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 autonomous system for transporting an item from a first location to a second location includes an autonomous vehicle and a trailer. The autonomous vehicle includes a compartment, a vehicle sensor, a vehicle drive mechanism, a vehicle power source, and a vehicle control module for controlling the vehicle drive mechanism. The trailer includes a hitch for connecting the trailer to the autonomous vehicle, an electrical system, a trailer sensor in communication with the electrical system, a trailer power source in communication with the electrical system, a storage space, and a mechanism for autonomously transferring the item from the storage space into the compartment of the autonomous vehicle. The autonomous vehicle and trailer are configured to transport the item to the first location, the trailer is configured to transfer the item to the autonomous vehicle, and the autonomous vehicle is configured to transport the item to the second location.

Disclosed is a mobile articulated crane having a boom for carrying a load when the crane is stationary and while the crane is mobile. The boom has an end for engaging with a load and an opposed end. The crane further comprises a counterweight attached to the boom at or close to the opposed end of the boom. A rear body of the crane can comprise first and second rear axles, each for supporting the rear body on the ground. The first rear axle can be arranged to be displaced relative to the second rear axle such that wheels of the first rear axle selectively engage or disengage with the ground.

A robotic vehicle may include a first chassis platform including a first wheel assembly, a second chassis platform including a second wheel assembly where the first and second chassis platforms are spaced apart from each other, and a combination linkage operably coupling the first and second chassis platforms. The combination linkage may be operably coupled to the first chassis platform via a first link and is operably coupled to the second chassis platform via a second link. The combination linkage employs at least two different coupling features to operably couple the first and second chassis platforms. The at least two different coupling features include at least any two among a fixed attachment, an attachment that enables rotation about a turning axis, and an attachment that enables pivoting about a pivot axis that is substantially perpendicular to the turning axis.

A robotic vehicle may include a first chassis platform including a first wheel assembly, a second chassis platform including a second wheel assembly where the first and second chassis platforms are spaced apart from each other, and a combination linkage operably coupling the first and second chassis platforms. The combination linkage may be operably coupled to the first chassis platform via a first link and is operably coupled to the second chassis platform via a second link. The combination linkage employs at least two different coupling features to operably couple the first and second chassis platforms. The at least two different coupling features include at least any two among a fixed attachment, an attachment that enables rotation about a turning axis, and an attachment that enables pivoting about a pivot axis that is substantially perpendicular to the turning axis.

Methods and apparatus for verifiable inspection operations are described. An example apparatus may have an inspection description circuit to interpret an inspection definition value and a payload status circuit to provide a payload identification value in response to at least one of a payload specific configuration or signals from a payload. The example apparatus may also have an inspection integrity circuit to determine an inspection description value in response to the inspection definition value and the payload identification value and an inspection reporting circuit to communicate the inspection description value to an external device.

Methods and apparatus for verifiable inspection operations are described. An example apparatus may have an inspection description circuit to interpret an inspection definition value and a payload status circuit to provide a payload identification value in response to at least one of a payload specific configuration or signals from a payload. The example apparatus may also have an inspection integrity circuit to determine an inspection description value in response to the inspection definition value and the payload identification value and an inspection reporting circuit to communicate the inspection description value to an external device.

An electric truck that travels by electric power supplied from a battery includes a ladder frame including a pair of side rails, where the side rails face each other in a vehicle width direction, and a power supply unit including the battery, where the power supply unit is disposed between the side rails and is connected to the side rails. The side rails each have flanges having a predetermined width provided at each edge of a respective web. At least one of the flanges at a location facing a corner of the power supply unit as viewed in the vehicle width direction has a narrowed flange portion having a width smaller than the predetermined width.

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 system for controlling propulsion of a machine is described. The system includes a first sensor for generating a first signal indicative of an articulation angle of the machine. The system also includes at least one transmission power unit coupled to front and rear powertrains of the machine. The system further includes a control module in communication with the first sensor and the at least one transmission power unit. The control module is configured to receive the first signal from the first sensor. The control module is also configured to control the at least one transmission power unit to provide power to at least one of the front powertrain or the rear powertrain, based on the articulation angle of the machine.