Abstract: In a grain unloading system for a combine harvester a grain bin includes a frame, the frame has a floor with a trough. An unloading auger is disposed at least partially within the trough. An auger cover at least partially covers the auger. The auger cover has a hat for a top portion of the auger cover and a pair of gates movable between the hat and locations on the floor that are proximal to the trough. A gate adjustment structure is coupled to the pair of gates to move the pair of gates relative to the auger. A control system is coupled to the gate adjustment structure and configured to control the gate adjustment structure.

Abstract: 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.

Abstract: An unloading system for a combine harvester having a belt-driven unloading auger assembly and a spill saver door mounted proximate to a discharge end of the unloading auger assembly. Engagement of the belt drive is controlled by a first hydraulic cylinder. Opening of the spill saver door is controlled by a second hydraulic actuator. The first and second hydraulic cylinders are hydraulically connected in parallel.

Abstract: An unloading system for a combine harvester having a belt-driven unloading auger assembly and a spill saver door mounted proximate to a discharge end of the unloading auger assembly. Engagement of the belt drive is controlled by a first hydraulic cylinder. Opening of the spill saver door is controlled by a second hydraulic actuator. The first and second hydraulic cylinders are hydraulically connected in parallel.

Abstract: In a grain unloading system for a combine harvester a grain bin includes a frame, the frame has a floor with a trough. An unloading auger is disposed at least partially within the trough. An auger cover at least partially covers the auger. The auger cover has a hat for a top portion of the auger cover and a pair of gates movable between the hat and locations on the floor that are proximal to the trough. A gate adjustment structure is coupled to the pair of gates to move the pair of gates relative to the auger. A control system is coupled to the gate adjustment structure and configured to control the gate adjustment structure.

Abstract: 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.

Abstract: An unloading conveyor swing control system including an unloading conveyor fitted to a self-propelled harvesting machine such as a combine harvester. The conveyor is moveable around a pivot axis through a movement range between a first, stowed, position and a second position. An actuator is connected to the conveyor and arranged to move the conveyor throughout the movement range. A sensor is configured to sense an angular position of the conveyor within the movement range and generate a representative position signal. A user interface device is provided for receiving user-commands to move the conveyor. A controller is in communication with the sensor, the actuator and the user interface device. The conveyor is automatically moved into the stowed position in response to an angular position falling below a predetermined threshold angle.

Abstract: In a grain unloading system for a combine harvester a grain bin includes a frame, the frame has a floor with a trough. An unloading auger is disposed at least partially within the trough. An auger cover at least partially covers the auger. The auger cover has a hat for a top portion of the auger cover and a pair of gates movable between the hat and locations on the floor that are proximal to the trough. A gate adjustment structure is coupled to the pair of gates to move the pair of gates relative to the auger. A control system is coupled to the gate adjustment structure and configured to control the gate adjustment structure.

Abstract: An unloading conveyor swing control system including an unloading conveyor fitted to a self-propelled harvesting machine such as a combine harvester. The conveyor is moveable around a pivot axis through a movement range between a first, stowed, position and a second position. An actuator is connected to the conveyor and arranged to move the conveyor throughout the movement range. A sensor is configured to sense an angular position of the conveyor within the movement range and generate a representative position signal. A user interface device is provided for receiving user-commands to move the conveyor. A controller is in communication with the sensor, the actuator and the user interface device. The conveyor is automatically moved into the stowed position in response to said angular position falling below a predetermined threshold angle.

Abstract: A cleaning shoe material-other-than-grain (MOG) discharge system of a combine harvester has a thresher rotor assembly configured to produce a stream of thresher rotor MOG and a shoe disposed beneath the thresher rotor assembly configured to produce a stream of shoe MOG. A chopper receives and chops the stream of thresher rotor MOG. Vanes disposed at an outlet of the chopper distribute the chopped thresher rotor MOG. A plate having top and bottom surfaces is adjacent to the plural vanes. A duct is set on the plate, the duct having a first inlet and a first outlet, the first inlet disposed adjacent to an outlet of the shoe to receive the stream of shoe MOG, the first outlet disposed downstream of the outlet of the chopper such that the stream of shoe MOG is received in the stream of chopped thresher rotor MOG.

Abstract: A cleaning shoe, material-other-than-grain (MOG) discharge method of a combine harvester is provided. The method comprises discharging first MOG from a rotor assembly; chopping with a chopper the discharged first MOG; discharging second MOG from an outlet end of a shoe; and combining the second MOG with the chopped first MOG before the chopped first MOG and the second MOG reaches the ground, wherein the second MOG that is combined with the chopped first MOG is not chopped by the chopper.

Abstract: The airflow through a harvesting machine is adjusted by calculating a G-factor at a first point on an upper chaffer to determine if it is greater than 1+n, where n represents a desired factor. A blower is adjusted to reduce an airstream if the G-factor is greater than 1+n. A MOG factor is calculated if the G-factor is less than 1+n. The blower is adjusted to increase the airstream if the MOG-factor is less than 1+x, where x represents a desired factor. A MOG-factor is calculated at a second point if the MOG-factor at the point is greater than 1+x and the blower is adjusted to reduce the airstream if the MOG-factor at the second point is greater than 1+y, where y represents a desired factor or adjusted to increase the airstream if the MOG-factor at the second point is less than 1+y.

