A cleaning system for a combine harvester has a chaffer and a blower configured to direct air rearward and upward through the chaffer. The chaffer has a perforated base, a plurality of longitudinal lateral walls, and a plurality of airbags, each of which is disposed adjacent to a lateral wall. An air supply is configured to inflate at least one of the airbags. Another cleaning system for a combine harvester also has a chaffer and a blower configured to direct air rearward and upward through the chaffer. The chaffer has a perforated base, a plurality of longitudinal lateral walls, a plurality of rigid members disposed adjacent to a corresponding lateral wall, and at least one actuator configured to move each rigid member relative to the corresponding lateral wall. Related methods are also disclosed.

A head assembly can be operationally mounted to the outlet of a conventional harvester extractor, such as a sugarcane harvester. The ancillary fan assemblies can generally direct suspended trash materials (that would otherwise be expelled from an extractor outlet) in a substantially upward and laterally outboard directionthat is, toward both lateral sides of a harvester. A duct assembly having an inlet and an outlet generally extends from each ancillary fan assembly to a position generally above a track of a harvester. Trash material expelled by a harvester extractor enters the head assembly and is directed by the ancillary fan assemblies into the duct assemblies, through the duct assemblies, and onto the upper surfaces of the tracks of the harvesters. The trash material is then conveyed by the tracks toward the front or forward portion of the harvester, where it falls off of the tracks generally in the path of the harvester. As the harvester continues moving forward, the harvester runs over the deposited organic trash material, plowing the organic trash material into the underlying terrain.

A crop loss correction system receives one or more crop loss sensor signals that are indicative of crop lost by a harvesting machine. A correction component receives context information from a set of context sensing components to identify a context of the harvesting machine. The correction component corrects the crop loss sensor signals, based upon the context information, to obtain a corrected loss signal indicative of the sensed crop loss, corrected based on the mobile machine context. The corrected loss signal is output to an output device.

A shaker table with air flow openings and airflow to preprocess the crop before it fully enters the separating and cleaning system of the harvester through a means of corrugation platforms with air flow directed from below to break up the material into a more easily cleaned condition.

A combine harvester includes one or more threshing rotors (5) mounted in the harvester, a grain pan (7) and a set of sieves (8), and a drive mechanism configured to drive a longitudinal reciprocating motion of the grain pan (7) and superimpose a lateral reciprocating motion component on the longitudinal reciprocating motion.

An airflow system for a rotary harvester includes a cleaning charge fan assembly, a cleaning fan assembly, and bonus sieves with fan assemblies. Each of the fan assemblies is powered by a hydraulic motor. By linking the charge fan motor, the left/right tailings fan motors, and the cleaning fan motor in a series hydraulic circuit, each of the motors will increase/decrease in speed at the same time and by the same proportional amount.

A display controller controls a display device in a harvester to display an interface showing adjustments to combine harvester settings, received from a remote computing system, along with an adjustment actuator. A settings adjustment is made based on user actuation of the adjustment actuator input is received through the settings adjustment actuator on the displayed interface. A verification notification is sent to the remote computing system, showing the adjusted settings on the combine.

A combine harvester fan housing assembly may include a fan enclosure formed as a single unitary body out of a polymeric material. The fan enclosure may include a spiral duct spiraling about an axis, a first axial inlet opening sized to axially receive a fan therethrough and a second axial inlet opening and a discharge duct extending from the spiral duct. The combine harvester fan housing assembly may further include an inlet ring releasably mounted to the fan enclosure about the first axial opening, the inlet ring projecting into the first axial opening by an extent so as to extend radially inward of blade ends of the fan.

A combine harvester includes threshing apparatus, separating apparatus, a grain cleaning system located downstream of the separating apparatus, and a material conveyance system arranged to convey crop material from the separating apparatus to the grain cleaning system. The grain cleaning system includes screening apparatus, a fan arranged to generate a cleaning airstream through the screening apparatus, and a fan control system configured to control a fan speed. The fan control system includes a proximity sensor mounted above the material conveyance system for sensing a material volume. The fan control system controls the fan speed in dependence upon the material volume.

A combine (10) including a cutting wheel for harvesting crop, a separating system (24) for threshing the harvested crop to separate grain from residue, at least one of a yield monitor (115) or a loss monitor (113), a crop cleaning system (26) including a cleaning fan (52), and a controller (310) coupled to the at least one of the yield monitor (115) or the loss monitor (113). The controller (310) controls the crop cleaning system (26), and is configured to determine at least one of a throughput from the yield monitor (115), or a loss from the loss monitor (113), compare the determined throughput or loss to a respective throughput threshold or loss threshold, and control a speed of the cleaning fan (52) based on the throughput or loss comparison.