh hopper assembly including a plurality of adjacently aligned weigh hoppers connected via a frame, and longitudinal conveyor mechanism extending along a top portion of the weigh hopper assembly. Each weigh hopper has independent load cells in order to individually weigh the material discharged into the weigh hopper. The conveyor mechanism includes a plurality of gates along a bottom surface of the conveyor mechanism, each gate being aligned with a corresponding weigh hopper of the plurality of weigh hoppers. The conveyor mechanism is in turn connected to a plurality of product bins. A top portion of the conveyor mechanism is in communication with a plurality of product bins via a series of inlet chutes and gates. The weigh hoppers are aligned adjacent to each other and spaced so that each weigh hopper aligns with the transport vehicle.

A wet sand loading system includes a material conveyor configured for carrying wet sand from a hopper to an elevated position over a loading platform. A funnel assembly is coupled to the material conveyor. The funnel assembly has a lower end movable relative to the material conveyor to direct wet sand into the hopper in a selectable direction.

A material handling system includes a conveyor, an actuation unit, and a chute. The chute is mechanically coupled to the conveyor at a defined angle with respect to a surface of the conveyor. The chute includes an inlet defining a first end and a second end, where the first end of the inlet is mechanically coupled to the surface of the conveyor. Further, the chute includes at least one tube configured to be rotated by the actuation unit at a defined rotational speed. The chute also includes an outlet mechanically coupled to the at least one tube. In this aspect, the defined angle and the defined rotational speed is based on at least one of: physical characteristic of an item to be passed through the chute, a rate of inflow of the item through the inlet, and a rate of outflow of the item through the outlet.

The invention relates to a feed unit for a processing plant, in particular for a crushing or screening station, having a feed chute which has a chute beam (90), wherein the chute beam (90) has a bottom (92), wherein the bottom (92) extends in the conveying direction (V) of the feed chute, wherein at least one beam (130) extending in the conveying direction (V) is arranged in the area of the underside of the bottom (92) and supports the bottom (92), wherein furthermore a bracket (140) is provided, which supports at least one vibration exciter (150), and wherein the bracket (140) is connected to the beam (130). A particularly resilient and in continuous operation durable feed unit is created according to the invention by the beam forming a closed hollow section or at least a wall segment of the beam (130) in conjunction with a reinforcing section (120) connected thereto forming a closed hollow section, and the hollow section extending with an angular deviation in the range of +/15 in the direction of the excitation direction.

A device (30, 40) for the transfer of a plurality of watch components (2) arranged on a first support (10) to their arrangement on a second support (20), wherein it comprises an inlet surface (31, 41) comprising inlet orifices (33, 43) so arranged as to correspond to a first arrangement of the watch components (2) on a first support (10), an outlet surface (32, 42) comprising outlet orifices (34, 44) so arranged as to correspond to a second arrangement of the watch components (2) on a second support (20), and guide elements (35, 45) adapted to guide the watch components (2) automatically from the inlet orifices (33, 43) to the outlet orifices (34, 44).

A transfer or distribution chute for conveying bulk material by gravity flow, includes an elongated chute casing defining a flow path for bulk material and a wear-resistant lining arrangement covering at least part of a flow path facing an upper side of the elongated chute casing. The wear-resistant lining arrangement includes a perforated plate affixed to the chute casing and has a plurality of perforations through which wear-resistant inserts having a body and an enlarged base are fitted in the perforations from a side opposite the flow path, such that their body protrudes through the perforation within the flow path, and their enlarged base abuts the borders of the perforation from the side opposite the flow path on one side and is held in place by the chute casing on the other side.

An object orientation device includes a shaking stand and a slide provided on the shaking stand; the slide includes a sliding groove and a retaining member on the sliding groove. A retaining member is parallel to and extends along a sliding direction, and has a retaining surface parallel to a side wall of the sliding groove. The retaining surface and the side wall form an orientation space which is parallel to the sliding direction. After asymmetric objects are on the slide and shaken by the shaking stand, each object has a first end restricted into the orientation space, and has a seat orientation and moves towards a predetermined direction. Such object orientation device allows objects to be aligned in the slide and have consistent seat orientations; a printing equipment can print on the same position of each object. Additionally, a system and a method of orientation and printing are provided.