A lift and rotate style agricultural implement with forward folding wings is provided. The agricultural implement includes a center frame that may be operatively configured to be lifted and rotated approximately 90 degrees when switching between a field configuration and a transport configuration. Furthermore, the wings may include an inner portion and an outer portion, wherein the outer portion may be operatively configured to be rotated or pivoted approximately 180 degrees relative to the inner wing portion when switching between a field configuration and a transport configuration. The inner and outer wing portions may be connected by a hinge and the outer wing may be pivoted about the inner wing portion by a cylinder.

An agricultural vehicle header system having a center section, an inboard height sensor located on the center section between a lateral centerline and an end of the center section, a wing section movably attached to the end of the center section, a number of outboard height sensors located on the wing section between an inboard end and an outboard end of the wing section, and a header control subsystem. Each of the outboard height sensors is configured to output a respective outboard height sensor signal. The header control subsystem is operatively connected to the outboard height sensors, and configured to receive the respective outboard height sensor signals from each of the outboard height sensors, and generate a single emulated outboard height sensor signal based on the outboard height sensor signals.

An implement intended for harvesting and/or gathering farm produce is used together with a self-propelled agricultural machine, more specifically a grain harvester, in order to provide driving power for its crop processing systems. A top roller (11) is positioned at the rear end of each conveyor belt (1) whereby, internally and concentrically thereto, the supports (9) move in a continuous rotating movement with the slats (10); the conveyor belt (1) has electronics for adjusting the speeds of the machine and the belts, varying electronically between these magnitudes according to the proportionality parameter; in addition to also regulating the height of the conveyor belt (1B) through electronics and a pivoting device (26); the set of conveyor belts (1) may also be articulated into a transportation position.

A tillage implement has a frame connectable to a towing vehicle and at least two transverse rows of secondary tillage tools mounted on the frame, the at least two transverse rows comprising a row of main rollers mounted on the frame rearward of all other rows of the at least two transverse rows. The implement also has a transverse row of auxiliary rollers mounted rearward of the row of main rollers, the transverse row of auxiliary rollers independently pivotable vertically about a transverse pivot axis. The implement has at least one ground-engaging wheel. Independent pivoting of the row of auxiliary rollers allows an operator to increase tillage/field finish on the go or as needed.

A wing locking system for a harvesting header is provided. The wing locking system includes an accumulator, a fluid cylinder operably attached to a wing of the harvesting header, a hose fluidly connecting the accumulator and the fluid cylinder, and a valve operably disposed between the accumulator and the fluid cylinder. The valve includes a first selectable position configured to permit a first fluid flow rate between the accumulator and the fluid cylinder and a second selectable position configured to permit a second fluid flow rate from the accumulator to the fluid cylinder. The first fluid flow rate is greater than the second fluid flow rate.

A system and apparatus for attaching ground engaging tools proximate to the pivot point of an agricultural implement is provided. The system includes a flex apparatus configured to be operatively attached proximate to the pivot point of an agricultural implement by a pin. The flex apparatus may be configured to rotate as the pivot point of the agricultural implement flexes. The flex apparatus may include tracks, slots, or the like, configured to dampen the rotation of the flex apparatus relative to the flex of the pivot point of the agricultural implement. The size, location and orientation of the tracks, slots, or the like, may be configured to provide varying amounts of rotation of the flex apparatus relative to the flex of the pivot point of the agricultural implement. Furthermore, the flex apparatus includes holes, slots, grooves, or the like, configured for attaching a ground engaging tool to the flex apparatus.

A system for remotely controlling hydraulic component of an agricultural implement towed by a work vehicle may include a vehicle-based valve assembly that selectively supplies hydraulic fluid to one or more supply lines of the implement. Specifically, a first supply line may be fluidly coupled to an implement-based valve assembly that regulates the supply of hydraulic fluid to a hydraulic actuator through a first actuator line. A second supply line may be fluidly coupled to the first actuator line downstream of the implement-based valve assembly such that when a user provides a control input at a remote interface, the vehicle-based valve assembly may instead regulate the supply of hydraulic fluid to the actuator. The supply of the hydraulic fluid through the supply lines may additionally be controlled by first and second override valves fluidly coupled to the first and second supply lines, respectively.

A tool bar and hydraulic system for a large scale agricultural implement. The tool bar includes opposed pivotable wings that are extended in a field configuration and retracted in a transport configuration. In some embodiments, each pivotable wing includes two lift assist assemblies for aiding in the execution of turns in the field, and for aiding in the transport of the agricultural implement. The tool bar may be configured to compensate for twist of the pivotable wings when in the transport configuration. The hydraulic system is configured to stiffen the tool bar assembly for lift assist during field operation and to flex the tool bar into a folded configuration for transport.

A hinge assembly for pivotally connecting a first frame section and a second frame section includes at least one pivot plate pivotally connected to the first mounting structure of the first frame section with a first pin and pivotally connected to the first mounting structure of the second frame section with a second pin. The hinge assembly further includes a linkage bar with a first end pivotally connected to the second mounting structure of the first frame section with a third pin and a second end pivotally connected to the second mounting structure of the second frame section with a fourth pin. The pivot plate and the linkage bar are configured such that the second frame section pivots about the fourth pin during a working state and about the third pin during a transition between the working state and a folding state.

The invention relates to an agricultural machine comprising two side units and a chassis that extends in a longitudinal direction and is equipped with two wheels, each side unit being fitted to pivot in relation to the chassis via a respective longitudinal joint around a folding axis parallel to a median plane of the chassis; each side unit comprising a tool unit connected to the chassis by a respective arm and being able to occupy a work position in which it rests on the ground and in which the length of the respective tool unit extends transversely to the longitudinal direction; each side unit being also able to occupy a transport position in which it is remote from the ground and in which the length and width of the respective tool unit are substantially parallel to the median plane. The machine comprises at least a tilter articulated with the chassis around at least one tilting axis oriented transversely to the longitudinal direction, and in the transport position of the side units, each tool unit is closer to the median plane than the respective arm.