Abstract: 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.

Abstract: In one aspect, a system for detecting ground engaging tool float for an agricultural implement may include an implement having a ground engaging tool pivotally coupled to a frame and a biasing element coupled between the frame and the ground engaging tool. The biasing element may be configured to bias the ground engaging tool to a predetermined ground engaging tool position relative to the frame. The system may also include a sensor configured to detect a parameter indicative of a current position of the ground engaging tool relative to the frame. Additionally, the system may include a controller configured to monitor the current position of the ground engaging tool based on measurement signals received from the sensor and identify a time period across which the ground engaging tool is displaced from the predetermined ground engaging tool position.

Abstract: In one aspect, a system for controlling the operation of an agricultural implement may include an agricultural implement configured to perform an agricultural operation on a field as the implement is moved across the field. A controller of the system configured to receive data indicative of a plurality of field characteristics of the field. The controller may also be configured to determine first and second soil moisture content values of the soil within the field at first and second depths below a field surface of the field based on the received data, respectively. Additionally, the controller may be configured to initiate adjustment of an operating parameter of the agricultural implement based on the determined the first soil moisture content value and the determined second soil moisture content value.

Abstract: A method for automatically leveling an agricultural implement being towed by a work vehicle includes monitoring a vehicle inclination angle via at least one vehicle-based sensor supported on the work vehicle, monitoring an implement inclination angle via at least one implement-based sensor supported on the implement, and determining that the work vehicle has begun to travel across an inclined surface based on the vehicle inclination angle. The method further includes initially adjusting a position of a hitch of the work vehicle in a first direction to maintain the implement inclination angle within a predetermined angular inclination range as the vehicle travels across the inclined surface and adjusting the position of the hitch in a second direction opposite the first direction to maintain the implement inclination angle within the predetermined angular inclination range.

Abstract: A method for controlling the actuation of wing sections of an agricultural implement may include regulating a supply of hydraulic fluid to a wing actuator coupled to a wing section to pivot the wing section relative to a center frame section of the implement from a transport position towards a work position. The method may also include monitoring a wheel load associated with at least one wheel of the wing section as the wing section is being moved towards the work position and detecting when the wheel(s) of the wing section contacts the ground based at least in part on the monitored wheel load. In addition, the method may include adjusting one or more flow parameters of the supply of hydraulic fluid to the wing actuator to reduce an actuation rate at which the wing section is being pivoted after detecting that wheel(s) has contacted the ground.

Abstract: In one aspect, a system for controlling the operation of an agricultural implement may include an agricultural implement configured to perform an agricultural operation on a field as the implement is moved across the field. A controller of the system configured to receive data indicative of a plurality of field characteristics of the field. The controller may also be configured to determine first and second soil moisture content values of the soil within the field at first and second depths below a field surface of the field based on the received data, respectively. Additionally, the controller may be configured to initiate adjustment of an operating parameter of the agricultural implement based on the determined the first soil moisture content value and the determined second soil moisture content value.

Abstract: In one aspect, a system for creating a soil compaction map for a field may include a plurality of sensors, with each sensor being provided in operative association with one of the plurality of fluid-driven actuators. Each sensor may be configured to detect a force associated with its respective fluid-driven actuator as associated shanks engage the ground with movement of the tillage implement across the field. Furthermore, a controller of the system may be configured to identify one or more locations of a compaction layer within the field based on sensor data received from the plurality of sensors associated with the detected forces. Additionally, the controller may further be configured to create a soil compaction map for the field based on the identified one or more locations of the compaction layer.

Abstract: In one aspect, a system for monitoring the displacement of a ground engaging tool of an agricultural implement. 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.

Abstract: A method for automatically leveling an agricultural implement being towed by a work vehicle may generally include monitoring a vehicle inclination angle via at least one vehicle-based sensor supported on the work vehicle, monitoring an implement inclination angle via at least one implement-based sensor supported on the implement, and determining that the work vehicle has begun to travel across an inclined surface based on the vehicle inclination angle. Additionally, the method may include initially adjusting a position of a hitch of the work vehicle in a first direction to maintain the implement inclination angle within a predetermined angular inclination range as the vehicle travels across the inclined surface and adjusting the position of the hitch in a second direction opposite the first direction to maintain the implement inclination angle within the predetermined angular inclination range as at least one ground-engaging component of the implement travels across the inclined surface.

Abstract: A method for controlling the actuation of wing sections of an agricultural implement may include regulating a supply of hydraulic fluid to a wing actuator coupled to a wing section to pivot the wing section relative to a center frame section of the implement from a transport position towards a work position. The method may also include monitoring a wheel load associated with at least one wheel of the wing section as the wing section is being moved towards the work position and detecting when the wheel(s) of the wing section contacts the ground based at least in part on the monitored wheel load. In addition, the method may include adjusting one or more flow parameters of the supply of hydraulic fluid to the wing actuator to reduce an actuation rate at which the wing section is being pivoted after detecting that wheel(s) has contacted the ground.

