The present invention comprises a removable cover plate assembly, which may be quickly attached, detached and adjusted to the exterior of a concave grate of a combine harvester in order to adjust the flow characteristics of the concave or separator grate assemblies. The cover plate assembly improves the threshing capability of the rasp bar threshing cylinder while simultaneously capturing additional threshed grain. Moreover, the cover plate assembly of the present invention enables a single set of concave grate assemblies to better harvest a wider variety of crop types.

A method for growing plants includes both a seeder and a harvester both of which include arrangements for singulating the seeds and for measuring parameters of the seeds while singulated. This can be used for seeding selected seeds and for harvesting particular plants. The system operates by correlating information from the individual seeded seeds and from the harvested seeds in respect of a particular location on the growth medium and may include information relating the growth medium at the location. The location can be determined by seeding the plants in patterns which can be detected by a reader on the harvester. The system can be used to control selection of seeds to take into account soil conditions at the plant.

A method for growing plants includes both a seeder and a harvester both of which include arrangements for singulating the seeds and for measuring parameters of the seeds while singulated. This can be used for seeding selected seeds and for harvesting particular plants. The system operates by correlating information from the individual seeded seeds and from the harvested seeds in respect of a particular location on the growth medium and may include information relating the growth medium at the location. The location can be determined by seeding the plants in patterns which can be detected by a reader on the harvester. The system can be used to control selection of seeds to take into account soil conditions at the plant.

A removable cover plate assembly may be quickly attached, detached and adjusted to the exterior of a concave grate of a combine harvester in order to adjust the flow characteristics of the concave or separator grate assemblies.

Embodiments of an intelligent power allocation system include a ground traction undercarriage controllable to propel a hybrid combine over terrain, a separator device configured to separate grain from other crop material ingested by the hybrid combine, a mechanical powertrain including an internal combustion engine, and an electric drive subsystem containing a rechargeable battery pack and a motor/generator (M/G). A controller architecture is configured to monitor a current separator load placed on the hybrid combine when driving movement of the separator device during active harvesting. The controller architecture further selectively places the intelligent power allocation system in a separator power splitting mode in which the M/G and the internal combustion engine concurrently drive movement of the separator device based, at least in part, on whether the current separator load exceeds an upper load threshold.

A crop processing assembly includes a tube-shaped cage structure and a threshing and separation rotor mounted in the cage structure. The cage structure includes one or more curved gratings at the bottom and a cover at the top, so that the rotation of the rotor actuates the movement of crops along a helicoidal path through the gap between the rotor and the cover and gratings. Inclined guide vanes are arranged on the inner surface of the cover to provide guidance to the crops. The cover includes a step between an upstream portion of the cover and a downstream portion of the cover, so that the gap between the rotor and the cover is larger in the downstream portion than in the upstream portion. The step is oriented at an oblique inclination angle, when the cover is regarded in a parallel projection view from a position above the step.

The invention comprises an automated, dynamic cover plate system, which may be quickly attached, detached and adjusted to the exterior of a concave grate of a combine harvester in order to adjust the flow characteristics of the concave or separator grate assemblies. The automated, dynamic cover plate system adjusts the threshing capability of the rasp bar threshing cylinder while simultaneously capturing additional threshed grain. The automated, dynamic cover plate system of the present invention is designed to be controlled, either manually or automatically, by the operator of the combine harvester or by a computerized or automated intelligence system.

An embodiment includes a threshing system of an agricultural harvester. The threshing system including a rotor cage surrounding a rotor defining a threshing space there between, where the rotor cage has a cut crop entrance, a transition cone defining an infeed to said rotor cage, where the transition cone is positioned to direct crop flow toward the cut crop entrance of the rotor cage, and an infeed ramp positioned between the rotor cage and the transition cone, where the infeed ramp includes guide vanes for guiding the crop flow from the transition cone into the cut crop entrance of the rotor cage.

A combine has a feeder house extending forward from the front of the combine, with the front of the feeder house defining a rectangular frame for supporting a harvesting head. A gauge wheel arrangement is supported on the rectangular frame and in turn supports the harvesting head. The gauge wheel arrangement includes a center frame that abuts the rectangular frame and pivots with respect to it. A left side frame with gauge wheels is hinged to the center frame. A right side frame with gauge wheels is hinged to the center frame. The center, left, and right frames can support the harvesting head and permit the harvesting head to pivot with respect to the feeder house, as well as supporting a part of the weight of the harvesting head on the gauge wheels.

A combine has a feeder house extending forward from the front of the combine, with the front of the feeder house defining a rectangular frame for supporting a harvesting head. A gauge wheel arrangement is supported on the rectangular frame and in turn supports the harvesting head. The gauge wheel arrangement includes a center frame that abuts the rectangular frame and pivots with respect to it. A left side frame with gauge wheels is hinged to the center frame. A right side frame with gauge wheels is hinged to the center frame. The center, left, and right frames can support the harvesting head and permit the harvesting head to pivot with respect to the feeder house, as well as supporting a part of the weight of the harvesting head on the gauge wheels.