The present invention relates to a method for operating an attachment arranged on a pick-up apparatus of a self-propelled combine harvester, wherein the attachment comprises a central portion and two side portions which are each connected to the central portion by a frame joint so as to be pivotable about a pivot axis oriented in the direction of travel, wherein the respective side portion is pivotable about the pivot axis transversely to the direction of travel relative to the central portion by means of an actuator that is activated by a control apparatus, wherein a vertical distance of the attachment from the ground is adaptively set by at least one hydraulic cylinder on the pick-up apparatus, wherein, for the ground guidance of the attachment, the positioning of the side portions relative to the central portion is controlled or regulated independently of vertical and transverse guidance, activated by the combine harvester, of the attachment.

A header support for supporting a header during road transport of an agricultural harvester. The header support has a header mounted to it in order to reduce a front axle load of the agricultural harvester. During harvesting, a support wheel of the header support is folded upwardly so it does not touch the ground during harvesting. The rotation axis of the support wheel extends in a substantially vertical plane during harvesting. This allows for a simple construction of the header support and reduces the vibration loads on the bearing of the support wheel during harvesting.

An agricultural implement includes a first central implement section. At least one second implement section is positioned on each of two sides of the first implement section. Adjacent implement sections are each displaceable relative to one another about a pivot axis in order to displace the implement between a transport position and a working position. Each implement section comprises mowing mechanisms, conveying mechanisms or both. A hat-like conveying element made from an elastically deformable material is positioned on at least one of the mowing mechanisms, on at least one of the conveying mechanisms or both.

A header bar assembly has a row of header bar elements mounted on a fixed header bar section. The assembly includes a first moveable wing having mounted thereon one or more further header bar elements, the fixed header bar section supporting at the first end a first pillar extending generally perpendicular to the fixed header bar section and via which the first moveable wing is retained moveably captive relative to the fixed header bar section. The first moveable wing is moveable relative to the first pillar vertically and rotatably from an operative, deployed position in which it extends generally parallel to the fixed header bar section to a stowed position through vertical movement on the first pillar and rotation such that the first moveable wing lies adjacent the fixed header bar section inboard of the first pillar.

A harvester or combine includes a folding corn head with a center section and folding wing sections. A folding row separator cover at the hinge location of the folding head sections folds to an angled position so that the folding action between the wings and the center section is not impaired. A single assembly actuates the folding of the row separator as well as locking and unlocking of the wing sections relative to the center frame section. A hydraulic cylinder actuates a main link that connects to the row separator cover and to a lock pin. Actuation of the hydraulic cylinder raises and lowers the cover and disengages and engages the locking pin.

A system for controlling harvesting implement position of an agricultural harvester includes a harvesting implement configured to be coupled to the harvester to permit adjustment of a current position of the implement relative to a field surface. Additionally, the system includes a sensor configured to capture data indicative of the current position of the implement relative to the field surface, a display device, and a controller communicatively coupled to the sensor and the display device. As such, the controller is configured to monitor the current position of the implement based on the data captured by the sensor. Furthermore, the controller is further configured to initiate display of a graphical user interface on the display device, with the graphical user interface displaying a first interface element associated with the current position of the implement relative to a second interface element associated with a reference position of the implement.

A draper header includes a draper frame and a reel arm. The reel arm is coupled to a reel and pivotally coupled to the draper frame. The draper header further includes a cutterbar pivotally coupled to the draper frame. The reel arm and the cutterbar are configured to pivot about the draper frame to adjust a side profile aspect ratio of the draper header from a first aspect ratio to a second aspect ratio. A height of the first aspect ratio is less than a height of the second aspect ratio, and a width of the first aspect ratio is greater than a width of the second aspect ratio.

A header system includes a first header segment comprising a cutter bar configured to cut crops, and a first portion of a conveyor assembly. The header system further includes a center section comprising a center section tilted top beam and a second portion of the conveyor assembly, wherein the center section is configured to receive cut crops from the first header segment via the first portion of the conveyor assembly, wherein the center section tilted top beam is disposed at a first angle tilted relative to ground when the header system is in use.

A corn head corn head includes a first wing segment and a center segment. A corn head adjustment system includes a first fold actuator; a first deck plate actuator mounted on at least one of the first wing segment frame or the center frame and configured to reposition at least one of the first deck plate rod or the center deck plate rod; and corn head hydraulics. During a fold process, the corn head hydraulics is configured to actuate the first fold actuator in order to fold the first wing segment relative to the center segment and to actuate the first deck plate actuator in order to decouple the first deck plate rod from the center deck plate rod. During an unfold process, the corn head hydraulics is configured to actuate the first fold actuator in order to unfold the first wing segment relative to the center segment.

A corn head includes a first wing segment; a center segment; and a corn head adjustment system. The corn head adjustment system includes a first fold actuator and corn head hydraulics fluidly coupled to receive a fluid from a source and to selectively direct the fluid to the first fold actuator. During a fold process, the corn head hydraulics is configured to actuate the first fold actuator in order to lift and fold the first wing segment frame relative to the center frame. During an unfold process, the corn head hydraulics is configured to actuate the first fold actuator in order to lift and unfold the first wing segment frame relative to the center frame. The corn head hydraulics includes a force relief arrangement configured such that, at a predetermined position during the fold process and the unfold process, fluid pressure to the first fold actuator is reduced.