In an autonomous traveling unit, a toggle mechanism including a plurality of sliders is provided. In the plurality of sliders, cam followers are provided, respectively. Meanwhile, in a workpiece loading unit, a clamped portion is provided. As a result of the cam followers, which are displaced so as to separate away from each other, entering intersection portions of the clamped portion, the workpiece loading unit is restrained by the autonomous traveling unit.

A robotic work tool system may include a robotic work tool. The robotic work tool may include two front wheels and a chassis. The robotic work tool is characterized in that the two front wheels are arranged on a beam axle that is pivotably arranged to the chassis.

A vehicle has first and second parts with at least one road wheel. The first part pivotally connects to a connecting member at two spaced apart points to pivot about a first axis relative and the second part pivotally connects to the connecting member at two spaced apart points 18 to pivot about a second axis, which is perpendicular to the second axis, intersecting at a pivot point. A first drive shaft rotatably mounts to the first part and extends in a direction perpendicular to a longitudinal axis of the first part, a second drive shaft rotatably mounts to the second part and extends in a direction perpendicular to a longitudinal axis of the second part. The first and second drive shafts connect by a universal joint so that the two shafts to pivot relative to each other about the pivot point.

A robotic vehicle for traversing surfaces is provided. The vehicle is comprised of a chassis supporting a magnetic drive wheel for driving and steering the vehicle and a stabilization mechanism. The magnetic wheel comprises two flux concentrator yokes and an axially magnetized hub extending therebetween. The hub includes a central housing configured to house a sensor probe and enhance the magnetic pull force of the wheel by providing a continuous pathway of high magnetic permeability material for magnetic flux to flow axially through the drive wheel. The stabilization mechanism comprises a front and rear facing support element moveably coupled to the chassis and configured to contact the surface and move symmetrically relative to the chassis thereby maintaining the vehicle and probe normal to the surface and providing stability to the vehicle while traversing surfaces regardless of surface curvature and vehicle orientation.

A robotic vehicle for traversing surfaces is provided. The vehicle is comprised of a front chassis section including a magnetic drive wheel for driving and steering the vehicle and a front support point configured to contact the surface. The vehicle also includes a rear chassis section supporting a follower wheel. The front and rear chassis sections are connected by joints including a hinge joint and a four-bar linkage. The hinge is configured to allow the trailing assembly to move side-to-side while the four-bar linkage allows the trailing assembly to move up and down relative to the front chassis. Collectively, the rear facing mechanism is configured to maintain the follower wheel in contact with and normal to the surface and also maintains the front support in contact with the surface and provides stability and maneuverability to the vehicle while traversing surfaces regardless of surface curvature and vehicle orientation.

An off-highway vehicle has a front chassis portion, a rear chassis portion, a front ground drive system and a rear ground drive system. The front chassis portion has a front axle assembly having a front axle housing and a front axle shaft carrying a front wheel hub. The rear chassis portion has a rear axle assembly including a rear axle housing and a rear axle shaft carrying a rear wheel hub. The front ground drive system includes a front drive wheel mounted to the front wheel hub, a front idler wheel mounted to the front axle housing via a front drive frame member in front of the front drive wheel. The rear ground drive system has a rear drive wheel mounted to the rear wheel hub, a rear idler wheel mounted to the rear axle housing via a rear frame member behind the rear drive wheel.

An off-highway vehicle has a front chassis portion, a rear chassis portion, a front ground drive system and a rear ground drive system. The front chassis portion has a front axle assembly having a front axle housing and a front axle shaft carrying a front wheel hub. The rear chassis portion has a rear axle assembly including a rear axle housing and a rear axle shaft carrying a rear wheel hub. The front ground drive system includes a front drive wheel mounted to the front wheel hub, a front idler wheel mounted to the front axle housing via a front drive frame member in front of the front drive wheel. The rear ground drive system has a rear drive wheel mounted to the rear wheel hub, a rear idler wheel mounted to the rear axle housing via a rear frame member behind the rear drive wheel.

An articulated vehicle including two wheeled sections hinged together in the middle of the vehicle by a universal movement joint enabling relative pivoting about three axes extending at right angles to each other through the center of the vehicle. A hydraulically operated strut and a hydraulically operated cylinder/jack extend between the two vehicle sections. The strut is universally pivoted at its ends to the two vehicle sections to control the relative pivoting of the two vehicle sections while, the cylinder is trunnion mounted to one end and bolted to the other to permit vertical articulation of the vehicle.

A robotic vehicle chassis is provided. The robotic vehicle chassis includes a first chassis section, a second chassis section, and a hinge joint connecting the first and second chassis sections such that the first and second chassis sections are capable of rotation with respect to each other in at least a first direction. The vehicle includes a drive wheel mounted to one of the first and second chassis sections and an omni-wheel mounted to the other of the first and second chassis sections. The omni-wheel is mounted at an angle orthogonal with respect to the drive wheel. The hinge joint rotates in response to the curvature of a surface the vehicle is traversing.

A robotic vehicle chassis is provided. The robotic vehicle chassis includes a first chassis section, a second chassis section, and a hinge joint connecting the first and second chassis sections such that the first and second chassis sections are capable of rotation with respect to each other in at least a first direction. The vehicle includes a drive wheel mounted to one of the first and second chassis sections and an omni-wheel mounted to the other of the first and second chassis sections. The omni-wheel is mounted at an angle orthogonal with respect to the drive wheel. The hinge joint rotates in response to the curvature of a surface the vehicle is traversing.