A vehicle includes a chassis, an axle pivotally coupled to the chassis such that the axle can tilt from side to side relative to the chassis, a tilt-angle sensor configured to detect a tilt angle of the axle relative to the chassis, and steerable hubs carried by the axle. Each hub is configured to rotate about steering axes relative to the axle, and a steering-angle sensor is configured to detect a steering angle of at least one hub relative to the axle. A control system limits a maximum steering angle of the hubs based at least in part on a size of tires or tracks carried by the steerable hubs and the detected tilt angle of the axle. A method includes detecting a tilt angle of the axle relative to the chassis and limiting the maximum steering angle of the hubs.

One or more information maps are obtained by an agricultural work machine. The one or more information maps map one or more agricultural characteristic values at different geographic locations of a field. An in-situ sensor on the agricultural work machine senses an agricultural characteristic as the agricultural work machine moves through the field. A predictive map generator generates a predictive map that predicts a predictive agricultural characteristic at different locations in the field based on a relationship between the values in the one or more information maps and the agricultural characteristic sensed by the in-situ sensor. The predictive map can be output and used in automated machine control.

A work vehicle may include a load sensor, an engine, a drive train driven by the engine and a track system including at least one track. The track system is connected to the drive train. The work vehicle may further comprise a temperature sensor configured to sense a temperature and a vehicle control system configured to receive the sensed temperature and a vehicle load from the load sensor. The vehicle control system is configured to output a work speed vehicle alert based upon a combination of the temperature sensed by the temperature sensor and the vehicle load sensed by the load sensor.

A header for an agricultural harvester is disclosed. The header comprises a frame, a cooler assembly support by the frame for cooling a hydraulic system of the header, and a hydraulic system. The cooler assembly includes an air pre-cleaner for receiving air and outputting a flow of air, a rotary fan downstream the air pre-cleaner, and a heat exchanger downstream and in fluid communication with a first air output of the rotary fan. The rotary fan includes an air intake in fluid communication with the air pre-cleaner for receiving the flow of air, a first air output in fluid communication with the air intake, and a second air output in fluid communication with the air intake and spaced from the first air output. The hydraulic system is downstream the heat exchanger and receives an output flow of air from the cooler assembly.

An air management assembly for a work machine, the air management assembly having a cooling orifice defined in a panel, a cooling fan generating a cooling airflow through the cooling orifice to a cooling package, at least one fixed screen positioned along an intake orifice, and a first baffle positioned at least partially between the cooling orifice and the intake orifice. Wherein, the first baffle directs the cooling airflow partially across the fixed screen to clear the fixed screen of debris.

A work vehicle including a body, a cooling system with one or more coolers, and a fan disposed adjacent to the coolers. A louver system is disposed adjacently to an inlet of the vehicle body. The louver system includes a first actuator operatively connected to a first plurality of slats and a second actuator operatively connected to a second plurality of slats. A first sensor operatively connected to a first cooler is configured to identify a first temperature of the first cooler and to generate a signal responsive to the identified first temperature. A second sensor operatively connected to a second cooler is configured to identify a second temperature of the second cooler and to generate a signal responsive to the identified second temperature. A position of the first plurality and second plurality of slats is determined respectively by the first and second temperatures.

Cooling and debris mitigation systems for use with work vehicle powertrains include a pressurized air source, a plurality of impingement outlets positioned proximate the work vehicle powertrain, and a flow network fluidly coupling the pressurized air source to the impingement outlets. A first vortex tube is positioned in the flow network and configured to separate pressurized airflow received from the pressurized air source into a hot stream and a reduced temperature stream. The first vortex tube includes a vortex tube inlet fluidly coupled to the pressurized air source, an exhaust port through which the hot stream is discharged, and a nozzle through which the reduced temperature stream is discharged. The reduced temperature stream impinges upon at least one of the targeted exterior regions of the work vehicle powertrain to provide cooling thereto and reduce debris accumulation thereon.

A work vehicle including a floor, a forward pedal arm, a reverse pedal arm, a forward rotation shaft, and a reverse rotation shaft. The floor has a first insertion hole and a second insertion hole. The forward pedal arm is placed in the first insertion hole and provided with a forward pedal. The reverse pedal arm is placed in the second insertion hole and provided with a reverse pedal. The forward rotation shaft serves as a rotation shaft of the forward pedal arm, and is oriented so that an outer end thereof is directed toward the rear of a vehicle body of the work vehicle. The reverse rotation shaft serves as a rotation shaft of the reverse pedal arm, and is oriented so that an outer end thereof is directed toward the rear of the vehicle body.

The disclosure relates to a steering control system useful for providing stable control during high-speed operation of harvesters, such as self-propelled windrowers. The steering control system utilizes a sensor for detecting and regulating a position of a single steering cylinder associated with a first caster, a damper being free of sensing and providing passive damping to the second caster.

A vehicle includes a rear steering system and a front differential hydraulic drive system. A first front drive control valve is operable to output a defined fluid flow in response to a steering command input. A second front drive control valve is operable to selectively divert a portion of the defined fluid flow output from the first front drive control valve. When the vehicle is operating in a pre-defined condition, a steering controller may control the second front drive control valve to divert a portion of the defined fluid flow from the first front drive control valve to define a reduced fluid flow, which is communicated to the front differential hydraulic drive system, to reduce a steering ratio of the front differential hydraulic drive system relative to the rear steering system, to desensitize steering provided by the front differential hydraulic drive system.