An agricultural harvester comprises a feederhouse pivotally attached to a chassis, where the feederhouse defines a conduit for conveying crop material rearwardly from a front opening. A header interface frame is pivotally mounted to the feederhouse over the front opening to permit header pitch adjustment around a pitch adjustment axis. Upper and lower linear actuators are connected on one side of the feederhouse between the feederhouse and interface frame to control the pitch adjustment.

In a combine harvester (10), the forward-directed driveline from the combine is coupled to the transversely oriented header drive axle through a transverse gearbox (26) that is mounted on a moveable cradle frame (20) onto which the header is mounted. in addition, the housing (28) of the gearbox or at least the portion of the housing including the input axle of the gearbox is rotatably arranged relative to the cradle frame (20), about a rotation axis oriented transversely to the combine's forward direction. A mechanical link (45) is furthermore provided between the rotatable gearbox housing (portion) (28) and the feeder housing (11), configured to control the orientation of the input axle (29) of the transverse gearbox, so as to maintain the alignment of the input axle (29) relative to the driveline of the combine.

In a combine harvester (10), the forward-directed driveline from the combine is coupled to the transversely oriented header drive axle through a transverse gearbox (26) that is mounted on a moveable cradle frame (20) onto which the header is mounted. in addition, the housing (28) of the gearbox or at least the portion of the housing including the input axle of the gearbox is rotatably arranged relative to the cradle frame (20), about a rotation axis oriented transversely to the combine's forward direction. A mechanical link (45) is furthermore provided between the rotatable gearbox housing (portion) (28) and the feeder housing (11), configured to control the orientation of the input axle (29) of the transverse gearbox, so as to maintain the alignment of the input axle (29) relative to the driveline of the combine.

In a combine harvester, the header (1) is lifted up by the feeder (8) and secured thereto by a mechanism including a pair of securing pins (23) on the feeder's carrier structure (20,21). The securing pins are provided with stops (35) protruding towards the header and which include a sloped surface, configured to interact with positioning aids (39) on the header. The lateral outward or inward movement of the securing pins (23) is driven by a centrally placed actuator (24). As the actuator is extended, the positioning aids (39) roll or glide down the sloped surfaces, enabling a gradual approach of the header towards the feeder, up to a point where the securing pins (23) become aligned with slots (50) on the header. Continued actuation of the pin motion then establishes the securing of the header to the feeder.

In a combine harvester, the header (1) is lifted up by the feeder (8) and secured thereto by a mechanism including a pair of securing pins (23) on the feeder's carrier structure (20,21). The securing pins are provided with stops (35) protruding towards the header and which include a sloped surface, configured to interact with positioning aids (39) on the header. The lateral outward or inward movement of the securing pins (23) is driven by a centrally placed actuator (24). As the actuator is extended, the positioning aids (39) roll or glide down the sloped surfaces, enabling a gradual approach of the header towards the feeder, up to a point where the securing pins (23) become aligned with slots (50) on the header. Continued actuation of the pin motion then establishes the securing of the header to the feeder.

An attachment mechanism for effecting a load-bearing interconnection between a header and a feederhouse of a self-propelled harvester is provided. The mechanism has a hook element secured to one of the header and feederhouse, the hook element having a limb defining an edge of a jaw opening with a inwardly tapering edge for longitudinally aligning and receiving a transverse pin secured to the other of the header and feederhouse. The limb has a non-vertical face configured to engage the other of the header and feederhouse and align such in the transverse direction as the feederhouse is lifted to engage the pin and jaw opening.

An attachment mechanism for effecting a load-bearing interconnection between a header and a feederhouse of a self-propelled harvester is provided. The mechanism has a hook element secured to one of the header and feederhouse, the hook element having a limb defining an edge of a jaw opening with a inwardly tapering edge for longitudinally aligning and receiving a transverse pin secured to the other of the header and feederhouse. The limb has a non-vertical face configured to engage the other of the header and feederhouse and align such in the transverse direction as the feederhouse is lifted to engage the pin and jaw opening.

In a combine harvester, the driveline coupling mechanism is configured to couple the header driveline to a jackshaft (22) extending from the feeder (8). The mechanism includes a pendulum arm (36) that is pivotably connected to the header (1). An actuator (45) is furthermore provided for driving a pivoting motion of the pendulum arm (36) about a pivot axis (37) oriented transversely with respect to the jackshaft. At the end of the pendulum arm, a bearing hub (30) is mounted including a shaft portion (32) that is rotatably coupled to the header driveline at one end and that includes one part (60) of a clutch at the other end. The second part (62) of the clutch is mounted on the jackshaft (22). The pivoting motion of the pendulum arm (36), driven by the actuator (45), closes or releases the clutch.

In a combine harvester, the driveline coupling mechanism is configured to couple the header driveline to a jackshaft (22) extending from the feeder (8). The mechanism includes a pendulum arm (36) that is pivotably connected to the header (1). An actuator (45) is furthermore provided for driving a pivoting motion of the pendulum arm (36) about a pivot axis (37) oriented transversely with respect to the jackshaft. At the end of the pendulum arm, a bearing hub (30) is mounted including a shaft portion (32) that is rotatably coupled to the header driveline at one end and that includes one part (60) of a clutch at the other end. The second part (62) of the clutch is mounted on the jackshaft (22). The pivoting motion of the pendulum arm (36), driven by the actuator (45), closes or releases the clutch.

A drive arrangement for a harvesting header of a harvesting machine having a running gear on which a feeder housing is mounted. A front side of the feeder housing has a header mount that moves relative to the feeder housing and on which the harvesting header is detachably fastened. An automated coupling mechanism is provided to link a driven shaft from the harvesting machine to a drive shaft of the harvesting header as the header is connected to the harvesting machine. The drive connector connected with the header mount is movable relative thereto during the attachment of the harvesting header to axially align the driven shaft and drive shaft as the harvesting header approaches the feeder housing during the attachment to accommodate differing header drive shaft orientations.