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.

An agricultural header includes: a header frame; a cutter carried by the header frame; a steering assembly coupled to the header frame and including an axle; and a transport assembly coupled to the header frame. The transport assembly includes: a first arm coupled to the header frame and movable between a first transport position and a first operating position; a first wheel mount pivotably coupled to the first arm; a second arm pivotably coupled to the header frame and movable between a second transport position and a second operating position; a second wheel mount pivotably coupled to the second arm; and a linkage reversibly coupling the first wheel mount to the second wheel mount and coupled to the axle such that the second arm is movable independently of the first arm when the linkage is uncoupled from at least one of the first wheel mount or the second wheel mount.

An agricultural header includes: a header frame; a cutter carried by the header frame; a steering assembly coupled to the header frame and including an axle; and a transport assembly coupled to the header frame. The transport assembly includes: a first arm coupled to the header frame and movable between a first transport position and a first operating position; a first wheel mount pivotably coupled to the first arm; a second arm pivotably coupled to the header frame and movable between a second transport position and a second operating position; a second wheel mount pivotably coupled to the second arm; and a linkage reversibly coupling the first wheel mount to the second wheel mount and coupled to the axle such that the second arm is movable independently of the first arm when the linkage is uncoupled from at least one of the first wheel mount or the second wheel mount.

A header including a cutter bar configured to cut crop for harvesting and a header frame supporting the cutter bar. A transport assembly is operatively connected to the header frame. A support arm is rotatably coupled to an axle of the transport assembly and is pivotably coupled to a mounting frame coupled to the header frame. A cam linkage is disposed at the support arm to provide a mechanical advantage for an operator when moving the transport assembly from a transport position to a harvest position. The cam linkage includes a lift assist device having a first end connected to the mounting frame and a second end coupled to a cam arm. Extension of the second end from the first end of the lift assist device applies the cam arm to a cam surface of the support arm to move the transport assembly to the harvest position.

A header including a cutter bar configured to cut crop for harvesting and a header frame supporting the cutter bar. A transport assembly is operatively connected to the header frame. A support arm is rotatably coupled to an axle of the transport assembly and is pivotably coupled to a mounting frame coupled to the header frame. A cam linkage is disposed at the support arm to provide a mechanical advantage for an operator when moving the transport assembly from a transport position to a harvest position. The cam linkage includes a lift assist device having a first end connected to the mounting frame and a second end coupled to a cam arm. Extension of the second end from the first end of the lift assist device applies the cam arm to a cam surface of the support arm to move the transport assembly to the harvest position.

In one aspect, a system for adjusting harvesting implement orientation of an agricultural harvester may include a harvesting implement configured to be coupled to the agricultural harvester in a manner that permits a fore/aft tilt angle defined between a longitudinal axis of the harvesting implement and a field surface to be adjusted. The system may also include a sensor configured to detect a parameter indicative of a distance between the harvesting implement and the field surface. Furthermore, the system may include a controller configured to receive an input associated with a predetermined characteristic of the harvesting implement. The controller may also be configured to monitor the distance between the harvesting implement and the field surface based on data received from the sensor and initiate adjustments of the fore/aft tilt angle based on the received input and the monitored distance.

In one aspect, a system for adjusting harvesting implement orientation of an agricultural harvester may include a harvesting implement configured to be coupled to the agricultural harvester in a manner that permits a fore/aft tilt angle defined between a longitudinal axis of the harvesting implement and a field surface to be adjusted. The system may also include a sensor configured to detect a parameter indicative of a distance between the harvesting implement and the field surface. Furthermore, the system may include a controller configured to receive an input associated with a predetermined characteristic of the harvesting implement. The controller may also be configured to monitor the distance between the harvesting implement and the field surface based on data received from the sensor and initiate adjustments of the fore/aft tilt angle based on the received input and the monitored distance.

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.

One or more information maps are obtained by an agricultural work machine. The one or more information maps map one or more agricultural characteristic values at different geographic locations of a field. An in-situ sensor on the agricultural work machine senses an agricultural characteristic as the agricultural work machine moves through the field. A predictive map generator generates a predictive map that predicts a predictive agricultural characteristic at different locations in the field based on a relationship between the values in the one or more information maps and the agricultural characteristic sensed by the in-situ sensor. The predictive map can be output and used in automated machine control.