A threshing and separating system including a non-stationary rotor cage including a perforated cylindrical body extending in a longitudinal direction from a first open end portion to a second open end portion. The first open end portion supported by a first rotatable coupling point, and the second open end portion supported by a second rotatable coupling point. The threshing and separating system also includes a rotor configured to rotate within the non-stationary rotor cage to thresh harvested crop. The non-stationary rotor cage is configured to rotate about an axis extending between the first rotatable coupling point and the second rotatable coupling point, and to be rotationally driven by the rotor via the threshed harvested crop.

A threshing and separating system including a non-stationary rotor cage including a perforated cylindrical body extending in a longitudinal direction from a first open end portion to a second open end portion. The first open end portion supported by a first rotatable coupling point, and the second open end portion supported by a second rotatable coupling point. The threshing and separating system also includes a rotor configured to rotate within the non-stationary rotor cage to thresh harvested crop. The non-stationary rotor cage is configured to rotate about an axis extending between the first rotatable coupling point and the second rotatable coupling point, and to be rotationally driven by the rotor via the threshed harvested crop.

A separating rotor with a rotor tube for use on a combine harvester has a plurality of crop engaging finger elements. Each finger element is mounted to a respective finger support which is secured to the rotor tube. Each finger element has a planar body with a flared base portion which presents a leading edge to the crop material with a relatively shallow angle with respect to the tube.

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.

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 characterized 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.

A cogged drive arrangement for an endless belt conveyor for a feederhouse of an agricultural combine has a first drive wheel with an axis of rotation, a hub extending around the axis of rotation, flanges fixed to an outer edge of the hub and extending outward from the hub and a plurality of cogs fixed to the outer ends of the flanges.

A cogged drive arrangement for an endless belt conveyor for a feederhouse of an agricultural combine has a first drive wheel with an axis of rotation, a hub extending around the axis of rotation, flanges fixed to an outer edge of the hub and extending outward from the hub and a plurality of cogs fixed to the outer ends of the flanges.

A transition cone for a threshing system of an agricultural harvesting machine has an inner surface with a tapering inner circumference between a wider upstream end and a narrower downstream end, and a plurality of vanes in the transition cone. Each vane extends between the upstream end and the downstream end and at least partly around the tapering inner circumference. Each vane includes an upstanding segment extending away from the inner surface, and a base segment extending from the upstanding segment along the inner surface on the downstream side of the upstanding segment. The base segment has a thicker proximal region adjacent the upstanding segment and a thinner distal edge opposite thereto.

A chopper for receiving the straw and/or chaff from a combine harvester includes a housing with a chopping rotor to transport the materials though a discharge opening onto a tailboard construction with downwardly facing guide surface and fins for spreading of the crop materials. A rotary spreader has a plurality of fan members with blades rotatable for discharge to a respective side of the rotary spreader. An arrangement is operable so that in a first mode the crop material is spread wholly by the tailboard and in a second mode the crop material is spread at least mainly by the rotary spreader. In the second mode the tailboard remains position above the rotary spreader which is therefore located underneath a guide surface with fins of the guide surface facing downwardly adjacent the blades. The movement to the second ode is provided by the rotary spreader being moved forwardly and downwardly.