A header for a harvesting machine which includes one or more crop-engaging components and a sensing unit positioned within a flowpath of material and downstream of at least one of the one or more crop-engaging components. The sensing unit is configured, in use, to measure an impact parameter indicative of a force and/or frequency of material incident on a detection surface of the sensing unit in order to determine a measure of grain loss associated with the header.

A flexible and rotatable coupling assembly for a feeder conveyor of a combine harvester, for example. The coupling assembly connects a first rotatable shaft to a second rotatable shaft. The coupling assembly includes a spherical bearing that is connectable to the first rotatable shaft for accommodating a radial or angular misalignment between the first and second rotatable shafts; and a flexible and rotatable coupler that is non-rotatably connectable to the first and second rotatable shafts for transferring rotation between the first and second rotatable shafts. The flexible and rotatable coupler is either directly or indirectly connected to the spherical bearing. The flexible and rotatable coupler has a flexible component for accommodating the radial or angular misalignment.

An agricultural harvesting machine has a cutting apparatus formed as a header for cutting and picking up crop of a crop stand, an inclined conveyor downstream of the cutting apparatus and in which a temporal layer height flow is adjusted, and a driver assistance system for controlling the cutting apparatus. The driver assistance system has a computing device and a sensor arrangement with a crop sensor system for generating crop parameters of the crop stand and a layer height sensor for generating the temporal layer height flow. The computing device simultaneously generates the cutting apparatus parameters of the cutting table length, horizontal reel position and vertical reel position so as to be adapted to one another and conveys them to the cutting apparatus to implement a harvesting process strategy in ongoing harvesting operation.

An agricultural vehicle feeder assembly having: a feeder housing, a shaft mounted to rotate relative to the feeder housing, first and second rotary drives mounted to rotate with the shaft at a first and second axial positions along the shaft, and an anti-wrap cover assembly extending an entire distance from the first rotary drive to the second rotary drive and at least partially surrounding the first rotary drive, the second rotary drive, and the shaft between the first rotary drive and the second rotary drive. The anti-wrap cover assembly is rotatably mounted the first rotary drive, the second rotary drive and/or the shaft. A connector joins the feeder housing to the anti-wrap cover assembly. The connector is configured to allow the anti-wrap cover assembly to move through a predetermined limited range of motion relative to the feeder housing.

A feeder housing for an agricultural harvester includes: a housing; a conveyor system disposed in the housing, the conveyor system including a drive shaft, at least one drive loop coupled to the drive shaft such that rotation of the drive shaft causes rotation of the at least one drive loop, and a plurality of crop grabbers coupled to the at least one drive loop; a rock beater disposed in the housing and including a rotatable beater roll and at least one fin carried by the beater roll; and a motor coupled to the beater roll and configured to rotate the beater roll. The motor is an electrically powered motor or a hydraulically powered motor. The motor is coupled to the beater roll such that the motor is configured to rotate the beater roll without rotating the drive shaft.

An agricultural header for use with an agricultural harvester is configured to cut crop when the agricultural harvester moves in a direction of travel. The agricultural header comprises a first frame, a side draper belt supported by the first frame and positioned to receive cut crop and advance cut crop laterally relative to the direction of travel, a second frame, a center draper belt supported by the second frame and positioned in register with the side draper belt to receive cut crop laterally therefrom and advance cut crop rearwardly toward the agricultural harvester opposite to the direction of travel, and a joint interconnecting the first frame and the second frame and enabling relative fore-aft and lateral translation between the first frame and the second frame.

A header for an agricultural vehicle includes: a header frame; a flexible cutter supported by the header frame and including a plurality of cutting edges; a reel including a plurality of reel sections movably supported by the header frame, each of the reel sections including a plurality of tines and being independently movable from the other reel sections; and at least one rigid link connecting the flexible cutter to one of the reel sections, the at least one rigid link being configured to transmit flexing forces acting on the flexible cutter to the connected one reel section such that a substantially constant separation is maintained between the flexible cutter and the connected one reel section.

A combine includes a feeder housing that include a movable cradle frame at the front, configured to receive a header, so that a controlled movement of the cradle frame may be imparted to the header during a harvesting run. The combine further includes a driveline for driving moving components of the combine header. The driveline includes a belt drive mounted laterally with respect to the feeder housing. The belt drive is configured to transfer a rotation of a first drive axle that is part of the driveline, to a rotation of a second axle to which a drive axle of the header can be coupled. The belt drive includes two pulleys which are maintained in a common plane regardless of movement of the header relative to the feeder housing. The pulleys are rotatably mounted in a longitudinally extendable bridge structure, and are coupled to the first and second axles.

A piston lock system comprising: a cylinder, a rod receiver fixed to the cylinder, a piston slidably mounted to the cylinder, and a rod fixed to a free end of the piston and extending parallel to the piston to be located within the rod receiver. The piston and rod are movable relative to the cylinder and rod receiver between a retracted position and an extended position. A lock pin is mounted to the rod receiver and movable between a unlocked position in which the lock pin does not intersect a path of the rod, and a locked position in which the lock pin intersects the path of the rod and prevents the rod and piston from moving to the retracted position. Lock pins of multiple actuators can be connected to operate in unison.

An apparatus for actuating a rocking motion of a movable component including an adjustable length actuator, a lever whose angular position is controlled by the actuator, and a force transfer element attached to the movable component. The lever comprises a pair of oppositely placed pawls shaped so as to interact with the force transfer element for respectively actuating movement of the component in one of two opposite directions, when the lever exits a neutral positional range in which range any interaction between both pawls and the force transfer element is prohibited. The neutral range may be defined by a support plate positioned, shaped, and dimensioned so as to prohibit interaction between the pawls and the force transfer element. The displacement of the component in one direction may be larger than in the opposite direction.