A controller communicates with a user interface and sends a first signal to a first actuator to unlock a first lock, sends a second signal to move a first ground-engaging implement into a stowed position, sends a third signal to the first actuator to lock first lock to retain the first ground-engaging implement in the stowed position, sends a fourth signal to inhibit flow through a first hose with a flow blocking element, sends a fifth signal to a second actuator to unlock a second lock, sends a sixth signal to move a second ground-engaging implement into a deployed position, sends a seventh signal to the second actuator to lock the second lock to retain the second ground-engaging implement in the deployed position, and sends an eighth signal to a second flow blocking element to permit flow through a second hose around the flow blocking element.

A controller communicates with a user interface and sends a first signal to a first actuator to unlock a first lock, sends a second signal to move a first ground-engaging implement into a stowed position, sends a third signal to the first actuator to lock first lock to retain the first ground-engaging implement in the stowed position, sends a fourth signal to inhibit flow through a first hose with a flow blocking element, sends a fifth signal to a second actuator to unlock a second lock, sends a sixth signal to move a second ground-engaging implement into a deployed position, sends a seventh signal to the second actuator to lock the second lock to retain the second ground-engaging implement in the deployed position, and sends an eighth signal to a second flow blocking element to permit flow through a second hose around the flow blocking element.

Locations of seeds in a field can be identified using event-based processing or frequency-based processing. A material is applied to the field, based upon the seed locations.

A metering system includes a plurality of metering elements that are independently controllable. A calibration method of the present disclosure includes generating calibration factors for the individual metering elements. Also, a method of the present disclosure includes operating the metering elements according to the respective calibration factor.

Depth of penetration of a soil coulter is detected using a sensor being mounted on the side of the disk adjacent the edge such that the sensor as the disk rotates is located above the surface of the soil during a first part of its rotation and is located below the surface during a second part of its rotation. The sensor issues a signal which changes in response to whether the sensor is above or below the soil surface which is received by a controller which calculates from the signal a first time when the sensor enters below the soil surface and a second time when the sensor departs the soil surface and calculates from the first and second times the depth of penetration of the coulter in the soil. The system can also detect variations in depth indicative of a value of surface roughness.

Depth of penetration of a soil coulter is detected using a sensor being mounted on the side of the disk adjacent the edge such that the sensor as the disk rotates is located above the surface of the soil during a first part of its rotation and is located below the surface during a second part of its rotation. The sensor issues a signal which changes in response to whether the sensor is above or below the soil surface which is received by a controller which calculates from the signal a first time when the sensor enters below the soil surface and a second time when the sensor departs the soil surface and calculates from the first and second times the depth of penetration of the coulter in the soil. The system can also detect variations in depth indicative of a value of surface roughness.

An agricultural implement includes a main frame assembly, a toolbar coupled to the main frame assembly, and a wing wheel linkage assembly coupled to the toolbar. The agricultural implement also includes a wing wheel rotatably coupled to the wing wheel linkage assembly. In addition, the agricultural implement includes an actuator coupled to the wing wheel linkage assembly and configured to drive the wing wheel linkage assembly to move the wing wheel linkage assembly substantially along a vertical axis between a planting position and a headland position.

A seeding apparatus includes a frame supported on ground-engaging wheels, an opening device for creating a trench, a seed reservoir, and seed dispensing apparatus configured to deposit seed in the trench. The opening device is mounted to the frame by a four-bar linkage having first and second link arms. Each of the first and second link arms is pivotably connected to the frame by respective first and second pivot joints, and to the opening device by respective third and fourth pivot joints disposed forwardly of the first and second pivot joints. The opening device is ‘pushed’ through the soil via the four-bar linkage.

A seeding apparatus includes a frame supported on ground-engaging wheels, an opening device for creating a trench, a seed reservoir, and seed dispensing apparatus configured to deposit seed in the trench. The opening device is mounted to the frame by a four-bar linkage having first and second link arms. Each of the first and second link arms is pivotably connected to the frame by respective first and second pivot joints, and to the opening device by respective third and fourth pivot joints disposed forwardly of the first and second pivot joints. The opening device is ‘pushed’ through the soil via the four-bar linkage.

This document concerns a device for airflow-assisted feeding of granular material in an agricultural implement, comprising an air inlet (1611, 1612), a material inlet (167), and an outlet (162) for material-laden airflow, a roof (163), the horizontal extension of which defines a material pickup zone (160), wherein the material inlet (167), air inlet (1611, 1612) and outlet (162) are connected to the material pickup zone (160), wherein the device furthermore comprises an air inlet valve (164) containing a valve seat (1641) and a valve body (1642). The valve body is rotatable about a geometric axis which is substantially perpendicular to a flow direction at the air inlet. The document also concerns a method for airflow-assisted feeding of material in an agricultural implement, a meter housing, and an agricultural implement comprising such a meter housing. It also concerns a frame for a material pickup module and a method for forming a meter housing.