Abstract: An agricultural apparatus includes an agricultural tractor and at least one agricultural implement. The agricultural tractor has at least one tractor controller and the agricultural implement has at least one implement controller. At least one wireless connection is connected to the at least one tractor controller and/or to the at least one implement controller. The agricultural tractor and/or the at least one agricultural implement has at least one adjustable setting controllable by the at least one tractor controller and/or by the at least one implement controller. A multi-purpose handheld wireless device communicates with the tractor controller and/or the implement controller by way of the wireless connection. The multi-purpose handheld wireless device has at least one application that transmits adjustment instructions to the tractor controller and/or to the implement controller to be carried out upon the at least one adjustable setting.

Abstract: An agricultural implement includes a chassis; an implement frame carried by the chassis; a shank connected to the implement frame, the shank including a shank point configured to break apart soil and a load sensor associated with the shank point which is configured to output shank load signals as the shank point advances through soil; an actuator carried by the chassis and configured to adjust a depth of the shank point; and a controller electrically coupled to the load sensor and the actuator. The controller is configured to receive the shank load signals; generate a load profile from the received shank load signals; analyze the load profile to determine whether the shank point is in a soil compaction layer; and activate the actuator to adjust the depth of the shank point based on the analyzed load profile.

Abstract: In one aspect, a system for detecting ground engaging tool float for an agricultural implement may include an implement having a ground engaging tool pivotally coupled to a frame and a biasing element coupled between the frame and the ground engaging tool. The biasing element may be configured to bias the ground engaging tool to a predetermined ground engaging tool position relative to the frame. The system may also include a sensor configured to detect a parameter indicative of a current position of the ground engaging tool relative to the frame. Additionally, the system may include a controller configured to monitor the current position of the ground engaging tool based on measurement signals received from the sensor and identify a time period across which the ground engaging tool is displaced from the predetermined ground engaging tool position.

Abstract: An agricultural implement includes a chassis; an implement frame carried by the chassis; a shank connected to the implement frame, the shank including a shank point configured to break apart soil and a load sensor associated with the shank point which is configured to output shank load signals as the shank point advances through soil; an actuator carried by the chassis and configured to adjust a depth of the shank point; and a controller electrically coupled to the load sensor and the actuator. The controller is configured to receive the shank load signals; generate a load profile from the received shank load signals; analyze the load profile to determine whether the shank point is in a soil compaction layer; and activate the actuator to adjust the depth of the shank point based on the analyzed load profile.

Abstract: An agricultural apparatus includes an agricultural tractor and at least one agricultural implement. The agricultural tractor has at least one tractor controller and the agricultural implement has at least one implement controller. At least one wireless connection is connected to the at least one tractor controller and/or to the at least one implement controller. The agricultural tractor and/or the at least one agricultural implement has at least one adjustable setting controllable by the at least one tractor controller and/or by the at least one implement controller. A multi-purpose handheld wireless device communicates with the tractor controller and/or the implement controller by way of the wireless connection. The multi-purpose handheld wireless device has at least one application that transmits adjustment instructions to the tractor controller and/or to the implement controller to be carried out upon the at least one adjustable setting.

Abstract: A tool system is provided for resisting abrasive wear of a ground-engaging tool of an agricultural implement during a crop production procedure. The tool system may include a tool for engaging an agricultural field while performing crop production procedure and that defines a main segment and a cutting segment having a working edge covered by a nanostructure coating. The cutting segment may include multiple wear zones with multiple working edges, respectively, covered by nanostructure coatings which may have different thicknesses.

Abstract: An agricultural implement for supporting a plurality of gangs of disk blades extending generally laterally relative to a forward travel direction. The implement has carrier frames pivotally connected to wheel assemblies for controlling the height of the carrier frames relative to the ground through hydraulic actuators acting on the wheel assemblies. The hydraulic control unit enables independent and individual control of each actuator. An electronic control unit (ECU) receives displacement signals from the actuators and stores the signals when the agricultural implement is on a reference surface for synchronized set points. Thereafter any deviation from the synchronized set point is corrected.

Abstract: An agricultural implement for supporting a plurality of gangs of disk blades extending generally laterally relative to a forward travel direction. The implement has carrier frames pivotally connected to wheel assemblies for controlling the height of the carrier frames relative to the ground through hydraulic actuators acting on the wheel assemblies. The hydraulic control unit enables independent and individual control of each actuator. An electronic control unit (ECU) receives displacement signals from the actuators and stores the signals when the agricultural implement is on a reference surface for synchronized set points. Thereafter any deviation from the synchronized set point is corrected.

Abstract: A hitch system for automatically hitching a tractor to a trailing implement is provided. The hitch system may allow an operator that is in a cab of the tractor to remotely connect and electrical system and/or a hydraulic system of a tractor an implement to each other and to remotely secure a hitch pin that connects a tongue of the implement to a drawbar of the tractor. The hitch system may include implement and tractor connector bank assemblies that are respectively provided on the implement and tractor. The tractor connector bank assembly may be moveable in multiple directions for allowing the tractor connector bank assembly to be remotely controlled from the cab of the tractor to align and move into engagement with the implement connector bank assembly.

Abstract: A blade sharpening system is provided that includes a sharpening assembly including a sharpener configured to engage a generally circular agricultural implement blade while mounted on the agricultural implement. The blade sharpening system also includes a rail configured to support the sharpening assembly and to facilitate movement of the sharpening assembly along the rail. The blade sharpening system further includes a mounting feature coupled to the rail and configured to engage a structural member of the agricultural implement to support the rail and sharpening assembly.