This invention relates to an agricultural disc for use in agricultural work, such as to open furrows in the soil for sowing or to prepare the land for tillage and grinding, comprising two surfaces, a cutting circular perimeter edge and a plurality of notches located on a first surface of said agricultural disc, distributed in a circular matrix shape concentric to the agricultural disc, located adjacent to the perimeter edge. The invention also comprises the process for manufacturing the agricultural disc comprising a step of creating a plurality of undulations in a circular disc and a step of shaving or straightening via machining the crests generated on a second surface when the undulations are generated.

This invention relates to an agricultural disc for use in agricultural work, such as to open furrows in the soil for sowing or to prepare the land for tillage and grinding, comprising two surfaces, a cutting circular perimeter edge and a plurality of notches located on a first surface of said agricultural disc, distributed in a circular matrix shape concentric to the agricultural disc, located adjacent to the perimeter edge. The invention also comprises the process for manufacturing the agricultural disc comprising a step of creating a plurality of undulations in a circular disc and a step of shaving or straightening via machining the crests generated on a second surface when the undulations are generated.

A system for detecting plugging of ground-engaging tools of agricultural implements includes an aft sensor(s) configured to capture data indicative of a post-worked residue coverage of a portion of a field aft of a ground-engaging tool(s). The system includes a controller configured to monitor the data received from the aft sensor(s) and determine the post-worked residue coverage for the portion of the field. The controller is configured to identify when the ground-engaging tool(s) is experiencing a plugged condition based at least in part on the determined post-worked residue coverage for the field.

A cultivating disc for a tillage implement includes an attachment portion positioned at a radial center of the cultivating disc. The attachment portion includes one or more attachment features configured to couple the cultivating disc to the tillage implement about an axis of rotation of the cultivating disc. The attachment portion extends along a first plane perpendicular to the axis of rotation of the cultivating disc. The cultivating disc also includes a cutting edge portion positioned at a distal end of the cultivating disc relative to the axis of rotation. The cutting edge portion extends along a second plane parallel to the first plane. The cultivating disc further includes a curved connecting portion positioned between and connecting the attachment portion to the cutting edge portion. The curved connecting portion further defines one or more radii of curvature.

A cultivating disc for a tillage implement includes an attachment portion positioned at a radial center of the cultivating disc. The attachment portion includes one or more attachment features configured to couple the cultivating disc to the tillage implement about an axis of rotation of the cultivating disc. The attachment portion extends along a first plane perpendicular to the axis of rotation of the cultivating disc. The cultivating disc also includes a cutting edge portion positioned at a distal end of the cultivating disc relative to the axis of rotation. The cutting edge portion extends along a second plane parallel to the first plane. The cultivating disc further includes a curved connecting portion positioned between and connecting the attachment portion to the cutting edge portion. The curved connecting portion further defines one or more radii of curvature.

A system for identifying plugging within an agricultural implement is provided. The system includes a ground engaging tool configured to be supported by the agricultural implement. A weight sensor is operable to measure a weight of one or both of the ground engaging tool and the agricultural implement. A controller is communicatively coupled to the weight sensor. The controller is configured to receive, from the weight sensor, a signal that corresponds to the weight of one or both of the ground engaging tool and the agricultural implement. The controller is further configured to determine when the ground engaging tool is plugged based at least in part on the signal from the weight sensor.

A system that includes a wheel carrier system. The wheel carrier system includes a first wheel that couples to a first shaft. A first connector couples the first shaft to a central shaft. A second wheel couples to a second shaft. A second connector couples the second shaft to the central shaft. The first wheel and the second wheel independently rotate and move vertically. A first wheel carrier arm couples to a wheel carrier frame. A first link rotates a ground engaging tool system with respect to the wheel carrier frame to transition the ground engaging tool system from a lowered position to a raised position. An actuator simultaneously rotates the first wheel carrier arm from a first position to a second position and the ground engaging tool system from the lowered position to the raised position.

In one aspect, a system for detecting plugging of an agricultural implement includes include a frame member and a ground-engaging tool rotatably coupled to the frame member. The ground-engaging tool is configured to engage soil within a field as an agricultural implement is moved across the field. The system also includes a tool scraper positioned relative to the ground-engaging tool such that the tool scraper is configured to remove field materials from the tool as the tool engages the soil. Moreover, the system includes a sensor configured to detect a parameter indicative of a load on the tool scraper and a controller communicatively coupled to the sensor. The controller is configured to monitor the load on the tool scraper based on data received from the sensor and determine when the tool is experiencing a plugged condition based at least in part on the monitored load.

A method of manufacturing an agricultural tillage disk blade includes providing a substantially circular-shaped disk body with an outer peripheral edge and a central opening that defines a rotation axis, the outer body being disposed within a first plane. A plurality of waves is formed in a predetermined pattern in the outer peripheral edge of the disk body, and the outer peripheral edge is sharpened to form a plurality of teeth such that at least a portion of the sharpened outer peripheral edge is disposed within a second plane that is parallel to the first plane and substantially perpendicular to the rotation axis. The method also includes machining a plurality of relief portions in each of the plurality of waves at a location radially inward of the plurality of teeth, and heat treating the disk body after the sharpening and machining steps.

A method of manufacturing an agricultural tillage disk blade includes providing a substantially circular-shaped disk body with an outer peripheral edge and a central opening that defines a rotation axis, the outer body being disposed within a first plane. A plurality of waves is formed in a predetermined pattern in the outer peripheral edge of the disk body, and the outer peripheral edge is sharpened to form a plurality of teeth such that at least a portion of the sharpened outer peripheral edge is disposed within a second plane that is parallel to the first plane and substantially perpendicular to the rotation axis. The method also includes machining a plurality of relief portions in each of the plurality of waves at a location radially inward of the plurality of teeth, and heat treating the disk body after the sharpening and machining steps.