A system for directing the movement of a grain transfer element. The system includes a torque sensor and a processor. The torque sensor is configured to detect a torque of a drivetrain configured to drive the transfer element. The processor is configured to compare the detected torque to a torque threshold, and direct the movement of the transfer element between a folded position and an unloading position. The directed movement of the transfer element is based at least in part on a result of the comparison of the detected torque and the torque threshold.

A mobile machine includes a material receptacle configured to hold a material and a material spill sensor configured to detect a characteristic indicative of a material spill characteristic and to generate a sensor signal based on the detected characteristic. The mobile machine further includes a control system configured to determine the material spill characteristic based on the sensor signal. In some examples, the control system is configured to generate an action signal to control an action of the mobile machine based on the determined material spill characteristic.

A harvesting machine has a crop tank and a conveyor screw inside the tank which extends from a material inlet opening on a wall of the crop tank into the interior of the crop tank. The conveyor screw comprises at least one proximal portion adjacent to the material inlet opening and one distal portion spaced apart from the material inlet opening at least by the proximal portion. The proximal portion and distal portion are rotatable around conveying axes running in different directions. The conveyor screw can be operated in a work position in which the conveying axis of the distal portion is oriented to be steeper than the conveying axis of the proximal portion.

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.

An extendable and retractable conveyor comprises a hopper for receiving agricultural product a housing having an inlet and an outlet that are separated by a fixed distance, the inlet being adjacent to the hopper for receiving the agricultural product from the hopper. The conveyor may include a belt conveyor disposed within the housing for conveying the agricultural product from the inlet to the outlet, the conveyor defining a direction of conveyance. The conveyor further includes a hood connected to the outlet for deflecting the agricultural product relative to the direction of conveyance. The conveyor further includes a movable spout that is slidably connected to the tube and disposed beneath the hood to receive the agricultural product from the hood, the movable spout being slidable in a direction parallel to the direction of conveyance to thereby extend or retract the conveyor.

A method for continuously conveying agricultural product from an agricultural vehicle to an agricultural product storage tank includes receiving a signal at an autonomous grain cart indicating that another autonomous grain cart is moving to the agricultural product storage tank from the agricultural vehicle. The method also includes determining an expected location of the agricultural vehicle based on a harvesting map for the agricultural vehicle. The method further includes determining a route to the expected location of the agricultural vehicle based on the expected location of the agricultural vehicle and the location of the autonomous grain cart. The method also includes controlling the autonomous grain cart based on the route to the expected location of the agricultural vehicle after the signal indicating that the other autonomous grain cart is moving to the agricultural product storage tank from the agricultural vehicle is received.

An intelligent system and a method for coordinating harvester and logistics vehicle are illustrated. The intelligent system comprises a harvester terminal and a logistics vehicle terminal. The harvester terminal comprises a repository monitoring module and a control module, wherein the repository monitoring module monitors storage information of a storage bin of the harvester. The control module receives the storage information from the repository monitoring module, and determines whether the storage location of the storage bin of the harvester reaches a preset location. The harvester terminal and the logistics vehicle terminal are communicatively connected. When the storage location of the storage bin of the harvester reaches the preset location, the control module sends a transport instruction to the logistics vehicle terminal to control the logistics vehicle to transport grain, thereby achieving intelligent coordination between the harvester and the logistics vehicle.

A harvester includes a first electromagnetic detecting and ranging module for detecting the location of a receiving vehicle and a second electromagnetic detecting and ranging module for detecting at least one of a fill level and a distribution of processed crop in a grain bin of the receiving vehicle. One or more computing devices are configured to receive first data from the first electromagnetic detecting and ranging module, receive second data from the second electromagnetic detecting and ranging module and use the first data and the second data to generate graphic data defining a graphical representation illustrating the relative positions of an unload conveyor of the harvester and the grain bin and illustrating at least one of a fill level and a distribution of processed crop in the grain bin. An electronic device is configured to use the graphic data to present the graphical representation on a graphical user interface.

A system includes an agricultural crop receiving vehicle with a bin for receiving and holding agricultural crop material and a camera positioned to capture images of an area proximate the receiving vehicle. One or more computing devices receive the image data from the camera, identify one or more features of a harvester in the image data, determine a location of the agricultural harvester relative to the crop receiving vehicle, and use the location of the agricultural harvester to generate control signals for controlling movement of the agricultural crop receiving vehicle to coordinate receiving crop material in the bin from the harvester or for controlling a graphical user interface to present a visual indicator of the relative locations of the agricultural crop receiving vehicle and the agricultural harvester.

A system includes an agricultural crop receiving vehicle with a bin for receiving and holding agricultural crop material and an electromagnetic detecting and ranging module for generating data indicating the presence and location of a harvester proximate the agricultural crop receiving vehicle. One or more one or more computing devices are configured to receive the data from the electromagnetic detecting and ranging module, determine a location of the harvester relative to the agricultural crop receiving vehicle, and use the location information to generate control signals for controlling movement of the agricultural crop receiving vehicle to coordinate receiving crop material in the bin from the harvester or for controlling a graphical user interface to present a visual indicator of the relative locations of the agricultural crop receiving vehicle and the harvester.