A row crop header for harvesting crop in a field comprises a header frame having a center section and a pair of side wing sections operatively coupled to the center section. An upper link is pivotally coupled between the center section and each one of the side wing sections adjacent the top portion thereof. A lower link is pivotally coupled between the center section and each one of the side wing sections adjacent the bottom portion thereof. The upper links and lower links provide independent pivotal movement of the side wing sections relative to the center section to contour to the surface of the field of crops to be harvested. An automatic float system is operatively coupled between the center section and each one of the side wing sections to adjust the weight of the side wing sections on the surface of the field and allow the side wing sections to float relative to the center section.

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.

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.

A work machine that has an implement coupled to the frame of the work machine, a first sensor coupled to the implement, a controller, and an implement position system that couples the implement to the frame. The first sensor identifies the orientation of the implement along more than one axis and the controller manipulates the implement position system to reposition the implement relative to the frame based on the orientation of the implement identified by the first sensor.

A method of operating an agricultural vehicle having a feeder housing and a header. The method includes the steps of providing an automated adjustment system configured for adjusting at least one of: at least one header function, at least one feeder housing function, and at least one agricultural vehicle function. The automated adjustment system includes a controller and a memory operably coupled to the controller. The method includes the further steps of receiving an input from one of an operator manually inputting the input or the header automatically communicating the input, defining an origin position, calibrating an origin pitch angle of the header, adjusting a position of the header, maintaining the origin position, determining a condition, and adjusting or maintaining at least one of the at least one header function, the at least one feeder housing function, and the at least one agriculture vehicle function in response to the condition.

A harvesting head has a middle section connected to a carrier device and at least one side section connected by an articulated connection to the middle section about which the side section pivots between a lower and an upper limit value. The carrier device has a height adjustment device whose adjusting movements are controlled by a control. The harvesting head has a sensor transmitting a sensor signal to the evaluation device at least upon pivoting of the side section when a limit value has been achieved during pivoting of the side section to the middle section. The evaluation device switches upon the presence of a corresponding sensor signal into a correction mode for height adjustment of the carrier device. The evaluation device outputs an adjusting signal in the correction mode to adjust the carrier device up or down by the evaluation device according to the sensor signal.

A lateral tilt control system for an agricultural 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 rod-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 exceeds a relief pressure setting.

A structural set for assembling a header intended for harvesters is capable of compensation of the lateral movement of the header according to the ground conditions of the planting rows being harvested. More particularly, a structural set for assembling a header in an agricultural machine comprising a girder with a central beam interconnected to at least two structural columns, the central beam being provided with a pivoting point for engaging and fastening a bracket, and at least one return element of the bracket for returning the bracket in a substantially horizontal position when at rest.

A method of operating an agricultural vehicle having a feeder housing and a header. The method includes the steps of providing an automated adjustment system configured for adjusting at least one of: at least one header function, at least one feeder housing function, and at least one agricultural vehicle function. The automated adjustment system includes a controller and a memory operably coupled to the controller. The method includes the further steps of receiving an input from one of an operator manually inputting the input or the header automatically communicating the input, defining an origin position, calibrating an origin pitch angle of the header, adjusting a position of the header, maintaining the origin position, determining a condition, and adjusting or maintaining at least one of the at least one header function, the at least one feeder housing function, and the at least one agriculture vehicle function in response to the condition.

A header system includes a frame; a cutter carried by the frame; a cutter sensor associated with the cutter which outputs a cutter height signal; a gauge wheel carried by the frame behind the cutter; a wheel sensor associated with the gauge wheel which outputs a wheel position signal; and a controller electrically coupled to the cutter height sensor and the wheel sensor. The controller is configured to: receive the cutter height signal; receive the wheel position signal; compare the cutter height signal and the wheel position signal to determine a terrain irregularity is present; and activate one or more actuators to adjust the frame in response to determining the terrain irregularity is present.