A method for controlling a power-split gear shift device in a vehicle by providing an electric variator and a transmission with variable gear shift and connecting a drive motor to a traction drive of the vehicle. The electric variator has a compound gear train with at least one first and at least one second electric machine. The method also includes providing a controller for the electric machines for steplessly varying a gear shift of the compound gear train. Upon detection of an external power requirement by an electric consumer, a gear shift region of the transmission with variable gear shift is set to operate the first electric machine in a generator mode and to operate the second electric machine to compensate for an existing power deficit or a power excess relative to an external power demand.

A method for controlling a power-split gear shift device in a vehicle by providing an electric variator and a transmission with variable gear shift and connecting a drive motor to a traction drive of the vehicle. The electric variator has a compound gear train with at least one first and at least one second electric machine. The method also includes providing a controller for the electric machines for steplessly varying a gear shift of the compound gear train. Upon detection of an external power requirement by an electric consumer, a gear shift region of the transmission with variable gear shift is set to operate the first electric machine in a generator mode and to operate the second electric machine to compensate for an existing power deficit or a power excess relative to an external power demand.

A soil apparatus (e.g., seed firmer) includes a locking system. In one embodiment, the soil apparatus includes a lower base portion for engaging in soil of an agricultural field, an upper base portion, and a neck portion having protrusions to insert into the lower base portion of a base and then lock when a region of the upper base portion is inserted into the lower base portion and this region of the upper base portion presses the protrusions to lock the neck portion to the upper base portion.

A soil apparatus (e.g., seed firmer) includes a locking system. In one embodiment, the soil apparatus includes a lower base portion for engaging in soil of an agricultural field, an upper base portion, and a neck portion having protrusions to insert into the lower base portion of a base and then lock when a region of the upper base portion is inserted into the lower base portion and this region of the upper base portion presses the protrusions to lock the neck portion to the upper base portion.

A sensor system that can be used to analyze parts/components associated with agricultural equipment using one or more radio frequency (RF) or microwave frequency signals. For example, the sensor system can be used to analyze a part/component to detect metal fatigue, micro-cracks, thermal stress, defects, deformations, and other possible indicators of overstress and/or failure. The parts/components that can be analyzed are any parts/components associated with or used on agricultural equipment.

A sensor system that can be used to analyze parts/components associated with agricultural equipment using one or more radio frequency (RF) or microwave frequency signals. For example, the sensor system can be used to analyze a part/component to detect metal fatigue, micro-cracks, thermal stress, defects, deformations, and other possible indicators of overstress and/or failure. The parts/components that can be analyzed are any parts/components associated with or used on agricultural equipment.

A system that is able to vary a depth of a row cleaner by adjusting a downforce applied to the row cleaner to promote planting at a desired seed depth and soil moisture.

A system that is able to vary a depth of a row cleaner by adjusting a downforce applied to the row cleaner to promote planting at a desired seed depth and soil moisture.

A control system for a tillage implement includes an emitter configured to direct a beam across a set of disc blades of the tillage implement. An axis of the beam is configured to intersect the set of disc blades at a first position radially offset from a rotational axis of the set of disc blades. The control system also includes a sensor configured to receive the beam associated with the emitter. The control system also includes a controller including a memory configured to store instructions and one or more processors. The controller is configured to receive a signal from the sensor indicative of detection of the beam. The controller is also configured to determine a wear status of the set of disc blades based on the signal.

A control system for a tillage implement includes an emitter configured to direct a beam across a set of disc blades of the tillage implement. An axis of the beam is configured to intersect the set of disc blades at a first position radially offset from a rotational axis of the set of disc blades. The control system also includes a sensor configured to receive the beam associated with the emitter. The control system also includes a controller including a memory configured to store instructions and one or more processors. The controller is configured to receive a signal from the sensor indicative of detection of the beam. The controller is also configured to determine a wear status of the set of disc blades based on the signal.