Disclosed is an apparatus that can transport a payload (e.g., a parcel, package, box, bag) from one position in a facility to any other point via conveyance on an overhead track system. It can be used to move a payload from the warehousing portion of the facility to the shipping area but can also transport to a value-add station where additional labor/material(s) can be added to the payload or any other destination required. It can also be loaded at most any location due to the small footprint of the induction stations to be brought to shipping or back to warehousing.

A transport device has a position detection portion, a holding portion attached to an arm, a driving portion to drive the holding portion and the arm, and a control portion. A control portion controls the position detection portion and the driving portion to perform, as one cycle, a procedure to detect a position of a parcel, select parcels based on a predetermined condition, and set priority for the selected parcels, and a procedure to refer to a result of the detection, and cause the holding portion to take out one or more parcels from the accumulation portion in accordance with the priority to transport the parcels to a predetermined location, and excludes, from parcels to be taken out, a second parcel that is present within a predetermined distance from a first parcel and has priority lower than the priority of the first parcel, during the one cycle.

A transport apparatus for poultry bodies/parts includes a frame, a transport unit on the frame with a revolvingly driven transport device, and a holding apparatus for saddling/holding the poultry during transport/processing. The holding apparatus includes a clamping device with a clamping hook pivotable by an actuating mechanism about a rotational axis from a standby into a clamping position and back. The actuating mechanism includes an adjusting lever pivotable about a rotational axis into connection with an actuating member, on the frame along the transport path, for pivoting the adjusting lever and hook. The holding apparatus rotates relative to the transport device about an axis perpendicular to the transport direction, and is brought into operative connection with an actuating lever on the frame. The adjusting lever rotational axis is oriented perpendicular to the hook axis. The actuating lever for rotating the holding apparatus is before the adjusting lever actuating member.

A combine feeder slat having a first base, a second base, and a slat body. The bases are located at respective ends of the slat, and have respective upper and lower surfaces. The slat body extends longitudinally and connects the bases. The slat body has a variable profile as viewed along the longitudinal direction, that transitions from a first profile shape at the first base, to an intermediate profile shape between the first base and the second base, to a second profile shape at the second base. The intermediate profile shape includes a front lip, a rear lip, and an upward-facing concave projection that connects the front lip to the rear lip and extends below an attachment plane defined between the first lower surface and the second lower surface. The first base, second base, and slat body are made from a unitary metal part.

A combine feeder slat having a first base, a second base, and a slat body. The bases are located at respective ends of the slat, and have respective upper and lower surfaces. The slat body extends longitudinally and connects the bases. The slat body has a variable profile as viewed along the longitudinal direction, that transitions from a first profile shape at the first base, to an intermediate profile shape between the first base and the second base, to a second profile shape at the second base. The intermediate profile shape includes a front lip, a rear lip, and an upward-facing concave projection that connects the front lip to the rear lip and extends below an attachment plane defined between the first lower surface and the second lower surface. The first base, second base, and slat body are made from a unitary metal part.

A combine feeder slat having a first base, a second base, and a slat body. The bases are located at respective ends of the slat, and have respective upper and lower surfaces. The slat body extends longitudinally and connects the bases. The slat body has a variable profile as viewed along the longitudinal direction, that transitions from a first profile shape at the first base, to an intermediate profile shape between the first base and the second base, to a second profile shape at the second base. The intermediate profile shape includes a front lip, a rear lip, and an upward-facing concave projection that connects the front lip to the rear lip and extends below an attachment plane defined between the first lower surface and the second lower surface. The first base, second base, and slat body are made from a unitary metal part.

A combine feeder slat having a first base, a second base, and a slat body. The bases are located at respective ends of the slat, and have respective upper and lower surfaces. The slat body extends longitudinally and connects the bases. The slat body has a variable profile as viewed along the longitudinal direction, that transitions from a first profile shape at the first base, to an intermediate profile shape between the first base and the second base, to a second profile shape at the second base. The intermediate profile shape includes a front lip, a rear lip, and an upward-facing concave projection that connects the front lip to the rear lip and extends below an attachment plane defined between the first lower surface and the second lower surface. The first base, second base, and slat body are made from a unitary metal part.

A product management system (100) including a first panel (102) with a first continuous track (106) including a queuing section, a product engagement section and a return section, and a first series of magnetic sources (115) disposed circumferentially along the first continuous track (106). A first series of lugs (116) are movably dispersed around the first continuous track (106) configured to react to the first series of magnetic sources in order to increase or decrease a velocity of each lug (116) of the first series of lugs along the first continuous track (116) and a product engagement member (118) attached to each lug configured and adapted to actuate to engage a product.

Some embodiments relate to printing system is described that has an intermediate transfer member (ITM) in the form of a seamed endless belt for transporting an ink image from an image forming station, at which an ink image is deposited on ITM, to an impression station, where the ink image is transferred onto a printing substrate. Two drive members are provided for movement in synchronism with one another. Rotation of the drive members during installation of a new ITM serves to thread the strip through the printing system by pulling the strip from its leading end. Alternatively or additionally, indirect printing system comprising the ITM and an image forming station at which droplets of ink are applied to the ITM to form ink images thereon is disclosed. One or more blowing mechanisms (e.g. associated with the image forming station) are disclosed herein.

Apparatuses, systems, and methods are provided for transplanting slips with an automated slip transplanter. The transplanter comprises a planter unit, a singulation unit, a conveyor belt, a node sensor, and a controller. The planter unit is configured to plant consistent rows of evenly spaced slips in a field. The singulation unit comprises automated grippers and slip cartridges, and is configured to continuously singulate harvested slips stored in the slip cartridges. The conveyor belt is configured to receive the singulated slips from the automated grippers with brushed holders, and transfer the received slips on a belt to the planter unit. The node sensor is configured to autonomously collect performance data of the singulated slips in real-time. The controller is communicatively coupled to the node sensor, and configured to implement operational modes and dynamically adjust a planting slip rate based on the operational modes and performance data collected by the node sensor.