A spreader arrangement for an agricultural harvester includes a windrow chute having a first position for building a windrow in which the chute angles downwardly from a proximal edge to a distal edge of the chute, and a second position for cleanout of the chute in which the chute angles downwardly from the distal edge to the proximal edge of the chute. Adjustment from the first position to the second position and back to the first position can occur automatically when the combine is operating but not currently harvesting, such as during the time period between when a harvesting swath is completed and the next harvesting swath is commenced, so that accumulated crop residue material can be dislodged from the windrow chute without disrupting harvesting or the windrow building process.

In a combine harvester the cleaning arrangement is placed above the threshing and separation system so that the sieves of the cleaning arrangement can be wider than the distance between the front wheels or tracks of the harvester. A supply such as one or more auger beds are provided underneath the threshing and separation system, for gathering the grain/residue mixture in a single location. From that location, an elevator transports the grain/residue mixture up towards the cleaning arrangement, where it is distributed over the width of the cleaning arrangement.

A harvesting machine includes a chassis; an engine to propel the harvesting machine; a header mounted on a front of the chassis; a cutter bar arranged on the header to cut crops during operation of the harvesting machine; a plurality of implements on the chassis configured to facilitate processing the crops cut by the cutter bar; at least one cutter bar load sensor arranged on the header and configured to collect cutter bar load data representing a load on the cutter bar resulting from cutting the crops; and a controller operatively coupled to the at least one cutter bar sensor. The controller is configured to receive the cutter bar load data, determine a cutter bar load value based on the cutter bar load data, and generate an adjustment command for an operational parameter associated with at least one of the implements based on the cutter bar load value.

An assembly for rotating a chain or toothed belt includes a shaft and a sprocket rotatably mounted on the shaft. The sprocket includes a plurality of teeth configured to engage the chain or toothed belt. The assembly further includes a shield assembly covering at least a portion of the sprocket. The shield assembly has an interior groove formed therein defining an enclosed interior space. Each of the teeth of the sprocket rotate through the enclosed interior space during a full rotation of the sprocket.

A harvester may include a crop path along which crops are moved, a working member to interact with weed seeds moving along the crop path and a controller. The controller is to receive data indicating forthcoming weed seeds and is to output control signals controlling the working member based on the data.

Disclosed is a grain separating apparatus (1) for a combine harvester (2). The grain separating apparatus (1) comprises at least a first walker-sieve (3) and a second walker-sieve (4) arranged side by side, wherein the first walker-sieve (3) and the second walker-sieve (4) are suspended in at least two suspension points (5,6) in the combine harvester (2) and wherein at least one of the two suspension points (5,6) is arranged to describe a rotational motion. A rotational motion drive (7) is arranged to drive the rotational motion of the first walker-sieve (3) out of phase with the rotational motion of the second walker-sieve (4), wherein each of the at least two walker-sieves (3,4) include a straw walker (8) comprising drivers (9) for conveying a straw material (10) and wherein grain (11) and debris (12) are separated from the straw material (10) through walker apertures (13) arranged in the straw walker (8). Furthermore, the straw walker (8) is arranged on top of at least one sieve (14,15) which is arranged to separate grain (11) from the debris (12) and wherein the straw walker (8) and the at least one sieve (14,15) are rigidly connected. Furthermore, a method for separating grain (11) from straw material (10) in a combine harvester (2) by means of a grain separating apparatus (1) as described above.

A controller for controlling a harvesting performance of an agricultural harvester. The controller receives automation settings, selected by an operator via a human-machine interface. The controller also receives data from on-board harvester sensors. The controller defines a target value for quality parameters based on the automation settings, and determines a current value of each of the quality parameters in dependence on the crop sensor data. The controller determines an actuator setting for actuators of the agricultural harvester when the current value of one or more of the plurality of quality parameters differs by greater than an acceptable amount from the associated target value. The actuator setting is determined in dependence on the automation settings and the target value. The controller controls the actuators to achieve the determined actuator setting.

A sugarcane harvester for harvesting sugarcane including a cutter configured to cut sugarcane into a sugarcane mat and a primary extractor disposed adjacent to the sugarcane mat configured to remove crop residue from the sugarcane mat. An elevator includes a conveyor to move the sugarcane mat to an end of the conveyor and an extractor is operatively connected to the elevator. The extractor includes a fan housing having an arm extending laterally from a sidewall of the fan housing and toward a center of the fan housing. A fan assembly is supported by the arm and is configured to remove crop residue from the sugarcane mat at the end of the conveyor. A cover assembly is fixedly connected to the support arm and subtends a fan of the fan assembly and a portion of the support arm, wherein the cover assembly directs crop debris away from the fan and the support arm.

An operator interface for a combine harvester, having a display device, input means and a processor configured to activate the display device such that the display device depicts having an elongated element, a scale being assigned thereto, and a first marking, the position thereof relative to the elongated element depending on an operating parameter of the threshing device and/or the cleaning device. A second marking and/or third marking, which represents a lower and/or upper limit of the setting range of the operating parameter which is predetermined depending on the type of crop, is assigned to the elongated element in the diagram.

A fan hub for an extractor for a harvesting machine that harvests a crop. The fan hub having a hub cover positioned along a rotation axis of a fan of the extractor. The hub cover is adjustable to alter the profile of the hub cover relative to the rotation axis.