A grain facility has a grain receiving station and a grain transport line with a grain elevator, a distributor with at least one input spout, and at least one grain bin. The grain transport line moves grain from the grain receiving station to one of the at least one grain bins and the distributor directs the grain to a selected bin of the at least one grain bin. The grain facility further includes an optical sensing system having at least one optical sensor positioned in the grain transport line at or before the distributor, wherein the optical sensing system senses the type of grain in the grain transport line. A control system determines if the grain passing through the grain transport line is suitable for the selected grain bin and produces an alarm if the grain in the grain transport line is not suitable for the selected grain bin.

A grain facility has a grain receiving station and a grain transport line with a grain elevator, a distributor with at least one input spout, and at least one grain bin. The grain transport line moves grain from the grain receiving station to one of the at least one grain bins and the distributor directs the grain to a selected bin of the at least one grain bin. The grain facility further includes an optical sensing system having at least one optical sensor positioned in the grain transport line at or before the distributor, wherein the optical sensing system senses the type of grain in the grain transport line. A control system determines if the grain passing through the grain transport line is suitable for the selected grain bin and produces an alarm if the grain in the grain transport line is not suitable for the selected grain bin.

A portable grain storage bin including a circular sidewall having a top edge and a bottom edge, a conical cover coupled to and extending upwardly and radially inwardly from the top edge of the circular sidewall, to an opening and a partial floor extending radially inwardly from the bottom edge of the circular sidewall and terminating at a free edge. The circular sidewall, conical cover and partial floor are movable between a collapsed configuration when empty and a deployed configuration when filled.

The present invention relates to a sweep conveyor assembly for use in a silo or granary (70) having a floor (71) and 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 (S) assembly comprising: 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), a link mechanism (8) for connecting the sweep conveyor (S) to the holder (H), said link mechanism (8) comprising a connection link (L) having a first end (83) and a second end (84), said first end (83) being configured to be connected to the holder (H) at a fixed pivot point and the sweep conveyor (S) being configured to be connected to the second end (84) of the connection link (L) at a movable pivot point, wherein the connection link (L) is arranged to rotate about the fixed pivot point, forming a first angle (+) between the connection link (L) and the holder (H) and wherein further the sweep conveyor (S) is arranged to rotate about the movable pivot point, forming a second angle () between the sweep conveyor (S) and the connection link (L), and wherein the link mechanism (8) is arranged to control a relation between the first angle () and the second angle (), and a magnitude of the first angle () and second angle () is controlled by an angular position of the sweep conveyor (S).

A modular storage bin sweep system utilizing paddles to sweep particulate matter across a floor may comprise a sweep assembly including at least two units connectable together. The assembly may comprise a plurality of interconnected paddles, a power unit configured to the paddles, a drive unit configured to move the sweep assembly with respect to a surface of the bin below the sweep assembly. In some embodiments, a traction enhancement structure may increase traction of the drive unit on the floor. In some embodiments, a pivot unit is configured to permit a degree of pivotability of the axes of the units with respect to each other, and may be combined with a drive unit. In some embodiments, the power unit includes a rotary electrical power transfer structure configured to transfer electrical power to the power unit when rotating in the bin.

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.

A material handling device for the loosening of forage, in particular silage from a silo. The material handling device is provided with a grab device provided with grab device members of which the edges facing towards each other are provided with cutting elements. The grab device members are movable between a closed position and an opened position, wherein the cutting elements are positioned at an angle with the vertical. This angle is in the range of 25 to 25 degrees, preferably 15 to 15 degrees with the vertical.

A modular logistics system (10) including: a container (12) having a top (14), a base (16), side walls (18) and end walls (20); and a storage frame (23) housed within the container (12) in an operationally ready state, wherein in a first configuration the side walls (18) and end walls (20) are fixed to form an enclosure around the storage frame (23) for transport of the storage system (10), and in a second configuration the end panels (20) are removable to allow extension of the storage frame (23), and at least a portion of one of the side walls (18) is removable to provide access to the storage frame (23) during use, so that the container (12) and the storage frame (23) are transported and installed as a single unit.

A control system for controlling a shared variable frequency drive for operating more than one mechanical systems of a grain bin. The control system includes at least one processor circuit that is configured to operate the shared VFD in both a first mode, wherein operating in the first mode results in operating a fan assembly of the grain bin, and a second mode, wherein operating in the second mode results in operating an unload sweep assembly within the grain bin.

A sweep auger system having a driveshaft with auger fighting 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.