A hinge for a gauge wheel arm for movably swinging the gauge wheel away from the agricultural equipment, such as an agricultural planter, is disclosed. The hinge is located along the length of the gauge wheel arm for rotating the gauge wheel away from the agricultural equipment to expose an inner surface of the gauge wheel and an interior portion of the agricultural equipment. The gauge wheel arm rotates about an angle of rotation formed by the hinge and permitting rotation between 0 and 180 degrees. The gauge wheel arm may also include a lock bolt for preventing rotation of the gauge wheel when desired.

A hinge for a gauge wheel arm for movably swinging the gauge wheel away from the agricultural equipment, such as an agricultural planter, is disclosed. The hinge is located along the length of the gauge wheel arm for rotating the gauge wheel away from the agricultural equipment to expose an inner surface of the gauge wheel and an interior portion of the agricultural equipment. The gauge wheel arm rotates about an angle of rotation formed by the hinge and permitting rotation between 0 and 180 degrees. The gauge wheel arm may also include a lock bolt for preventing rotation of the gauge wheel when desired.

In one aspect, the present subject matter is directed to a system for managing material accumulation relative to a ground engaging assembly of an agricultural implement. The system may include one or more ground engaging tools of the ground engaging assembly, a sensor detecting material accumulation relative to the ground engaging tools, and a controller communicatively coupled to the sensor. The controller may receive an input from the sensor associated with material accumulation relative to the ground engaging tools. The controller may further access data associated with an amount of crop residue present and data associated with a moisture content of soil within the field. Additionally, the controller may determine an accumulation type of the material accumulation based at least in part on the crop residue data and the soil moisture data.

In one aspect, the present subject matter is directed to a system for managing material accumulation relative to a ground engaging assembly of an agricultural implement. The system may include one or more ground engaging tools of the ground engaging assembly, a sensor detecting material accumulation relative to the ground engaging tools, and a controller communicatively coupled to the sensor. The controller may receive an input from the sensor associated with material accumulation relative to the ground engaging tools. The controller may further access data associated with an amount of crop residue present and data associated with a moisture content of soil within the field. Additionally, the controller may determine an accumulation type of the material accumulation based at least in part on the crop residue data and the soil moisture data.

A system for monitoring the levelness of a multi-wing agricultural implement may include a central frame section, a wing section pivotably coupled to the central frame section and a field contour sensor configured to generate data indicative of a contour of an aft portion of the field located rearward of the implement relative to a direction of travel of the implement. The system may further include a controller communicatively coupled to the field contour sensor. The controller may be configured to monitor the data received from the field contour sensor and assess a levelness of the implement based at least in part on the contour of the aft portion of the field.

A system for monitoring the levelness of a multi-wing agricultural implement may include a central frame section, a wing section pivotably coupled to the central frame section and a field contour sensor configured to generate data indicative of a contour of an aft portion of the field located rearward of the implement relative to a direction of travel of the implement. The system may further include a controller communicatively coupled to the field contour sensor. The controller may be configured to monitor the data received from the field contour sensor and assess a levelness of the implement based at least in part on the contour of the aft portion of the field.

An agricultural implement includes a chassis; a linkage carried by the chassis; a turnbuckle connected to the linkage and having a frame which includes a threaded hole formed therein and a non-circular region; and a latch pivotable about a fulcrum carried above the frame. The latch has a notch formed therein which is shaped to prevent substantial rotation of the frame when engaged with the non-circular region of the frame.

A castor wheel support for a towed agricultural implement. The castor support has a spindle for supporting a castor mounting structure for pivoting movement. The castor mounting structure includes an annular friction element received over the spindle and a plurality of C-shaped shims removable laterally without disassembly of the mounting structure to allow the pressure on the friction element to be set to minimize wobbling.

A method for reducing an overall transport profile of a multi-section tillage implement. The tillage implement includes a frame including a center frame section and at least one wing frame section. The tillage implement includes a plurality of ground-engaging tools pivotally mounted to the frame. The method includes pivoting each of the plurality of ground-engaging tools away from the ground surface from a ground-engaging position to a retracted position. The frame is disposed at an initial height relative to the ground surface before pivoting. After pivoting, the frame is lowered to a transport height relative to the ground surface. At least one wing frame section is folded relative to the center frame section from an operating position to a transport position to reduce a width of the tillage implement in the widthwise direction.

A method for reducing an overall transport profile of a multi-section tillage implement. The tillage implement includes a frame including a center frame section and at least one wing frame section. The tillage implement includes a plurality of ground-engaging tools pivotally mounted to the frame. The method includes pivoting each of the plurality of ground-engaging tools away from the ground surface from a ground-engaging position to a retracted position. The frame is disposed at an initial height relative to the ground surface before pivoting. After pivoting, the frame is lowered to a transport height relative to the ground surface. At least one wing frame section is folded relative to the center frame section from an operating position to a transport position to reduce a width of the tillage implement in the widthwise direction.