A rake having tine wheels has a coupler configured to attach to the front end loader of a vehicle, such as a tractor. The rake has a series a tine wheels and support elements extend generally forward and outward from the coupler with the tine wheels overlapping to move vegetation toward the center of the rake. The tine wheels and support elements are rotatably mounted around substantially horizontal axes directed generally in the direction of travel for the rake which allows the rake to adapt to terrain. The support elements may also rotate around additional axes that allow the support elements to raise and lower. Some embodiments of the rake have trailing arms with wheels to support the rake while deployed for use. These wheels trail the rake and keep the turning radius nearly the same as the vehicle.

A system includes an agricultural raking vehicle, including a motor drive and raking members mechanically coupled to the motor drive. The raking members rake agricultural product via rotation about an axis substantially orthogonal to a field on which the agricultural vehicle travels. The system also includes a sensor assembly that outputs a signal indicative of a determined windrow quality of the agricultural product raked by the raking members. The system also includes a controller communicatively coupled to the motor drive and to the sensor assembly. The controller receives the signal and controls an angular speed of the motor drive, a ground speed of the agricultural vehicle, and/or a height of the raking members or tines above the field, based on a comparison of the determined windrow quality to a target windrow quality.

Merger control device (21) for controlling the operation of a merger, wherein the merger control device (21) is designed to receive a cornering steering angle from a steering angle sensor (22, 23) as an input variable, and wherein the merger control device (21) is designed, as a function of the received cornering steering angle, to generate as an output variable at least one adjusting signal for transverse conveying devices (18) of the merger configured as belt conveyors and/or at least one adjusting signal for receiving members (17) of the merger configured as pick-ups, to output said adjusting signal to the transverse conveying devices (18) and/or receiving members (17) and to adapt the operation thereof automatically as a function of the cornering steering angle.

A rake apparatus is disclosed. The rake apparatus includes a plurality of material gathering members connected to a continuous conveyor member such as a chain or a belt. A drive sprocket supports the conveyor member at a discharge end of the rake apparatus. An idler sprocket supports the conveyor member at a distal end of the rake apparatus. The material gathering members contact a bottom stripper guard and a top stripper guard as they travel about the raking device to remove crop material from the material gathering members. The rake apparatus may be part of a harvesting machine in which the processing chamber of the harvesting machine has a width that is the same width as the pickup device of the harvesting machine.

Harvesting apparatus, namely merger or pickup swather, with a supporting frame (11) having a longitudinal member (12) and crossmembers (13, 14), with a chassis (16) having wheels (17), with a drawbar (15) which engages on the supporting frame (11) and via which the harvesting apparatus can be coupled to a tractor, with pickup members (18) designed as a pickup for picking up harvested crop, wherein at least one pickup member (18) is accommodated on a first side of the longitudinal member (12) and at least one further pickup member (18) is accommodated on a second side of the longitudinal member (12), in each case on a crossmember (13, 14), with transverse conveyor devices (19) designed as belt conveyors for conveying the picked-up harvested crop in a transverse conveying direction running transversely with respect to a longitudinal direction, wherein at least one transverse conveyor device (19) is accommodated on a first side of the longitudinal member (12) and at least one further transverse conveyor device (19) is accommodated on a second side of the longitudinal member (12), on the respective crossmember (13, 14), wherein the drawbar (15) is pivotable relative to the supporting frame (11) for transferring the harvesting apparatus between a working position and a headland position and/or a transport position.

An agricultural apparatus for forming from previously-cut agricultural crop, such as grass or the like, a windrow on a field, which may comprise: a frame, crop engaging elements supported on the frame and configured to form from previously-cut agricultural crop a windrow on a field, and a control unit configured to control operation of the crop engaging elements. The control unit is further configured to provide control signals to the crop engaging elements in such a way that, in a windrow forming mode of operation, the crop engaging elements are driven to engage with the previously-cut agricultural crop, and form from the previously-cut agricultural crop the windrow which may have a snake line form on the field. Further detailed is a method for forming from previously-cut agricultural crop, such as grass or the like, a windrow on a field.

Windrow diverting apparatus and method of controlling same proximate a roll baler pick-up which laterally shifts the windrow relative to the roll bale pick-up during baling.

In one embodiment, a machine, comprising: a chassis supporting a hydraulic float assembly, the hydraulic float assembly comprising first plural cylinders and a first control component; a header coupled to the hydraulic float assembly, the header comprising: a frame comprising processing components on an upper side of the frame and plural skid plates on a lower side of the frame, the plural skid plates adjustably coupled to the frame via respective second plural cylinders; and a controller configured to: receive a first input; and provide a first signal to a second control component coupled to the second plural cylinders based on the first input, the second control component configured to adjust fluid flow through the second plural cylinders based on the first signal, the second plural cylinders causing adjustment of a position of the plural skid plates based on the adjusted fluid flow.

A basket rake includes a main frame configured to be coupled to a tractor, a left basket coupled to the main frame via a left extension frame, a right basket coupled to the main frame via a right extension frame, a plurality of hydraulic actuators, a plurality of control lines, and a multi-function valve. Each of the plurality of control lines is hydraulically coupled to one of the plurality of actuators. The multi-function valve is hydraulically coupled to each of the plurality of control lines and is configured to receive hydraulic fluid from the tractor and control flow of hydraulic fluid independently to each of the plurality of hydraulic actuators via the plurality of control lines to extend or retract the extension frames, rotate the left or right baskets, raise or lower the left or right baskets, and operate drive motors of the left and right baskets.

Merger control device (21) for controlling the operation of a merger, wherein the merger control device (21) is designed to receive a cornering steering angle from a steering angle sensor (22, 23) as an input variable, and wherein the merger control device (21) is designed, as a function of the received cornering steering angle, to generate as an output variable at least one adjusting signal for transverse conveying devices (18) of the merger configured as belt conveyors and/or at least one adjusting signal for receiving members (17) of the merger configured as pick-ups, to output said adjusting signal to the transverse conveying devices (18) and/or receiving members (17) and to adapt the operation thereof automatically as a function of the cornering steering angle.