A harvest header for a harvesting machine includes a carrying frame, a mechanism for receiving or cutting harvest material from a field, a control device, a power-operated actuator operably controlled by the control device, and a transverse conveyor screw movably controlled between two or more positions. The position of the transverse conveyor screw is adjustably controlled by the actuator in order to transport the harvest material to a discharge opening. The control device independently controls the actuator based on at least one harvest material property.

A traction belt (2) for an inclined conveyor (12) of a combine harvester (1), with a traction belt body (20) which extends substantially in the longitudinal direction (X) of the belt (2) and is endlessly closed or designed to be endlessly closable. The traction belt (2) has at least one tension strand (22) which runs in the longitudinal direction (X) is embedded in the traction belt body (20) and is enclosed by the traction belt body (20).

An agricultural header including a belt that wraps around rollers. A cutter bar assembly that cuts a crop and delivers the crop to the belt. The cutter bar assembly includes a cutter bar, a stationary blade assembly that couples to the cutter bar, a moving blade assembly that couples to the cutter bar. The moving blade assembly moves relative to the stationary blade assembly to cut the crop. A skid couples to the cutter bar and maintains a distance between the ground and the stationary blade assembly and the moving blade assembly. The cutter bar defines a recess that receives debris from the belt and directs the debris to the skid.

Harvesting device, having cutting members (14) for separating the crop material and/or having receiving members for collecting the crop material, having at least one transverse conveying device (19) for delivering the separated and/or collected crop material in a transverse conveying direction (20) running transversely to the harvesting direction, wherein the at least one transverse conveying device (19) is configured as a screw conveyor (21), comprising a trommel (22) and spiral conveying elements (23) sticking out from the trommel (22) in its radial direction. The respective screw conveyor (21) is conical or cone shaped, such that an envelope surface (24) of the spiral conveying elements (23) subtends a cone, which expands in conical or cone-shaped manner looking in the transverse conveying direction.

An agricultural header comprises a first frame, a second frame, an endless side draper belt supported by the first frame, an endless center draper belt positioned in register with the side draper belt to receive cut crop laterally therefrom, an inter-frame flexible seal coupled to the first frame and the second frame. The first frame is coupled for movement relative to the second frame. The flexible seal underlies the side draper belt to receive cut crop that falls from the side draper belt and is arranged relative to the center draper belt to guide fallen crop toward the center draper belt. The flexible seal is configured to flex to accommodate movement of the first frame relative to the second frame.

An agricultural vehicle header includes a frame, a front conveyor, and a rear conveyor. The frame extends in a lateral direction from a first end to a second end and has a leading edge, and a feeder housing opening positioned behind the leading edge with respect to a forward direction. The front conveyor is attached to the frame behind the leading edge with respect to the forward direction, and includes a front movable surface configured to move an adjacent portion of crop material towards the feeder housing opening. The rear conveyor is attached to the frame behind the front conveyor, and has a rear belt having an operative surface that faces in the forward direction and is configured to move an adjacent portion of crop material towards the feeder housing opening.

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.

An agricultural harvester has a frame and a spout that is movably mounted relative to the frame. A spout actuator drives movement of the spout relative to the frame based on a spout actuator control signal. Harvesting functionality engages material from a field and delivers the material through an outlet end of the spout as the agricultural harvester moves through the field in a direction of travel. A turn identifier identifies a location of a turn forward of the agricultural harvester in the direction of travel and generates a turn location indicator indicative of the location of the turn. A speed detector detects a speed of the agricultural harvester and generates a speed indicator indicative of the detected speed. A position compensation control system generates spout position compensation information for controlling the spout actuator based on the turn location indicator and the speed indicator, and a spout position controller generates the spout actuator control signal to control the spout actuator based on the spout position compensation information.

A process for conveying a flow of harvested crop along a first conveyor, which is configured to convey the flow along a first direction, and a second conveyor arranged downstream of the first conveyor and which is configured to convey the flow along a second direction different from the first direction. The process includes operating the first conveyor at a variable conveyor speed presenting a cycle of acceleration and deceleration, the cycle being operable to ensure a spatial repartition of the flow of harvested crop on the second conveyor, which receives the flow at a location that is variable according to the first direction.

A process for conveying a flow of harvested crop along a first conveyor, which is configured to convey the flow along a first direction, and a second conveyor arranged downstream of the first conveyor and which is configured to convey the flow along a second direction different from the first direction. The process includes operating the first conveyor at a variable conveyor speed presenting a cycle of acceleration and deceleration, the cycle being operable to ensure a spatial repartition of the flow of harvested crop on the second conveyor, which receives the flow at a location that is variable according to the first direction.