Systems and methods for automatically configuring a cutterbar between a flexible configuration and a rigid configuration in response to actuation of a gauge wheel are disclosed. The cutterbar is coupled to the gauge wheel such that extension of the gauge wheel causes the cutterbar to move into the rigid configuration and retraction of the gauge wheel causes the cutterbar to move into the flexible configuration.

Systems and methods for automatically configuring a cutterbar between a flexible configuration and a rigid configuration in response to actuation of a gauge wheel are disclosed. The cutterbar is coupled to the gauge wheel such that extension of the gauge wheel causes the cutterbar to move into the rigid configuration and retraction of the gauge wheel causes the cutterbar to move into the flexible configuration.

Systems and methods for automatically configuring a cutterbar between a flexible configuration and a rigid configuration in response to actuation of a gauge wheel are disclosed. The cutterbar is coupled to the gauge wheel such that extension of the gauge wheel causes the cutterbar to move into the rigid configuration and retraction of the gauge wheel causes the cutterbar to move into the flexible configuration.

Systems and methods for automatically configuring a cutterbar between a flexible configuration and a rigid configuration in response to actuation of a gauge wheel are disclosed. The cutterbar is coupled to the gauge wheel such that extension of the gauge wheel causes the cutterbar to move into the rigid configuration and retraction of the gauge wheel causes the cutterbar to move into the flexible configuration.

Systems and methods for automatically configuring a cutterbar between a flexible configuration and a rigid configuration in response to actuation of a gauge wheel are disclosed. The cutterbar is coupled to the gauge wheel such that extension of the gauge wheel causes the cutterbar to move into the rigid configuration and retraction of the gauge wheel causes the cutterbar to move into the flexible configuration.

Systems and methods for automatically configuring a cutterbar between a flexible configuration and a rigid configuration in response to actuation of a gauge wheel are disclosed. The cutterbar is coupled to the gauge wheel such that extension of the gauge wheel causes the cutterbar to move into the rigid configuration and retraction of the gauge wheel causes the cutterbar to move into the flexible configuration.

A combine header includes a header frame and a set of reciprocating knives at a front of the combine header. The combine header includes a driveline for driving reciprocating movement of the knives, the driveline including a transverse drive shaft at a back of the header frame, a bevel gearbox, a lateral drive shaft, and a transmission near the knives. The lateral drive shaft is coupled respectively to the bevel gearbox and the transmission by first and second universal joints. An inlet axle of the transmission is integral with or fixed to a flywheel configured to stabilize rotation of the lateral drive shaft. The second universal joint includes two orthogonal forks coupled by a cross-piece One of the forks is integral with or fixed to a flange that is attached to a surface of the flywheel that faces the lateral drive shaft. The flange is configured to contribute to the stabilizing function of the flywheel when the flange is attached to the surface.

A combine header includes a header frame and a set of reciprocating knives at a front of the combine header. The combine header includes a driveline for driving reciprocating movement of the knives, the driveline including a transverse drive shaft at a back of the header frame, a bevel gearbox, a lateral drive shaft, and a transmission near the knives. The lateral drive shaft is coupled respectively to the bevel gearbox and the transmission by first and second universal joints. An inlet axle of the transmission is integral with or fixed to a flywheel configured to stabilize rotation of the lateral drive shaft. The second universal joint includes two orthogonal forks coupled by a cross-piece One of the forks is integral with or fixed to a flange that is attached to a surface of the flywheel that faces the lateral drive shaft. The flange is configured to contribute to the stabilizing function of the flywheel when the flange is attached to the surface.

In some embodiments, a system includes a housing, a cutting assembly, a tine assembly, and an auger. The cutting assembly includes a plurality of axially-aligned cutting portions and a plurality of projections extending distally relative to the plurality of cutting portions and configured to urge a non-stalk portion of a plant vertically upward relative to a stalk portion of the plant. Adjacent projections of the plurality of projections extending distally from opposite sides of each cutting portion define a receiving space aligned with each cutting portion within which the stalk of a plant can be received to be cut by the cutting portion into a first plant portion and a second plant portion. The tine assembly can be rotated to urge the first plant portion into the interior space of the housing; and an auger can urge the first plant portion toward and through a rear opening.

A cutting system includes knives attached to a continuously moving belt-type carrier. The carrier motion moves the knives past stationary counterknife fingers which are attached to or uniform with a cutterbar, as the cutting system is driven through a field of crop stalks, which are cut by the interaction between the knives and counterknives. One or more sensing devices produce signals or images related to the condition of the knives when the knives are moving past the sensing devices. A processing unit processes the signals or images and derives therefrom one or more parameters representative of the condition of the knives, and compares the parameters to a reference, to thereby monitor the condition. An agricultural implement such as a combine harvester, can be equipped with the cutting system.