A draper header for a combine, the draper header including an attachment frame adapted for attachment to the combine. A harvesting assembly includes a plurality of sections and a plurality of belts operable to feed crop material into the combine. The draper header is operable in a first mode that allows the plurality of sections to float relative to the attachment frame for ground following during harvesting, and in a second mode in which the attachment frame is raised to lift and support the harvesting assembly to be spaced above the ground. A hydraulic leveling system includes at least one leveling actuator. A valve is operable in response to the movement of the draper header into the second mode to direct pressurized hydraulic fluid into the at least one leveling actuator to automatically level the plurality of sections of the harvesting assembly when in the second mode.

A draper header for a combine, the draper header including an attachment frame adapted for attachment to the combine. A harvesting assembly includes a plurality of sections and a plurality of belts operable to feed crop material into the combine. The draper header is operable in a first mode that allows the plurality of sections to float relative to the attachment frame for ground following during harvesting, and in a second mode in which the attachment frame is raised to lift and support the harvesting assembly to be spaced above the ground. A hydraulic leveling system includes at least one leveling actuator. A valve is operable in response to the movement of the draper header into the second mode to direct pressurized hydraulic fluid into the at least one leveling actuator to automatically level the plurality of sections of the harvesting assembly when in the second mode.

A work vehicle for cutting crops includes a header a supported by a chassis of the work vehicle. The header includes a cutter assembly having a cutter bar frame supporting a series of rotary cutters arranged in a lengthwise direction. A gear train, having a first gear and a second gear, is coupled to the series of rotary cutters to transfer power thereto. A cutter control system includes a first motor coupled to the first gear of the gear train and a second motor coupled to the second gear of the gear train. A controller, including a processor and memory architecture, is operably connected to the first motor and the second motor to control operation thereof. The cutter control system drives the first gear at a first speed via the first motor and drives the second gear at a second speed via the second motor. The second speed is different than the first speed to pre-load the gear train into enmeshing engagement with each other in one rotational direction.

A work vehicle for cutting crops includes a header a supported by a chassis of the work vehicle. The header includes a cutter assembly having a cutter bar frame supporting a series of rotary cutters arranged in a lengthwise direction. A gear train, having a first gear and a second gear, is coupled to the series of rotary cutters to transfer power thereto. A cutter control system includes a first motor coupled to the first gear of the gear train and a second motor coupled to the second gear of the gear train. A controller, including a processor and memory architecture, is operably connected to the first motor and the second motor to control operation thereof. The cutter control system drives the first gear at a first speed via the first motor and drives the second gear at a second speed via the second motor. The second speed is different than the first speed to pre-load the gear train into enmeshing engagement with each other in one rotational direction.

A hydraulic cooler pressure isolation circuit for a header of an agricultural harvester equipped with a reservoir and a pump. The circuit comprises a hydraulic fluid cooler, a supply line extending from the hydraulic fluid cooler to the pump, a return line extending from the hydraulic fluid cooler to the reservoir, and a drain line operatively in fluid communication with the return line for connecting to the reservoir. A first valve, a second valve, a return valve, and a bypass valve of the circuit operate to direct hydraulic fluid flow through the cooler under normal system operating conditions, and direct hydraulic fluid flow to bypass the cooler when the system experiences high pressure operating conditions at the cooler.

A rotary cutter is provided that has a center section and at least one wing section pivotally connected to the center section. The rotary mower is transformable between a transport position, with the wing section pivoted upwards, and an operating position, with the wing section pivoted downwards. A lifting assembly is provided between the center section and the at least one wing section to pivot the wing section. The lifting assembly can have a lifting actuator, a lug provided on the lifting actuator, a pivot member, and a pivotal connection between the lifting actuator and the pivot member. A guide member can run adjacent to the lifting actuator and have a guide channel for receiving the lug when the wing section is pivoted upwards into the transport position.

A rotary cutter is provided that has a center section and at least one wing section pivotally connected to the center section. The rotary mower is transformable between a transport position, with the wing section pivoted upwards, and an operating position, with the wing section pivoted downwards. A lifting assembly is provided between the center section and the at least one wing section to pivot the wing section. The lifting assembly can have a lifting actuator, a lug provided on the lifting actuator, a pivot member, and a pivotal connection between the lifting actuator and the pivot member. A guide member can run adjacent to the lifting actuator and have a guide channel for receiving the lug when the wing section is pivoted upwards into the transport position.

A hydraulically powered implement is designed for use in connection with a tractor that has a hydraulic pump that supplies pressurized hydraulic fluid to the implement. The implement includes a variable displacement hydraulic motor, an operative element driven by the hydraulic motor, a speed sensor configured to measure the rotational speed of the operative element and output a speed signal representative of the measured speed, a shift module that adjusts the displacement of the hydraulic motor in response to a shift command signal, and a controller. The controller sends the shift command signal to the shift module in response to speed signal output by the speed sensor.

A hydraulically powered implement is designed for use in connection with a tractor that has a hydraulic pump that supplies pressurized hydraulic fluid to the implement. The implement includes a variable displacement hydraulic motor, an operative element driven by the hydraulic motor, a speed sensor configured to measure the rotational speed of the operative element and output a speed signal representative of the measured speed, a shift module that adjusts the displacement of the hydraulic motor in response to a shift command signal, and a controller. The controller sends the shift command signal to the shift module in response to speed signal output by the speed sensor.

In one embodiment, a system, comprising: one or more pairs of oppositely rotatable, laterally extending rolls, wherein for each pair, at least one of the rolls is moveable relative to the other of the rolls; a hydraulic circuit, comprising: a tensioner circuit comprising: for each pair of rolls, one or more pairs of hydraulic cylinders arranged in parallel, each configured to resist movement of the at least one of the rolls at a respective end of the at least one of the rolls; an accumulator arranged in parallel to the hydraulic cylinders; and plural control valves; and a computing system configured to cause the one or more pairs of hydraulic cylinders to adjust the resistance to movement of the at least one of the rolls of the respective pair of rolls by sending signals to one or more of the plural control valves.