A suction traveling device includes: a main pressure reducing chamber, sub pressure reducing chambers communicating with the main pressure reducing chamber and disposed in drive parts, ventilation holes on a same side of the sub pressure reducing chamber as suction holes and communicating the sub pressure reducing chambers and suction holes, and an open/close unit for releasing the ventilation holes when a pressure in suction chambers formed by a wall surface and the suction holes is equal to a pressure in the sub pressure reducing chamber and for closing the ventilation holes when the pressure in the suction chambers is higher than in the sub pressure reducing chamber. When the ventilation hole is closed, a gap of a size preventing the pressure in the sub pressure reducing chamber from affecting the pressure in the other suction chamber is formed in the ventilation hole.

A robotic device for providing vertical mobility has a payload is disposed inside a central compartment and supported by a skid. The skid can move up and down through latch and hook pairs to keep intimate contact with the surface and cross over bumps. The apparatus uses a flexible seal to create a reliable vacuum chamber. The flexible seal comprises a foam ring inside fabric pocket. A plurality of rod and spring strips are configured to apply a downward force to the flexible seal to conform with surface curvatures. The fabric pocket fills in the gaps or seams to maintain a vacuum. The air flows inside a manifold and passes through a filter to avoid debris from damaging the vacuum motor assembly.

A robotic device for providing vertical mobility has a payload is disposed inside a central compartment and supported by a skid. The skid can move up and down through latch and hook pairs to keep intimate contact with the surface and cross over bumps. The apparatus uses a flexible seal to create a reliable vacuum chamber. The flexible seal comprises a foam ring inside fabric pocket. A plurality of rod and spring strips are configured to apply a downward force to the flexible seal to conform with surface curvatures. The fabric pocket fills in the gaps or seams to maintain a vacuum. The air flows inside a manifold and passes through a filter to avoid debris from damaging the vacuum motor assembly.

An improved vehicle is provided that has an excellent obstacle overcoming ability, including stair climbing. The apparatus comprises a frame, and a pair of endless track units positioned on opposite sides. Each track unit has a plurality of telescoping rollers in contact with the inner track surface configured to guide the track around a track pathway, and move vertically when navigating over obstacles. Each track unit further comprises a drive assembly in contact with the track, and movable between a raised position and a lowered position, such that movement of the drive assembly also operates to provide track tension.

An improved vehicle is provided that has an excellent obstacle overcoming ability, including stair climbing. The apparatus comprises a frame, and a pair of endless track units positioned on opposite sides. Each track unit has a plurality of telescoping rollers in contact with the inner track surface configured to guide the track around a track pathway, and move vertically when navigating over obstacles. Each track unit further comprises a drive assembly in contact with the track, and movable between a raised position and a lowered position, such that movement of the drive assembly also operates to provide track tension.

The present invention relates to a remotely operated underwater robot device for removing marine biofouling, mainly aimed at organisms such as sun coral, settled on hulls of floating units for transporting oil and derivatives thereof, or on exploration and production platforms. The system comprises a remotely operated robot that removes the marine biofouling from said hulls, without damaging the hull, containing and capturing the waste. It is an intelligent device that is capable of operating in two modes: as an ROV to allow it to travel through the water, and as a crawler to perform the actual functions of removing the macrofouling containing sun coral and the functions resulting therefrom. It has non-georeferenced reference systems using acoustic elements to facilitate location by the operator. It uses computer vision to enter the parking areas without human assistance. It contains thrusters for controlling aquatic movements and self-levelling systems with control of the centre-of-buoyancy dynamics, and has wheels for movement, which can be electromagnets or a set of wheels that works in conjunction with a magnetic fastening system, both with variation in the coupling force. It has either a system for removing, containing, capturing and crushing the biofouling or a removal system using cavitation and mechanical impact that can have an approximate height of 30 centimetres, normally applied to sun coral.

This specification describes unmanned ground vehicle track systems. In some examples, an unmanned ground vehicle includes a frame having right and left sides and right and left track assemblies, each track assembly being coupled to a corresponding side of the frame in parallel with the other track assembly. Each track assembly includes a drive pulley coupled to the corresponding side of the frame and a track including a continuous flexible belt supported by the drive pulley. The track includes an interior surface engaged with the drive pulley and an exterior surface opposite the interior surface, and the exterior surface of the track includes a plurality of flexible bristles. The unmanned ground vehicle includes one or more drive motors configured to drive the drive pulleys of the right and left track assemblies.

This specification describes unmanned ground vehicle track systems. In some examples, an unmanned ground vehicle includes a frame having right and left sides and right and left track assemblies, each track assembly being coupled to a corresponding side of the frame in parallel with the other track assembly. Each track assembly includes a drive pulley coupled to the corresponding side of the frame and a track including a continuous flexible belt supported by the drive pulley. The track includes an interior surface engaged with the drive pulley and an exterior surface opposite the interior surface, and the exterior surface of the track includes a plurality of flexible bristles. The unmanned ground vehicle includes one or more drive motors configured to drive the drive pulleys of the right and left track assemblies.

A ladder chair contains: a body, a continuous track assembly, and a lifting mechanism. The body includes a sitting portion arranged on a top thereof and a pedal extending outward from a bottom of the body. The climbing assembly is arranged on a rear end of the body. The lifting mechanism is located behind the body and the sitting portion, and the lifting mechanism includes two telescopic posts and two rollers individually disposed on two bottoms of the two telescopic posts. The climbing assembly includes two continuous tracks arranged on two peripheral sides thereof respectively and obliquely extending upward relative to the body, a transmission shaft mounted on a bottom of the climbing assembly, two idlers respectively fixed on two tops of the two continuous tracks. Each continuous track is defined between the transmission shaft and each idler and is driven by the transmission shaft to rotate.

A caterpillar device includes: a water film removing part which is provided in a power transmission member including chains, presses and removes a water film between an attachment object as a magnetic material, and the power transmission member with a magnetic force, and attaches the power transmission member to the attachment object to secure a frictional force; and an apparatus body magnet attachment part which is connected to the power transmission member and attaches the body of the apparatus to the attachment object.