The vehicle includes: a chassis which includes a front cross-member and a rear cross-member; a nacelle receiving a person or a load, pivotally mounted relative to the central part of the cross-members about a substantially longitudinal hinge axis, the center of gravity of the nacelle being situated below said hinge axis; a front train and a rear train, each including two movement supports on the ground, each movement support being connected to the end part of the corresponding cross-member by a connecting system; the cross-members, situated in the upper part of the nacelle, being separate pieces linked together only by the nacelle, via the hinge axis, so as to be able to pivot about the hinge axis independently of one another.

A camber adjustment apparatus is provided for alignment of a vehicle wheel. The camber adjustment apparatus includes: a plate member configured to be bolted to the vehicle wheel; an adjuster plate member coupled to a bottom surface of the plate member and comprising a first end and a second end; an adjuster bolt coupled to the first end and the second end of the adjuster plate member; and an adjusting body movably coupled to the adjuster bolt and at least partially disposed between the first end and the second end of the adjuster plate member. The adjusting body is configured so that rotation of the adjuster bolt moves the adjusting body between the first end and the second end of the adjuster plate member such that the plate member is adjusted to a predetermined camber.

A system for providing an interactive inspection map of an inspection surface inspected by an inspection robot includes an inspection circuit structured to interpret inspection data of the inspection surface from the inspection robot and a user interaction circuit structured to interpret a user focus value from a user device. The user focus value includes an activation state value. The system further includes an inspection visualization circuit structured to provide the interactive inspection map to the user device in response to the user focus value. The interactive inspection map is based on the inspection data. Also, the system includes an inspection data validation circuit that determines an inspection data validity description of the inspection data. The inspection data validity description is provided as a display layer on the interactive inspection map to indicate whether the inspection data is valid.

A three-wheeled vehicle may include one rear wheel and two front wheels coupled to a tiltable chassis, such that tilting of the chassis causes a corresponding tilting of the three wheels. The tiltable chassis includes a tiltable body coupled to a non-tilting frame by a pair of rotatable joints, such that the tiltable body is configured to rotate relative to the frame. A fore-and-aft connecting beam of the tiltable body extends beneath the frame to accommodate a battery compartment or other storage on top of the frame. A front tower extends upward from a front end of the connecting beam, above the frame, to couple to a tilt linkage and seat post of the vehicle. A rear tower extends upward from a rear end of the connecting beam to retain the rear wheel.

An inspection robot, including, a multi-sensor sled carriage including a plurality of sleds arranged on the multi-sensor sled carriage, each one of the plurality of sleds including a sensor opening, an acoustic inspection sensor coupled to the corresponding sensor opening; where a width of the multi-sensor sled carriage and a radial position of the plurality of sleds are configured to accommodate an inspection surface including a pipe outer diameter; a plurality of acoustic inspection sensors coupled to the sensor opening of the plurality of sleds.

A system for providing an interactive inspection map of an inspection surface inspected by an inspection robot includes an inspection circuit structured to interpret inspection data of the inspection surface from the inspection robot and a user interaction circuit structured to interpret a user focus value from a user device. The user focus value includes an activation state value. The system further includes an inspection visualization circuit structured to provide the interactive inspection map to the user device in response to the user focus value. The interactive inspection map is based on the inspection data. Also, the system includes an inspection data validation circuit that determines an inspection data validity description of the inspection data. The inspection data validity description is provided as a display layer on the interactive inspection map to indicate whether the inspection data is valid.

A system includes an inspection robot comprising a main body and at least one payload; a plurality of arms, where each of the plurality of arms is pivotally mounted to the at least one payload to rotate around respective ones of a plurality of axes while the inspection robot traverses an inspection surface in a direction of travel, and where at least one of the plurality of axes is in the direction of travel; a plurality of sleds mounted to the plurality of arms; a plurality of inspection sensors coupled to the plurality of sleds such that each sensor is operationally couplable to the inspection surface; and where the plurality of sleds are distributed horizontally at adjustable positions spaced apart from each other across the at least one payload to inspect the inspection surface at a selected horizontal resolution.