A multi-terrain wall climbing vehicle including a generally rectangular housing having a top opening and a bottom opening. A power source is placed within the housing. A first motor and a second motor are located within the housing and are connected to the power source. At least four pairs of wheels are connected to the housing, at least two of the wheel pairs being connected to and powered by the first motor. Two tracks are placed onto the wheels so as to surround the housing to enable the vehicle to ride along a riding surface. A propeller is placed within the housing between the top opening and the bottom opening. The propeller is connected to the second motor. As the propeller rotates, it draws in air from at least one of the top opening and the bottom opening and exhausts the air through the top opening so as to generate an adhesion force enabling a secure connection between the tracks of the vehicle and the riding surface.

A multi-terrain wall climbing vehicle including a generally rectangular housing having a top opening and a bottom opening. A power source is placed within the housing. A first motor and a second motor are located within the housing and are connected to the power source. At least four pairs of wheels are connected to the housing, at least two of the wheel pairs being connected to and powered by the first motor. Two tracks are placed onto the wheels so as to surround the housing to enable the vehicle to ride along a riding surface. A propeller is placed within the housing between the top opening and the bottom opening. The propeller is connected to the second motor. As the propeller rotates, it draws in air from at least one of the top opening and the bottom opening and exhausts the air through the top opening so as to generate an adhesion force enabling a secure connection between the tracks of the vehicle and the riding surface.

The present invention provides a robot which is suitable for travel through a pipeline. The inventive robot comprises at least one tracked drive means and at least one roller means that can swivel about an axis substantially normal to a rolling axis thereof, wherein said at least one tracked drive means and at least one roller means are provided with magnetic means for generating a magnetic adhesion force between the robot and an internal wall of the pipeline.

A caterpillar assembly for moving along a non-horizontal surface comprising a track, a moving system, and a plurality of vacuum grippers successively arranged along the track configured be attached to the non-horizontal surface by means of vacuum and move with respect to the track by means of the moving system to advance the caterpillar assembly along the non-horizontal surface.

A caterpillar assembly for moving along a non-horizontal surface comprising a track, a moving system, and a plurality of vacuum grippers successively arranged along the track configured be attached to the non-horizontal surface by means of vacuum and move with respect to the track by means of the moving system to advance the caterpillar assembly along the non-horizontal surface.

Adhesion devices for transport assemblies are configured to engage non-metallic surfaces. The transport assemblies can be wheels, such as omni-directional wheels, or can be a tractor tread assembly. The transport assembly is configured to move adjacent to a non-metallic surface of a structure. The transport assembly comprises an outer surface disposed adjacent to the non-metallic surface as the transport assembly moves, and a plurality of adhesion devices are each mounted to the outer surface and extend at least in a normal direction away from the outer surface. Each adhesion device is responsive to proximity to the non-metallic surface to adhere to the non-metallic surface. The adhesion devices in one or more embodiments include a Van der Waals-type adhesion device, a micro spine-type adhesion device, a suction cup-type adhesion device, or a combination of such devices.

Adhesion devices for transport assemblies are configured to engage non-metallic surfaces. The transport assemblies can be wheels, such as omni-directional wheels, or can be a tractor tread assembly. The transport assembly is configured to move adjacent to a non-metallic surface of a structure. The transport assembly comprises an outer surface disposed adjacent to the non-metallic surface as the transport assembly moves, and a plurality of adhesion devices are each mounted to the outer surface and extend at least in a normal direction away from the outer surface. Each adhesion device is responsive to proximity to the non-metallic surface to adhere to the non-metallic surface. The adhesion devices in one or more embodiments include a Van der Waals-type adhesion device, a micro spine-type adhesion device, a suction cup-type adhesion device, or a combination of such devices.

State of art techniques utilize active systems for stronger suction in surface crawlers while the passive approaches have limitation in providing consistent grip while moving across curved surfaces or dents. Embodiments herein provide an autonomous surface crawling robot for crawling over surfaces using electro-mechanical assembly for creating strong suction force and enabling the robot to smoothly crawl over flat surfaces, horizontal/vertical/inclined surfaces, curved surfaces, and surfaces with dents. Battery powered motors are used for only mobilization, while mechanical assembly generates suction to provide consistent grip across different type of surfaces. A dual flexible cam profile assembly including a cam profile and a guide rail generates required suction and addresses the technical challenge of maintaining suction across varying surfaces without using external power for suction generation. The dual flexible cam profile provides a robust, less prone to error or slippage type passive crawler mechanism, with consistent grip across uneven the surface.

State of art techniques utilize active systems for stronger suction in surface crawlers while the passive approaches have limitation in providing consistent grip while moving across curved surfaces or dents. Embodiments herein provide an autonomous surface crawling robot for crawling over surfaces using electro-mechanical assembly for creating strong suction force and enabling the robot to smoothly crawl over flat surfaces, horizontal/vertical/inclined surfaces, curved surfaces, and surfaces with dents. Battery powered motors are used for only mobilization, while mechanical assembly generates suction to provide consistent grip across different type of surfaces. A dual flexible cam profile assembly including a cam profile and a guide rail generates required suction and addresses the technical challenge of maintaining suction across varying surfaces without using external power for suction generation. The dual flexible cam profile provides a robust, less prone to error or slippage type passive crawler mechanism, with consistent grip across uneven the surface.

A kit that may include an interfacing device that includes pool sidewall interface, and a pool cleaning robot that includes a housing and a drive system. The drive system may include a drive motor system, a group of interfacing modules and a transmission system that is arranged to mechanically couple the drive motor system to the group of interfacing modules. At least one interfacing module of the group may include protuberances that are shaped to fit a non-smooth surface of the pool sidewall interface.