A cleaning system for an agricultural harvester includes: at least one sieve; a cleaning blower directed at the at least one sieve and configured to supply a cleaning air flow directed at the at least one sieve; and a conveyor assembly configured to supply crop material to the at least one sieve. The conveyor assembly includes: a conveyor frame; a shaker coupled to the conveyor frame and configured to shake the conveyor frame; and an endless conveyor carried by the conveyor frame and including a conveyor loop with a substantially solid surface and a conveyor driver coupled to the conveyor loop, the conveyor driver being configured to selectively rotate the conveyor loop.

The present invention provides an improved dust control system for removing debris and particulate matter from a fouled air stream. The system may be incorporated into crop harvesting equipment to eliminate the dust pollution generated by conventional harvesting equipment. The dust control system may use a multi-stage air filtering process that employs inertial separation techniques to eliminate particulate matter from the fouled air, without the need for water or electrostatic mechanisms to capture the fine particulates in the fouled air.

A combine harvester includes a grain pan arranged to catch a crop stream, the grain pan being driven in an oscillating manner to convey the crop stream rearwardly to a rear edge. A cleaning unit includes a fan for generating a cleaning airstream which is directed under the rear edge. The grain pan includes a floor profile which defines a transverse profile having ridges and troughs. The troughs provide a plurality of longitudinal channels, wherein the ridge-to-trough height increases in the direction of conveyance. Crop material conveyed by the grain pan experiences channels that deepen towards the rear edge of the pan.

A combine harvester includes a grain pan arranged to catch a crop stream, the grain pan being driven in an oscillating manner to convey the crop stream rearwardly to a rear edge. A cleaning unit includes a fan for generating a cleaning airstream which is directed under the rear edge. The grain pan includes a floor profile which defines a transverse profile having ridges and troughs. The troughs provide a plurality of longitudinal channels, wherein the ridge-to-trough height increases in the direction of conveyance. Crop material conveyed by the grain pan experiences channels that deepen towards the rear edge of the pan.

Weed seeds are destroyed in the chaff from a combine harvester by repeated high speed impacts caused by a rotor mounted in one of a pair of side by side housings which accelerate the discarded seeds in a direction centrifugally away from the rotor onto a stator including angularly adjustable stator surfaces around the axis. Thus the discarded seeds rebound back and forth between the rotor and the stator to provide a plurality of impacts. The destructor is mounted on a suitable drive shaft within the straw path and the chaff and weed seed material is carried from the rear end of the sieve to the destructor on the straw chopper by one or more fans driving the material through a transfer duct.

A combine harvester including a grain pan arranged to catch a crop stream from threshing or separating apparatus. The grain pan is driven in an oscillating manner to convey the crop stream rearwardly to a rear edge. A cleaning unit including a fan for generating a cleaning airstream which is directed under the rear edge of the grain pan. The grain pan comprises includes a transversely corrugated surface and longitudinal gullies having a curved profile for compensating for side-hill operation.

A combine harvester including a grain pan arranged to catch a crop stream from threshing or separating apparatus. The grain pan is driven in an oscillating manner to convey the crop stream rearwardly to a rear edge. A cleaning unit including a fan for generating a cleaning airstream which is directed under the rear edge of the grain pan. The grain pan comprises includes a transversely corrugated surface and longitudinal gullies having a curved profile for compensating for side-hill operation.

A system for leveling grain on a return pan (128) of an agricultural combine (102), including a plurality of sensors (S1, S2, S3) coupled to the return pan (128) to detect a quantity of grain on the return pan (128) at a corresponding plurality of locations; a plurality of grain steering devices (156, 158) disposed on the return pan (128) to steer grain sliding down the return pan (128); and at least one ECU (192) coupled to the plurality of sensors (S1, S2, S3) and to the plurality of grain steering devices (156, 158); wherein the at least one ECU (192) is programmed to read the plurality of sensors (S1, S2, S3), to determine a side-to-side (lateral) distribution of grain on the return pan (128), to calculate a preferred position of the grain steering devices (156, 158) that will more evenly distribute the grain on the return pan (128), and to command an actuator coupled to the grain steering devices (156, 158) to steer them to the preferred position.

A system for leveling grain on a return pan (128) of an agricultural combine (102), including a plurality of sensors (S1, S2, S3) coupled to the return pan (128) to detect a quantity of grain on the return pan (128) at a corresponding plurality of locations; a plurality of grain steering devices (156, 158) disposed on the return pan (128) to steer grain sliding down the return pan (128); and at least one ECU (192) coupled to the plurality of sensors (S1, S2, S3) and to the plurality of grain steering devices (156, 158); wherein the at least one ECU (192) is programmed to read the plurality of sensors (S1, S2, S3), to determine a side-to-side (lateral) distribution of grain on the return pan (128), to calculate a preferred position of the grain steering devices (156, 158) that will more evenly distribute the grain on the return pan (128), and to command an actuator coupled to the grain steering devices (156, 158) to steer them to the preferred position.

A tailings conveyance including a housing having a front plate, a back plate, and a wall, and is adapted to recycle tailings through a cleaning system of a combine using at least one impeller. The wall of the housing describes an arc near the impeller paddles over a segment of a circle described by the circumference of the impeller. The wall further continues on a tangent away from the circle at a point of tangency. A sensor is positioned proximate to the point of tangency, and senses whether a space between the front plate and the back plate directly adjacent to the sensor is obscured by tailings as the impeller rotates. A controller or control system connected to the sensor calculates an amount or percentage of time the space between the front plate and the back plate directly adjacent to the sensor is obscured by tailings as the impeller rotates.