A method for ascertaining a compaction state of silage stored in a flat silo, in which a work vehicle used for compacting the silage has inflated tires on at least one vehicle axle, includes in a first step, via an acceleration sensor, one or more of a normal and a tangential acceleration occurring in a tire bead is detected and wirelessly transmitted in the form of sensor data corresponding thereto to a processor unit, in a second step, starting from the transferred sensor data from the processor unit, the deformations of the tire casing occurring in each case during the rolling of the tire in an entry point and an exit point are ascertained and compared to one another, and in a third step, based on the comparison, a compression behavior and in turn therefrom the compaction state of the silage is determined by the processor unit.

Systems and method for forming a stable silo face in bulk material are disclosed. Particularly, systems and methods for forming a negative rake angle in a silo face of bulk silage are disclosed. Rotation of an articulated arm (e.g., raising and lowering), altering a length of the articulated arm (e.g., extension or retraction), and movement of a machine relative to the silo face (towards and away from) may be automatically controlled to form the negative rake angle. Different implementations contemplate automated control of all or fewer than all of these operations.

A method for assisting a compaction-appropriate distribution of harvested material in a flat silo includes providing a silo vehicle having a control unit, ascertaining a dry-substance density to be achieved via the control unit, determining a maximally producible compaction pressure via the control unit, ascertaining a maximally permissible layer thickness via the control unit for the implementation of a distribution-and-compaction process, determining a layer thickness currently being applied during the implementation of the distribution-and-compaction process in a location-specific manner via a GPS receiver, comparing the maximally permissible layer thickness and the layer thickness currently being applied in the location-specific manner via the control unit in order to ascertain a target layer thickness, and driving a regulating device of a distribution tool provided on the silo vehicle to assimilate the layer thickness currently being applied to the target layer thickness via the control unit in an automated manner.

A method for compacting silage in a silo includes controlling a compacting vehicle via an electronic control device, passing over the silage deposited in the silo with the compacting vehicle, exerting a compacting action along a compacting path via the compacting vehicle, and varying the compacting action of the compacting vehicle in a location-dependent manner along the compacting path by the action of the control device.

A grain spreading device for evenly distribute grain as it is poured into a storage bin. The grain spreading device generally includes a flow-control ring (e.g., an evenflow ring) adapted to be positioned below a grain bin opening, the flow-control ring comprising an upper opening and a bottom, and a cone movably suspended below the flow-control ring by a plurality of springs to create a variable opening between the cone and the bottom of the flow-control ring, the plurality of springs creating a restoring force, wherein the variable opening increases in size when a weight of grain on the cone moves the cone away from the bottom of the flow-control ring against the restoring force of the plurality of springs.

A method for assisting a compaction-appropriate distribution of harvested material in a flat silo includes providing a silo vehicle having a control unit, ascertaining a dry-substance density to be achieved via the control unit, determining a maximally producible compaction pressure via the control unit, ascertaining a maximally permissible layer thickness via the control unit for the implementation of a distribution-and-compaction process, determining a layer thickness currently being applied during the implementation of the distribution-and-compaction process in a location-specific manner via a GPS receiver, comparing the maximally permissible layer thickness and the layer thickness currently being applied in the location-specific manner via the control unit in order to ascertain a target layer thickness, and driving a regulating device of a distribution tool provided on the silo vehicle to assimilate the layer thickness currently being applied to the target layer thickness via the control unit in an automated manner.

A grain spreading device for evenly distribute grain as it is poured into a storage bin. The grain spreading device generally includes a flow-control ring (e.g., an evenflow ring) adapted to be positioned below a grain bin opening, the flow-control ring comprising an upper opening and a bottom, and a cone movably suspended below the flow-control ring by a plurality of springs to create a variable opening between the cone and the bottom of the flow-control ring, the plurality of springs creating a restoring force, wherein the variable opening increases in size when a weight of grain on the cone moves the cone away from the bottom of the flow-control ring against the restoring force of the plurality of springs.

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.

A forage compactor is provided having a frame that has cross bars supporting risers that in turn support a shaft. At least one asymmetric wheel is supported by the shaft. The wheels can be paired whereby journals are used to connect to the shaft between recesses of respective wheels. Each wheel has a first side and a second side, each with radiused portions that turn forage away from the wheel. The wheels have a band that is flush with the outer portion of the wheel sides to prevent lifting of the forage. A storage assembly is provided and is integrated into the framework. The storage assembly can be stored within the frame when the compactor is in use, and can be deployed to a locked position in order to store the compactor. A hitch framework is provided that can attach to multiple categories of three point hitches.

A grain spreader wherein grain received in the hopper is directed to spreader arms by a spreader cone. The spreader cone has a convergent cone and a divergent cone. The spreader cone has a center opening that allows a first portion of the grain collecting in the convergent cone to pass through and fall through the underside of the divergent cone. The grain spreader further includes support springs that lift the spreader cone upwards into the hopper when the spreader cone is lightly loaded. A center flow choke is configured to throttle the flow of grain through the center opening to partially close the center opening in low grain flow conditions, wherein the center flow choke is mounted to the hopper body such that up and down movement of the spreader cone moves the center opening into or out of engagement with the center flow choke.