Abstract: A combine has a grain bin with a sump and an unloading system for unloading grain out of the bin. The unloading system has a pivoting unloading tube assembly movable between a storage position and an unloading position. The unloading tube assembly has an inner riser section and a variable-length outer transport section. When the unloading tube assembly is in the storage position, at least a portion of the inner riser section nests underneath a rear floor portion of the grain bin. The variable-length transport section has a proximal chute nested with a distal chute that can be moved relative the proximal chute. A nested conveyor assembly transports grain through the variable-length section. The nested conveyor assembly includes an endless conveyor and pulleys configured to form an upper grain transporting reach inside of the chutes and a return reach outside of the chutes.

Abstract: The airflow through a harvesting machine is adjusted by calculating a G-factor at a first point on an upper chaffer to determine if it is greater than 1+n, where n represents a desired factor. A blower is adjusted to reduce an airstream if the G-factor is greater than 1+n. A MOG factor is calculated if the G-factor is less than 1+n. The blower is adjusted to increase the airstream if the MOG-factor is less than 1+x, where x represents a desired factor. A MOG-factor is calculated at a second point if the MOG-factor at said the point is greater than 1+x and the blower is adjusted to reduce the airstream if the MOG-factor at the second point is greater than 1+y, where y represents a desired factor or adjusted to increase the airstream if the MOG-factor at the second point is less than 1+y.

Abstract: A work vehicle includes a first loader arm portion pivotably connected at one end to a frame of the vehicle and configured to slidably receive a second loader arm portion along an opposed end of the first loader arm portion. A mechanical linkage interconnects the loader arm portions and the frame. A fluid cylinder operatively connected between each of the frame and the loader arm portions is configured to raise and lower the loader arm portions between a retracted (lowered) position and an extended (raised) position. As the fluid cylinder is actuated to urge the loader arm portions toward the extended (raised) position, the mechanical linkage results in slidable movement of the second loader arm portion with respect to the first loader arm portion so that a collective length of the loader arm portions in the extended (raised) position is increased.

Abstract: The airflow through a harvesting machine is adjusted by calculating a G-factor at a first point on an upper chaffer to determine if it is greater than 1+n, where n represents a desired factor. A blower is adjusted to reduce an airstream if the G-factor is greater than 1+n. A MOG factor is calculated if the G-factor is less than 1+n. The blower is adjusted to increase the airstream if the MOG-factor is less than 1+x, where x represents a desired factor. A MOG-factor is calculated at a second point if the MOG-factor at the point is greater than 1+x and the blower is adjusted to reduce the airstream if the MOG-factor at the second point is greater than 1+y, where y represents a desired factor or adjusted to increase the airstream if the MOG-factor at the second point is less than 1+y.

Abstract: A combine harvester has a threshing mechanism for threshing grain and cleaning apparatus for removing chaff from the threshed grain. The threshing mechanism includes a rotor and a plurality of concaves and the cleaning apparatus includes and upper chaffer and a lower sieve. A blower provides cleaning air to the combine harvester. The blower is situated in a blower housing having a first cut off plate separating high-velocity air coming from the blower and directing a first portion of the high-velocity air to a lower duct that provides an airstream to the upper chaffer and lower sieve. The blower housing also has a second cut off plate directing a second portion of the high-velocity air to an upper duct that provides an airstream under the concaves. A leading portion of the second cut off plate contains a rolled edge along the width of the upper duct.

Abstract: A steering and engine speed control mechanism for operating a vehicle. The control mechanism has a control handle mounted on the vehicle. The control handle is configured to deflect about an axis by movement of an operator's hand. A steering direction of the vehicle is related to a deflection angle of the control handle about the axis. An actuating element for changing the speed of the engine of the vehicle is attached to the control handle and is conveniently movable by an operator's digit to a plurality of positions to effect the desired speed of the engine.

Abstract: A cleaning system in a combine harvester includes a fan producing an airstream, an oscillating upper chaffer that separates grain and smaller residue from larger non-grain particles while the airstream entrains light non-grain particles and carries them out the rear of the machine. An oscillating lower sieve receives the grain and smaller residue passing through the upper chaffer and allows grain to pass through openings while residue unable to penetrate the lower sieve travels off the end of the lower sieve and the airstream entrains light non-grain particles and carries them out of the machine. An airstream diverter located between the upper chaffer and the lower sieve redirects a portion of the airstream through lower air-flow areas of the upper chaffer. The diverter is horn-shaped with a narrow leading edge and a wider trailing edge with a concave air-directing surface between the leading and trailing edges.

Abstract: A work vehicle includes a first loader arm portion pivotably connected at one end to a frame of the vehicle and configured to slidably receive a second loader arm portion along an opposed end of the first loader arm portion. A mechanical linkage interconnects the loader arm portions and the frame. A fluid cylinder operatively connected between each of the frame and the loader arm portions is configured to raise and lower the loader arm portions between a retracted (lowered) position and an extended (raised) position.