A boom mower attachment that moves a cutting mechanism in a first movement, a second movement, and a third movement by only using two motions of a single control and method of use thereof is provided. The boom mower may include a frame, a boom assembly carried by the frame, a cutting mechanism operably engaged with the boom assembly, and at least one translation assembly operably engaged with the boom assembly and the cutting mechanism that moves the cutting mechanism in one or more of the first movement, the second movement, and the third movement. An implement control system including a control, at least one function switching mechanism, and an implement is also provided. Activation of the control is operative to move the implement in a first mode, a second mode, and a third mode by only using two motions of the control.

A boom mower attachment that moves a cutting mechanism in a first movement, a second movement, and a third movement by only using two motions of a single control and method of use thereof is provided. The boom mower may include a frame, a boom assembly carried by the frame, a cutting mechanism operably engaged with the boom assembly, and at least one translation assembly operably engaged with the boom assembly and the cutting mechanism that moves the cutting mechanism in one or more of the first movement, the second movement, and the third movement. An implement control system including a control, at least one function switching mechanism, and an implement is also provided. Activation of the control is operative to move the implement in a first mode, a second mode, and a third mode by only using two motions of the control.

A boom mower attachment that moves a cutting mechanism in a first movement, a second movement, and a third movement by only using two motions of a single control and method of use thereof is provided. The boom mower may include a frame, a boom assembly carried by the frame, a cutting mechanism operably engaged with the boom assembly, and at least one translation assembly operably engaged with the boom assembly and the cutting mechanism that moves the cutting mechanism in one or more of the first movement, the second movement, and the third movement. An implement control system including a control, at least one function switching mechanism, and an implement is also provided. Activation of the control is operative to move the implement in a first mode, a second mode, and a third mode by only using two motions of the control.

A crop harvesting header having a frame mounted on a propulsion vehicle has a cutter bar carrying a sickle knife and a draper transport. The draper is guided at its front edge by a longitudinally extending rail mounted on the frame for movement therewith. The cutter bar is mounted on the frame at spaced positions by spring blades attached to a fixed beam at the rear which allow up and down flexing movement of the cutter bar relative to the draper engagement member. At the center discharge the cutter bar is carried on shorter blades which are carried on a beam in front of the front draper roller. The small amount of flexing of the cutter bar combines with a balanced three piece header frame to provide effective ground following.

A sickle bar drive mount may include an arm and a sickle bar drive eye. The arm is mountable to a horizontally extending sickle bar. The sickle bar drive eye is to receive a sickle bar drive bearing of a sickle bar drive. The arm may extend along a first horizontal axis parallel to the sickle bar. The sickle bar drive eye is pivotally coupled to the arm for pivotal movement about a second horizontal axis perpendicular to the first axis.

A header for a harvester includes: a header frame; one or more harvesting elements carried by the header frame; a lift arm coupled to the header frame and configured to displace the header frame vertically relative to the ground; and a lift assembly displaceably coupling the header frame to the lift arm, the lift assembly being configured to displace the header frame vertically further than and/or independently of the lift arm.

An agricultural harvesting head has three frame sections. Each frame section is pivotally coupled to its adjacent frame section by two links. The two links are pivotally coupled to the two adjacent frame sections at both ends of each link.

A header for a combine harvester comprising a drive arm assembly, bearing assembly and knife head assembly is disclosed. The drive arm assembly includes a drive arm with a proximal end operatively connected to a drive mechanism for reciprocating motion therewith and a distal end opposite the proximal end. The bearing assembly is attachable to the distal end of the drive arm and includes an eccentric hub. The knife head assembly includes a knife head and a housing mounted to the knife head. The housing houses the bearing assembly.

In an agricultural harvester header for an agricultural vehicle including a frame, a reel attached to the frame and having a plurality of reel tine bars, a cutterbar attached to the frame and positioned beneath the reel, an actuator for moving the reel tine bars between a deployed position and a retracted position, a sensor for sensing a position of the cutterbar, and a computer, a method for returning the reel tine bars to the deployed position includes (i) receiving, at the computer, signals from the sensor, (ii) recording a sensed position of the cutterbar when the actuator moves the reel tine bars to the retracted position, and (iii) activating the actuator to return the reel tine bars to the deployed position as a function of when the cutterbar returns to the recorded sensed position.

In an agricultural harvester header for an agricultural vehicle including a frame, a reel attached to the frame and having a plurality of reel tine bars, a cutterbar attached to the frame and positioned beneath the reel, an actuator for moving the reel tine bars between a deployed position and a retracted position, a sensor for sensing a position of the cutterbar, and a computer, a method for returning the reel tine bars to the deployed position includes (i) receiving, at the computer, signals from the sensor, (ii) recording a sensed position of the cutterbar when the actuator moves the reel tine bars to the retracted position, and (iii) activating the actuator to return the reel tine bars to the deployed position as a function of when the cutterbar returns to the recorded sensed position.