A method and system for measuring a working height, such as an absolute working height, of a plurality of agricultural attachments using a sensor assembly is disclosed. The sensor assembly includes a sensor and at least one sensor holder. The sensor holder is mounted at mounting positions onto different attachments, with the sensor being reversibly mounted in the sensor holder at the mounting position. The sensor, in a mounted state, records measured data relating to a working height of the agricultural attachment and transmits the measured data to the control assembly. In turn, the control assembly determines the working height of the particular attachment from a calibration data set specific to the mounting position.

A method and system for measuring a working height, such as an absolute working height, of a plurality of agricultural attachments using a sensor assembly is disclosed. The sensor assembly includes a sensor and at least one sensor holder. The sensor holder is mounted at mounting positions onto different attachments, with the sensor being reversibly mounted in the sensor holder at the mounting position. The sensor, in a mounted state, records measured data relating to a working height of the agricultural attachment and transmits the measured data to the control assembly. In turn, the control assembly determines the working height of the particular attachment from a calibration data set specific to the mounting position.

A method and system for regulating a rear power lift of an agricultural production machine in an agricultural combination is disclosed. The agricultural combination includes an agricultural production machine and an agricultural attachment. The agricultural attachment is connected to the agricultural production machine via a rear power lift of the agricultural production machine. The agricultural production machine includes a driver assistance system that regulates machine parameters of the rear power lift using position regulation and/or traction regulation on which a slip control is superimposed. The driver assistance system determines a target slip for slip regulation optimized for position regulation and/or traction regulation depending on at least one existing soil property and at least one existing tire property, and regulates the rear power lift to the optimized target slip.

A method and system for regulating a rear power lift of an agricultural production machine in an agricultural combination is disclosed. The agricultural combination includes an agricultural production machine and an agricultural attachment. The agricultural attachment is connected to the agricultural production machine via a rear power lift of the agricultural production machine. The agricultural production machine includes a driver assistance system that regulates machine parameters of the rear power lift using position regulation and/or traction regulation on which a slip control is superimposed. The driver assistance system determines a target slip for slip regulation optimized for position regulation and/or traction regulation depending on at least one existing soil property and at least one existing tire property, and regulates the rear power lift to the optimized target slip.

The present disclosure relates to a method for adjusting a working depth of a plough implement, the plough implement comprising a plurality of ground engaging tools for penetrating and moving soil and a depth adjustment apparatus configured to adjust a working depth of at least one of the ground engaging tools, wherein the method comprises receiving control-data indicative of at least one of an operation the plough implement or a field condition of a field across which the plough implement is moved; and automatically controlling an operation of the depth adjustment apparatus in a manner that adjusts a working depth of the at least one ground engaging tool on the basis of the control-data received.

The present disclosure relates to a method for adjusting a working depth of a plough implement, the plough implement comprising a plurality of ground engaging tools for penetrating and moving soil and a depth adjustment apparatus configured to adjust a working depth of at least one of the ground engaging tools, wherein the method comprises receiving control-data indicative of at least one of an operation the plough implement or a field condition of a field across which the plough implement is moved; and automatically controlling an operation of the depth adjustment apparatus in a manner that adjusts a working depth of the at least one ground engaging tool on the basis of the control-data received.

A method to prevent drift in an agricultural implement. Drift is when one side of an agricultural implement is further behind or further ahead of the other side of the agricultural implement in a direction of travel. Drift can be controlled by increasing a downforce on the side that is further ahead, decreasing force on the side that is further behind, or a combination of both. The force can be a moment of force.

An agricultural implement system includes a down force cylinder configured to apply a downward force to a row unit, and a depth control cylinder configured to vary a penetration depth of a ground engaging tool of the row unit. The agricultural implement system also includes a valve assembly in fluid communication with the down force cylinder and the depth control cylinder. The valve assembly is configured to automatically adjust the downward force by varying fluid pressure within the down force cylinder based on fluid pressure within the depth control cylinder.

An agricultural implement system includes a down force cylinder configured to apply a downward force to a row unit, and a depth control cylinder configured to vary a penetration depth of a ground engaging tool of the row unit. The agricultural implement system also includes a valve assembly in fluid communication with the down force cylinder and the depth control cylinder. The valve assembly is configured to automatically adjust the downward force by varying fluid pressure within the down force cylinder based on fluid pressure within the depth control cylinder.

A system for detecting material accumulation relative to rotating ground-engaging tools includes an agricultural implement having a frame and first and second ground-engaging tools supported relative to the frame, with the first ground-engaging tool corresponding to a different tool type than the second ground-engaging tool. The system also includes first and second speed sensor configured to provide data indicative of the rotational speeds of the first and second ground-engaging tools, respectively. In addition, the system includes a computing system communicatively coupled to the first and second speed sensors. The computing system is configured to monitor the rotational speeds of the ground-engaging tools based on the data provided by the speed sensors, determine a speed correlation between the rotational speed of the first ground-engaging tool and the rotational speed of the second ground-engaging tool, and determine when the speed correlation differs from a speed correlation threshold associated with the ground-engaging tools.