A self-propelled combine configured to collect and handle harvested material and a method for operating the self-propelled combine are disclosed. The combine may include a bypass device that includes an optical measuring device configured to determine one or more harvested material properties of the partial flow of harvested material. The bypass device may have at least one capacitive measuring device for determining the harvested material properties of the partial flow of harvested material.

A harvester capable of autonomous travel in a field includes: a harvesting unit that harvests a crop from the field; a conveyance device that conveys, toward the rear of a harvester body, a whole culm of the harvested crop harvested by the harvesting unit; a detection sensor that detects a drive speed of the conveyance device; and a clog determining unit that determines a clog of the harvested crop in the conveyance device on the basis of the drive speed. The clog determining unit outputs a vehicle stop command that stops the harvester body when the drive speed becomes lower than a pre-set first threshold during the autonomous travel.

An agricultural harvester includes a chassis, a cleaning system carried by the chassis, and a crop material elevator for receiving crop material that has passed through the cleaning system. The crop material elevator has a top-most end, a bottom-most end, a first inlet between the top-most end and the bottom-most end, and a second inlet between the top-most end and the first inlet. The agricultural harvester also includes an auger system for supplying crop material from the cleaning system to the crop material elevator. The auger system includes a first auger defining an auger axis for supplying crop material to the first inlet, a second auger defining a second auger axis, and a crop material conveyor for supplying crop material from the second auger to the second inlet.

An agricultural harvester includes a chassis, a cleaning system carried by the chassis, and a crop material elevator for receiving crop material that has passed through the cleaning system. The crop material elevator has a top-most end, a bottom-most end, a first inlet between the top-most end and the bottom-most end, and a second inlet between the top-most end and the first inlet. The agricultural harvester also includes an auger system for supplying crop material from the cleaning system to the crop material elevator. The auger system includes a first auger defining an auger axis for supplying crop material to the first inlet, a second auger defining a second auger axis, and a crop material conveyor for supplying crop material from the second auger to the second inlet.

An agricultural harvester comprises a feederhouse pivotally attached to a chassis, where the feederhouse defines a conduit for conveying crop material rearwardly from a front opening. A header interface frame is pivotally mounted to the feederhouse over the front opening to permit header pitch adjustment around a pitch adjustment axis. Upper and lower linear actuators are connected on one side of the feederhouse between the feederhouse and interface frame to control the pitch adjustment.

A combine harvester includes a feederhouse mounted to a chassis. The feederhouse is adapted at a front end to support a crop gathering header in a manner that places a front inlet in communication with a discharge opening of the header. The feederhouse defines a crop conveying passage and includes a chain and slat conveyor arranged in the passage to convey a crop stream rearwardly from the front inlet over a floor. A longitudinally-aligned ridge is provided on the floor for dividing the crop stream.

A system and related method of applying forage treatment material to harvested forage is provided. The system can include a mobile forage harvester having a chute, a vacuum source that produces a vacuum, and a bin that stores granular treatment material for dispensation. The chute can be joined with a catch tube having a catch opening. A tube can extend from the bin toward the catch tube, but can be separated from the catch opening by an open gap. The material can be dispensed from the tube into the open gap, and drawn across the open gap and into the catch opening with the vacuum so the material mixes with the harvested forage moving along the pathway in the chute under force of the vacuum. The bin, tubes and the open gap can be located in an interior compartment to protect them from the elements. A related method is provided.

Two-sided cleaning arrangements for an endless belt for an agricultural header are disclosed. An endless belt with a two-sided cleaning arrangement may include a crop carrying surface and first and second cleaning features disposed in first and second edge regions, respectively, of the endless belt. The first and second cleaning features may extend above or be recessed below the crop-carrying surface.

An apparatus for processing harvested crops, in particular a threshing and/or separating apparatus, comprising a rotor which is mounted rotatably about its longitudinal axis, a separating device with a separating device region which at least partially surrounds a lower circumferential region of the rotor, the circumferential region being arranged below the longitudinal axis in an operationally ready state of the apparatus, and is arranged radially spaced apart from the rotor. A passage region for the harvested crop is formed between the separating device regions and the lower circumferential region of the rotor, wherein the separating device region extends along the longitudinal axis, and comprises at least one control element. The control element is movable into the passage region and/or into an axial projection of the passage, in order to control the flow of harvested crop.

A bubble up auger includes a tubular housing, a screw auger and a baffle. The tubular housing includes an inlet opening having a first width end adjacent a first end of the tubular housing and a second width end opposite the first width end. The baffle extends from the inlet opening, outwardly from the central longitudinal axis of the tubular housing and towards the first end of the tubular housing.