An agricultural harvester may include a system for determining the residue yield of plant materials being ingested by a harvesting implement of the harvester. A controller of the system may be configured to determine the weight of the quantity of plant materials being ingested by a harvesting implement of the harvester based on measurement signals received from the plant yield sensor. The system may be configured to determine the weight of the quantity of crop materials removed from the quantity of harvested plant materials based on measurement signals received from the crop yield sensor. The system may be configured to determine the residue yield value by comparing the determined weight of the quantity of plant materials and the determined weight of the quantity of crop materials.

A separator arrangement has an inlet head housing, a feed drum and two axial separating rotors projecting by one end portionwise into the inlet head housing. The inlet head housing has planar inlet portions which extend over the width of the respective axial separating rotor and between which is arranged a ramp-shaped housing portion extending paraxial to the conveying direction of the axial separating rotors and which assists in dividing a harvested material flow into partial flows to be fed to the axial separating rotors. At least one separating element is associated with the ramp-shaped housing portion and has a base body which extends perpendicular to the surface of the housing portion and which has an end face formed as a cutting edge. A coating comprising a wear-resistant second material is arranged on the end face and extends substantially medially in the longitudinal direction of the end face.

A combine feeder assembly having conveyors and slats pivotally connected to the conveyors to rotate about respective slat pivot axes. Each slat has a paddle that is movable between a first position in which the paddle extends outside the travel path of the conveyor by a first distance, and a second position in which the paddle does not extend outside the travel path or extends outside the travel path by a second distance that is less than the first distance. A cam surface moves the slats to the first slat position along a delivery path of the conveyors. A first housing wall extends over the delivery path and is spaced from the travel path by at least the first distance. A second housing wall extends over a return path. The second housing wall is spaced from the travel path by less than the first distance.

The present application for patent of invention refers to a device designed to thresh agricultural products. The agricultural products it is designed to process include grains in general, particularly peanuts and beans, but not limited thereto, and can be applied to other similar crops. The invention comprises a cylinder (1) that has a larger diameter zone (2) and smaller diameter zone (3), said larger or smaller diameter zones intermediated by a transition zone (4); in the smaller diameter zone (3) the helical path is contoured by rigid scale-like components (6) as far as part of the transition zone (4), where flexible elements are applied (7) following the entire length of the larger diameter zone (2), completing the (1) cylinder or rotor, and the flexible elements (7) can be arranged in consecutive way or interspersed, so that the interval between the flexible elements (7) is intermediated by substantially upside-down U-shaped elements (7B).

A threshing section for a combine harvester includes a rotor and a transition cone. The rotor has an axis of rotation, a downstream end, and an upstream end. The upstream end includes one or more blades for moving crop downstream in a direction of crop flow. The transition cone at least partially surrounds the upstream end of the rotor and the blades. An annular space is formed between a swept profile of the blades and an interior surface of the transition cone through which crop is introduced into the threshing section. A cross-sectional area of the annular space, which is measured in a radial direction, is substantially constant along at least a portion of a length of the swept profile.

A threshing section for a combine harvester includes a rotor and a transition cone. The rotor has an axis of rotation, a downstream end, and an upstream end. The upstream end includes one or more blades for moving crop downstream in a direction of crop flow. The transition cone at least partially surrounds the upstream end of the rotor and the blades. An annular space is formed between a swept profile of the blades and an interior surface of the transition cone through which crop is introduced into the threshing section. A cross-sectional area of the annular space, which is measured in a radial direction, is substantially constant along at least a portion of a length of the swept profile.

A threshing and separating system including a non-stationary rotor cage including a perforated cylindrical body extending in a longitudinal direction from a first open end portion to a second open end portion. The first open end portion supported by a first rotatable coupling point, and the second open end portion supported by a second rotatable coupling point. The threshing and separating system also includes a rotor configured to rotate within the non-stationary rotor cage to thresh harvested crop. The non-stationary rotor cage is configured to rotate about an axis extending between the first rotatable coupling point and the second rotatable coupling point, and to be rotationally driven by the rotor via the threshed harvested crop.

A threshing and separating system including a non-stationary rotor cage including a perforated cylindrical body extending in a longitudinal direction from a first open end portion to a second open end portion. The first open end portion supported by a first rotatable coupling point, and the second open end portion supported by a second rotatable coupling point. The threshing and separating system also includes a rotor configured to rotate within the non-stationary rotor cage to thresh harvested crop. The non-stationary rotor cage is configured to rotate about an axis extending between the first rotatable coupling point and the second rotatable coupling point, and to be rotationally driven by the rotor via the threshed harvested crop.

Methods and systems for monitoring a throughput of a crop cut from a field. The system may include, and the method may be performed at least in part using, a combine harvester including a feeder box, a main body, a threshing mechanism, and an organic material throughput sensor provided within the feeder box. The system may also include a data management system. The organic material throughput sensor senses organic material throughput data including at least one of a volume of the organic material, and a weight of the organic material, and the data management system outputs an organic material throughput map or other information based on the organic material throughput data. Using the organic material throughput data or the organic material throughput map, a producer or other operator can make a more informed planting or treatment decision for a field.

Methods and systems for monitoring a throughput of a crop cut from a field. The system may include, and the method may be performed at least in part using, a combine harvester including a feeder box, a main body, a threshing mechanism, and an organic material throughput sensor provided within the feeder box. The system may also include a data management system. The organic material throughput sensor senses organic material throughput data including at least one of a volume of the organic material, and a weight of the organic material, and the data management system outputs an organic material throughput map or other information based on the organic material throughput data. Using the organic material throughput data or the organic material throughput map, a producer or other operator can make a more informed planting or treatment decision for a field.