An agricultural combine includes a self-propelled agricultural harvesting vehicle and a feederhouse extending forward from the vehicle. The combine further includes a rotor and concave arrangement for threshing and separating grain received in the feederhouse. A cleaning shoe is disposed below the rotor and concave arrangement. The combine moreover includes a grain tank for receiving and accumulating grain from the cleaning shoe and an unloading conveyor for conveying grain from the grain tank. An electrostatic grain cleaner is coupled to a distal end of the conveyor for electrostatically cleaning grain from the grain tank.

A cooler box for an agricultural harvester includes: a frame including an opening; a screen held in the opening and including a plurality of screen apertures defining a screen aperture size; a cooling fan configured to produce an airstream that flows through a front of the screen; a wand assembly including a wand associated with the screen and a blower coupled to the wand, the wand assembly being configured to vacuum accumulated debris from the screen; and a debris guard covering the front of the screen and including a plurality of guard openings defining a guard opening size that is greater than the screen aperture size.

Systems for harvesting machines, transmissions for harvesting machines, and methods of operating systems for harvesting machines are disclosed herein. A system includes a drive unit, a cleaner unit, an aspirator, and a transmission. The drive unit is configured to produce rotational power in use of the system. The cleaner unit is fluidly coupled to the drive unit and configured to separate debris from air so that the air becomes cleaned air and provide the cleaned air to the drive unit in use of the system. The aspirator is fluidly coupled to the cleaner unit and configured to draw debris away from the cleaner unit and exhaust the debris in use of the system. The transmission is coupled to the drive unit and the aspirator.

Systems for harvesting machines, transmissions for harvesting machines, and methods of operating systems for harvesting machines are disclosed herein. A system includes a drive unit, a cleaner unit, an aspirator, and a transmission. The drive unit is configured to produce rotational power in use of the system. The cleaner unit is fluidly coupled to the drive unit and configured to separate debris from air so that the air becomes cleaned air and provide the cleaned air to the drive unit in use of the system. The aspirator is fluidly coupled to the cleaner unit and configured to draw debris away from the cleaner unit and exhaust the debris in use of the system. The transmission is coupled to the drive unit and the aspirator.

A fan assembly that has a fan hub having a plurality of blades extending radially therefrom and having a variable pitch and a controller in communication with the fan assembly to reposition a pitch of the plurality of blades. The controller establishes a variable maximum pitch of the plurality of blades based on an ambient temperature.

In one aspect, an aspiration system for a work vehicle may include an exhaust tube extending defining an exhaust passage therein. The exhaust tube may include a venturi portion, with the exhaust tube further defining an aperture within the venturi portion of the exhaust tube. The system may also include an aspiration tube configured to be coupled between the exhaust tube and a separate component of the work vehicle. The aspiration tube may define an aspiration passage extending between the separate component and the exhaust tube. The aperture defined by the exhaust tube may fluidly couple the aspiration passage and the exhaust passage. Furthermore, the system may include a restrictor body positioned within the exhaust passage. As such, the restrictor body and the venturi portion may be configured to adjust a flow parameter of exhaust gases flowing through the exhaust passage.

An agricultural equipment air screen cleaning assembly having a frame having an airflow opening having a non-circular outer perimeter, a screen mounted to the frame within the airflow opening and extending to the non-circular outer perimeter, a motor, and a suction wand operatively connected to the motor and located on an upstream side of the screen. The suction wand is rotatably connected about a rotation axis at a central region of the screen, and includes: at least one distal end that is movable in a radial direction with respect to the rotation axis to follow the non-circular outer perimeter as the suction wand rotates about the rotation axis, one or more inlet openings facing the screen, and an internal suction flow path in fluid connection with the one or more inlet openings, the suction flow path extending from a manifold to the distal end of the suction wand.

A combine crop trash removal system for mounting to a combine corn harvester using hydraulically driven air blowers coupled to the combine header control system for reduction and/or removal of stalks, leaves, dirt and dust type material from accumulating on the combine feeder house and obscuring the operators view of the operating combine header during operation of the combine harvester for corn picking. The air blower may also be driven electrically or pneumatically. The operator of the combine harvester controls the crop trash removal system from the operator cab of the combine harvester.

A combine including an engine for propelling the combine, a feeder housing for receiving cut crop, a separating system for threshing the cut crop to produce grain and residue, a residue chopper for chopping the residue, and a controller. The controller is configured to estimate risk factors that correlate to a risk of fire in the engine due to airborne particles created by at least one of the cut crop, the separating system or the residue chopper, estimate a fire risk based on the risk factors, and implement corrective action based on the estimated fire risk.

A debris removal system for an agricultural harvester may include a chopper assembly configured to chop harvested crops into billets; an elevator having an elevator inlet that receives a stream of billets from the chopper assembly; and an extractor positioned adjacent the elevator inlet that is configured to remove from the harvester debris separated from the billets. A fan assembly may be positioned between the chopper assembly and the elevator inlet and may include a fan and a fan discharge outlet. The fan assembly may blow a stream of air through the stream of billets and toward the extractor to separate the debris from the billets for removal by the extractor. Moreover, the fan has a diameter that is approximately twice a height of the fan discharge outlet. Other debris removal systems and methods for removing debris from harvested crops also are provided.