An agricultural tillage system including a carriage frame assembly, a plurality of tillage elements coupled to the carriage frame assembly, an actuator and a residue reactive system. The actuator is moveably coupled to the tillage elements, and is directly in control of a soil contact depth of the tillage elements. The residue reactive system is in controlling communication with the at least one actuator. The residue reactive system reduces the soil contact depth of the tillage elements when the residue mass on the soil is reduced and/or the slope of the soil is above a predetermined value.

An agricultural tillage system including a carriage frame assembly, a plurality of tillage elements coupled to the carriage frame assembly, an actuator and a residue reactive system. The actuator is moveably coupled to the tillage elements, and is directly in control of a soil contact depth of the tillage elements. The residue reactive system is in controlling communication with the at least one actuator. The residue reactive system reduces the soil contact depth of the tillage elements when the residue mass on the soil is reduced and/or the slope of the soil is above a predetermined value.

A harrow apparatus comprising an implement frame and a harrow section attached to a mounting assembly extending rearward from the implement frame such that the harrow section engages the ground surface. The mounting assembly is movable upward and downward to move the harrow section down and up. The mounting assembly comprises a beam extending rearward above the harrow frame, and front and rear arms pivotally attached at upper ends thereof to corresponding front and rear beam pivot axes located on the beam. The front arm slopes downward and rearward to a lower end thereof that is pivotally attached to the harrow frame at a front frame pivot axis, and the rear arm slopes downward and forward to a lower end thereof that is pivotally attached to the harrow frame at a rear frame pivot axis located rearward of the front frame pivot axis.

A mobile machine includes a frame and a set of frame support elements supporting the frame. A set of ground engaging elements is mounted to the frame and movable relative to the wheels to change a depth of engagement of the ground engaging elements with the ground over which the mobile machine travels. At least one actuator drives movement of the set of ground engaging elements relative to the frame. A ground sensor is operably coupled to the mobile machine and configured to provide a ground distance signal. Ground engaging element height adjustment logic is configured to receive the ground distance signal and provide a control output to the at least one actuator to generate a height value of the ground engaging elements relative to ground.

A mobile machine includes a frame and a set of frame support elements supporting the frame. A set of ground engaging elements is mounted to the frame and movable relative to the wheels to change a depth of engagement of the ground engaging elements with the ground over which the mobile machine travels. At least one actuator drives movement of the set of ground engaging elements relative to the frame. A ground sensor is operably coupled to the mobile machine and configured to provide a ground distance signal. Ground engaging element height adjustment logic is configured to receive the ground distance signal and provide a control output to the at least one actuator to generate a height value of the ground engaging elements relative to ground.

An agricultural machine includes a frame member; a toolbar coupled to the frame member parallel to the frame member; a row unit coupled to the toolbar; and an actuator coupled between the frame member and the toolbar, the actuator configured to rotate the toolbar based on a sensed position of the toolbar. Related methods are also disclosed.

An agricultural machine includes a frame member; a toolbar coupled to the frame member parallel to the frame member; a row unit coupled to the toolbar; and an actuator coupled between the frame member and the toolbar, the actuator configured to rotate the toolbar based on a sensed position of the toolbar. Related methods are also disclosed.

A system for a row unit of a planting implement includes a frame operably coupled with a toolbar. One or more ground-engaging tools can be operably coupled with the frame. A depth adjustment system includes one or more actuators and a sensor system configured to capture data indicative of a soil characteristic. A computing system is communicatively coupled to the one or more actuators and the sensor system. The computing system is configured to receive the data indicative of the soil characteristic, determine a probability of a penetration variation of the one or more ground-engaging tools relative to a respective depth range for each of the one or more ground-engaging tools, and perform a control action based at least in part on the probability deviating from a defined threshold.

A system for a row unit of a planting implement includes a frame operably coupled with a toolbar. One or more ground-engaging tools can be operably coupled with the frame. A depth adjustment system includes one or more actuators and a sensor system configured to capture data indicative of a soil characteristic. A computing system is communicatively coupled to the one or more actuators and the sensor system. The computing system is configured to receive the data indicative of the soil characteristic, determine a probability of a penetration variation of the one or more ground-engaging tools relative to a respective depth range for each of the one or more ground-engaging tools, and perform a control action based at least in part on the probability deviating from a defined threshold.

A system for detecting the levelness of ground engaging tools of a tillage implement including an agricultural implement including a frame and tool assemblies supported relative to the frame. The tool assemblies each include a toolbar coupled to the frame and one or more ground engaging tools coupled to the toolbar. The system further includes sensors coupled to two of the tool assemblies and configured to capture data indicative of a load acting on the one or more ground engaging tools of the tool assemblies. Additionally, the system includes a controller configured to monitor the data received from the sensors and compare at least one monitored value associated with the load acting on the ground engaging tool(s) of each of the tool assemblies. Moreover, the controller is further configured to identify the ground engaging tool(s) are not level when the monitored value(s) differ by a predetermined threshold value.