A rotary pivot arm positioning assembly for a paving, texturing, or curing machine allows the machine to automatically transition from an operational orientation to a transport orientation without manual repositioning or disconnection of its components. The assembly includes a pivot arm coupled to both the front and aft ends of an end frame by a helical actuator, slew gear drive or other rotary actuator. The rotary actuator articulates each pivot arm, as well as the adjustable leg and steerable crawler connected to the pivot arm, through at least a 90-degree range. The end frame may be fixed to the left or right end of the machine. The assembly may additionally include a second helical actuator, slew gear drive or rotary actuator connecting each steerable crawler to the adjustable leg and configured to rotate the steerable crawler through a full 360 degrees.

A system for extraction of a pool cleaning robot from a pool, the system may include a pool cleaning robot interface that is arranged to be coupled to a pool cleaning robot during an exit process during which the pool cleaning robot is extracted from the pool; and a pool cleaning robot manipulator that is coupled to the pool cleaning robot interface, wherein the pool cleaning robot manipulator is arranged to move the pool cleaning robot interface between a first and second portion; wherein when the pool cleaning robot interface is at the first position and is coupled to the pool cleaning robot, the pool cleaning robot is within the pool; wherein when the pool cleaning robot interface is at the second position and is coupled to the pool cleaning robot, the pool cleaning robot is positioned outside the pool.

A drive system includes a main track frame adapted to be coupled with the associated tracked vehicle, a sprocket carrier, and a gear assembly operable to communicate rotational power from an associated input driving member to the sprocket carrier for driving the sprocket carrier relative to the main track frame. The main track frame includes an inboard support member, and an outboard member. The inboard and outboard support members are spaced apart relative to each other defining a gap therebetween. The sprocket carrier spans the gap and is rotatably carried by the inboard and outboard support members, and is adapted to couple with the associated sprocket of the associated tracked work vehicle. The gear assembly may be a planetary gear system. The planetary gear system may be disposed in the gap between the inboard and outboard support members. The planetary gear system may be disposed in the sprocket carrier.

A drive system includes a main track frame adapted to be coupled with the associated tracked vehicle, a sprocket carrier, and a gear assembly operable to communicate rotational power from an associated input driving member to the sprocket carrier for driving the sprocket carrier relative to the main track frame. The main track frame includes an inboard support member, and an outboard member. The inboard and outboard support members are spaced apart relative to each other defining a gap therebetween. The sprocket carrier spans the gap and is rotatably carried by the inboard and outboard support members, and is adapted to couple with the associated sprocket of the associated tracked work vehicle. The gear assembly may be a planetary gear system. The planetary gear system may be disposed in the gap between the inboard and outboard support members. The planetary gear system may be disposed in the sprocket carrier.

Vehicles, systems and methods for providing articulating two section vehicles with tracks, and a front body attached superstructure with telescopic forklift, for use on all terrain condition applications. The vehicle can include front and rear track assemblies that can tilt up and down while traveling over different ground surfaces. Each of the track assemblies can have rotatable articulating/oscillating track wheels which can traverse different contoured surfaces. The right and left tracks on both the front and rear track assemblies can separately extend outward and inward from underneath the vehicles to add stability to the vehicles. The cab can be raised and lowered to add greater visibility for the operator. Hydraulics can be used for raising and lowering the extendable boom and operator cab, as well as controlling the body articulating hinge, the articulating tracks and the tilting controls for the front track assembly.

Disclosed are various embodiments, aspects and features an oscillating track system that includes an oscillating track lock subsystem. The oscillating track system may include a track operable to rotate around a housing structure that is configured to receive an axle. While in operation, i.e. while the track is being rotated around the housing, the oscillating track system may be able to oscillate about the axle and, in doing so, incline or decline to accommodate undulating terrain. Advantageously, when stopped, the degree to which the oscillating track system has oscillated around the axle may be locked in place via an oscillating track lock subsystem comprised within the oscillating track system, thereby providing stability to the heavy equipment that includes the oscillating track system.

The invention relates to a forest machine, comprising a chassis having a first chassis and a second chassis pivoted consecutively by a central pivot, first sets of wheels arranged in connection with the first chassis, an engine fitted in connection with the first chassis, a load space supported on the second chassis extending at least partly below an upper surface of the second sets of wheels, power transmission transmitting power to the second drive wheel of the second sets of wheels, wherein the second chassis includes two longitudinal parts attached to each other at least in front of the load space, which longitudinal parts are at a distance from each other in lateral direction of the forest machine at least over a partial length of the load space, in which forest machine the load space extends between the longitudinal parts in vertical direction of the forest machine.

The invention relates to a forest machine, comprising a chassis having a first chassis and a second chassis pivoted consecutively by a central pivot, first sets of wheels arranged in connection with the first chassis, an engine fitted in connection with the first chassis, a load space supported on the second chassis extending at least partly below an upper surface of the second sets of wheels, power transmission transmitting power to the second drive wheel of the second sets of wheels, wherein the second chassis includes two longitudinal parts attached to each other at least in front of the load space, which longitudinal parts are at a distance from each other in lateral direction of the forest machine at least over a partial length of the load space, in which forest machine the load space extends between the longitudinal parts in vertical direction of the forest machine.

A work machine includes a drive wheel, a drivable track engaged with the drive wheel, a deformable spacer coupled to the drive wheel, and a secondary weight coupled to the deformable spacer. The deformable spacer facilitates oscillation of the secondary weight relative to the drive wheel to limit vibrations of the work machine.

A robotic system comprises a first robotic crawler having a mobility mechanism for locomotion, a second robotic crawler having a mobility mechanism for locomotion, and at least one coupling mechanism supported by at least one of the first or second robotic crawlers to couple and uncouple the first and second robotic crawlers to and from each other. When coupled together, the first and second robotic crawlers are operable as a unified robotic crawler system in a coordinated drive mode for operational control of respective mobility mechanisms in a coordinated manner. Various operating modes provide for selective control of various aspects of the first and second robotic crawlers, whether coordinated or independent control. The unified robotic crawler system provides greater or enhanced stability of the first and second robotic crawlers. Associated methods are provided herein.