A pivotably adjustable attachment apparatus for an agricultural vehicle includes an attachment connected to a mounting structure. The mounting structure is operatively connected to an adapter assembly in communication with a feed device for moving a crop from the attachment to a feed device for further processing of the crop. A frame supports the feed device over an uneven surface. An apparatus is positioned between the mounting structure and the adapter assembly. The apparatus provides a substantially non-sliding contact between the mounting structure and the adapter assembly in response to the mounting structure being directed to a pivotable movement with respect to the mounting structure, thereby providing a pivotable movement of the attachment in response to encountering the uneven surface.

In accordance with an example embodiment, an agricultural vehicle may include first and second harvesting devices connected to the agricultural vehicle. The agricultural vehicle may include a sensor which detects whether the agricultural vehicle is traveling in an operational or non-operational direction. The agricultural vehicle may include a lift controller in communication with the sensor and the first and second harvesting devices. The lift controller may automatically reposition the first and second harvesting devices into non-operating positions when the lift controller determines an intention to move the agricultural vehicle in a non-operational direction.

A feeder for a combine harvester. The feeder includes a housing and a conveyor assembly mounted in the housing. The conveyor assembly includes a frame having lateral support arms, and moveable belts guided by sprocket wheels. The sprocket wheels are mounted on a drive shaft proximate an outlet section of the housing and on a conveyor shaft proximate an inlet section of the housing. The sprocket wheels are mounted on a drive shaft proximate an outlet section of the housing and on a conveyor shaft proximate an inlet section. The conveyor assembly is equipped with a first and second tensioning mechanism, the first mechanism being configured to push the conveyor shaft forward with respect to the frame, the second mechanism including spring-operated tensioning arms and tensioning rolls mounted above the support arms.

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 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 locking mechanism for an agricultural header includes a rod that extends laterally along the header and a hook coupled to the rod. The rod is configured to rotate in a first direction to transition the locking mechanism to a first position and rotate in a second direction, opposite the first direction, to transition the locking mechanism to a second position. The hook is configured to engage an arm of the header. The arm is configured to support a cutter bar assembly of the header and is configured to rotate about a pivot joint relative to a frame of the header. The rod is configured to rotate in the first direction to engage the hook with the arm to block rotation of the respective arm, and the rod is configured to rotate in the second direction to disengage the hook from the respective arm to enable rotation of the arm.

A locking mechanism for an agricultural header includes a rod that extends laterally along the header and a hook coupled to the rod. The rod is configured to rotate in a first direction to transition the locking mechanism to a first position and rotate in a second direction, opposite the first direction, to transition the locking mechanism to a second position. The hook is configured to engage an arm of the header. The arm is configured to support a cutter bar assembly of the header and is configured to rotate about a pivot joint relative to a frame of the header. The rod is configured to rotate in the first direction to engage the hook with the arm to block rotation of the respective arm, and the rod is configured to rotate in the second direction to disengage the hook from the respective arm to enable rotation of the arm.

A header includes a belt conveyor configured to direct a movement of harvested crop material toward a feederhouse of the combine harvester. The belt conveyor is located adjacent an inlet of the feederhouse. The belt conveyor includes at least one protrusion extending radially from the belt conveyor that helps direct movement of harvested crop material toward the feederhouse.

Harvesting vehicle, in particular forage harvester or combine harvester, comprising a mounting frame (10), wherein the mounting fame (10) is designed to couple an attachment to the mounting frame (10) and via the mounting frame (10) to the harvesting vehicle, and comprising a drive coupler (16) which engages with the mounting frame (10) and which is designed to form a drive connection between the attachment and the harvesting vehicle in order to transmit a drive power provided by the harvesting vehicle in the direction of the attachment, wherein the drive coupler (16) has a drive hub (17) which can be coupled to the harvesting vehicle, a coupling disk (19) which can be coupled to the attachment and a centering mandrel (22) which cooperates with the attachment, wherein the centering mandrel (22) is fixedly engaged with the coupling disk (19), a slide piece (24) which can be displaced in a translatory manner relative to the drive hub (17) is coupled fixedly in terms of rotation to the drive hub (17), and wherein the slide piece (24) is connected to the coupling disk (19) via universal joints (30, 31) such that the centering mandrel (22) can be displaced together with the coupling disk (19) and the slide piece (24) in a translatory manner relative to the drive hub (17).

Feederhouse gearboxes are provided for installation on combine harvesters. In embodiments, the feederhouse gearbox includes a gearbox housing, an output shaft rotatable about an output axis, and a primary drive input. The primary drive input is mechanically linked to an engine of the combine harvester when the feederhouse gearbox is installed thereon. A reverser drive input is mechanically linked to a reverser motor of the combine harvester when the feederhouse gearbox is installed on the combine harvester. The feederhouse gearbox further includes a selector mechanism within the gearbox housing and movable between a primary drive position and a reverser drive position, a primary gear train transmitting rotation from the primary drive input to the output shaft when the selector mechanism is in the primary drive position, and a reverser worm drive transmitting rotation from the reverser drive input to the output shaft when the selector mechanism is in the reverser drive position.