A grading machine includes a machine body, a grading blade, and a control system. The control system is configured to automatically set at least one machine parameter of the grading blade based on a determined location of the grading machine and automatically set a mode of operation of the grading machine based on a determined location of the grading machine.

A drawbar assembly for a motor grader is provided. The drawbar assembly includes a yoke plate, a backbar, a drawbar tube, and a sleeve. The yoke plate includes a first surface and a second surface. The backbar is attached to the first surface of the yoke plate. The backbar includes a tube facing surface. The drawbar tube includes a first end and a second end. The drawbar tube is attached to the first surface of the yoke plate, defining a clearance between the first end of the drawbar tube and the tube facing surface of the backbar. The sleeve encloses at least a portion of the drawbar tube. The sleeve includes a backbar attachment portion and a yoke attachment portion. The backbar attachment portion is attached to the tube facing surface of the backbar and the yoke attachment portion is attached to the first surface of the yoke plate.

A walking beam assembly includes a support beam and a mount member configured to mount the support beam on a vehicle chassis. Furthermore, the assembly includes a gear assembly that is supported proximate an end of the support beam. The gear assembly includes a gear train and a gear housing. The gear train is operably coupled to a wheel hub. The gear housing substantially encloses the gear train. Moreover, the walking beam assembly includes an input drive assembly with at least one movable part configured to deliver an input torque from the vehicle engine to the gear train. The input drive assembly includes an input drive housing that substantially encloses the at least one movable part. The input drive housing is attached to the gear housing such that an interior of the input drive housing is in fluid communication an interior of the gear housing.

A vehicle walking beam assembly includes a support beam and a mount member configured to rotatably mount the support beam on the chassis. A gear assembly with a gear train and a gear housing is supported by the support beam. The gear train includes a gear with a first journal surface, and the housing includes a second journal surface. The walking beam assembly additionally includes an input drive assembly that delivers input torque from the engine to the gear train. Moreover, the walking beam assembly includes a reaction member connected to one of the gear housing and the gear of the gear train. The reaction member is configured to transfer a reaction force between the chassis and the one of the gear housing and the gear of the gear train as the first journal surface journals on the second journal surface.

Methods and apparatus to track a blade are disclosed. A disclosed example apparatus includes a blade that is pivotable, first and second optical targets operatively coupled to the blade, and a first camera for collecting first imaging data of the first optical target within a first field of view. The example apparatus also includes a second camera for collecting second imaging data of the second optical target within a second field of view. The example apparatus also includes a selector to select at least one of the first or second imaging data, and a processor to determine an orientation of the blade based on the selected imaging data.

A control system is disclosed for use with a machine. The control system may have a first blade mountable to the machine and configured to engage a ground surface below the machine, and at least a first actuator configured to move the first blade. The control system may also have a second blade mountable to the machine and configured to engage the ground surface below the machine, and at least a second actuator configured to move the second blade. The control system may additionally have a controller in communication with the at least a second actuator. The controller may be configured to determine a first position of the first blade, and to automatically cause the at least a second actuator to move the second blade to a second position based on the first position of the first blade.

A mobile construction equipment includes: a blade that is movable with respect to the mobile construction equipment, the blade imparting at least one cross slope on a surface on which the mobile construction equipment is operating; and a controller for receiving at least a first target cross slope, a second target cross slope, and at least one input, and, based on the at least one input, transitioning the blade from a first blade position to impart the first target cross slope on the surface to a second blade position to impart the second target cross slope on the surface.

An interchangeable operator interface system for a work vehicle has at least one controller, at least one operator interface device having a plurality of controls, and at least one interface device docking arrangement. The docking arrangement removably mounts different interface devices to alternatively physically connect them to the work vehicle and operatively couple them to the controller. Different operator interface devices have at least one common control that operates in a different mode of operation and/or in a different physical layout on the associated operator interface device. The controller is configured to effect an associated common change in state of an associated component of the work vehicle upon receiving a control input from the different common controls.

A coordinated multi-vehicle grade control system and method includes receiving, by a first controller onboard a first work vehicle, a first grade control signal. The method and system also include receiving, by a second controller onboard a second work vehicle, a second grade control signal. Additionally, the method and system include orienting, by a first actuator of the first work vehicle, the first grading implement with respect to the first work vehicle according to the first grade control signal. Furthermore, the method and system include orienting, by a second actuator of the second work vehicle, the second grading implement with respect to the second work vehicle according to the second grade control signal. The second grade control signal is based, at least in part, on the first grade control signal to coordinate the orientation of the first grading implement with respect to the second grading implement along the grading pass.

A moldboard rail cleaner for removing debris from a rail of a work machine having a tilt frame housing defining a first cavity. The work machine has a wear insert positioned within the first cavity and adapted to slide along the rail as the rail moves along a rail axis. Further, a sub-housing may be coupled to the tilt frame housing and define a second cavity. Finally, a wiper is disposed at least partially within the second cavity, the sub-housing configured to bias the wiper into contact with the rail.