A feederhouse assembly (200) for an agricultural harvester (100) includes a feederhouse (200) having an inlet end (204), ea yaw frame (214) adjacent the inlet end (204) and arranged to pivot about a vertical axis (216) relative to the feederhouse (200), and at least one hydraulic cylinder (220) configured to apply a hydraulic force to rotate the yaw frame (214) about the vertical axis (216). A method of connecting a harvesting header to an agricultural harvester includes applying a first hydraulic force from at least one hydraulic cylinder to a yaw frame (214), moving the agricultural harvester toward the harvesting header, securing the harvesting header to the yaw frame (214), and applying a second hydraulic force from the at least one hydraulic cylinder to the yaw frame (214) to orient the harvesting header at a right angle with respect to a longitudinal axis of the agricultural harvester (100).

A shaped conveyor assembly configured for use in association with a harvester comprising a first side lower conveyor sub-assembly and a second lower conveyor sub-assembly. One or both of the sub-assemblies having a frame structure, a discharge assembly and a conveyor assembly. The frame structure has a gathering portion, an outward portion and a terminating portion. The gathering portion is positioned proximate the first end and spaced apart from the second end. The terminating portion is positioned proximate the second end and spaced apart from the first end. The outward portion extends therebetween, the outward portion being inclined in an upward direction relative to the gathering portion, and directed in an outward direction, thereby extending away from the channel, and away from the other one of the first side and the second side lower conveyor sub-assemblies.

A transportable drive-over conveyor system includes a drive-over hopper for receiving material and having a belt-type conveyor for conveying the material, a transition section pivotally connected at an upstream end to the drive-over hopper, an auger mounted at a downstream end of the transition section. The transition section transfers the material from the belt-type conveyor to the auger. The system may include radially offset wheels that support and move the conveyor system. The system further includes a pair of foldable ramps having hooks. The system further includes a folding and lifting mechanism which may include cables connected to the hooks for folding the foldable ramps and then lifting the conveyor system by the ramps.

A header for an agricultural harvester comprising a chassis and an auger having a tube extending in end to end relation with and rotatably supported by the chassis. The header further includes a drive mounted adjacent a mid-portion of the auger and operatively engaged with the mid-portion of the auger for driving rotation thereof. The header thus provides an auger which is driven at its mid-portion, thereby eliminating the hydraulic complexities of augers that are driven at their ends. In addition, when the auger tube is continuous, the mid-portion driven, continuous tube auger eliminates the crop dead spot that typically occurs when split augers are deployed.

The invention relates to a self-propelled harvesting machine comprising:—a removable harvesting unit (6) which can be mounted at the front in the direction of travel (F);—a processing unit in the interior; and—a harvested material conveyor channel (5) connecting said harvesting unit, when mounted, to the processing unit. According to the invention, the self-propelled harvesting machine is characterised in that a receiving space which at least partially receives said conveyor channel when in the harvesting mode can have its width adjusted transversely to the direction of travel.

An agricultural combine including an agricultural harvester, a crop tank for harvested material, and an unloading auger assembly for unloading and discharging crop material. The auger assembly has inner and outer auger tubes pivotally connected to one another. The auger tubes pivot between a first position in which the auger tubes extend transversely and are coaxial and a second position in which the auger tubes form an angle. The auger tubes contain augers having first and second couplings at cooperating ends. The first coupling has two projections extending to cooperate with a single radial projection on the second coupling to provide improved engagement.

Agricultural machine and method for harvesting a crop with upright stalks (29) on a soil, wherein means of transport are provided to convey the stalks (29) harvested upright to a feed-through channel (6), wherein the means of transport are provided on the front (1) of the machine and comprise at least a conveyor belt (7, 14) extending partly at the front (1) of the agricultural machine and which is designed to be driven in a direction of rotation (8) thereof in order to transport cut stalks (29) substantially upright to said feed-through channel (6). A cutter (12) is provided extending in said feed-through channel (6) to cut the stalks (29) while they are being moved upright through the feed-through channel (6).

A feederhouse for a combine harvester comprises an endless conveyor having at least two traction means made of inherently flexible material circulating about the deflection rollers and offset from one another in the axial direction of the deflection rollers, between which conveying strips extend. The inner sides of the traction conveying strips are furnished with cams made of inherently flexible material. Anchor plates are embedded in each of the cams. A first fastener having a first head recessed within the individual cam extends through individual cams, through individual anchor plates and through individual conveying strips. The anchor plate comprises two non-circular openings, wherein the first fastener and the second fastener each have non-cylindrical outer circumferential surfaces received within the non-circular openings to inhibit rotation of each of the first fastener and the second fastener relative to the anchor plate.

An inclined conveyor for a combine harvester has two drive elements which define a conveying direction and revolve in a conveying duct. Conveying duct is divided into an overshot return duct and an undershot conveying duct by a separating element situated between the upper run and the lower run of the drive element. Drive element is interconnected by carriers situated transversely with respect to conveying direction that convey harvested crop in undershot conveying duct. The difference in speed between the carrier bars and harvested crop stream is eliminated, and at least reduced, by additional acceleration of harvested crop stream. Carrier bars serve as carriers, and as acceleration elements for the harvested crop. That is because the cross section of each of the carrier bars viewed in conveying direction, occupies at least 30% of the smallest internal cross section of undershot conveying duct.

An inclined conveyor for a combine harvester has two drive elements which define a conveying direction and revolve in a conveying duct. Conveying duct is divided into an overshot return duct and an undershot conveying duct by a separating element situated between the upper run and the lower run of the drive element. Drive element is interconnected by carriers situated transversely with respect to conveying direction that convey harvested crop in undershot conveying duct. The difference in speed between the carrier bars and harvested crop stream is eliminated, and at least reduced, by additional acceleration of harvested crop stream. Carrier bars serve as carriers, and as acceleration elements for the harvested crop. That is because the cross section of each of the carrier bars viewed in conveying direction, occupies at least 30% of the smallest internal cross section of undershot conveying duct.