An agricultural implement may include a frame and a row unit supported by the frame, where the row unit works a field as the implement is moved across the field. The row unit includes a first frame member coupled to a support structure of the row unit, a second frame member rotatable relative to the first frame member, and at least one cleaning wheel rotatable relative to the second frame member. Additionally, the row unit includes a depth stop member movably coupled to the first frame member, where the depth stop member is configured to set a lower height limit for the at least one cleaning wheel, with the second frame member being configured to abut against the depth stop member when the at least one cleaning wheel is disposed at the lower height limit.

A system for monitoring the displacement of a ground engaging tool of an agricultural implement includes a controller of the system may be configured to monitor a magnitude of a displacement defined between a current position of a ground engaging tool of the implement and a predetermined ground engaging tool position. The controller may also be configured to initiate a first control action when it is determined that the magnitude of the displacement of the ground engaging tool exceeds a first threshold displacement value. Moreover, the controller may further be configured to initiate a second control action when it is determined that the magnitude of the displacement of the ground engaging tool exceeds a second threshold displacement value, with the second threshold displacement value corresponding to a greater displacement relative to the predetermined ground engaging tool position than the first displacement threshold value.

A compaction mitigation system for a work area and a method of mitigating compaction in a work area may include determining a compaction map of the work area having compaction data associated with a plurality of reference points, passing a work tool through the work area at the plurality of reference points, and adjusting the work tool at the plurality of reference points based on the compaction data.

A soil penetrating apparatus having an automatic tool (e.g., aerator tine) depth control system and method. The system includes an actuator that sets and controls tine depth, a sensor that monitors tine depth, and a controller that controls the actuator in response to the sensor. In some embodiments, the actuator is a hydraulic actuator, wherein once tine depth is set, flow to the actuator is bypassed. A relief may be provided to allow the tines to lift to a shallower depth temporarily when soil hardness exceeds a threshold. The system may then automatically return the tines to the pre-selected depth once soil conditions permit.

A system for monitoring wear on ground engaging tools of an agricultural implement includes a ground engaging tool supported relative to a frame of the agricultural implement, the ground engaging tool configured to rotate with engagement of the ground during operation of the agricultural implement, a non-contact sensor configured to detect a parameter indicative of wear on the ground engaging tool, and a controller communicatively coupled to the non-contact sensor. The controller is configured to determine a status of the wear on the ground engaging tool based on sensor data received from the non-contact sensor.

A soil penetrating apparatus having an automatic tool (e.g., aerator tine) depth control system and method. The system includes an actuator that sets and controls tine depth, a sensor that monitors tine depth, and a controller that controls the actuator in response to the sensor. In some embodiments, the actuator is a hydraulic actuator, wherein once tine depth is set, flow to the actuator is bypassed. A relief may be provided to allow the tines to lift to a shallower depth temporarily when soil hardness exceeds a threshold. The system may then automatically return the tines to the pre-selected depth once soil conditions permit.

An agricultural implement system includes a down force cylinder configured to apply a downward force to a row unit, and a depth control cylinder configured to vary a penetration depth of a ground engaging tool of the row unit. The agricultural implement system also includes a valve assembly in fluid communication with the down force cylinder and the depth control cylinder. The valve assembly is configured to automatically adjust the downward force by varying fluid pressure within the down force cylinder based on fluid pressure within the depth control cylinder.

A tractor mounted tiller/cultivator system that includes right and left swing arms pivotally attached to tractor chassis, right and left cutting head assemblies mounted on the swing arms, each including a right disc motor driving a rotary disc mounted on a distal portion of the swing arm and operatively coupled to the motor. Ground-engaging cultivation wheels surround the rotary disc, and an annular guard prevents unwanted contact of the wheels with vines or trunks of vines and trees. A drive mechanism lowers and raises the swing arms to put the cultivation wheels into engagement and disengagement with ground and to rotate said swing arms about their longitudinal axes. User controls operatively connected to the swing arms, cutting head assemblies, and drive mechanisms enable a user to finely tune the movement of the cutting heads into and out from rows of trees or vines.

A dirt extraction apparatus for use by a user in a crawlspace of a building to extract dirt and debris is provided. The dirt extraction apparatus includes a housing having an internal conduit with an inlet and an outlet, a plurality of blades rotatably mounted to the housing proximate the inlet, a motor disposed within the housing and operably connected to the plurality of blades, a support handle coupled to the top face of the housing and having a plurality of bars coupled together, and a collection assembly coupled to the outlet of the housing. Any bar of the support handle is grabbed by the user to maneuver the apparatus within the building crawlspace, thereby enabling the rotating blades to evacuate the dirt and debris from the ground surface through the internal conduit of the housing to the collection assembly.

An agricultural implement system includes a down force cylinder configured to apply a downward force to a row unit, and a depth control cylinder configured to vary a penetration depth of a ground engaging tool of the row unit. The agricultural implement system also includes a valve assembly in fluid communication with the down force cylinder and the depth control cylinder. The valve assembly is configured to automatically adjust the downward force by varying fluid pressure within the down force cylinder based on fluid pressure within the depth control cylinder.