A method and an apparatus for separating a crop flow on at least one conveying and cleaning unit, particularly a top sieve, of a combine harvester, wherein the conveying and cleaning unit is excited to a longitudinal oscillation and a transverse oscillation. The transverse oscillation is controlled depending on at least one state, wherein least one state for controlling the transverse oscillation is the inclination of the combine harvester, wherein at least one further state for controlling the transverse oscillation is the grain purity, particularly the grain purity of a main crop flow. The transverse oscillation is pre-controlled depending on the inclination of the combine harvester and fine-tuned depending on the grain purity.

A system for determining the cut quality of a crop by a harvester includes an electrode maintained at voltage above ground. The electrode is mounted downstream of a cutter bar on the harvester. The electrode communicates with a controller which measures changes in an electrical parameter, such as voltage or current, between the electrode and ground. The electrode is positioned to ride at a particular height above the ground specific to a particular crop. Crop stubble left by crop which is cut cleanly by the harvester does not contact the electrode. Crop stubble left by crop which is not cut properly will engage the electrode and effect a change in the electrical parameter measured by the controller. The controller reports changes in the electrical parameter indicative of cut quality to the operator of the harvester via a display device thereby allowing the operator to take corrective action in harvester operation.

A cleaning assembly for a combine harvester including a vibrating floor conveyor for conveying crops. The vibrating floor conveyor is moved into a vibrating movement and is supported at the conveyors downstream end by hangers on a cleaning shoe. At least one sieve is arranged in the cleaning shoe that can be moved into a vibrating movement, and which can be exposed to an air flow by a blower. A rotatable transverse auger conveyor is arranged downstream of the vibrating floor conveyor and upstream of the sieve for lateral conveying of the crop and includes a shaft and conveying coils attached to the shaft, wherein the hangers are supported on the shaft of the transverse screw conveyor.

One or more information maps are obtained by an agricultural work machine. The one or more information maps map one or more agricultural characteristic values at different geographic locations of a field. An in-situ sensor on the agricultural work machine senses an agricultural characteristic as the agricultural work machine moves through the field. A predictive map generator generates a predictive map that predicts a predictive agricultural characteristic at different locations in the field based on a relationship between the values in the one or more information maps and the agricultural characteristic sensed by the in-situ sensor. The predictive map can be output and used in automated machine control.

In one example, an apparatus includes a plate configured to pivot about a pivot point, a pulley coupled to a first planar side of the plate and configured to rotate a belt, a motor coupled to the first planar side of the plate and configured to drive the pulley, and a torsion spring coupled to a second planar side of the plate that is opposite the first planar side and configured to apply tension to the belt.

A harvesting head for an agricultural harvester including a center frame section that is pivotally coupled to each of a left frame section and a right frame section. The elevation or height of the center frame section is determined by setting a height of the inner gauge wheels of the left and right frame sections. A gauge assembly for each of the left and right frame sections includes a linking member that spans between and operatively connects to outer and inner gauge wheels. The gauge assemblies are operably connected to the left and right frame sections to adjust an elevation of the outer and inner gauge wheels relative to the linking member to thereby adjust the elevation or height of the frame section when actuated by an actuation mechanism.

A header for an agricultural vehicle including a frame, a reel rotatably mounted to the frame, and a reel drive assembly operably connected to the reel. The reel drive assembly rotates the reel in a first drive configuration and a second drive configuration. The reel drive assembly includes a first drive operably connected to the reel, and a second drive selectively connected to the reel such that the second drive is disconnected from the reel in the first drive configuration and the second drive is operably connected to the reel in parallel with the first drive in the second drive configuration.

A harvesting platform is connected to a combine for movement with the combine over the ground surface. The harvesting platform includes a cutter bar that cuts a crop being harvested, and a reel that presses the crop against the cutter bar during harvesting. The cutter bar moves between a cutter bar harvesting position and a cutter bar transport position, and the reel moves between a reel harvesting position and a reel transport position. A controller receives a first signal from a user via a user interface, sends a second signal to the cutter bar to move the cutter bar between the cutter bar harvesting position and the cutter bar transport position in response to the first signal, and send a third signal to the reel to move the reel between the reel harvesting position and the reel transport position in response to the first signal.

A sensor input is detected on a cotton harvester. A performance characteristic value is identified based upon the detected sensor input. A speed control system controls cotton harvester drum speed and spindle speed, automatically, and separately from the ground speed of the cotton harvester, to improve the performance characteristic value, in a closed-loop fashion.

A monitoring device for monitoring crop yield is disclosed. The monitoring device is mounted to a housing of a grain elevator of an agricultural work machine proximate a crop conveyor assembly arranged in the housing and has at least one aperture formed therein. A material engagement member is arranged on the mounting structure and is pivotal with respect to the mounting structure about a pivot point. The material engagement member can comprise first end and a second end opposite of the first end. At least one rotational sensor is arranged in the monitoring device and is configured to detect spatial movement or position of the material engagement member. A processing device is coupled to the at least one rotational sensor and is configured to determine an aggregate crop yield based on the detected rotational magnitude of the displacement of the first end or second end.