In one embodiment, a frame member; a toolbar coupled to the frame member, the toolbar parallel to, and rearward of, the frame member; a row unit coupled to the toolbar; and an actuator coupled between the frame member and the toolbar, the actuator configured to rotate the toolbar based on a sensed position of the toolbar.

A planting machine for forming a trench for planting seeds and/or fertilizer in a ground surface, including a frame that supports a planting assembly having a cutting tool and a gauge that sets the height of the cutting tool so as to determine a depth of the trench formed by the tool, wherein the assembly includes a linkage coupled between the frame to the gauge and an actuator to allow for remote adjustment of the linkage, in order to vary a planting depth of the trench.

An agricultural product control system for an agricultural implement includes an actuator configured to control a penetration depth of an agricultural product application system within soil, a sensor positioned above a surface of the soil and configured to output a sensor signal indicative of agricultural product above the surface of the soil, and a controller including a memory and a processor. The controller is configured to receive the sensor signal indicative of the agricultural product above the surface of the soil, and output a control signal to the actuator indicative of instructions to adjust the penetration depth of the agricultural product application system based on the sensor signal indicative of the agricultural product above the surface of the soil.

Agricultural seed planting systems include a processing unit, a frame, a furrow opener coupled to the frame for opening a furrow in soil, and a sensor in communication with the processing unit and adapted to sense a characteristic associated with seed planting. The sensor may generate a signal associated with the sensed characteristic and the processing unit may receive the signal. In some aspects, the sensed characteristic may be either a soil characteristic or a seed characteristic. Information associated with the sensed characteristic can be saved in memory for future use and to assist with more effective planting in the future.

A seed depth device for an agricultural planter includes an electric motor, an actuator, a stop, a controller, and a seed depth auto-learn system. The actuator is driven by the electric motor, and is constructed and arranged to move between a home position and a full extension position. The stop is proximate to the actuator when in the home position. The controller includes a computing processor and a computer readable storage medium configured to control the electric motor. The seed depth auto-learn system is, at least in-part, stored and executed by the controller. The seed depth auto-learn system is configured to learn the home position based, at least in-part, on the actuator stalling upon the stop.

A machine includes a first device, a second device and at least one controller. The first device includes a first motor located at a first address and associated with first operating characteristic data. The second device includes a second motor located at a second address and associated with second operating characteristic data that is substantially the same as the first operating characteristic data. The at least one controller includes a computing processor and a computer readable storage medium, and is configured to communicate with the first and second devices, and store the first and second operating characteristic data while associating the first and second operating characteristic data with the first and second addresses. The exchange of at least one of the first and second motors causes an exchange of the associated one of the first and second operating characteristic data.

A sectional control apparatus and method prompts the operator of an implement when the implement, or portion thereof, is traversing over land that has already been seeded and/or disturbed. The apparatus includes a GPS or GNSS receiver that communicates with a GPS or GNSS system and a controller that maps movement of the implement so that real-time positional data for the implement can be compared to the movement map. When the position of the implement, or portion thereof, is detected as moving over previously seeded and/or disturbed land, the controller activates an alert mechanism in the operator cab of the implement to notify the operator that sectional control, i.e., shutting down metering of product or raising the tool bar, needs to be implemented.

An adjustable row cleaner includes a row cleaner assembly that functions to clear material from the ground surface. The adjustable row cleaner includes, in one embodiment, a connector that is in mechanical communication with both a row cleaner frame, to which row cleaner wheels may be pivotally mounted, and a first end of a translator member. The translator member may pivot with respect to the row unit frame and/or row unit sub-frame about a translator member pivot. The position of a translator member second end may be manipulated, thereby adjusting the maximum depth to which the row cleaner wheels penetrate the ground surface. The adjustable row cleaner may be powered or manually adjusted, and the position of the row cleaner wheels may be monitored and automatically adjusted via a control system.

Agricultural seed planting systems are provided. In some aspects, the system includes a processing unit, a frame, a furrow opener coupled to the frame for opening a furrow in soil, and a sensor in communication with the processing unit and adapted to sense a characteristic associated with seed planting. The sensor may generate a signal associated with the sensed characteristic and the processing unit may receive the signal. In some aspects, the sensed characteristic may be either a soil characteristic or a seed characteristic. Information associated with the sensed characteristic can be saved in memory for future use and to assist with more effective planting in the future.

Openers for a seeder, configured to be adjustably engaged with a soil surface when in use; each opener having compliance to vertical and lateral excessive forces independently applied to soil-engaging parts: a fertiliser tine, a seed tine, a press wheel, a coulter, and a support wheel. The openers share a hydraulic circuit, linked to each internal frame-lifting ram so that localised rise and fall effects arising from soil surface irregularities are shared, maintaining a mean height. The seed tine of each opener is made liftable immediately the preceding fertiliser tine is displaced. The openers do not require external weight support.