A method and system for planning an optimized soil cultivation process of a field for anf agricultural combination is disclosed. The agricultural combination includes an agricultural production machine and a soil cultivating agricultural attachment. A planning control assembly is used to determine recommended actions for the soil cultivation process with an expert model using soil data of the field, wherein the soil data of the field is location-dependent.

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.

A method and system for collecting agricultural measured data in an agricultural production machine that is combined with at least one agricultural attachment for fieldwork is disclosed. A sensor assembly is provided that has a sensor and a control assembly. The sensor may be integrated in combinations comprising (or consisting of) an agricultural production machine and a plurality of agricultural attachments. The sensor records measured data relating to at least one work quality parameter of the particular attachment and transmits it to the control assembly. In turn, the control assembly generates a common data set in a standardization routine from the measured data relating to the different attachments.

A method and system for collecting agricultural measured data in an agricultural production machine that is combined with at least one agricultural attachment for fieldwork is disclosed. A sensor assembly is provided that has a sensor and a control assembly. The sensor may be integrated in combinations comprising (or consisting of) an agricultural production machine and a plurality of agricultural attachments. The sensor records measured data relating to at least one work quality parameter of the particular attachment and transmits it to the control assembly. In turn, the control assembly generates a common data set in a standardization routine from the measured data relating to the different attachments.

An agricultural work system has an agricultural work machine to which at least one mounted implement can be fitted via at least one implement interface. A work machine configuration is associated with the work machine, and a mounted implement configuration is associated with the mounted implement. A drive unit is provided which acts via a drivetrain on ground engaging elements, particularly on tires. A system control and a control/display unit associated with the work machine are provided. It is proposed that the system control is adapted to determine the mounted implement configuration, to calculate the implement interface load transmitted via the implement interface based on the determined mounted implement configuration, and to evaluate and/or optimize the work machine configuration based on the calculated implement interface load.

A work vehicle includes a travelling vehicle body; a work machine mounted on a rear portion of the travelling vehicle body to be capable of being lifted and lowered; a control unit for controlling lifting and lowering of the work machine; and a rear sensor provided on the rear portion of the travelling vehicle body and configured to detect an object present behind the travelling vehicle body. The control unit may be configured to set a regulation height based on a height where the rear sensor detects the work machine while the work machine is lifted and then regulate lifting of the work machine during work in such a manner that a height of the work machine is kept less than or equal to the regulation height.

A drawn agricultural implement includes a main frame and a plurality of ground engaging units supporting the main frame from a ground surface. A working unit is supported from the main frame and configured to engage crops as the implement moves in a forward direction across the ground surface. A draft tongue extends from the main frame for attachment to a tractor. A camera having a field of view is mounted on at least one of the draft tongue, the main frame and the working unit. The camera is movable relative to the at least one of the draft tongue, the main frame and the working unit to reposition the field of view.

A system for monitoring the operational status of ground-engaging tools of an agricultural implement. The system includes a frame and an assembly including an attachment structure configured to be coupled to the frame and a ground-engaging tool pivotably coupled to the attachment structure at a pivot point. The system further includes a shear pin at least partially extending through both the attachment structure and ground-engaging tool to prevent pivoting of the ground-engaging tool about the pivot point. Additionally, the system includes a sensor configured to detect a load applied through a pivot member extending through at least one of the frame or assembly at any pivot point between the frame and the ground engaging tool. The system further includes a controller, communicatively coupled to the sensor, configured to determine a change in the working condition of the shear pin based on the detected load applied through the pivot member.

A system for monitoring the operational status of ground-engaging tools of an agricultural implement. The system includes a frame and an assembly including an attachment structure configured to be coupled to the frame and a ground-engaging tool pivotably coupled to the attachment structure at a pivot point. The system further includes a shear pin at least partially extending through both the attachment structure and ground-engaging tool to prevent pivoting of the ground-engaging tool about the pivot point. Additionally, the system includes a sensor configured to detect a load applied through a pivot member extending through at least one of the frame or assembly at any pivot point between the frame and the ground engaging tool. The system further includes a controller, communicatively coupled to the sensor, configured to determine a change in the working condition of the shear pin based on the detected load applied through the pivot member.