An agricultural row cleaner having: a frame; a first row cleaner wheel disposed on a first side of the frame; a second row cleaner wheel disposed on a second side of the frame; and a row cleaner diverter connected to the frame and disposed forward of the first row cleaner wheel and the second row cleaner wheel in a direction of travel and disposed between the first row cleaner wheel and the second row cleaner wheel.

A control system for a tillage implement broadly includes front and rear sensors, a leveling assembly, and a controller. The front sensor is positioned on a front of a central section, wherein the front sensor is configured to obtain height information indicative of a height of the front of the central section above a ground. The rear sensor is positioned on a rear of the central section, wherein the rear sensor is configured to obtain height information indicative of a height of the rear of the central section above the ground. The leveling assembly is configured to adjust a front to rear orientation of the central section. The controller is configured to receive the height information from the front sensor and the height information from the rear sensor, and to provide instructions to the leveling assembly to adjust the front to rear orientation of the central section based on the received height information.

An agricultural planting or seeding implement having a ground engaging tool that forms an opening along an axis in the soil, a sensor disposed aft of the ground engaging tool, and a row unit disposed aft of both the ground engaging tool and the sensor relative to a direction of travel of the agricultural planting or seeding implement. The sensor engages with the ground at a depth within the opening and generates a signal indicative of a soil property of the ground.

A row crop planter including a frame, a seed bin supported by the frame, the seed bin configured to hold seeds, and a plurality of agricultural row units coupled to one or more seed bins. Each of the plurality of row units includes a seed deposit assembly, including a disk to cut a furrow in the soil, gage wheel, and a seed deposit chute to direct seeds into the furrow. A bar linkage is operatively connected to the seed deposit assembly. A downforce actuator is operatively connected to the bar linkage and applies a force to the disk and to the gage wheel, to cut the furrow in the soil. A primary actuator is operatively connected to the bar linkage, wherein the primary actuator raises and lowers the seed deposit assemblies, and moves the disk into the soil to cut the furrow at a depth determined by the primary actuator and the gage wheel.

A seed coulter arranged to place one or more inputs in a groove behind a tine of a direct seed drill for field crops. The seed coulter is arranged for displaceable connection to the tine and is freely displaceable in the longitudinal direction of the tine between a lower position and an upper position. A seeding unit comprising the seed coulter, and a direct seed drill comprising a plurality of seeding units are described as well.

A row unit, including a frame with an upper portion and a lower portion, the upper portion having a parallel linkage, the lower portion having a gauge wheel depth control linkage, the gauge wheel depth control linkage coupled to plural gauge wheels; a first device coupled to the upper portion and configured to provide an adjustable down force; and an electric actuator coupled to the gauge wheel depth control linkage, the electric actuator configured to provide adjustable positioning of the gauge wheels.

A penetration depth control and gauge wheel contact force monitoring system for a row unit includes a penetration depth actuator configured to drive a gauge wheel arm assembly to move a gauge wheel relative to a row unit frame to control a penetration depth of an opener of the row unit. The penetration depth actuator includes a contact force sensor configured to output a sensor signal indicative of a contact force between the gauge wheel and a soil surface, the penetration depth actuator includes a body configured to be coupled to one of the frame or the gauge wheel arm assembly, the penetration depth actuator includes an actuating device configured to be coupled to the other of the frame or the gauge wheel arm assembly, and the actuating device is configured to move relative to the body to drive the gauge wheel arm assembly to move the gauge wheel.

A closing wheel assembly is provided for a row unit agricultural planter. The planter is configured to open a trench in the soil and the closing wheel assembly is configured to close the trench. A resilient flap is provided for firming and leveling the soil returned to the trench by the closing wheel assembly. Pivotally mounted offset closing wheels are also provided.

A method of controlling the downpressure on an air seeder that has a plurality of seed assemblies and a plurality of fertilizer assemblies each applying an adjustable downforce, wherein the method includes keeping a total downforce applied by all of the plurality of seed assemblies and all of the plurality of fertilizer assemblies less than a maximum downforce. The method may also include keeping the downforce applied by each of the fertilizer assemblies less than the downforce applied by each of the seed assemblies.

An agricultural implement includes at least one row unit having a plurality of support members, each of which is pivotably coupled to an attachment frame or another of the support members to permit vertical pivoting vertical movement of the support members, and a plurality of soil-engaging tools, each of which is coupled to at least one of the support members. A plurality of hydraulic cylinders are coupled to the support members for urging the support members downwardly toward the soil. A plurality of controllable pressure control valves are coupled to the hydraulic cylinders for controlling the pressure of hydraulic fluid supplied to the cylinders. A plurality of sensors produce electrical signals corresponding to predetermined conditions, and a controller is coupled to the sensor and the controllable pressure control valves. The controller receives the electrical signals from the sensors and produces control signals for controlling the pressure control valves.