A diversion assembly for use with a feed material. The diversion assembly includes a plurality of movable gate chutes, a first conveyor, and a second conveyor. The plurality of movable gate chutes are each positionable in a retracted position and an extended position. The first conveyor is configured to carry, for each of any of the plurality of movable gate chutes in the retracted position, a first portion of the feed material to a first area. The second conveyor is configured to carry, for each of any of the plurality of movable gate chutes in the extended position, a second portion of the feed material to a second area. The second area is spaced apart from the first area.

A feeder device for feeding powder, having a barrel feeding channel with a downstream end. The feeding channel including at least one conveying element for conveying the powder material to the downstream end. A rotatable exit element provided at the downstream end of the feeding channel. The rotatable exit element includes an annular portion defining exit openings defined by powder engaging edges. The rotatable exit element is positioned transversally outside the barrel in a proximity of the downstream end of the feeding channel. The feeding channel has a first, inner diameter and the rotatable exit element has a second, outer diameter, where the second, outer diameter is equal to or larger than the first inner diameter.

A feeder device for feeding powder, having a barrel feeding channel with a downstream end. The feeding channel including at least one conveying element for conveying the powder material to the downstream end. A rotatable exit element provided at the downstream end of the feeding channel. The rotatable exit element includes an annular portion defining exit openings defined by powder engaging edges. The rotatable exit element is positioned transversally outside the barrel in a proximity of the downstream end of the feeding channel. The feeding channel has a first, inner diameter and the rotatable exit element has a second, outer diameter, where the second, outer diameter is equal to or larger than the first inner diameter.

A telescoping rotatable tool includes a first shaft and a second shaft. The first shaft has a first material-engaging element extending from an exterior surface of the first shaft. The second shaft has a second material-engaging element extending from an exterior surface of the second shaft. The second shaft is configured to extend from and retract within an interior space presented by the first shaft. The first shaft includes at least one helical-shaped groove extending along an interior surface of the first shaft. The second shaft includes at least one guide element extending from the exterior surface of the second shaft. The guide element is configured to engage with the groove, such that as the second shaft extends from and retracts within the first shaft, the second shaft is configured to rotate with respect to the first shaft.

An auger assembly (1) for receiving and conveying cheese curd downstream along a cheese processing line (32) includes an auger housing (2), a first auger (3) having a first shaft (5) extending through the auger housing (2), a second auger (4) having a second shaft (6) extending through the auger housing (2) and arranged colinearly with the first shaft (5), a first bearing (9) mounted to the auger housing (2) and arranged at the end (7) of the first shaft (5), and a second bearing (10) mounted to the auger housing (2) and arranged at the end (8) of the second shaft (6). The first bearing (9) and second bearing (10) are colinear and facing each other. At least one slotted groove (11, 12) is formed the bearings (9, 10) to enable a cleaning fluid to contact a surface (13, 14) of the respective bearing (9, 10).

An auger assembly (1) for receiving and conveying cheese curd downstream along a cheese processing line (32) includes an auger housing (2), a first auger (3) having a first shaft (5) extending through the auger housing (2), a second auger (4) having a second shaft (6) extending through the auger housing (2) and arranged colinearly with the first shaft (5), a first bearing (9) mounted to the auger housing (2) and arranged at the end (7) of the first shaft (5), and a second bearing (10) mounted to the auger housing (2) and arranged at the end (8) of the second shaft (6). The first bearing (9) and second bearing (10) are colinear and facing each other. At least one slotted groove (11, 12) is formed the bearings (9, 10) to enable a cleaning fluid to contact a surface (13, 14) of the respective bearing (9, 10).

A gearbox below a grain bin floor can have a shift coupling movable between a drive position and a neutral position. A control rod can be axially movable between a corresponding drive position and a corresponding neutral position. A pair of biasing members can be operably positioned between the control rod and the shift coupling to bias the shift coupling in opposite directions. The opposite biasing forces of the biasing members can act against each other to bias the control rod into the neutral positioning recess to retain the external shift coupling and the control rod in the neutral position and the corresponding neutral position, respectively. The opposite biasing force of the biasing members can bias the control rod into the drive positioning recess to retain the external shift coupling and the control rod in the drive position and the corresponding drive position, respectively.

A diversion assembly for use with a feed material. The diversion assembly includes a plurality of movable gate chutes, a first conveyor, and a second conveyor. The plurality of movable gate chutes are each positionable in a retracted position and an extended position. The first conveyor is configured to carry, for each of any of the plurality of movable gate chutes in the retracted position, a first portion of the feed material to a first area. The second conveyor is configured to carry, for each of any of the plurality of movable gate chutes in the extended position, a second portion of the feed material to a second area. The second area is spaced apart from the first area.

A bulk feed tank has a boot unloader through which feed is directed into a supply system having at least one conveyor housing an auger. The boot unloader includes an unloader body formed of front, rear and opposing side panels forming a rectangular receiving portion. An auger mounting plate is mounted to the front panel and mates with the conveyor. A bearing assembly is secured to the rear panel and rotatably mounts the auger such that the auger passes through the receiving portion. A clear access door is attached to at least one of the opposing side panels. A wear plate assembly is attached to an. The wear plate assembly is fastened to the front, rear and side panels under the boot unloader body and can be removed without unfastening the side panels from the front panel and the rear panel or removing the auger from the receiving portion.

A bulk feed tank has a boot unloader through which feed is directed into a supply system having at least one conveyor housing an auger. The boot unloader includes an unloader body formed of front, rear and opposing side panels forming a rectangular receiving portion. An auger mounting plate is mounted to the front panel and mates with the conveyor. A bearing assembly is secured to the rear panel and rotatably mounts the auger such that the auger passes through the receiving portion. A clear access door is attached to at least one of the opposing side panels. A wear plate assembly is attached to an. The wear plate assembly is fastened to the front, rear and side panels under the boot unloader body and can be removed without unfastening the side panels from the front panel and the rear panel or removing the auger from the receiving portion.