In one aspect, an agricultural planted is associated with an apparatus, a system and/or a method for calibrating a depth control arrangement in each of one or more row units adapted for attachment to a toolbar of the planter, where each row unit has a depth controlling linkage arrangement operatively connected to an adjustable-depth gauge wheel of the row unit. The linkage arrangement includes a load-sensing element that is monitored during adjustment of a calibration mechanism of the linkage arrangement to remove tolerance stack-up in the linkage arrangement and achieve a uniform desired value of the present load on the linkage arrangement of each of the one or more row units that is consistent with a zero-depth or other reference depth setting.

Systems, methods and apparatus are provided for monitoring soil properties. An example control and monitoring system for an agricultural implement having a plurality of row units includes a reflectivity sensor, a camera, a processor, and a monitoring device. The reflectivity sensor generates a reflectivity signal related to reflectivity of soil worked by the row units. The camera captures images of a seed trench opened by an opening assembly of the row units. The camera is disposed on a shank extension forward of seeds being deposited in the seed trench by the row units. The processor is configured to calculate a statistical variation in the reflectivity signal and the monitoring device is configured to display one or more of the images captured by the camera and a representation of the statistical variation.

An agricultural row unit having a coulter assembly comprising a pair of gauge wheels and a coulter between the pair of gauge wheels, wherein the coulter is configured to penetrate soil and cut debris. The row unit also having a soil engaging assembly comprising sweep and a seed tube, wherein the sweep is configured to open a seed channel and the seed tube is configured to deposit seeds into the seed channel. The row unit also including a closing assembly configured to replace soil displaced by the coulter and sweep. The row unit configured for independent and optionally automatic variable depth control of the seed channel.

A system for sensing characteristics of a trench in a soil surface during planting operations. A trench opening assembly opens a trench in the soil surface as the trench opening assembly moves in a forward direction of travel. A trench closing assembly disposed rearward of the trench opening assembly closes the opened trench with soil. One or more sensors may be disposed on an appurtenance disposed in said trench configured to provide characteristics of an area of the open trench or an area of the trench closed with soil by the trench closing assembly or a sensor may be disposed outside of said trench configured to provide characteristics of an area of the trench closed with soil or a combination of the sensors may be disposed in the trench and outside of the trench.

Systems, methods, and apparatus for shifting weight between a tractor and toolbar and between sections of the toolbar, for controlling operative height of a toolbar and sections of a toolbar and for folding a toolbar between a work position and a transport position. A ground engaging wheel and an actuator are coupled to the toolbar. In one embodiment, a fluid control system is responsive to a command signal to modify the actuator pressure such that the actuator pressure corresponds to a desired pressure.

A row unit for a work vehicle includes a row unit frame with a closer frame. The closer frame defines a longitudinal axis and a transverse axis. The closer frame is supported for rotational movement about a substantially vertical steering axis to vary a turning angle between the longitudinal axis the vehicle longitudinal axis. The row unit includes a closer implement assembly with first and second closer implements and a walking beam construction. The first and second closer implements are attached to opposite areas of the walking beam construction. The walking beam construction is rotationally attached to the closer frame to support rotation of the closer implement assembly about the transverse axis. The first and second closer implements are configured to move ground material into a ground opening from opposites sides as the work vehicle moves across the field.

The disclosed apparatus, systems and methods relate to devices, systems and methods for on-the-go monitoring and controlled feedback in a supplemental downforce application. Certain implementations provide real-time monitoring of furrow depth via contact and non-contact approaches, some of which are combined with gauge wheel feedback to calibrate and otherwise control the application of supplemental downforce to the row unit. A combination of sensor types are employed in collecting furrow depth measurements, which can be used to adjust the supplemental downforce through a control system module. A gauge wheel load sensor may be used to modify the application of supplemental downforce.

A planting unit includes a seed meter for singulating and dispensing seed. Opening wheels or discs are included to create an opening in the field, such as a furrow. The unit includes one or more continuous tracks for supporting the row unit as it moves through the field. The tracks can be positioned on opposite sides. The tracks reduce compaction around the created furrow and provide better control of seed depth placement. One or more motors are included to operate the tracks to move the planting unit through a field for planting independent of a tow vehicle.

An agricultural machine includes a frame member; a toolbar coupled to the frame member parallel to 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. Related methods are also disclosed.

An agricultural planting machine includes a frame and a planting system supported on the frame and configured to plant seeds in a row. The planting system includes a ground-engaging element movable relative to the frame and configured to engage a ground surface of a field. A field contour detection system is configured to receive in-situ sensor data representing a location of the ground-engaging element, generate field contour data representing a contour of the ground surface based on the in-situ sensor data, and generate a control signal based on the field contour data.