A row planting unit closing system including a first stage closing unit adapted to be attached to a row planting unit and including: a first stage frame; and a set of at least one row closing wheel having a closing angle orientation non-perpendicular relative to the ground; and wherein the first stage frame is attached at a first end to the row planting unit, the first stage frame comprising a linkage mechanism for setting a toe in angle orientation of the set of at least one row closing wheel relative to the first stage frame.

A roller assembly for smoothing an expanse of granular media such as golf bunker sand, snow, horse race track dirt, or other media. The assembly has one or more rollers having a longitudinal axis. Each roller includes wires spaced from the axis to define a roller surface. Each wire is resiliently flexible to distort inwardly in response to force of contact on, and to recover during release of force from, the granular media as the roller rotates about the axis on the granular media. A shaft extends along the axis of the roller assembly between the arms of a yoke with a handle extending therefrom. As the roller surface traverses the media, at least some of the media is flung outwardly of the roller, smoothing the expanse. The roller assembly may be manually operated or may be towed behind a towing apparatus.

The stalk eliminator chops stalks, uproots stalks, and re-chops stalks. The apparatus includes a front stalk chopper on a rotating cylinder with angularly attached blades. A plow tool attaches to the apparatus and provides a subsoiler wing behind and under the front stalk chopper. A rear stalk chopper on a rotating cylinder with angularly attached blades follows the plow tool.

A control system for multiple row units of an agricultural implement includes a controller configured to selectively enable automatic downforce control for at least one controllable ground-engaging tool of each row unit that is within a work zone of an agricultural field. The automatic downforce control for the at least one controllable ground-engaging tool includes controlling a downforce of the at least one controllable ground-engaging tool such that the downforce is within a threshold range of a respective target downforce. In addition, the controller is configured to selectively disable the automatic downforce control for the at least one controllable ground-engaging tool of each row unit that is within a no-work zone of the agricultural field, or selectively adjust the respective target downforce for the at least one controllable ground-engaging tool of each row unit that is within the no-work zone of the agricultural field.

An agricultural device associated with reduced tillage techniques in a field includes a frame and a separator supported by the frame. The separator is configured to form a strip of exposed soil in residual plant matter in the field. A crimping device associated with the separator is configured to at least partially crush stems of residual plant matter while maintaining the strip.

The document discloses an agricultural implement, comprising a main frame (11), which carries a plurality of soil working tools (32), a first support frame (12a), which is pivotally connected to the main frame (11) via a first support frame joint (21a) and which carries at least one first rolling ground support (31a), such as a wheel or a roller, a control lever (13) rotatably connected to the main frame (11) via a control lever joint (22), a support frame control link (14) rotatably connected to the control lever via a first support frame control link joint (23a) and which is pivotally connected to the support frame (12) via a second support frame control link joint (23b) so that rotation (V1) of the control lever (13) around the control lever (22) provides rotation (V2) of the first support frame (12a) relative to the main frame (11), wherein the control lever (13) is rotatable in a first direction of rotation (V1) so that the first support frame control link joint (23a) can pass a line (C1) through rotation centers of the control lever joint (22) and the second support frame control link joint (23b) and wherein the first support frame (12a), when the first support frame control link joint (23a) passes the line (C1), changes direction of rotation (−V2).

A row cleaner connected to a strip till machine and adapted to clear mulch and other debris encountered in strip or low till planting. A row cleaner frame assembly comprising: a pair of row cleaner arms and a pair of clearing wheels configured to have a toe-in alignment; wherein the pair of row cleaner arms share a common plane and are pivotally connected at a pair of pivot points common or close to the rotational axis of a cutting disc; wherein the cutting disc is disposed intermediate the pair of row cleaner arms; and wherein the row cleaner arms are configured to maintain the clearing wheels in a close-proximity to the cutting disc to provide stretch and cut row clearing operation with a biasing actuator for adjustability. An actuator pivotally adjusts the row cleaner assembly relative to the cutting disc. A pivot limiter restricts pivotal travel of the row cleaner to avoid damage to the actuator. A row closing section is provided and includes a lever adapted to adjust toe and/or camber of a closing wheel.

A system for detecting the levelness of ground engaging tools of a tillage implement including an agricultural implement including a frame and tool assemblies supported relative to the frame. The tool assemblies each include a toolbar coupled to the frame and one or more ground engaging tools coupled to the toolbar. The system further includes sensors coupled to two of the tool assemblies and configured to capture data indicative of a load acting on the one or more ground engaging tools of the tool assemblies. Additionally, the system includes a controller configured to monitor the data received from the sensors and compare at least one monitored value associated with the load acting on the ground engaging tool(s) of each of the tool assemblies. Moreover, the controller is further configured to identify the ground engaging tool(s) are not level when the monitored value(s) differ by a predetermined threshold value.

A system for identifying plugging within an agricultural implement is provided. The system includes a ground engaging tool configured to be supported by the agricultural implement. A fluidic actuator is coupled to the ground engaging tool. The fluidic actuator is operable to adjust the ground engaging tool between a lifted position and a ground engaging position. A pressure sensor is configured to measure a pressure of fluid supplied to the fluidic actuator. A controller is communicatively coupled to the pressure sensor. The controller is configured to receive, from the pressure sensor, a signal that corresponds to the pressure of fluid supplied to the fluidic actuator. The controller is further configured to determine when the ground engaging tool is plugged based at least in part on the signal from the pressure sensor.

A system for preventing material accumulation relative to an agricultural implement may include a ground engaging tool supported on an agricultural implement and a controller configured to determine a presence of excessive residue across a forward portion of the field forward of the ground engaging tool based at least in part residue data associated with an amount of residue across a forward portion of the field. The controller may initiate a control action associated with adjusting an operating parameter of the ground engaging tool such that the amount of residue incorporated into the field by the ground engaging tool is reduced across a section of the field having excessive residue to reduce a likelihood of material accumulation relative to the ground engaging tool as it passes across the section of the field.