A method of storing harvested crop material in a silo includes loading the harvested crop material into a container of a transport vehicle in a field. The container includes a discharge system that is operable to unload the crop material, and which is controlled via an electronic control device. The crop material is transported from the field to the silo with the transport vehicle. The crop material is unloaded from the container of the transport vehicle directly into the silo with the discharge system. The electronic control device automatically controls at least one of the transport vehicle and the discharge system while unloading the crop material to form a harvested material layer in the silo having a predetermined layer thickness.

A vehicle includes a frame, a tractive element coupled to the frame, a prime mover coupled to the frame and configured to drive the tractive element to propel the vehicle, and a silage compactor. The silage compactor includes a wheel rotatably coupled to the frame and positioned to engage silage positioned below the frame, a vibrator coupled to the wheel and configured to cause the wheel to vibrate, and a controller configured to control the vibrator to vibrate the wheel while the wheel is in contact with the silage to compress the silage.

A control system for a working machine includes a ground engaging structure which performs a compaction operation by passing over a body of a harvested crop. The control system includes a controller and at least one sensor providing an input to the controller. The controller is configured to determine a state of compaction of a section of the body of the harvested crop based on at least the input from the sensor, and provides at least one output to control the movement of the working machine over the body of the harvested crop and also provides an indication to an operator of the working machine as to the state of compaction of the body of the harvested crop at a particular section thereof.

A compactor includes a frame supporting a first roller assembly and a second roller assembly. At least one of the first roller assembly and the second roller assembly is moveable relative to the frame in a motion that includes an upward vertical component and a downward vertical component. An actuator is coupled to at least one of the first and second roller assemblies and is operable to repeatedly move at least one of the roller assemblies relative to the frame in both the upward vertical component and the downward vertical component to oscillate the roller assemblies relative to each other.

A system and method for remotely managing content levels in one or more defined areas includes a computer system communicatively connected to one or more resident sensor units and controllers linked to devices such as content loading drive mechanisms and/or supply reordering modules. When a sensor reports that a content level is or will be lower or higher than desired, the computer system generates an alert and forwards the alert across a wireless communications network to a user's mobile device. The user may select a user command to send to the computer system, whereupon the computer system may selectively regulate the content levels in accordance with the response action or alternatively override the user command based upon one or more contextual determinations.

A grain storage arrangement, the arrangement including: a generally box-shaped grain storage receptacle enclosing a grain receiving space; the storage receptacle including a base, a top, two opposite sidewalls, a first end wall, and a second end wall opposite the first end wall; a receptacle support, wherein the receptacle support supports the receptacle such that the base slopes downwardly from the first end wall to the second end wall; a grain inlet provided on or proximate to the first end wall for adding grain to the receptacle; and a grain outlet provided on or proximate to the second end wall for removing grain from the receptacle.

A sensor arrangement for detecting a density of harvested crops deposited as silage in a silo includes a source of a pressurized gaseous medium and an opening connected by a line to the source and which is movable along a surface of the silage. The gaseous medium is guided out of the opening from the source into the silage. The arrangement further includes a sensor for detecting a property of the medium flowing through the line, and an evaluation device connected to the sensor for providing an output signal containing information based on the signal of the sensor regarding the density of the silage.

A method and system of a pneumatic conveying system for moving separated grain and small plant material to an onboard storage tank or out of the combine harvester. The pneumatic conveying system having a gateway for introducing the material into an air flow channel, and with a diverter valve or an airlock directing separated grain and small plant material to the tank or outside of the harvester.

A grain storage arrangement, the arrangement including: a generally box-shaped grain storage receptacle enclosing a grain receiving space; the storage receptacle including a base, a top, two opposite sidewalls, a first end wall, and a second end wall opposite the first end wall; a receptacle support, wherein the receptacle support supports the receptacle such that the base slopes downwardly from the first end wall to the second end wall; a grain inlet provided on or proximate to the first end wall for adding grain to the receptacle; and a grain outlet provided on or proximate to the second end wall for removing grain from the receptacle.

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.