A vertical crop divider knife is mounted at each end of the cutter bar of a header and stands upwardly from the end to cut crop tending to collect over the end divider. Each divider knife includes a drive linkage in the housing for communicating drive to the knife sickle bar. Each divider housing has a mounting assembly for coupling to a cooperating mounting assembly on the housing of the crop divider knife structure by which the crop divider knife structure is readily attachable to the crop divider housing using a hook coupling at the bottom and a latch at the top for operation and releasable from the crop divider housing when not required. The divider housing carries a hydraulic motor and a forwardly facing output coupling mounted on the divider housing which automatically meshes with an input coupling on the knife housing when the knife drive housing is installed.

A harvester is provided with a draper head that has a frame extending substantially across a working width of the draper head. Cutting elements are arranged at a front side of the draper head and connected to the frame. Conveying surfaces and conveying members transport cut crop from the cutting elements to a discharge location of the draper head. A reel extends transversely to a working direction of the draper head across the working width of the draper head. Reel support arms are pivotably supported on the frame and support the reel. A hydraulic adjusting drive is operatively connected to the reel support arms to pivot the reel support arms to carry out a height adjustment of the reel. A hydraulic circuit is operatively connected to the hydraulic adjusting drive and has a hydraulic valve that is able to lock the hydraulic circuit.

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 feederhouse assembly for an agricultural harvester includes a feederhouse comprising an inlet end, a rotational shaft coupled to the feederhouse and defining a plurality of fluid passages therethrough, and a frame adjacent the inlet end and arranged to pivot about the rotational shaft relative to the feederhouse. The frame defines a crop opening therethrough and is configured to carry a harvesting header. An agricultural harvester includes a chassis, the feederhouse assembly mounted to the chassis, and a processing system carried by the chassis and structured to receive crop material from the feederhouse.

A vertical crop divider knife is mounted at each end of the cutter bar of a header and stands upwardly from the end to cut crop tending to collect over the end divider. Each divider knife includes a drive linkage in the housing for communicating drive to the knife sickle bar. Each divider housing has a mounting assembly for coupling to a cooperating mounting assembly on the housing of the crop divider knife structure by which the crop divider knife structure is readily attachable to the crop divider housing using a hook coupling at the bottom and a latch at the top for operation and releasable from the crop divider housing when not required. The divider housing carries a hydraulic motor and a forwardly facing output coupling mounted on the divider housing which automatically meshes with an input coupling on the knife housing when the knife drive housing is installed.

A method of autonomously controlling the ground speed of a harvester, such as a self-propelled or towed wind rower, uses both the engine speed and the header speed as control parameters to increase or decrease the ground speed as necessary to maintain efficient harvester operation over varying terrain and crop conditions. A control system includes a controller which receives signals from sensors indicative of engine speed, header speed and harvester ground speed and uses actuators to control the header speed, engine speed and harvester ground speed. An operator interface permits an operator to engage or disengage the autonomous mode of control system operation, as well as to directly control the harvester.

A harvester comprising: a drive engine connected via a first drive train to ground engagement equipment of the harvester and via a second drive train to crop processing equipment of the harvester; an actuator configured to adjust the transmission ratio of the first drive train to control the propulsion speed of the harvester; and a controller configured to receive setpoint and actual values dependent on the crop throughput of the harvester, the controller configured to calculate an acceleration signal based on the setpoint and actual values, the acceleration signal representing an acceleration of the harvester suitable for minimizing the difference between the setpoint and actual values, and to determine a control signal for controlling the actuator based on the acceleration signal.

The present application for patent of invention refers to equipment designed for harvesting, cleaning and storing farming produce. The farming produce it is designed to process particularly includes peanuts, beans or any other produce disposed in rows that can be gathered from the ground. The invention comprises a head (2), endowed with a collecting platform (3) with belts (5); the head (2) comprises a transmission box (4) of the dual and pivotable type; the head (2) has complete hydraulic system with hydraulic oil tank (9), heat exchanger (9A) and filters; said transmission box (4) further has auxiliary input (11) to couple an accessory that can be hydraulic; pneumatic or electric, in order to drive auxiliary systems; in the rear part of the equipment are helicoids (6) that extend to the vertical transporter (7) and latter to the container (8).

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 directional control conversion and method for a self-propelled zero turn two-wheel drive center deck lawn care vehicles that changes the vehicle's directional orientation and adaptive use with a variety of front equipment attachments. The method provides custom components that allows the operator's rear drive zero turn equipment to be driven from the front caster wheel position thus reversing the operator's orientation and primary direction of travel of the lawn care vehicle by control lever extension and custom adaptive assemblies for auxiliary forward attachment mounting and power operational remote controls.