An agricultural vehicle header having a center section, a wing section, a hinge connecting the center section's lower frame to the wing section's lower frame, and a torque transfer linkage connecting the center section's upper frame to the wing section's upper frame. The torque transfer link has a first link, a second link, a first pivot connection joining the first link to the center section upper frame, and providing a respective single degree of rotational freedom between the first link and the center section upper frame, a second pivot connection joining the first link to the second link, and providing a respective single degree of rotational freedom between the first link and the second link, and a third pivot connection joining the second link to the first wing section upper frame, and providing a respective single degree of rotational freedom between the second link and the first wing section frame.

A header for a combine harvester includes a conveyor belt for conveying crop material in a conveyance direction, and an adjusting device for adjusting a tension of the conveyor belt. The adjusting device includes a cable that is movable with respect to a frame member of the header. A portion of the cable that is either directly or indirectly attached to one end of a roller for the conveyor belt extends either parallel to or substantially parallel to a tensioning direction of the conveyor belt for adjusting the tension of the conveyor belt. The conveyor belt may be an infeed conveyor belt or a lateral conveyor belt of a draper header, for example.

A harvesting header includes a header frame structured to be coupled to the crop-harvesting machine, a hydraulic pump carried by the header frame, at least one tool carried by the header frame, a hydraulic fluid loop carried by the header frame, a fluid inlet structured to receive hydraulic fluid from the crop-harvesting machine, and a fluid outlet structured to deliver hydraulic fluid to the crop-harvesting machine. The hydraulic fluid loop is structured to circulate hydraulic fluid within the header from the hydraulic pump to the tool(s) and back to the hydraulic pump. Related methods of operating a harvesting header and a non-transitory computer-readable media are also disclosed.

A harvesting header includes a header frame structured to be coupled to the crop-harvesting machine, a hydraulic pump carried by the header frame, at least one tool carried by the header frame, a hydraulic fluid loop carried by the header frame, a fluid inlet structured to receive hydraulic fluid from the crop-harvesting machine, and a fluid outlet structured to deliver hydraulic fluid to the crop-harvesting machine. The hydraulic fluid loop is structured to circulate hydraulic fluid within the header from the hydraulic pump to the tool(s) and back to the hydraulic pump. Related methods of operating a harvesting header and a non-transitory computer-readable media are also disclosed.

A combine comprising a feeder housing, and an auger for receiving harvested crop. The auger includes an auger tube rotatable around an auger axis, and a tined-tube positioned inside the auger tube and rotatable around a tined-tube axis that is offset from the auger axis, the tined-tube including fingers extending from the tined-tube and protruding through the auger tube to convey the harvested crop to the feeder housing.

A combine comprising a feeder housing, and an auger for receiving harvested crop. The auger includes an auger tube rotatable around an auger axis, and a tined-tube positioned inside the auger tube and rotatable around a tined-tube axis that is offset from the auger axis, the tined-tube including fingers extending from the tined-tube and protruding through the auger tube to convey the harvested crop to the feeder housing.

An agricultural vehicle header having a base structure, a header wing section, an articulated joint connecting the header wing section to the base structure, an actuator, a load sensor, and a controller. The actuator is configured to move the header wing section relative to the base structure between a wing lowered position and a wing raised position the load sensor is operatively connected to the header wing section. The controller is configured to acquire load sensor data from the load sensor to evaluate a magnitude of a gravitational load on the header wing section, and prevent the actuator from moving the header wing section towards the wing raised position if the magnitude of the gravitational load exceeds a predetermined threshold load value. An agricultural combine having the header and methods of operating the same are also provided.

A float cylinder is coupled to an accumulator by a first hydraulic fluid conduit. The float cylinder and accumulator are coupled to apply a float force on a header main frame.

A float cylinder is coupled to an accumulator by a first hydraulic fluid conduit. The float cylinder and accumulator are coupled to apply a float force on a header main frame.

A draper belt tensioning system having a frame having a first tensioner mount, a roller, and a first belt tensioner. The roller is movable along a lateral direction that is perpendicular to a roller rotation axis. The first belt tensioner is connected to the first roller end and selectively connectable to the first tensioner mount. The first belt tensioner includes a first travel stop configured to selectively abut the first tensioner mount with the first tensioner mount between the first travel stop and the first roller end, a first spring, and a first threaded connector configured to move the first roller end closer to and further from the first travel stop upon rotation of the threaded connector. The first travel stop, first spring and first threaded connector are removable from the first tensioner mount without disassembly from each other and without disassembly from the first roller end.