A magazine (200) is described for portion-wise receiving individualized bulk electronic components (298). The magazine (200) comprises (a) a receiving structure (110) which comprises multiple closable receiving cavities (112, 112a), which are arranged along a longitudinal axis (100a) of the receiving structure (110); (b) a cover structure (120) which is arranged at an upper side of the receiving structure (110), displaceable along the longitudinal axis (100a), so that in a closed position of the cover structure (120) all receiving cavities (112, 112a) are covered and in one opening position of multiple opening positions at least one receiving cavity (112) is free; and (c) a closure foil (225) which encompasses the cover structure (120) along the longitudinal axis (100a) in the form of a closed tape, wherein at least a part of the closure foil (225) is releasably connected to the receiving structure (110). Further, a device (430) is described for portion-wise transferring components (298) from one such magazine (200) into a reservoir (490) for a component supply device. Further, a method is described for portion-wise transferring components from one such magazine (200) into the one such reservoir (490).

A piler conveyor system for screening debris such as tare dirt from materials such as beets as the materials are conveyed across a piler. The piler conveyor system generally includes a frame supporting an upper conveyor and a pair of lower conveyors. The upper conveyor is adapted to receive materials such as beets. As the materials are conveyed by the upper conveyor, debris such as tare dirt or the like will fall through screening openings in the upper conveyor and onto the lower conveyor. The lower conveyor may then dispense the debris through a debris opening. The materials will drop off the end of the upper conveyor and fall onto the second lower conveyor, which will convey the screened materials to be dispensed.

A method for transporting material using a gravity driven pulley system is described. The method may include moving the material from a first location to a second location using a transport pulley secured to a cable and detaching the transport pulley from the cable at the second location, wherein the transport pulley is detached by a momentum of the transport pulley bringing the transport pulley into contact with a derailer attached to the cable.

A system enables management of dispensable units by supporting functions such as retrieval, scheduled distribution, analysis, and notifications. To this end, a dispensable retrieval mechanism may be programmed to carry out blind retrievals of dispensable units using a retrieval strategy with a predetermined sequence of retrieval attempts (e.g., fixed or varying two-dimensional retrieval patterns), which may be open loop or closed loop. Techniques may also include the identification of dispensable units through optical sensors and weight measurement devices that can detect, e.g., a texture, a shape, and a size of dispensable units. Such identification can be used to program retrieval attempts by a retrieval robot and in the formulation of the retrieval pattern. Additionally, networked notification systems for dispensable units can be used for updating rules or schedules related to the dispensable units, or alerting users and remote resources of any potential misuse or hazards of the dispensable units.

Connector assembly (100), system and method for converting a batch wise supply of insects (102) to a continuous supply of insects (102). A container unit is present (105) having an internal volume, a water inlet unit (106-109, 117), and a suspension outlet unit (110-113). A receiving unit (101) has a top opening (101a) arranged for receiving batch wise quantities of insects (102) and a bottom opening (114). A conveyor unit (104) has a receiving part (104b) arranged near the bottom opening (114) of the receiving unit (101), and an outlet end (119) extending into the container unit (105). By suspending the insects (102) in water it is possible to transport the suspension of insects (102) in water, e.g. to a buffer container (300).

A piler conveyor system for screening debris such as tare dirt from materials such as beets as the materials are conveyed across a piler. The piler conveyor system generally includes a frame supporting an upper conveyor and a pair of lower conveyors. The upper conveyor is adapted to receive materials such as beets. As the materials are conveyed by the upper conveyor, debris such as tare dirt or the like will fall through screening openings in the upper conveyor and onto the lower conveyor. The lower conveyor may then dispense the debris through a debris opening. The materials will drop off the end of the upper conveyor and fall onto the second lower conveyor, which will convey the screened materials to be dispensed.

A gravity-feed dispenser is connected to a hopper configured to hold a bulk material for dispense. The gravity-feed dispenser includes a spout and a valve separating the hopper from the spout. An actuator assembly is connected to the valve and includes a detectable element. The actuator assembly is operable to move the valve between open and closed conditions to selectively permit bulk material to pass from the hopper out of the spout. A fixture is configured to engage and support the gravity feed dispenser. A sensor is connected to the fixture and is positioned relative to the actuator assembly. The sensor operates to detect the detectable element of the actuator assembly and produce a signal indicative of the open condition or the closed condition.

Embodiments include a parcel processing system and methods for operating the same. The parcel processing system includes a collector configured to receive a flow of parcels and a slug accumulation system configured to receive the flow of parcels and produce a normalized bulk flow of parcels. The parcel processing system also includes a bulk transport conveyor configured to receive the normalized bulk flow of parcels and a singulator configured to receive the normalized bulk flow of parcels from the bulk transport conveyor. The normalized bulk flow of parcels is a flow of parcels having an approximately constant parcel density traveling at a fixed speed.

A piler conveyor system for screening debris such as tare dirt from materials such as beets as the materials are conveyed across a piler. The piler conveyor system generally includes a frame supporting an upper conveyor and a pair of lower conveyors. The upper conveyor is adapted to receive materials such as beets. As the materials are conveyed by the upper conveyor, debris such as tare dirt or the like will fall through screening openings in the upper conveyor and onto the lower conveyor. The lower conveyor may then dispense the debris through a debris opening. The materials will drop off the end of the upper conveyor and fall onto the second lower conveyor, which will convey the screened materials to be dispensed.

A supply device includes a replenishment device configured to replenish bolts to a surface of a table, and a supply control device configured to control the replenishment device. A determination region for determining the number of bolts is predetermined in a region where the table is disposed. When the number of bolts detected in the determination region is less than a determination value, the supply control device selects a divided region having the lowest bolt number density from among a plurality of divided regions. The supply control device controls the replenishing device so as to replenish bolts to a region of the table corresponding to the selected divided region.