A dual conveyor assembly for a windrower includes upper and lower conveyors. Each conveyor includes an endless conveyor element and rotatable supports spaced along a longitudinal conveyor path and entrained by the endless conveyor element. The endless conveyor elements define vertically spaced opposed runs that define the longitudinal conveyor path therebetween. The opposed runs are operable to be driven together to move a flow of severed plant material along the path. At least one of the opposed runs is shiftable relative to the other opposed run in an upright direction, while the runs are driven together, such that the opposed runs remain in moving engagement with the flow of severed plant material as the amount of severed plant material passing between the opposed runs varies.

A system and related method of applying forage treatment material to harvested forage is provided. The method can include harvesting forage, rotating an auger in a bin to convey a granular treatment material toward a tube, moving the material through the tube with a vacuum toward harvested forage moving in a chute to mix the material with the harvested forage, sensing rotation of the auger; displaying an RPM associated with the sensed auger rotation; displaying a measured harvested forage rate; adjusting the actuator to change the RPM to match the applied material amount to the harvested forage based on the measured harvested forage rate. The system can include a bin having an auger, a sensor that measures auger RPM, a tube, a display that displays the RPM in the cab, and an actuator to adjust applied material by changing the RPM based on a measured harvested forage rate.

A system and related method of applying forage treatment material to harvested forage is provided. The method can include harvesting forage, rotating an auger in a bin to convey a granular treatment material toward a tube, moving the material through the tube with a vacuum toward harvested forage moving in a chute to mix the material with the harvested forage, sensing rotation of the auger; displaying an RPM associated with the sensed auger rotation; displaying a measured harvested forage rate; adjusting the actuator to change the RPM to match the applied material amount to the harvested forage based on the measured harvested forage rate. The system can include a bin having an auger, a sensor that measures auger RPM, a tube, a display that displays the RPM in the cab, and an actuator to adjust applied material by changing the RPM based on a measured harvested forage rate.

A fill control system on a harvester detects that a receiving vehicle is to be repositioned relative to the harvester. The fill control system generates a signal indicative of how the receiving vehicle is to be repositioned relative to the harvester. The harvester sends the signal to a mobile device that is remote from the harvester. A mobile device receives an indication from a fill control system on a harvester that indicates how a receiving vehicle is to be repositioned relative to the harvester. The mobile device controls a user interface mechanism to generate an output indicating how the receiving vehicle is to be repositioned relative to the harvester.

A fill control system on a harvester detects that a receiving vehicle is to be repositioned relative to the harvester. The fill control system generates a signal indicative of how the receiving vehicle is to be repositioned relative to the harvester. The harvester sends the signal to a mobile device that is remote from the harvester. A mobile device receives an indication from a fill control system on a harvester that indicates how a receiving vehicle is to be repositioned relative to the harvester. The mobile device controls a user interface mechanism to generate an output indicating how the receiving vehicle is to be repositioned relative to the harvester.

An unloading automation system for unloading of harvested crop from an agricultural vehicle, such as a combine harvester, into a container. The container may be part of a vehicle container combination that is arranged to maneuver next to the agricultural vehicle in the field. The unloading automation system includes a filling degree measurement system and position measurement system, wherein the position measurement is based on UWB technology. This non-optical technology improves measurement results in dusty environments. The filing degree measurement system and the position measurement system have at least one UWB tag or base station in common.

An unloading automation system for unloading of harvested crop from an agricultural vehicle, such as a combine harvester, into a container. The container may be part of a vehicle container combination that is arranged to maneuver next to the agricultural vehicle in the field. The unloading automation system includes a filling degree measurement system and position measurement system, wherein the position measurement is based on UWB technology. This non-optical technology improves measurement results in dusty environments. The filing degree measurement system and the position measurement system have at least one UWB tag or base station in common.

A method for controlling one or more operating parameters of a forage harvester includes picking up harvested crop from a field by means of a harvesting attachment, processing the harvested crop by means of a chopping device and/or a post-processing device, and ejecting the processed harvested crop onto a loading container. An image of the processed ground-borne harvested crop is recorded by a camera, and an operating parameter of the forage harvester is set or adjusted with a control unit using the image.

One or more techniques and/or systems are disclosed for automating the collection of product harvested from a site, such as grain from a field, and filling truck trailer for transport off site. These techniques can help operations that want to improve efficiency, while reducing field compaction and other issues related to weather or environmental conditions. A predetermined level of product can be identified for the target truck trailer, and an optimized fill method can be determined for filling the truck trailer efficiently using one or more mobile transport containers moving product from the field. A sensor array can detect an amount of the product disposed in the mobile transport container during transfer, and used to fill the mobile transport container to a predetermined level based at least on the optimized fill method. The mobile transport container is then used to fill the target truck-trailer container to its predetermined level.

A method for tracking agricultural material to be transferred from a first entity to a second entity includes generating a transaction record indicating a destination location for the agricultural material and a first amount of the agricultural material to be applied at the destination location, receiving measurement information indicating a second amount of the agricultural material applied by vendor equipment at the destination location and location information indicating locations of the vendor equipment while applying the second amount of the agricultural material, updating the transaction record based on the received measurement information and location information, and at least one of transmitting, using a satellite data communication protocol, the transaction record to the second entity, and determining whether any of the agricultural material was not applied at the destination location based on a comparison between the first amount and the second amount and transmitting a notification based on the determination.