An unloading apparatus is arranged to direct material to a container. A controller determines a build-up speed of the material in the container; in accordance with the determined build-up speed, determine a rate of change to be applied when setting an attribute of at least one of the unloading apparatus and container; and set an attribute of at least one of the unloading apparatus and container in accordance with the determined rate of change in order to direct the material from the unloading apparatus to the container.

An agricultural harvester has a frame and a spout that is movably mounted relative to the frame. A spout actuator drives movement of the spout relative to the frame. Harvesting functionality engages material from a field and delivers the material through an outlet end of the spout as the agricultural harvester moves through the field in a direction of travel. A turn identifier identifies a location of a turn forward of the agricultural harvester and generates a turn location indicator indicative of the location of the turn. A speed detector detects a speed of the agricultural harvester and generates a speed indicator indicative of the detected speed. A position compensation control system generates spout position compensation information based on the turn location indicator and the speed indicator, and a spout position controller controls the spout actuator based on the spout position compensation information.

A harvesting machine is disclosed along with a method of operating the harvesting machine. The harvesting machine includes a frame having a first end and a second end. A rotatable pick-up head is pivotally mounted on the first end and is capable of urging a crop into the machine. A cutting mechanism is mounted on a bottom plate for cutting the stems of the plants. A crimper mechanism is positioned downstream of the bottom plate and is capable of compacting the cut stems into a moving web. A moisture removal mechanism is positioned after the crimper mechanism to lower the moisture in the cut stems. A crop converging mechanism is located downstream of the moisture removal mechanism and reduces the width of the moving web into a ribbon. A chopper then chops the ribbon into small pieces so that they can be blown into a storage wagon for transport.

A method of moving a component of a harvester that includes a topper for cutting top portions of crops, a conveyor for transporting the cut stalks of the crops, a primary hood, and a secondary hood, each of the primary and secondary hoods operable to direct the cut top portions of the crops away from the conveyor. The method includes selecting a cutting mode of operation from the following modes of operation: circular cutting mode and face cutting mode; selecting a crop position from the following crop positions: crop at right and crop at left; selecting at least one component from the following components: the conveyor, the primary hood, or the secondary hood; and in response to selecting at least one component, automatically moving the selected at least one component to one of a first operational position or a second operational position.

An agricultural harvester has a frame and a spout that is mounted to the frame. A display shows a representation of harvested crop in a receiving vessel. A control system detects an operator input selecting a portion of the receiving vessel and automatically controls a fill control system to being filling the receiving vessel, at the selected portions of the receiving vessel, with harvested material.

The present invention is related to a self-propelled forage harvester (1) comprising one or more sensors (15) mounted on the spout (30) of the harvester, and configured to measure the speed of the crop flow passing through the spout. The harvester is further equipped with a feed roll control unit (8) configured to receive a signal from the sensor and further configured to stop the rotation of the feed rolls (4,5) when the speed is lower than a pre-defined threshold, indicating that a blockage has occurred in the spout. According to an embodiment, the harvester is further provided with a hatch door arranged in the bottom of the spout. The hatch door enables the removal of the blocked crops after a blockage has occurred. In this way, a blockage can be detected quickly and removal of the blockage may also be realised in a fast and efficient way.

A control system for a harvester includes a plurality of actuators, each of which moves of one of the following: a knockdown roller for pressing crops down, a side knife for cutting crops along a substantially vertical plane, a base cutter for cutting crops along a substantially horizontal plane, and a crop divider configured to separate crops into rows. The control system also includes a controller in electrical communication with each actuator of the plurality of actuators. The controller receives a signal indicative of an operational position of at least one actuator of the plurality of actuators, and sends a signal to the at least one actuator of the plurality of actuators to initiate movement of the at least one actuator of the plurality of actuators in response to the received signal.

A harvester including a frame supported by a drive assembly for movement along a support surface, a head unit coupled to the harvester and configured to selectively harvest crop material, a camera coupled to the frame and configured to generate one or more images of a field of view, and a controller in operable communication with the camera and the head unit, where the controller is configured to determine one or more crop attributes based at least in part on the one or more images produced by the camera.

A forage harvester with a discharge chute. The discharge chute comprises a chute connecting piece arranged on the forage harvester so as to be pivotable about a first axis and a first chute extension arranged on the chute connecting piece. The first chute extension comprises a first section and a second section arranged on the first section so as to be pivotable about a second axis. In an unfolded position, the second section forms a longitudinal extension of the first section. A contact surface of the first and second sections lies in a plane, with the second axis being inclined at an angle relative to the plane.

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.