An agricultural apparatus including an agricultural vehicle and a number of work units suitable for cutting standing crop, including a front work unit and two lateral work units located behind and to the sides of the front work unit, each of the work units deposit cut crop as a swath. Each of the lateral work units include a conveyor to deposit cut crop. A plurality of sensors determine the speed of the agricultural apparatus and the speed of operation of each of the conveyors. A control unit receives inputs from the sensors, compares the inputs to a predetermined set of values for a desired vehicle speed and a speed of operation of the conveyors, and as indicated by the comparison, adjusts the speed of operation of at least one conveyor.

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 method of collecting material with a harvester when a storage vehicle is spaced from the harvester includes moving material from the field into the basket, actuating the conveyor for a first time period when the sensed parameter is above the set amount, transporting a first portion of the material a first distance with the actuated conveyor, after the first time period has elapsed, stopping the conveyor to store the first portion of the material on the conveyor, after the first time period has elapsed, if the conveyor can store more material, actuating the conveyor for a second time period, transporting a second portion of the material a second distance with the actuated conveyor and transporting the first portion of the material a third distance with the actuated conveyor, and if the conveyor cannot store more material, alerting an operator that the conveyor is full.

A chopping module which pulls plants inside the module and chops them into billets, comprising a box-shaped body with three open sides, a front inlet for plants to be chopped, a rear outlet for chopped plants and a lower outlet for residues. Plants are pulled by two crosswise pairs of rollers, after which plants are chopped by a rotating blade assembly and a fixed shearbar, which are aligned parallel to the pulling rollers. Between the pulling rollers, a passageway is formed for the plants to be chopped. After the fixed shearbar, said passageway continues in the form of a slide sloping downwards to the rear outlet. The rotating blade assembly is located above the slide and next to the fixed shearbar.

A crop cutting device including a crop guiding surface including parallel slots. A row of knives pivotally mounted below the guiding surface is pivotable between a retracted inoperative position in which it is located below the guiding surface and an extended operative position, wherein the knives project above the guiding surface. An actuating mechanism includes movable operating members. Each operating member is associated with a respective knife and is movable from a first position in which the knife is in its retracted position to a second position in which the knife is in its extended position. Further, there is included a lifting mechanism for raising at least a part of each knife above the guiding surface, while the operating members are in their first position.

A harvesting attachment for whole plant harvesting includes a pick-up for picking up plants from a field, a first transverse conveyor belt and a second transverse conveyor belt for conveying the plants picked up transversely in a direction toward of a longitudinal center plane of the harvesting attachment, and two longitudinal conveyor belts which are arranged side-by-side and adjacent to the longitudinal center plane of the harvesting attachment and are set up to convey the plants entering from the transverse conveyor belts rearward to a rear discharge point of the harvesting attachment. The two longitudinal conveyor belts are inclined vertically upward in a direction toward the center plane at least over part of their length along the center plane.

A self-propelled agricultural harvester, such as a forage harvester, is disclosed. The harvester has at least one post-acceleration unit for the variable acceleration of harvested material and a transfer device downstream from the post-acceleration unit for ejecting the harvested material into a loading container. The width of a harvested material passage gap of the post-acceleration unit may be adjusted using a gap-changing device for the variable acceleration of the harvested material. A control device may evaluate data generated by a swath detection device with the data indicative of properties of the harvested material. Based on the evaluation, the control device may generate control signals to control the gap-changing device, thereby for adjusting the width of the harvested material passage gap.

A user interface element includes a plurality of moveable outer points on a circular line and a fixed inner point inside the circular line, the fixed inner point being connected to each of the outer points by a straight line such that each pair of adjacent straight lines and a portion of the circular line between the adjacent straight lines defines a section of the graphical user interface element. The user interface is configured to, in response to interaction from the user, move any of the outer points along the circular line and independently of the other outer points to thereby change the size of two or more of the sections. Each section corresponds to one of a plurality of crop processing parameters, such that changing the amount of area within any section results in an adjustment to an operation of a crop processing system.

A method for operating a harvester may include initially operating the harvester in a discharge harvesting mode such that harvested crops are conveyed to a distal end of an elevator of the harvester and subsequently discharged from the harvester through a discharge opening defined by a storage hopper located at the distal end of the elevator. The method also includes reducing an operating speed of the elevator and blocking the discharge opening defined by the storage hopper upon receipt of an operator input associated with operating the harvester in a storage harvesting mode. Additionally, the method includes actively adjusting the operating speed of the elevator based on a crop flow parameter of the harvester as the harvested crops expelled from the distal end of the elevator are being stored within a storage volume of the storage hopper.

A corn harvesting header (24) includes a powered row unit (38) and a gathering hood (98). The row unit (38) defines a longitudinal crop row path that extends in a generally rearward crop travel direction and receives a corn row as the header (24) is advanced along the corn row. The gathering hood (98) partly overlies the row unit (38) and includes a laterally extending dam (132) that restricts corn from moving forwardly. The dam (132) at least partly defines a gutter to receive corn kernels and direct the corn kernels rearwardly.