An auger system and method that comprises at least one auger. The auger(s) are situated in a processing chamber that is adapted to receive material to be processed by the auger(s). A hopper or chute is associated with the processing chamber in order to direct material into the processing chamber to be processed by the auger(s). The hopper or chute comprises at least one door that is adapted to move into a position to assist with suppression and/or containment of smoke and/or fire that may emanate at any time in such material (e.g., before, during, or after processing of the material by the auger(s)).

The present invention relates to a dosing device for a product in powder form, comprising a holder (10) intended to hold a first quantity of the product therein. The holder is provided with dosing means to draw off the product from the holder and move it to an outlet. The dosing means comprise a worm body (20) with a worm thread (21). In a first aspect the worm body comprises at an outer end facing toward the outflow opening at least one further worm thread (22) which runs between the first worm thread (21). In a second aspect the worm thread (21) encloses a smaller volume between successive turns at a base than between successive turns in a part thereof located further toward the outer end.

The present invention relates to a dosing device for a product in powder form, comprising a holder (10) intended to hold a first quantity of the product therein. The holder is provided with dosing means to draw off the product from the holder and move it to an outlet. The dosing means comprise a worm body (20) with a worm thread (21). In a first aspect the worm body comprises at an outer end facing toward the outflow opening at least one further worm thread (22) which runs between the first worm thread (21). In a second aspect the worm thread (21) encloses a smaller volume between successive turns at a base than between successive turns in a part thereof located further toward the outer end.

A sweep auger system having a driveshaft with auger flighting and a backboard extending a length from an inward end to an outward end. An input of a gearbox is connected to an outward end of the drive shaft and a sweep wheel having a plurality of notches, arms and feet is connected to an output of the gearbox. A drive shield is placed around a rearward side of the sweep wheel that forms a channel that is configured to capture grain agitated by the drive wheel. A guide plate is connected to the gearbox and covers a portion of the gearbox. The guide plate angles from an upper outward edge downward and forward to a lower inward edge that is configured to urge the grain captured within the channel of the drive shield to move in front of the sweep auger system reducing grain left in the grain bin.

An apparatus for receiving and conveying bulk material is provided. The apparatus comprises a hopper for receiving bulk material, at least one outlet configured to enable bulk material, received by the hopper, to exit the hopper, and an agitator arrangement. The agitator arrangement is configured to agitate the bulk material in the hopper in order to counteract cohesion of the bulk material, and configured to urge the bulk material in the hopper towards the at least one outlet.

In one aspect, the disclosure describes an apparatus comprising an auger section having an auger and a drive unit containing a motor for driving the auger. A collector ring housing containing a collector ring is positioned between the auger section and the drive unit. In another aspect, the disclosure describes an apparatus for attachment to a floor grate. The apparatus includes a pivot stand attached to a top surface of the floor grate, the pivot stand defining a vertical pivot axis. A collector ring has a first stationary portion and a second rotatable portion, with the stationary portion attached to the pivot stand. A housing surrounds the collector ring, and the housing and second rotatable portion of the collector ring rotate together about the pivot axis.

A storage silo for storing granular material has a container supported by a base, the container having a roof and at least one side wall for defining a storage space beneath the roof. The storage silo includes: (a) a feed port for receiving the granular material at a feed-port height lower than the roof; (b) an auger for moving the granular material toward the roof within the storage space, the auger receiving the granular material via the feed port; and (c) first and second auger motors for cooperatively driving the auger, the first and second auger motors being disposed at opposing ends of the auger. A processor determines power levels for the first and second auger motors to minimize torsional strain on the auger. Granular material can be discharged from a first storage silo into a second storage silo positioned for cascading with the first storage silo.

There is herein described an apparatus and method for feeding bulk material. More particularly, there is described an apparatus and method for feeding bulk material such as bulk solids which provides a constant and reliable feed of material.

A system for handling particulate material includes a vessel and an outflow conveyor. The vessel includes an inlet configured for receipt of particulate material into the vessel, and a plurality of discharge conveyors. Each discharge conveyor is configured to move particulate material in the vessel towards a corresponding discharge valve. The outflow conveyor is configured to receive particulate material from each discharge valve.

A system for handling particulate material includes a vessel and an outflow conveyor. The vessel includes an inlet configured for receipt of particulate material into the vessel, and a plurality of discharge conveyors. Each discharge conveyor is configured to move particulate material in the vessel towards a corresponding discharge valve. The outflow conveyor is configured to receive particulate material from each discharge valve.