In one aspect, a method for reducing material accumulation relative to a closing assembly of an agricultural implement may include receiving an input associated with an amount of material accumulation relative to the closing assembly. Additionally, the method may include controlling an operation of the implement based on the received input such that at least one of a first closing tool or a second closing tool of the closing assembly moves from a working position to a material removal position to reduce an amount of material accumulation relative to the closing assembly. The method may also include controlling an operation of an actuator of the implement to actuate the at least one of the first closing tool or the second closing tool from the material removal position back to the working position.

An illustrative control system for an precision agricultural implement includes a controller having a convolutional neural network, a machine vision module, a plurality of sensors, and a plurality of actuators in communication with the controller, the plurality of actuators including a plurality of agricultural tool actuators.

A downforce control system for an agricultural ground engaging unit provides individual control of each agricultural ground engaging row unit by providing a proportional pressure control valve connected to the retracting chamber of a double acting cylinder which varies the upward force produced by the retracting chamber of the cylinder against a constant counteracting downward force produced by an extending chamber of the cylinder, the valve control based on a comparison of a sensed resultant downward force on the agricultural ground engaging row unit and a predetermined target downward force.

An agricultural implement system includes a tow bar configured to couple to a hitch assembly. The agricultural implement system also includes a tool bar pivot hinge assembly comprising two pivot points. The agricultural implement system additionally includes a first tool bar member mechanically coupled to a second tool bar member via the tool bar pivot hinge assembly; the first tool bar member extending transversely from the tow bar, wherein the tool bar pivot hinge assembly provides for an axis of rotation of the second tool bar member about the first tool bar member and additionally provides for an extension of the second tool bar member away from the first tool bar member.

An agricultural implement includes a transversely extending frame forming a first, a second, and a third frame section. A hydraulic control system controls a raising or lowering movement of each frame section. A first actuator and a second actuator are coupled to the first frame section, a third actuator is coupled to the second frame section, and a fourth actuator is coupled to the third frame section. A first control valve is fluidly coupled between a fluid source and the first and second actuators. A second control valve is fluidly coupled to the third actuator and a third control valve is fluidly coupled to the fourth actuator. A first flow path fluidly couples the first actuator, the second actuator, the third actuator, and the fourth actuator in series and a second flow path fluidly couples at least the third and fourth actuators in parallel with one another.

An agricultural implement includes a transversely extending frame forming a first, a second, and a third frame section. A first actuator is coupled to the first frame section, a second actuator coupled to the second frame section, and a third actuator coupled to the third frame section. Sensors are coupled to each frame section to detect a height of the respective frame section relative to an underlying surface. A control unit is disposed in electrical communication with the sensors and operably controls the actuators to adjust the height of each frame section.

An automated system for moving a crop harvester relative to an obstacle in a crop field. The system includes a sensor that is configured to sense a presence of the obstacle in the crop field, and transmit a signal corresponding to the presence of the obstacle. A motor is configured to move the crop harvester relative to the agricultural vehicle. A controller is configured to activate the motor based upon the signal received from the sensor and thereby move the crop harvester relative to the agricultural vehicle to prevent physical contact between crop harvester and the obstacle.

A tractor includes: a three-point linkage to which a tiller is mountable a hydraulic lifting/lowering driver to lift and lower the three-point linkage, and a mechanical linkage to transmit a lifting/lowering operation amount of the three-point linkage to the lifting/lowering driver. The mechanical linkage includes a load detector to detect an amount of change in traction load via the three-point linkage, a cable to interlock according to the amount of change in the traction load detected by the load detector, and a mechanical linkage interlocked and connected to the cable and the lifting/lowering driver, the mechanical linkage being capable of transmitting the lifting/lowering operation amount according to the amount of change in the traction load to the lifting/lowering driver.

A cultivator includes at least one cultivator row unit, each of the at least one cultivator row unit having a support assembly for securing the cultivator row unit to a tool bar, a shank, an earth working tool operatively connected to the shank, and at least one assembly for providing discrete incremental adjustment for at least one of (a) an angle of the earth working tool, (b) a depth of the earth working tool, and (c) a gauge wheel depth.

A system for adjusting the lateral positioning of wheel assemblies of agricultural implements includes a toolbar extending in a lateral direction and having a substantially circular cross-sectional shape. The system also includes a rail coupled to the toolbar and extending in the lateral direction along a length of the toolbar. Additionally, the system includes a wheel assembly configured to be removably coupled to the toolbar such that the rail is positioned between the toolbar and a portion of the wheel assembly. The wheel assembly includes engagement structure configured to engage the rail when the wheel assembly is installed relative to the toolbar, with the engagement between the rail and the engagement structure being configured to prevent rotation of the wheel assembly about the toolbar.