An apparatus and system for adjustably controlling the position and depth of row closer wheels in no-till planting applications, the apparatus comprising a frame, a piston movably secured at the top to the frame, upper and lower parallel arms disposed about the piston and movably secured at one end to the frame and at the other end to a hub stem, and a set of piston arms each movably secured at the top to one of the upper or lower parallel arms and at the other end to the bottom of the piston. A closing wheel assembly having a closing wheel frame and a set of closing wheels pivotally mounted to a lever on a single axle assembly allows the operator to change the angle at which the closing wheels intersect the ground surface during use. Accordingly, as the angle of the lever is manipulated, the angle of the closing wheel pivotally mounted to that lever changes in the vertical and/or horizontal dimensions.

A universal row clearing bracket including a mounting bracket configured to engage a toolbar of a tractor, wherein the mounting bracket may have a yoke engaged therewith. The yoke may connect to a first and second pivoting arm. One end of the pivoting arms configured to engage the yoke such that the yoke prevents the pivoting arms from moving with respect to the receiver past a certain point in at least one direction. The opposite end of the pivoting arms connecting to an interchangeable shoe, the interchangeable shoe configured to pivotally engage at least one engaging wheel and be replaced for other shoes to support different size engaging wheels.

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 sterns of residual plant matter while maintaining the strip.

A fluid control system for supplying fluid to multiple actuators associated with different implements disposed on an agricultural planter row unit. A first one of the multiple actuators is associated with a first implement disposed on the agricultural planter row unit. A second one of the multiple actuators is associated with a second implement disposed on the agricultural planter row unit. The fluid control system controls fluid flow from a fluid source to each of the first and second actuators. In one embodiment, the fluid control system includes an inlet valve, an outlet valve and a pressure sensor, wherein the inlet valve is in fluid communication with the fluid source and the pressure sensor is disposed to measure fluid pressure in a fluid line in fluid communication with the inlet valve and each of the first and second actuators.

In one aspect, a system for controlling the operation of a seed-planting implement may include a ground-engaging tool and an actuator configured to adjust an operating parameter of the ground-engaging tool. Furthermore, the system may include a controller configured to control the operation of the seed-planting implement such that a primary crop is planted in a field as the seed-planting implement is being moved across the field. Additionally, the controller may be configured to determine a density of a cover crop present within the field. Moreover, the controller may be configured to determine an adjustment to be made to the operating parameter of the ground-engaging tool based on the determined density. In addition, the controller may be configured to control the operation of the actuator to execute the adjustment of the operating parameter.

The disclosure relates to an on-the-go system for adjustment of various aspects of a planting row unit. The on-the-go system is able to vary the depth of the row cleaner by adjusting the downforce applied to the row cleaner to promote planting at an optimal seed depth and soil moisture while preventing late emergence.

A system for detecting the operational status of a seed-planting implement. The system includes a row unit including a frame and a residue removal device coupled to the frame. The residue removal device is configured to remove residue from a path of the row unit. The system further includes a sensor configured to capture data indicative of at least one of a position or an acceleration of the residue removal device. The system further includes a controller configured to monitor the data received from the sensor and compare at least one monitored value associated with the at least one of the position or the acceleration of the residue removal device to a predetermined threshold value set for the residue removal device. The controller is further configured to identify the residue removal device as being plugged when the at least one monitored value differs from the predetermined threshold value.

In one aspect, the present subject matter is directed to a system for managing material accumulation relative to a ground engaging assembly of an agricultural implement. The system may include one or more ground engaging tools of the ground engaging. assembly, a sensor detecting material accumulation relative to the ground engaging tools, and a controller communicatively coupled to the sensor. The controller may receive an input from the sensor associated with material accumulation relative to the ground engaging tools. The controller may further access data associated with an amount of crop residue present and data associated with a moisture content of soil within the field. Additionally, the controller may determine an accumulation type of the material accumulation based at least in part on the crop residue data and the soil moisture data,

The present invention is a row cleaning device having a main body with a proximal end and a distal end, the main body proximal end is adapted to mount to a seeder. A pivot leg has a first end and a second end, the first end is pivotally mounted to the main body distal end at a pivot, the second end extends toward the main body proximal end. A clearing implement is mounted to the pivot leg second end and rotates with respect to the pivot leg. The row cleaning device is adapted to be driven by a seeder in a direction of travel with the clearing implement being located behind the pivot in the direction of travel. The pivot leg pivots with respect to the main body as the clearing implement moves along the ground in the direction of travel.

An agricultural implement includes a frame, a first row of row units coupled to the frame, and a second row of row units coupled to the frame. The second row of row units is positioned behind the first row of row units relative to a direction of travel, and each row unit is configured to deposit seeds into the soil. The agricultural implement also includes a row of fertilizer applicators coupled to the frame and positioned between the first row and the second row of row units relative to the direction of travel. Each fertilizer applicator is laterally positioned between one row unit of the first row and one row unit of the second row that is laterally adjacent to the one row unit of the first row, and each fertilizer applicator is configured to direct displaced soil laterally toward the one row unit of the second row.