A threshing apparatus 1 includes a threshing unit 41 that has a receiving net 23 and threshes crops, and a sorting unit 42 that is provided below the threshing unit 41 and sorts grain from a threshed product that has leaked from the receiving net 23. The sorting unit 42 includes a sorter 24 that sorts grain as a sorted product from the threshed product, a first product collector 26 that collects the sorted product as a first product, a second product collector 27 that collects, as a second product, the threshed product that was not sorted as the sorted product, a second product returner 32 that returns the second product collected by the second product collector 27 to the sorter 24, and a return amount detector 71 that detects the return amount of the second product to be returned to the sorter 24.

A threshing system for a combine harvester includes a support bracket that is configured to be attached to a threshing rotor cylinder of the threshing system and a rasp bar that is configured to be mounted to the support bracket. A channel is formed in one of the rasp bar and the support bracket for receiving a surface of the other of the rasp bar and the support bracket, wherein engagement between the channel and the surface limits movement of the rasp bar on the support bracket.

A threshing system for a combine harvester includes a support bracket that is configured to be attached to a threshing rotor cylinder of the threshing system and a rasp bar that is configured to be mounted to the support bracket. A channel is formed in one of the rasp bar and the support bracket for receiving a surface of the other of the rasp bar and the support bracket, wherein engagement between the channel and the surface limits movement of the rasp bar on the support bracket.

An axial threshing/separating system having at least one spring tined accelerator cylinder, in where the accelerator cylinder includes a plurality of double torsional spring tine cylinder elements extending from the spring tined accelerator cylinder; and one or more spring tined axial rotors, in where each of the spring tined axial rotors includes a plurality of double torsional spring tine rotor elements extending from each of the spring tined axial rotors, in where each of the spring tined axial rotors is aligned such that a respective longitudinal axis of each spring tined axial rotor is substantially coplanar and substantially parallel to a respective longitudinal axis of each other spring tined axial rotor, and wherein a longitudinal axis of at least one spring tined accelerator cylinder is substantially perpendicular to the longitudinal axis of each spring tined axial rotor.

An axial threshing/separating system having at least one spring tined accelerator cylinder, in where the accelerator cylinder includes a plurality of double torsional spring tine cylinder elements extending from the spring tined accelerator cylinder; and one or more spring tined axial rotors, in where each of the spring tined axial rotors includes a plurality of double torsional spring tine rotor elements extending from each of the spring tined axial rotors, in where each of the spring tined axial rotors is aligned such that a respective longitudinal axis of each spring tined axial rotor is substantially coplanar and substantially parallel to a respective longitudinal axis of each other spring tined axial rotor, and wherein a longitudinal axis of at least one spring tined accelerator cylinder is substantially perpendicular to the longitudinal axis of each spring tined axial rotor.

An axial threshing/separating system having at least one spring tined accelerator cylinder, in where the accelerator cylinder includes a plurality of double torsional spring tine cylinder elements extending from the spring tined accelerator cylinder; and one or more spring tined axial rotors, in where each of the spring tined axial rotors includes a plurality of double torsional spring tine rotor elements extending from each of the spring tined axial rotors, in where each of the spring tined axial rotors is aligned such that a respective longitudinal axis of each spring tined axial rotor is substantially coplanar and substantially parallel to a respective longitudinal axis of each other spring tined axial rotor, and wherein a longitudinal axis of at least one spring tined accelerator cylinder is substantially perpendicular to the longitudinal axis of each spring tined axial rotor.

An axial threshing/separating system having at least one spring tined accelerator cylinder, in where the accelerator cylinder includes a plurality of double torsional spring tine cylinder elements extending from the spring tined accelerator cylinder; and one or more spring tined axial rotors, in where each of the spring tined axial rotors includes a plurality of double torsional spring tine rotor elements extending from each of the spring tined axial rotors, in where each of the spring tined axial rotors is aligned such that a respective longitudinal axis of each spring tined axial rotor is substantially coplanar and substantially parallel to a respective longitudinal axis of each other spring tined axial rotor, and wherein a longitudinal axis of at least one spring tined accelerator cylinder is substantially perpendicular to the longitudinal axis of each spring tined axial rotor.

A threshing system for a combine harvester includes a support bracket that is configured to be attached to a threshing rotor cylinder of the threshing system and a rasp bar that is configured to be mounted to the support bracket. A channel is formed in one of the rasp bar and the support bracket for receiving a surface of the other of the rasp bar and the support bracket, wherein engagement between the channel and the surface limits movement of the rasp bar on the support bracket.

A threshing system for a combine harvester includes a support bracket that is configured to be attached to a threshing rotor cylinder of the threshing system and a rasp bar that is configured to be mounted to the support bracket. A channel is formed in one of the rasp bar and the support bracket for receiving a surface of the other of the rasp bar and the support bracket, wherein engagement between the channel and the surface limits movement of the rasp bar on the support bracket.

A threshing and separating system for an agricultural harvester includes: a rotor; a rotor cage at least partially enclosing the rotor, the rotor cage including a first flat wall, a second flat wall connected to and angled with respect to the first flat wall, and a curved wall connected to the second flat wall; and at least one vane connected to the first flat wall or the second flat wall.