The present invention comprises multiple embodiments of an automated, dynamic cover plate system, which may be quickly attached, detached and adjusted to the exterior of a concave grate of a combine harvester in order to adjust the flow characteristics of the concave or separator grate assemblies. The automated, dynamic cover plate system improves the threshing capability of the rasp bar threshing cylinder while simultaneously capturing additional threshed grain. The automated, dynamic cover plate system of the present invention is designed to be controlled, either manually or automatically, by the operator of the combine harvester or by a computerized or automated intelligence system.

The present invention comprises multiple embodiments of an automated, dynamic cover plate system, which may be quickly attached, detached and adjusted to the exterior of a concave grate of a combine harvester in order to adjust the flow characteristics of the concave or separator grate assemblies. The automated, dynamic cover plate system improves the threshing capability of the rasp bar threshing cylinder while simultaneously capturing additional threshed grain. The automated, dynamic cover plate system of the present invention is designed to be controlled, either manually or automatically, by the operator of the combine harvester or by a computerized or automated intelligence system.

A rotary thresher for a combine harvester including a plurality of concaves which may be rotated around a rotor to move to or from a threshing position or one or more of one or more resting positions.

A rotary thresher for a combine harvester including a plurality of concaves which may be rotated around a rotor to move to or from a threshing position or one or more of one or more resting positions.

An agricultural vehicle including a chassis and a threshing system supported by the chassis. The threshing system includes a rotor, a front concave located at a distance radially away from the rotor and at least partially surrounding the rotor, and an infeed ramp connected to the front concave. The infeed ramp is located at a distance radially away from the rotor and has a plurality of slots therein. The threshing system also includes a support member positioned underneath the infeed ramp and a plurality of vanes connected to the support member. Each vane extends through a respective slot of the plurality of slots and is located at a distance radially away from the rotor. The vanes are configured for contacting and directing the crop material rearwardly towards the front concave.

A combine harvester including a frame and two axial-flow crop processing rotors mounted to the frame. An inner support structure is located between the two rotors and mounted to the frame by a first linkage. Two outer support structures are located outboard of the two rotors and mounted to the frame by respective second and third linkages. The inner support structure and two outer support structures carry first and second pluralities of concave grate segments at a radial distance from the respective rotors. A concave adjustment system includes a first actuator coupled to the first linkage which is configured to raise and lower the inner support structure. A second actuator is coupled to the second and third linkages and is configured to raise and lower the two outer support structures. The first linkage includes a first rockshaft mounted to the frame and aligned perpendicular to the rotation axis. The second and third linkages include and share a second rockshaft that is arranged coaxial to the first rockshaft.

A combine harvester including a frame and two axial-flow crop processing rotors mounted to the frame. An inner support structure is located between the two rotors and mounted to the frame by a first linkage. Two outer support structures are located outboard of the two rotors and mounted to the frame by respective second and third linkages. The inner support structure and two outer support structures carry first and second pluralities of concave grate segments at a radial distance from the respective rotors. A concave adjustment system includes a first actuator coupled to the first linkage which is configured to raise and lower the inner support structure. A second actuator is coupled to the second and third linkages and is configured to raise and lower the two outer support structures. The first linkage includes a first rockshaft mounted to the frame and aligned perpendicular to the rotation axis. The second and third linkages include and share a second rockshaft that is arranged coaxial to the first rockshaft.

A concave for an agricultural combine includes threshing bars carried by a base frame and forming openings therebetween for grain to pass through. Each threshing bar includes an inner extremity, a deflecting extremity including a deflecting surface, a separating grate between the inner extremity and the deflecting extremity, the separating grate extends across an adjacent one of the openings between the inner extremity and the deflecting extremity for separating grain from threshed crop material, the deflecting surface projects angularly upward relative to the separating grate, and the deflecting surface and the separating grate are arranged at an obtuse angle therebetween forming a grain-collecting trough between the deflecting surface and the separating grate.

A concave for an agricultural combine includes threshing bars carried by a base frame and forming openings therebetween for grain to pass through. Each threshing bar includes an inner extremity, a deflecting extremity including a deflecting surface, a separating grate between the inner extremity and the deflecting extremity, the separating grate extends across an adjacent one of the openings between the inner extremity and the deflecting extremity for separating grain from threshed crop material, the deflecting surface projects angularly upward relative to the separating grate, and the deflecting surface and the separating grate are arranged at an obtuse angle therebetween forming a grain-collecting trough between the deflecting surface and the separating grate.

The present invention comprises multiple embodiments of an automated, dynamic cover plate system, which may be quickly attached, detached and adjusted to the exterior of a concave grate of a combine harvester in order to adjust the flow characteristics of the concave or separator grate assemblies. The automated, dynamic cover plate system improves the threshing capability of the rasp bar threshing cylinder while simultaneously capturing additional threshed grain. The automated, dynamic cover plate system of the present invention is designed to be controlled, either manually or automatically, by the operator of the combine harvester or by a computerized or automated intelligence system.