An agricultural harvester includes a chassis and a grain tank carried by the chassis. The grain tank includes a frame having an opening formed therethrough; a pair of tank cover sections movably associated with the frame such that the tank cover sections can switch between an open position and a covering position relative to the opening of the frame; and at least one actuator linked to at least one of the tank cover sections and configured to selectively provide a switching force. The agricultural harvester further includes a force assistor or a brake linked to one of the pair of tank cover sections and configured to apply an assist force or a braking force, respectively, to one of the pair of tank cover sections but not the other of the pair of tank cover sections.

An agricultural harvester includes a chassis and a grain tank carried by the chassis. The grain tank includes a frame having an opening formed therethrough; a pair of tank cover sections movably associated with the frame such that the tank cover sections can switch between an open position and a covering position relative to the opening of the frame; and at least one actuator linked to at least one of the tank cover sections and configured to selectively provide a switching force. The agricultural harvester further includes a force assistor or a brake linked to one of the pair of tank cover sections and configured to apply an assist force or a braking force, respectively, to one of the pair of tank cover sections but not the other of the pair of tank cover sections.

A grain mass flow sensor assembly of an agricultural harvester has a continuously curved sensor plate positioned to receive a grain flow from an exit of the grain elevator. The continuously curved sensor plate is configured to change the direction of the grain flow in order to generate a reaction force for measuring the grain mass flow rate of the grain flow. The continuously curved sensor plate is attached to a sensor plate to load cell mounting bracket. The sensor plate to load cell mounting bracket is attached to a single point load cell torque or moment compensated force transducer at a single mounting point. The single point load cell torque or moment compensated force transducer produces a mass flow sensor signal that is proportionate to the grain mass flow rate.

A grain mass flow sensor assembly of an agricultural harvester has a continuously curved sensor plate positioned to receive a grain flow from an exit of the grain elevator. The continuously curved sensor plate is configured to change the direction of the grain flow in order to generate a reaction force for measuring the grain mass flow rate of the grain flow. The continuously curved sensor plate is attached to a sensor plate to load cell mounting bracket. The sensor plate to load cell mounting bracket is attached to a single point load cell torque or moment compensated force transducer at a single mounting point. The single point load cell torque or moment compensated force transducer produces a mass flow sensor signal that is proportionate to the grain mass flow rate.

A combine harvester comprises a threshing unit arranged to receive and thresh a crop stream. Separating apparatus are located downstream and rearward of the threshing unit and are arranged to receive the threshed crop stream and convey such a rearward direction. The front of a return pan, disposed below the separating apparatus, overlaps the rear of a stratification pan, disposed below the threshing unit. The stratification pan is driven in an oscillating manner to convey a primary grain/chaff stream rearwardly to a rear edge from where the primary grain/chaff stream falls under gravity into a cleaning unit. The return pan is driven in an oscillating manner to convey a secondary grain/chaff stream forwardly to a front edge from where the secondary grain/chaff stream falls under gravity to combine with the primary grain/chaff stream on the stratification pan. The cleaning unit comprises a fan for generating a cleaning airstream which is directed through the falling grain/chaff stream to encourage the lighter material away from the grain. A plurality of crop flow disrupting elements in the form of fins or tines are secured to the underside of the return pan above the stratification pan to disrupt the grain/chaff stream and enhance stratification thereof.

A combine harvester comprises a threshing unit arranged to receive and thresh a crop stream. Separating apparatus are located downstream and rearward of the threshing unit and are arranged to receive the threshed crop stream and convey such a rearward direction. The front of a return pan, disposed below the separating apparatus, overlaps the rear of a stratification pan, disposed below the threshing unit. The stratification pan is driven in an oscillating manner to convey a primary grain/chaff stream rearwardly to a rear edge from where the primary grain/chaff stream falls under gravity into a cleaning unit. The return pan is driven in an oscillating manner to convey a secondary grain/chaff stream forwardly to a front edge from where the secondary grain/chaff stream falls under gravity to combine with the primary grain/chaff stream on the stratification pan. The cleaning unit comprises a fan for generating a cleaning airstream which is directed through the falling grain/chaff stream to encourage the lighter material away from the grain. A plurality of crop flow disrupting elements in the form of fins or tines are secured to the underside of the return pan above the stratification pan to disrupt the grain/chaff stream and enhance stratification thereof.

A combine harvester with a separating rotor, rotor tube and a plurality of crop engaging finger elements. Each finger element is mounted to a respective finger support which is secured to the rotor tube. Each finger element has a planar body with a flared base portion which presents a leading edge to the crop material with a relatively shallow angle with respect to the tube.

A combine harvester self-adaptive cleaning control apparatus, includes a return plate, a cleaning sieve, a cleaning centrifugal blower, an impurity collection and stirring auger, a grain collection and stirring auger, a cleaning grain loss monitoring sensor, a grain tank grain impurity rate automatic monitoring apparatus, and an on-line monitoring and control system. The on-line monitoring and control system is connected to the cleaning centrifugal blower, the cleaning grain loss monitoring sensor, the grain tank grain impurity rate automatic monitoring apparatus, and a power driving mechanism of a louver sieve having an adjustable opening. Also disclosed is a self-adaptive cleaning method of the cleaning apparatus which can automatically adjust various working parameters according to a working quality of a working process, improve production efficiency, control failure rate, and improve a down-time working time for the apparatus.

A combine harvester self-adaptive cleaning control apparatus, includes a return plate, a cleaning sieve, a cleaning centrifugal blower, an impurity collection and stirring auger, a grain collection and stirring auger, a cleaning grain loss monitoring sensor, a grain tank grain impurity rate automatic monitoring apparatus, and an on-line monitoring and control system. The on-line monitoring and control system is connected to the cleaning centrifugal blower, the cleaning grain loss monitoring sensor, the grain tank grain impurity rate automatic monitoring apparatus, and a power driving mechanism of a louver sieve having an adjustable opening. Also disclosed is a self-adaptive cleaning method of the cleaning apparatus which can automatically adjust various working parameters according to a working quality of a working process, improve production efficiency, control failure rate, and improve a down-time working time for the apparatus.

A grain cart and foldable auger assembly having an upper auger assembly portion with a discharge portion, a lower auger assembly portion with an intake portion, and a compound angle joint that allows the upper auger assembly portion to be moved between operating and transport positions. When in an operating position, the upper auger portion and the lower auger portion are offset from each other by an operating offset angle. When in a transport position, the upper auger assembly portion is offset from the lower auger assembly portion by a transport offset angle such that the upper auger assembly portions folded across the front of the grain cart in a non-obstructive and non-protruding manner.