A conveyor for a combine harvester includes a chain and a sprocket. The sprocket includes an annular body defining an axis of rotation, two opposing sides, an outer perimeter extending between the two opposing sides, and gear teeth disposed on the outer perimeter. A bottom land extends between valleys of adjacent gear teeth. A single continuous edge is defined between two gear teeth at one of the adjacent sides. The bottom land includes (i) a central plateau portion, (ii) a first sloping surface extending from one edge of the central plateau portion to the single continuous edge at one of the two opposing sides, and (iii) a second sloping surface extending from the opposite edge of the central plateau portion to the single continuous edge at the other of the two opposing sides. The sloping surfaces either limit or prevent the accumulation of material thereon.

A device for conveying and feeding wet material for a cross-flow hot air combine harvester, the device consisting of a hot air pumping part and a material conveying part. The hot air pumping part uses an air suction pump (4) to pump a flow of hot waste air from an engine radiator (1) of the combine harvester by means of an air suction pipeline (3) so as to provide hot air flow for the material conveying and feeding device. The material conveying part consists of a chain harrow-type conveying groove structure (A) and a cross-flow air chamber structure (B), wherein the chain harrow-type conveying groove structure (A) is used for forcibly conveying and feeding a material; and the cross-flow air chamber structure (B) uses hot air to dry the material, blows to assist in feeding the material, and uses a cross-flow air wheel (14) to forcibly feed the material.

A combine comprising a feeder housing, and an auger for receiving harvested crop. The auger includes an auger tube rotatable around an auger axis, and a tined-tube positioned inside the auger tube and rotatable around a tined-tube axis that is offset from the auger axis, the tined-tube including fingers extending from the tined-tube and protruding through the auger tube to convey the harvested crop to the feeder housing.

A dust management system for an agricultural harvester includes a perforated tube extending transversely through a feeder housing of the harvester. The perforated tube has exhaust plenums at opposite ends directing any flow towards the ground over which an agricultural harvester operates. A longitudinal drive shaft mounts axial flow fans within the exhaust plenums and a drive shaft is driven through a pulley system so that rotation of the drive shaft induces flow through the perforated tube and out of the exhaust plenum.

A feed train assembly for a sugarcane harvester includes a first feed section comprising a plurality of first pairs of upper and lower feed rollers configured to receive a first mat of sugarcane, with such pairs of upper and lower feed rollers comprising a first upstream pair of upper and lower feed rollers. The feed train assembly also includes a second feed section comprising a plurality of second pairs of upper and lower feed rollers configured to receive a second mat of sugarcane, and a combined feed section configured to receive the first and second mats of sugarcane from the first and second feed sections, respectively. A rotational axis of the lower feed roller of the first upstream pair of upper and lower feed rollers is oriented non-parallel relative to a rotational axis of the upper feed roller of the first upstream pair of upper and lower feed rollers.

A self-propelled combine harvester has at least one tilting mechanism for the uniform distribution of a harvested material on an oscillating conveying and cleaning unit, in particular a top sieve. The tilting mechanism has elements for defining a swiveling direction of the conveying and cleaning unit which are arranged between the conveying and cleaning unit and a machine housing. The tilting mechanism has an actuator for continuous adjustment of at least one component part of the elements from an initial position to an adjusting position. The position of the at least one component part decisively defines the swiveling direction. An electric control unit controls the actuator depending on a state of the combine harvester and/or harvested material and the initial position of the at least one component part of the tilting mechanism.

Compound headers and combine harvesters that include compound headers are disclosed. The compound headers may include two or more crop harvester types that are operable to harvest different crops simultaneously, such as different crops grown in the same field in an intercropped relationship. The simultaneously harvested crops may be separated into individual crop flows that are handled separately from each other.

A grain processing assembly for a combine that comprises a feeder assembly, a threshing assembly having a rotor disposed within a housing, a hood. The feeder assembly comprises a lower conveyor and an upper conveyor. The position of the lower conveyor and the upper conveyor is such that upper conveyor assists the lower conveyor in directing crop material being transported on the lower conveyor towards a discharge end of the lower conveyor. The hood engages a belt of the second upper conveyor.

A conveyor guide unit for use in an elevator of a sugarcane harvester comprises a housing, an axle positioned in and supported by the housing, and a rotor mounted to the axle for rotation about a rotation axis and configured to interface with a conveyor of the elevator. The axle and the rotor mounted thereto are selectively repositionable axially along the rotation axis relative to the housing for lateral adjustment of the rotor relative to the conveyor.

A combine feeder slat having a first base, a second base, and a slat body. The bases are located at respective ends of the slat, and have respective upper and lower surfaces. The slat body extends longitudinally and connects the bases. The slat body has a variable profile as viewed along the longitudinal direction, that transitions from a first profile shape at the first base, to an intermediate profile shape between the first base and the second base, to a second profile shape at the second base. The intermediate profile shape includes a front lip, a rear lip, and an upward-facing concave projection that connects the front lip to the rear lip and extends below an attachment plane defined between the first lower surface and the second lower surface. The first base, second base, and slat body are made from a unitary wrought metal part.