In one aspect, a system for determining field characteristics of a field across which an implement is being moved may include a tine configured to engage a surface of soil within the field. The system may also include a sensor configured to detect a parameter indicative of a load being applied to the ground engaging tine by the soil. Furthermore, the system may include a controller communicatively coupled to the sensor, with the controller being configured to determine a field characteristic of the field based on measurement signals received from the sensor.

In one aspect, a system for determining field characteristics of a field across which an implement is being moved may include a tine configured to engage a surface of soil within the field. The system may also include a sensor configured to detect a parameter indicative of a load being applied to the ground engaging tine by the soil. Furthermore, the system may include a controller communicatively coupled to the sensor, with the controller being configured to determine a field characteristic of the field based on measurement signals received from the sensor.

An agricultural working device, such as a mulcher, is improved with a working rotor which is driven by a drive shaft and a cutting rail with a cutting edge which can be directed towards the working rotor. Sensors for acquiring parameters of working rotor and/or cutting rail are provided. An electronic control apparatus is provided with at least one encoder to set the cutting rail. A method for setting the position of a cutting rail of a working device, such as a mulcher, relative to a working rotor, is configured in such a way that the rotational speed of a drive shaft and the rotational speed of the working rotor are measured and compared with one another. When a ratio of the rotational speeds differs by a predefined threshold, a change in the position of the cutting rail is brought about.

An agricultural working device, such as a mulcher, is improved with a working rotor which is driven by a drive shaft and a cutting rail with a cutting edge which can be directed towards the working rotor. Sensors for acquiring parameters of working rotor and/or cutting rail are provided. An electronic control apparatus is provided with at least one encoder to set the cutting rail. A method for setting the position of a cutting rail of a working device, such as a mulcher, relative to a working rotor, is configured in such a way that the rotational speed of a drive shaft and the rotational speed of the working rotor are measured and compared with one another. When a ratio of the rotational speeds differs by a predefined threshold, a change in the position of the cutting rail is brought about.

The active coulter system includes a pivotable support structure that vertically adjusts the position of an active coulter component to compensate for changes in the contour of a target field. In the preferred embodiment, a proximity sensor and an associated controller are in electronic communication with a linear actuator assembly. Based on data from the proximity sensor, the controller sends electronic instructions to the linear actuator assembly to automatically move the active coulter component vertically. The system also optionally includes a torque/speed sensor that can operate independently to control the torque and/or power supplied to the active coulter component, or the sensor can interface with the controller and anticipate changes in power needs and increase/decrease power before the operation of the active coulter component is affected.

The active coulter system includes a pivotable support structure that vertically adjusts the position of an active coulter component to compensate for changes in the contour of a target field. In the preferred embodiment, a proximity sensor and an associated controller are in electronic communication with a linear actuator assembly. Based on data from the proximity sensor, the controller sends electronic instructions to the linear actuator assembly to automatically move the active coulter component vertically. The system also optionally includes a torque/speed sensor that can operate independently to control the torque and/or power supplied to the active coulter component, or the sensor can interface with the controller and anticipate changes in power needs and increase/decrease power before the operation of the active coulter component is affected.

A system for de-plugging rotating ground engaging tools of an agricultural implement includes first and second ground engaging tools spaced apart from each other such that a flow gap is defined between the tools, a rotational actuator configured to rotationally drive the tools about a rotational axis, a sensor configured to capture data indicative of material accumulation within the flow gap defined between the tools, and a controller configured to determine when the tools are experiencing a plugged condition based on the data received from the sensor. Additionally, in response to the determination that the tools are experiencing the plugged condition, the controller is further configured to control an operation of the rotational actuator such that the tools are rotationally driven while such tools are disposed at a working position relative to a soil surface of a field.

A system for de-plugging rotating ground engaging tools of an agricultural implement includes first and second ground engaging tools spaced apart from each other such that a flow gap is defined between the tools, a rotational actuator configured to rotationally drive the tools about a rotational axis, a sensor configured to capture data indicative of material accumulation within the flow gap defined between the tools, and a controller configured to determine when the tools are experiencing a plugged condition based on the data received from the sensor. Additionally, in response to the determination that the tools are experiencing the plugged condition, the controller is further configured to control an operation of the rotational actuator such that the tools are rotationally driven while such tools are disposed at a working position relative to a soil surface of a field.

A tillage implement comprising a frame operably supporting tillage tools, and a soil monitoring system comprising instrumentation operably supported from the frame and disposed to detect soil criteria before, after, or before and after the soil is tilled by the tillage tools. The soil criteria detected is at least one of surface residue criteria, soil clod size criteria, and soil shatter criteria.

A tillage implement comprising a frame operably supporting tillage tools, and a soil monitoring system comprising instrumentation operably supported from the frame and disposed to detect soil criteria before, after, or before and after the soil is tilled by the tillage tools. The soil criteria detected is at least one of surface residue criteria, soil clod size criteria, and soil shatter criteria.