Disclosed is a lifting assembly for a crop severing assembly forwardly carried by a tractor having a frame and front a frame and an axle assembly carrying front wheel assemblies. The crop severing assembly has a forward end and a rear end, and includes a pair of bracket assemblies located at the forward end and atop the crop severing assembly. A pair of lift cylinder assemblies each have a lower end and a top end. The lift cylinder lower ends are located at either side of the rear end of the crop severing assembly to bottom brackets extending from the tractor frame forward of the tractor axle assembly and are attached between each cylinder lower end and each cylinder top end to trunnions carried by the crop severing bracket assemblies for pivotally raising and lowering of the forward end of the crop severing assembly.

Disclosed is a lifting assembly for a crop severing assembly forwardly carried by a tractor having a frame and front a frame and an axle assembly carrying front wheel assemblies. The crop severing assembly has a forward end and a rear end, and includes a pair of bracket assemblies located at the forward end and atop the crop severing assembly. A pair of lift cylinder assemblies each have a lower end and a top end. The lift cylinder lower ends are located at either side of the rear end of the crop severing assembly to bottom brackets extending from the tractor frame forward of the tractor axle assembly and are attached between each cylinder lower end and each cylinder top end to trunnions carried by the crop severing bracket assemblies for pivotally raising and lowering of the forward end of the crop severing assembly.

A feeder for an agricultural vehicle includes a feeder body defining a hollow interior space for receiving crop material from a header of the agricultural vehicle, a faceplate that is movably mounted to the feeder body, and a scissor jack assembly that is configured for rotating the faceplate with respect to the feeder body to adjust a fore-aft angle of the faceplate relative to the feeder body. The faceplate is configured to be removably coupled to the header of the agricultural vehicle.

A feeder for an agricultural vehicle includes a feeder body defining a hollow interior space for receiving crop material from a header of the agricultural vehicle, a faceplate that is movably mounted to the feeder body, and a scissor jack assembly that is configured for rotating the faceplate with respect to the feeder body to adjust a fore-aft angle of the faceplate relative to the feeder body. The faceplate is configured to be removably coupled to the header of the agricultural vehicle.

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.

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 harvester including a header assembly, includes: a multicoupler storage assembly including: a multicoupler assembly including a plurality of at least one of hydraulic connectors and electrical connectors; and a cradle mechanism configured for storing the multicoupler assembly and for selectively pivoting between a receiving position associated with the cradle mechanism receiving the multicoupler assembly and a storage position associated with the cradle mechanism storing the multicoupler assembly.

An agricultural harvester including a header assembly, includes: a multicoupler storage assembly including: a multicoupler assembly including a plurality of at least one of hydraulic connectors and electrical connectors; and a cradle mechanism configured for storing the multicoupler assembly and for selectively pivoting between a receiving position associated with the cradle mechanism receiving the multicoupler assembly and a storage position associated with the cradle mechanism storing the multicoupler assembly.

A feederhouse assembly for an agricultural harvester includes a frame, a header lock pin, a biasing member coupled to the frame and the header lock pin, and a latch coupled to the frame and the header lock pin. The biasing member is configured to urge the header lock pin outward to lock a harvesting header to the frame. A rotatable latch in a first positron protrudes from the frame and retains the header lock pin in an inward positron. The latch in a second position permits the header lock pin to travel outward. A method includes applying a force from a harvesting header on a latch protruding from a frame of a feederhouse, pushing the latch to release a header lock pin from an inward position, and urging the header lock pin outward to lock the harvesting header to the frame.

A feederhouse assembly for an agricultural harvester includes a frame, a header lock pin, a biasing member coupled to the frame and the header lock pin, and a latch coupled to the frame and the header lock pin. The biasing member is configured to urge the header lock pin outward to lock a harvesting header to the frame. A rotatable latch in a first positron protrudes from the frame and retains the header lock pin in an inward positron. The latch in a second position permits the header lock pin to travel outward. A method includes applying a force from a harvesting header on a latch protruding from a frame of a feederhouse, pushing the latch to release a header lock pin from an inward position, and urging the header lock pin outward to lock the harvesting header to the frame.