A combine harvester including a cleaning shoe, having a tailings auger for collection of tailings, a tailings collection bin and apparatus for moving material from the tailings auger to the tailings collection bin.

The invention provides an unloading system which can be arranged to move a bin or box a distance away from metering equipment of an agricultural machine, such as a dry pneumatic applicator, to allow access to bottom oriented-gates of the bin and retractable chutes for directing particulate material out of the bin and away from the machine. In one aspect, the bin can be lifted or vertically raised by one or more cylinders to allow access to the bottom gates and allow gravity to empty the material from the box, through the bottom gates, down one or more chutes directed to a particular area. One or more hoppers of the bin, typically 1 to 4, can each have a bottom positioned slide gate or door that can be operated to expose a chute for emptying the material out of the box.

A vehicle automated unloading system may include a fill model and an unloading controller. The fill model is a model of a fill characteristic of a container as a function of variables comprising material unloading times, material unloading rates and material unloading locations. The unloading controller is to (a) determine a current model-based fill characteristic of the container using the dynamic fill model and (b) output control signals to adjust at least one of a material unloading time, a material unloading rate and a material unloading location based upon the current model-based fill characteristic of the container.

An agricultural product delivery applicator for delivering particulate product to a field. The applicator comprises a bin to hold the product, a pneumatic conveying system to provide an airflow, a metering system operably connected between the supply compartment and the pneumatic conveying system, and a rail system. The metering system meters product with the airflow to result in a mixed flow of airflow and product. The rail system includes first and second foldable rails.

A foldable auger having a first and second auger assemblies, each having a respective housing, auger screw and rotation axis. A pivot joins the assemblies, and is configured to permit the second auger assembly to fold relative to the first auger assembly. A first drive coupler is located at an end of the first auger screw and offset from the first axis, and a second drive coupler is located at an end of the second auger screw and offset from the second axis. A drive sleeve is rigidly connected to the end of the second auger screw. The drive sleeve has at least one slot that slidingly receives the second drive coupler. The second drive coupler is movable between a first position in driving connection with the first drive coupler, and a second position not in driving connection with the first drive coupler.

A farm implement includes a frame, a container mounted on the frame, an intake housing rotatably connected to a front wall of the container proximate to a discharge opening, a first auger assembly, and a second auger assembly. The first auger assembly is disposed in the container and conveys agricultural material through the discharge opening. The second auger assembly is rotatably connected to an outlet of the intake housing and includes an inlet that receives agricultural material from the intake housing and an outlet that discharges agricultural material. The farm implement further includes a first mounting assembly and a second mounting assembly disposed along the front wall. The second auger assembly is mounted on one of the first and second mounting assemblies at an operating position, without being mounted to the other one of the first and second mounting assemblies.

In a grain unloading system for a combine harvester a grain bin includes a frame, the frame has a floor with a trough. An unloading auger is disposed at least partially within the trough. An auger cover at least partially covers the auger. The auger cover has a hat for a top portion of the auger cover and a pair of gates movable between the hat and locations on the floor that are proximal to the trough. A gate adjustment structure is coupled to the pair of gates to move the pair of gates relative to the auger. A control system is coupled to the gate adjustment structure and configured to control the gate adjustment structure.

A system for sensing harvested crop levels within a crop tank of an agricultural harvester includes a tank cover section movable between an open position and a covered position relative to an opening of the crop tank. The system includes a sensor array including crop level sensors configured to capture data indicative of a crop level of harvested crop. The sensor array is supported, at least in part, relative to the crop tank such that the sensor array is configured to have a first orientation when the tank cover section is in the covered position and a second orientation when the tank cover section is in the open position. The sensor array defines a first vertical dimension when the sensor array is disposed in the first orientation that is less than a second vertical dimension defined by the sensor array when the sensor array is disposed in the second orientation.

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 agricultural harvester includes a cutting head configured to harvest an agricultural material, a transfer mechanism configured to transfer the harvested agricultural material from the agricultural harvester, and a fill management system. The fill management system is configured to provide open-loop control of an automated transfer of the agricultural material from the agricultural harvester. The fill management system includes a controller, a user interface module coupled to the controller and configured to receive user input indicative of a selected nudge direction, and a wireless communication module coupled to the fill management system and configured to communicate wirelessly with a receiving vehicle. The wireless communication module is configured to obtain storage dimensions relative to the receiving vehicle from the receiving vehicle. At least one sensor is operably coupled to the transfer mechanism and provides a sensor signal that is indicative of flow of the agricultural material through the transfer mechanism. The controller is configured to automatically generate relative positional adjustments between the agricultural harvester and the receiving vehicle based on the signal indicative of flow through the transfer mechanism and the storage dimensions relative to the receiving vehicle.