The invention relates to a machine for handling waste material, the machine comprising an upper conveyor member with a conveying portion of a first width, a downstream lower conveyor member with a receiving portion of equal or greater width and an apparatus for distributing material from the upper conveyor member to the downstream lower conveyor member, wherein the apparatus comprises oscillating means, a drive mechanism connected to the oscillating means; and a protruding element attached to the oscillating means for oscillatory movement thereof, wherein the protruding element is a reciprocating attachment adapted to oscillate in a direction transverse to the direction in which it extends, wherein the apparatus is mountable between the conveying portion of the upper conveyor member and the receiving portion of the downstream lower conveyor member such that the protruding element extends substantially in the direction of conveyance of the downstream conveyor member; and wherein in use the oscillating protruding element agitates material being transferred from the upper conveyor member to the downstream lower conveyor member.

The invention relates to a machine for handling waste material, the machine comprising an upper conveyor member with a conveying portion of a first width, a downstream lower conveyor member with a receiving portion of equal or greater width and an apparatus for distributing material from the upper conveyor member to the downstream lower conveyor member, wherein the apparatus comprises oscillating means, a drive mechanism connected to the oscillating means; and a protruding element attached to the oscillating means for oscillatory movement thereof, wherein the protruding element is a reciprocating attachment adapted to oscillate in a direction transverse to the direction in which it extends, wherein the apparatus is mountable between the conveying portion of the upper conveyor member and the receiving portion of the downstream lower conveyor member such that the protruding element extends substantially in the direction of conveyance of the downstream conveyor member; and wherein in use the oscillating protruding element agitates material being transferred from the upper conveyor member to the downstream lower conveyor member.

According to embodiments disclosed herein, there is provided a delivery box system to deliver a commodity material. In various instances, a single auger configuration, a dual auger configuration, a vertical auger configuration and/or further configurations or combinations of configurations are contemplated as described. One or more auger facilitates the metered release of the commodity material and ameliorates jamming of the commodity material against aspects of the delivery box system.

A conveyor station, robot module, sweeper module, and methods for autonomously emptying debris using the conveyor station are described. In one example, a conveyor station includes a housing having an input end and an output end. The conveyor station includes a conveyor belt having a receiving region proximate to the input end and an angled transport region leading toward a dispense region. The conveyor belt has a plurality of fins that extend out from a surface of the conveyor belt. The plurality of fins enable movement of debris collected at the receiving region toward the dispense region. The dispense region is configured to push debris into a drop funnel of the housing, and the drop funnel directs debris into a receptacle. The conveyor station includes a conveyor controller of the conveyor station is configured with a sensor for detecting presence of a sweeper module. The sweeper module includes a container that holds debris collected when the sweeper module is connected to a robot module. The debris is configured to be emptied from said sweeper module directly onto said receiving region of the conveyor belt.

A conveyor station, robot module, sweeper module, and methods for autonomously emptying debris using the conveyor station are described. In one example, a conveyor station includes a housing having an input end and an output end. The conveyor station includes a conveyor belt having a receiving region proximate to the input end and an angled transport region leading toward a dispense region. The conveyor belt has a plurality of fins that extend out from a surface of the conveyor belt. The plurality of fins enable movement of debris collected at the receiving region toward the dispense region. The dispense region is configured to push debris into a drop funnel of the housing, and the drop funnel directs debris into a receptacle. The conveyor station includes a conveyor controller of the conveyor station is configured with a sensor for detecting presence of a sweeper module. The sweeper module includes a container that holds debris collected when the sweeper module is connected to a robot module. The debris is configured to be emptied from said sweeper module directly onto said receiving region of the conveyor belt.

Provided is an improved animal feed distribution system and components, specifically tube belt conveyor system, that provides more efficient manner of delivering feed to the animals, such as poultry by using tube conveyor belt to distribute feed in a re-circulating loop.

Provided is an improved animal feed distribution system and components, specifically tube belt conveyor system, that provides more efficient manner of delivering feed to the animals, such as poultry by using tube conveyor belt to distribute feed in a re-circulating loop.

A sweep conveyor assembly is provided for use in a silo or granary (70) having a floor (71), a generally cylindrical wall (72) upstanding from the floor (71) and a discharge apparatus (1) for discharging material (74) from a centre of the floor (71) to an exterior location. The sweep conveyor assembly has a sweep conveyor (S) for transporting material (74) inside the silo (S) or granary towards the centre of the floor (71) where it can be discharged by the discharge apparatus (1), a holder (H), and a link mechanism (8) for connecting the sweep conveyor (S) to the holder (H), and in turn having a connection link (L) with a first end (83) and a second end (84). The first end (83) is connected to the holder (H) at a fixed pivot point and the sweep conveyor (S) is connected to the second end (84) of the connection link (L) at a movable pivot point. The connection link (L) rotates about the fixed pivot point, forming a first angle () between the connection link (L) and the holder (H), and the sweep conveyor (S) rotates about the movable pivot point, forming a second angle () between the sweep conveyor (S) and the connection link (L). The link mechanism (8) controls a ratio between the first angle () and the second angle (), with a magnitude of the first angle () and second angle () controlled by an angular position of the sweep conveyor (S).

A sweep conveyor assembly is provided for use in a silo or granary (70) having a floor (71), a generally cylindrical wall (72) upstanding from the floor (71) and a discharge apparatus (1) for discharging material (74) from a centre of the floor (71) to an exterior location. The sweep conveyor assembly has a sweep conveyor (S) for transporting material (74) inside the silo (S) or granary towards the centre of the floor (71) where it can be discharged by the discharge apparatus (1), a holder (H), and a link mechanism (8) for connecting the sweep conveyor (S) to the holder (H), and in turn having a connection link (L) with a first end (83) and a second end (84). The first end (83) is connected to the holder (H) at a fixed pivot point and the sweep conveyor (S) is connected to the second end (84) of the connection link (L) at a movable pivot point. The connection link (L) rotates about the fixed pivot point, forming a first angle () between the connection link (L) and the holder (H), and the sweep conveyor (S) rotates about the movable pivot point, forming a second angle () between the sweep conveyor (S) and the connection link (L). The link mechanism (8) controls a ratio between the first angle () and the second angle (), with a magnitude of the first angle () and second angle () controlled by an angular position of the sweep conveyor (S).

A bulk material conveyor include a housing having a first end with an inlet and a second end with a discharge and a conveyor at least partially positioned in the housing and extending from the inlet to the discharge. A support assembly has a base frame and an extension mechanism operably connected to the base frame for positioning the housing into an inclined position. A motor assembly is configured to drive the conveyor for advancing bulk material through the housing. A hopper is disposed at the intake end of the housing and includes a tapered wall section extending downwardly from a first end to a second end adjacent the inlet in the housing. A gate assembly is interposed between the hopper and the housing and includes a door positionable between a closed position and a fully opened position for metering the bulk material directed into the housing at the inlet.