An automatic uniform distribution apparatus for the threshed material from the combine harvester comprises a tangential flow threshing and separating device, a shaking plate threshed material detecting device, a shaking plate, a shaking plate flow guiding mechanism, an axial flow threshing and separating device, a chaff screw conveyor, a return plate, a return plate flow guiding mechanism, a return plate threshed material detecting device, a vibrating sieve, and an on-line detection controller. Force sensors are provided at lateral positions below discharge ports of the shaking plate and the return plate to measure flow rates of the threshed material in lateral regions of the shaking plate and the return plate.

A concave for an agricultural combine includes threshing beds carried by a base frame and forming openings therebetween for grain to pass through. Each threshing bed includes a first end, a second end, a length from the first end to the second end, an inner extremity, an outer extremity, and a separating grate extending across one of the openings for separating grain from threshed crop material. The separating grate extends along the length between the first end and the second end, is between the inner extremity and the outer extremity and includes grate openings and spaced-apart bars. The bars are between adjacent grate openings and include struts each connecting two adjacent parts of the separating grate between adjacent grate openings and severed bars each including bar segments extending inwardly toward one another to respective free ends on either side of a gap between adjacent grate openings.

A sieve assembly for use within an agricultural harvester may generally include a sieve, a crop material sheet, and at least one support element. The sieve extends along a length defined between a first sieve end and a second sieve end and processes a flow of harvested crop material. The sieve also defines a plurality of openings through which cleaned crop material of the flow of crop material is directed. The crop material sheet extends along a length defined between a first sheet end and a second sheet end and receives the cleaned crop material directed through the sieve's openings. The crop material sheet then directs the flow of cleaned crop material towards a separate component of the crop processing system. In addition, the support element(s) is directly coupled between the sieve and the crop material sheet and structurally connects the sieve to the crop material sheet.

A sugarcane harvester includes an improved discharge assembly that receives sugarcane billets and discharges the billets into a storage vehicle that travels alongside the harvester. The discharge assembly includes an elevator and a conveyor. The elevator lifts the billets vertically about an elevator axis that is substantially perpendicular to the longitudinal axis of the harvester. The conveyor receives the billets from the elevator and moves the billets horizontally along a conveyor axis that is substantially perpendicular to both the elevator axis and the longitudinal axis of the harvester. The discharge assembly also comprises height adjustment mechanism for vertically raising or lowering the conveyor and lateral adjustment mechanism for laterally adjusting positions of the conveyor. The height adjustment mechanism and the lateral adjustment mechanism can be manually or automatically operated to shift the conveyor between a number of use positions and a transport/storage position.

A harvesting machine feederhouse that comprises an outer body connectable to and between a head unit and a thresher of the machine. The feederhouse additionally comprises a liner disposed across a bottom surface of the outer body, and at least one conveyor rotatably disposed within the outer body for conveying harvested plant product received from the head unit along the liner into the thresher. Each conveyor includes a first guide, a second guide, a pair of conveyor transports that extend between, and are disposed around, the first guide and the second guide. Each conveyor additionally includes a plurality of plant product sweeps disposed across and connected to the transports. Each sweep is sized to contact the liner as the conveyor transports are rotated around the first guide and second guide, thereby conveying plant product received from the head unit along the liner into the thresher.

A harvesting machine including a cutting head configured to provide cut crop for threshing. The harvesting machine includes a conveyer disposed adjacent to the cutting head and configured to move the cut crop to be threshed along a path. A thresher is configured to thresh the cut crop to provide threshed grain from the cut crop. A separator is disposed adjacently to the thresher and is configured to separate debris from the threshed grain. A feed accelerator is disposed between the conveyor and the thresher, wherein the feed accelerator is configured to advance the cut crop along the path from the conveyor to the thresher. A pre-threshing device is disposed adjacently to the feed accelerator, wherein the feed accelerator interacts with the pre-threshing device to provide threshed grain, and the pre-threshing device is configured to collect the threshed grain before the remaining cut crop is threshed at the thresher.

A cleaning and tailings system of an agricultural harvester including an upper sieve and a lower sieve spaced from the upper sieve. A clean grain sheet is disposed below the lower sieve, and a tailings sheet is disposed below the clean grain sheet for receiving grain from the lower sieve and upper sieve. A tailings auger is disposed about a forward end of the tailings sheet, and a sensor is disposed about an inlet of the tailings auger for sensing impact of grain received by the tailings sheet. A controller is in communication with the sensor, wherein the controller is configured to determine an amount of grain received by the tailings sheet.

A high strength sieve which is lightweight and durable without having to add springs, and without requiring a high level of force to effect adjustment of the louvers. The high strength sieve utilizes hollow tubes to support the louvers. Providing hollow tubes (i.e., rather than solid wires) allows for larger diameter holes to be used in the frame. This provides for increased bearing surfaces, as well as provides for better tolerances. This reduces the movement of the tubes within the holes. Preferably, the tubes are mounted in the frame through holes which are extruded, thereby providing for increased bearing surfaces and a tighter fit. The extruded holes also provide a natural lead-in for the insertion of the tubes (i.e., during assembly of the sieve). Alternatively, solid wires can be provided extending through the extruded holes instead of hollow tubes.

Systems and methods are described for a virtual sensor that determines an amount of grain loss during operation of a combine harvester without any direct measurement of grain loss. An electronic controller is configured to determine values for a set of operating conditions including a plurality of sensor values and actuator settings. The electronic controller then applies an artificial neural network that is configure to receive as inputs the values for the set of operating conditions and to produce as an output a value indicative of an estimate amount of grain loss.

A charge fan assembly is located behind the forward operator cab and draws air from about the top of the PPU and a portion of an airflow from the charge fan assembly is directed downwardly into the crossflow cleaning fan assembly. A pair of closely spaced-apart sheets create a venturi and speed up the charge fan airflow into the crossflow cleaning fan and impact the crossflow cleaning fan at an angle where the blades of the crossflow cleaning fan are widely open. The exhaust air from the crossflow cleaning fan is nearly the same across the entire lengthwise extent of the crossflow cleaning fan.