A draper head (2) for attachment to a harvesting machine (4) is provided. In order to be able to effortlessly equip the draper head (2) with an active fan, with which grains and ears of corn are blown in the direction of the belt conveyor device (12) in the region of the blade bar (8), a retrofitting interface (18) is provided, at which either a closed cover profile sheet (26) or an angle profile sheet (50) that is provided with air outlet openings (52) can be installed in the installation space (20).

A draper head (2) for attachment to a harvesting machine (4) is provided. In order to be able to effortlessly equip the draper head (2) with an active fan, with which grains and ears of corn are blown in the direction of the belt conveyor device (12) in the region of the blade bar (8), a retrofitting interface (18) is provided, at which either a closed cover profile sheet (26) or an angle profile sheet (50) that is provided with air outlet openings (52) can be installed in the installation space (20).

A harvesting unit with a combine, having a user cab. A harvesting apparatus, advanced by the combine, has a frame and a harvesting assembly on the frame configured to process severed crop over a width between spaced sides of the frame. A fluid delivery system discharges pressurized fluid in discrete streams each directed to at least one of: a) facilitate severance of crop by the harvesting assembly; and b) facilitate advancement of severed crop rearwardly in relationship to the frame for further processing. A user can selectively vary at least one of: a) a volume of pressurized fluid; and b) a direction of pressurized fluid in the discrete streams. A control system has at least one actuator accessible and operable from outside of the cab through a user input to cause the at least one of the volume of pressurized fluid discharged, and direction of the pressurized fluid, in the discrete streams to be varied.

A pressurized air delivery system for assisting grain crop harvesting. The system includes a left hand side manifold and a right hand side manifold adapted for being mounted to a harvester header. Each manifold is connected to a plurality of nozzles disposed along the respective manifold. Each manifold is adapted for receiving a pressurized air flow at a first end thereof and for providing the pressurized air flow to the nozzles. Each manifold is closed at a second opposite end thereof. The left hand side manifold and the right hand side manifold span approximately from a left hand side of the harvester header to a right hand side of the harvester header. An air flow source provides the pressurized air flow. An air conduit is connected to: the air flow source; the first end of the left hand side manifold; and the first end of the right hand side manifold. The air conduit comprises a divider for: receiving the pressurized air flow from the air flow fan; dividing the pressurized air flow; and providing the divided pressurized air flow to the left hand side manifold and the right hand side manifold.

A pressurized air delivery system for assisting grain crop harvesting. The system includes a left hand side manifold and a right hand side manifold adapted for being mounted to a harvester header. Each manifold is connected to a plurality of nozzles disposed along the respective manifold. Each manifold is adapted for receiving a pressurized air flow at a first end thereof and for providing the pressurized air flow to the nozzles. Each manifold is closed at a second opposite end thereof. The left hand side manifold and the right hand side manifold span approximately from a left hand side of the harvester header to a right hand side of the harvester header. An air flow source provides the pressurized air flow. An air conduit is connected to: the air flow source; the first end of the left hand side manifold; and the first end of the right hand side manifold. The air conduit comprises a divider for: receiving the pressurized air flow from the air flow fan; dividing the pressurized air flow; and providing the divided pressurized air flow to the left hand side manifold and the right hand side manifold.

A system for monitoring an extractor fan of an agricultural harvester includes an extractor fan having a shaft configured to be coupled to a rotational drive source for rotationally driving the shaft, a fan hub coupled to a lower shaft end of the shaft such that rotation of the shaft rotationally drives the fan hub about a fan hub axis, with the fan hub extending between an upstream side and a downstream side along the fan hub axis, and fan blades coupled to and extending radially outwardly from the fan hub. The system further includes a sensor that generates data indicative of acceleration of the extractor fan. Additionally, the system includes a computing system that determines an acceleration of the extractor fan based at least in part on the data, and determines whether the extractor is imbalanced based at least in part on the acceleration of the extractor fan.

A system for monitoring an extractor fan of an agricultural harvester includes an extractor fan having a shaft configured to be coupled to a rotational drive source for rotationally driving the shaft, a fan hub coupled to a lower shaft end of the shaft such that rotation of the shaft rotationally drives the fan hub about a fan hub axis, with the fan hub extending between an upstream side and a downstream side along the fan hub axis, and fan blades coupled to and extending radially outwardly from the fan hub. The system further includes a sensor that generates data indicative of acceleration of the extractor fan. Additionally, the system includes a computing system that determines an acceleration of the extractor fan based at least in part on the data, and determines whether the extractor is imbalanced based at least in part on the acceleration of the extractor fan.

A harvesting unit with a combine, having a user cab. A harvesting apparatus, advanced by the combine, has a frame and a harvesting assembly on the frame configured to process severed crop over a width between spaced sides of the frame. A fluid delivery system discharges pressurized fluid in discrete streams each directed to at least one of: a) facilitate severance of crop by the harvesting assembly; and b) facilitate advancement of severed crop rearwardly in relationship to the frame for further processing. A user can selectively vary at least one of: a) a volume of pressurized fluid; and b) a direction of pressurized fluid in the discrete streams. A control system has at least one actuator accessible and operable from outside of the cab through a user input to cause the at least one of the volume of pressurized fluid discharged, and direction of the pressurized fluid, in the discrete streams to be varied.

A cutterbar knife drive cleaning apparatus for a header of an agricultural harvester is disclosed. The apparatus cleans the knife drives by discharging pressurized air from an apertured conduit toward the knife drive. Movement of a cutterbar supporting arm causes rotation of the conduit to produce a sweeping action of an air curtain over the knife drive in order to blow dirt and debris from the knife drive as the harvester traverses a field.

A cutterbar knife drive cleaning apparatus for a header of an agricultural harvester is disclosed. The apparatus cleans the knife drives by discharging pressurized air from an apertured conduit toward the knife drive. Movement of a cutterbar supporting arm causes rotation of the conduit to produce a sweeping action of an air curtain over the knife drive in order to blow dirt and debris from the knife drive as the harvester traverses a field.