A header positioning system for controlling a position of a header for a combine harvester. The header positioning system including a controller that is configured to receive signals corresponding to (i) a measured inclination of either the header or the combine, (ii) a measured ground speed of the header or the combine, and (iii) a measured height of the header with respect to ground. The controller is further configured to adjust a height and a pitch of the header as a function of the inclination, measured ground speed and the measured height.

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.

In one aspect, a method is disclosed for automatically controlling a position of an implement of an agricultural work vehicle relative to a ground surface. The method may include monitoring, with one or more computing devices, an implement position parameter indicative of the position of the implement relative to the ground surface. The method may also include calculating a normal output signal based on the implement position parameter. The method may also include determining when a boost condition is satisfied based on a comparison between the implement position parameter and a predetermined implement position parameter threshold. The method may also include computing a boost output signal based on the implement position parameter. The method may also include adjusting the position of the implement relative to the ground surface based on the normal output signal and the boost output signal.

An apparatus for damping a pitching oscillation of a working vehicle comprising: a first actuator for adjusting a position of an implement couple to the working vehicle; a second actuator for adjusting a propulsion rate of the working vehicle; and a control device in communication with the first and second actuators, the control device configured to receive an operating mode signal corresponding to an operating mode of at least one of the working vehicle and implement, and to generate control signals to the first actuator and the second actuator as a function of the operating mode signal.

An agricultural apparatus including an agricultural vehicle and a number of work units suitable for cutting a standing crop. The work units include a front work unit and two lateral work units located behind and to the sides of the front work unit, each of the work units depositing cut crop as a swath. Each of the lateral work units is supported from a central chassis by a hydraulic system. A plurality of sensors determine a speed of the agricultural vehicle, a speed of operation of each lateral work unit and a relief pressure in the hydraulic system of each lateral work unit. A control unit is configured to receive inputs from the plurality of sensors, compare the values for a desired vehicle speed or speed of operation of the mower unit and adjust the pressure relief in the hydraulic system based on this comparison. The inertia of the hydraulic control system can accordingly be compensated for and the work units are able to follow the terrain contour, resulting in an even cut.

An agricultural system includes a header and a controller. The controller is configured to receive an indication to operate the agricultural system in a non-harvesting mode, output a first signal to set the header in a set profile upon initialization of the non-harvesting mode, receive sensor feedback indicative of an obstacle position of an obstacle relative to the header while the agricultural system operates in the non-harvesting mode, and output a second signal to adjust the header to deviate from the set profile based on the sensor feedback while the agricultural system operates in the non-harvesting mode.

A lateral tilt control system for an agriculture harvester may include first and second tilt cylinders coupled between a support structure and an implement of the harvester. The first tilt cylinder may include a first cap-side chamber and a first rod-side chamber and the second tilt cylinder may include a second cap-side chamber and a second rod-side chamber. The system may also include a first fluid line providing a flow path between the first cap-side chamber and the second cap-side chamber and a second fluid line providing a flow path between the first rod-side chamber and the second cap-side chamber. Additionally, the system may include a pressure relief valve coupled between the first and second fluid lines to allow fluid to be transferred between the first and second fluid lines when a fluid pressure within either fluid line exceed a relief pressure setting.

An agricultural vehicle header having: a frame, a support arm having a proximal end rotatably mounted by a support arm pivot to the frame and a distal end spaced from the proximal end, a torque transfer anchor rigidly attached to the frame, a support torque rod having a distal end rotationally fixed to the support arm, and a proximal end rotatably mounted to the torque transfer anchor to rotate about a first axis, a frame torque rod having a proximal end rotatably mounted to the torque transfer anchor to rotate about a second axis and a distal end rotationally fixed to the frame, and a drive linkage connecting the support torque rod to the frame torque rod at the torque transfer anchor, to transfer a rotational motion of the support torque rod about the first axis into an opposite rotational motion of the frame torque rod about the second axis.

A harvesting platform includes a first section and extends along a first section plane that is substantially parallel to a ground surface along which the harvesting platform moves with a combine. A second section is connected to the first side of the first section, and rotates with respect to the first section within a range of angular positions. A locking mechanism retains the second section in a position with respect to the first section while activated, and permits movement of the second section with respect to the first section while deactivated. A controller receives a first signal indicative of the position, and sends a second signal to deactivate the locking mechanism in response to the position being at a positive non-parallel angle with respect to the first section plane. The second section moves toward the first section plane in response to gravity while the locking mechanism is deactivated.

In one aspect, a method for automatically controlling a height of an implement of an agricultural work vehicle relative to a ground surface may include monitoring the height of the implement relative to the ground surface; determining a proportional signal by comparing the height of the implement with a predetermined target height; detecting a local inclination of the ground surface; calculating a derivative signal based on the local inclination of the ground surface; and adjusting the height of the implement relative to the ground surface based on an output signal that includes the proportional signal and the derivative signal.