An agricultural system includes agricultural equipment and a user interface. The agricultural equipment includes a command and control system and an equipment configuration code file. The command and control system, in operation, configures and controls the agricultural equipment based at least in part on the equipment configuration code file. The agricultural equipment comprises a work vehicle or an implement to be carried or towed by a work vehicle. The user interface displays information to, and receive inputs from a user for one or more data fields in the equipment configuration code file for the agricultural equipment. The data fields comprise a user-given name and at least one of a compatible implement, an accessory, or a task for which the agricultural equipment may be configured.

An agricultural system includes agricultural equipment and a user interface. The agricultural equipment includes a command and control system and an equipment configuration code file. The command and control system, in operation, configures and controls the agricultural equipment based at least in part on the equipment configuration code file. The agricultural equipment comprises a work vehicle or an implement to be carried or towed by a work vehicle. The user interface displays information to, and receive inputs from a user for one or more data fields in the equipment configuration code file for the agricultural equipment. The data fields comprise a user-given name and at least one of a compatible implement, an accessory, or a task for which the agricultural equipment may be configured.

A control device for a power machine can be configured to determine an operating temperature of a power machine and to derate one or more electrical actuators of the power machine to limit regenerative charging to the electrical power source. A method of operating a power machine can include controlling one or more electrical actuators, with a control device, to cause an implement of a power machine to fluctuate in orientation over a plurality of cycles, based on receiving an operator input that initiates the fluctuation or detecting an operational condition of the power machine.

An agricultural implement has a hitch frame, a center frame pivotally attached rearward of the hitch frame about a hitch pivot axis. Wing frames are pivotally attached to ends of the center frame and a center actuator is pivots the center and wing frames from a rearward extending operating position to an upward extending transport position. Caster wheels are pivotally mounted on front sides of the wing frames about caster and transport axes. In the operating position, the caster axes are oriented vertically and the transport axes are oriented horizontally, and in the initial transport position, the caster axes are oriented horizontally, perpendicular to the hitch pivot, the transport axes are oriented vertically, and caster wheel actuators pivot the caster wheels 90 degrees about the transport axes to align the caster axes with the hitch pivot axis. The caster wheels support the wing frames in both operating and transport positions.

An agricultural implement has a hitch frame, a center frame pivotally attached rearward of the hitch frame about a hitch pivot axis. Wing frames are pivotally attached to ends of the center frame and a center actuator is pivots the center and wing frames from a rearward extending operating position to an upward extending transport position. Caster wheels are pivotally mounted on front sides of the wing frames about caster and transport axes. In the operating position, the caster axes are oriented vertically and the transport axes are oriented horizontally, and in the initial transport position, the caster axes are oriented horizontally, perpendicular to the hitch pivot, the transport axes are oriented vertically, and caster wheel actuators pivot the caster wheels 90 degrees about the transport axes to align the caster axes with the hitch pivot axis. The caster wheels support the wing frames in both operating and transport positions.

A system for monitoring the wear rates of agricultural implements may include an agricultural implement having ground-engaging tools configured to work a field area, at least one wear sensor configured to generate data indicative of wear of one or more of the ground-engaging tools, and a computing system communicatively coupled to the at least one wear sensor. The computing system may determine a first wear rate of the one or more of the ground-engaging tools based at least in part on the data indicative of the wear of the one or more of the ground-engaging tools and to compare the first wear rate to a threshold wear rate. Additionally, the computing system may perform a control action when a differential between the first wear rate and the threshold wear rate exceeds a wear rate differential threshold.

A system for monitoring the wear rates of agricultural implements may include an agricultural implement having ground-engaging tools configured to work a field area, at least one wear sensor configured to generate data indicative of wear of one or more of the ground-engaging tools, and a computing system communicatively coupled to the at least one wear sensor. The computing system may determine a first wear rate of the one or more of the ground-engaging tools based at least in part on the data indicative of the wear of the one or more of the ground-engaging tools and to compare the first wear rate to a threshold wear rate. Additionally, the computing system may perform a control action when a differential between the first wear rate and the threshold wear rate exceeds a wear rate differential threshold.

An accessory mount comprises: a lateral bar having a first end and a second end opposite the first end; a first arm connected to the first end of the lateral bar and terminating in a distal end; and a second arm pivotally connected to the second end of the lateral bar and terminating in a distal end. The first and second arms of the accessory mount are configured to engage respective frame portions of a mower or other turf or grounds care equipment, and the pivoting or movement of the second arm relative to the lateral bar adjusts a distance between the distal end of the first arm and the distal end of the second arm. A first clamping assembly may be connected to the first arm, and a second clamping assembly may be connected to the second arm to engage the respective frame portions of the article of turf or grounds care equipment.

An accessory mount comprises: a lateral bar having a first end and a second end opposite the first end; a first arm connected to the first end of the lateral bar and terminating in a distal end; and a second arm pivotally connected to the second end of the lateral bar and terminating in a distal end. The first and second arms of the accessory mount are configured to engage respective frame portions of a mower or other turf or grounds care equipment, and the pivoting or movement of the second arm relative to the lateral bar adjusts a distance between the distal end of the first arm and the distal end of the second arm. A first clamping assembly may be connected to the first arm, and a second clamping assembly may be connected to the second arm to engage the respective frame portions of the article of turf or grounds care equipment.

An agricultural implement includes a sensor configured to emit output signals for reflection off of a surface and detect reflections of the output signals as return signals. Furthermore, the agricultural implement includes a computing system configured to control the sensor such that the sensor emits the output signals for reflection off of a calibration device including a base portion and a plurality of projections extending outward from the base portion such that a top surface of the calibration device approximates a surface profile of the field. Moreover, the computing system is configured to receive data indicative of a profile of the top surface of the calibration device from the sensor in a spatial domain. Additionally, the computing system is configured to convert the received data to a frequency domain using a spectral analysis technique and calibrate an operation of the sensor based on the converted data.