Abstract: The present invention relates to a climbing machine and a moving method therefor. The climbing machine includes a machine body, a mechanical arm, and at least two ropes, each rope connects a suspension mechanism and the machine body; the suspension mechanism is connected to or disengaged from an object structure, the length of the rope between the suspension mechanism and the machine body is variable; through dragging or pulling of the rope, the machine body can move on the object structure; the mechanical arm connects a gripping mechanism and the machine body; the gripping mechanism can grip and move any suspension mechanism and disengage a gripped suspension mechanism. In the present invention, the machine body moves without interference, and can be pulled not only on a smooth surface but also on a hollow or bending surface, and features a simple structure, a wide application scope, and the like.

Abstract: A modular aerial vehicle for inspection of enclosed and open space environments. The aerial vehicle is employed for inspection of various environments in remotely controlled and autonomous fashions. The aerial vehicle is capable of carrying different sensory modules depending on the specific application including surface inspection. Aerial vehicle may be connected to a tether cable for electrical power delivery and transmission of control commands. The aerial vehicle may utilize a landing structure which allows landing on any angled metallic or non-metallic surface.

Abstract: An adhesion device 10 that defines a decompression space D to be decompressed between a wall surface W and the adhesion device 10, and adheres to the wall surface W, comprises: a base 11 disposed facing a wall surface W at a distance from the wall surface W and connected to a decompression device 14 that depressurizes the decompression space D created between the base 11 and the wall surface W; a first partition 12 disposed on a fringe of the base 11, wherein the first partition 12 forms the base 11 side portion of the peripheral wall of the decompression space D with an elastic member; a second partition 13 disposed closer to the wall surface W side than the first partition 12, wherein the wall surface W side portion of the peripheral wall of the decompression space D is formed by an elastic member so that the wall surface W side end of the second partition 13 contacts the wall surface W; and a first restricting member 16 formed in a frame shape corresponding to that of the second partition 13 by a member ha

Abstract: A wall-climbing toy vehicle includes a body having a car frame structure and a base member. The car frame structure is coupled to the base member. The base member includes a horizontal part and a vertical part. The horizontal part defines a curved surface negative pressure cavity. The horizontal part includes air inlet ports and shunt grooves. The vertical part includes at least one drive mechanism installation port and a plurality of wheel installation ports. Further an air suction assembly is coupled along the air inlet ports on the horizontal part. Furthermore, at least one drive mechanism assembly is coupled to the at least one drive mechanism installation port on the vertical part. The air suction assembly and the at least one drive mechanism assembly are adapted to be driven via a power supply arrangement to enable the wall-climbing toy vehicle to drive against the vertical wall.

Abstract: Apparatus and methods for providing gravity compensation to a cable-suspended, vacuum-adhered, tool-equipped crawler vehicle traveling along and following the contour of a non-level surface during the execution of an automated maintenance operation. One technical feature shared by multiple embodiments of the gravity-compensating systems is that a cable spool is operated to wind a portion of the cable from which the vacuum-adhered crawler vehicle is suspended to generate a tensile force that counteracts a gravitational force being exerted on the crawler vehicle during movement. Rotation of the cable spool may be driven by a motor or by a tensioning spring.

Abstract: The invention relates to a hybrid surface traversing apparatus adapted to be adhered to a (e.g., submerged or in air) surface by a non-flow-through pressure differential, the apparatus includes a frame forming a chamber; a seal (e.g., closed-cell foam) having a closed seal perimeter (e.g., a closed polygon, a quadrilateral, and the like) defining an opening of the chamber, the seal perimeter adapted substantially for rolling relative to the chamber and for contact with the surface to be traversed to prevent leakage and maintain a non-flow-through seal with the surface; a suction pump structured and arranged to produce the (e.g., negative) pressure differential and cooperate with the seal to adhere the apparatus to the surface; and a drive configured to move the apparatus relative to the surface.

Abstract: A robotic device that can adhere to the surface of an object by negative-pressure suction and that can travel in a Y-axis direction and an X-axis direction. The robotic device is equipped with four suction cup units, Y-axis actuators and X-axis actuators. As for the planar shape of each suction cup, it has a shape of each quadrangle when a roughly square was divided into four quadrangles of the same shape. The quadrangles are formed provided with two right-angle portions in a diagonal portion. One right angle of the two right-angle portions of each suction cup overlaps with one of the four right angles of the square. Two of the sides that constitute the above right angle of the suction cup overlap with two of the edges that constitute the above right angle of the square.

Abstract: A pneumatic device may be configured and used to provide multiple movement related functions, such as in an automated assembly system. The pneumatic device may comprise a chamber; a sealing element configurable to contact a surface, to enable creating a seal around the chamber by application of pneumatic suction into the chamber; a biasing element configurable to push the sealing element away from the surface; and a pneumatic cushion configurable to expand by application of pneumatic inflow, thus urging the pneumatic device away from the surface.

Abstract: The present invention discloses a high flow low pressure suction device. The device is a non-contact suction device based on multiple stage turbulence based low pressure suction mechanism which comprises fan(s) or rotating impeller(s) for drawing air/fluid/slurries operates without any seal between the device and the sucked surface. The device compounds this turbulence based low pressure generation along with Bernoulli's principle to yield a high efficiency suction device. The device implements the above concept by making the air/fluid/slurries flow through two or three zones selected from the acceleration zone(s), turbulence zone(s) (high turbulence zone) and smooth zone(s) (minimum turbulence zone).

Abstract: A humanoid robot foot (10) comprises: a foot base (12), at least one leaf spring (14) acting as a flexible toe of the foot, said at least one leaf spring (14) having a rear portion (14a) rigidly connected to a flat surface (12b) of the foot base (12), a front portion (14b) projecting from the foot base (12) and an intermediate portion (14c) which is not rigidly connected to the foot base (12) and is therefore freely deflectable, along with the front portion (14b), as a result of the application of an external force on the front portion (14b), and a stiffness adjustment device (26) for actively changing the stiffness (K) of said at least one leaf spring (14).

Abstract: 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.

Abstract: The sealing of a crack in a pool of a nuclear facility, using a robot. The sealing, concerns in particular, that of a crack in a wall of a pool of a nuclear facility. In particular, it implements a mobile robot carrying an adhesive tape dispenser. At least the following are provided: controlling a plurality of suction systems, the dispenser being mechanically integral with a first suction system, and controlling the movement of the first system relative to the other systems of said plurality of systems.

Abstract: A system for decelerating a vehicle includes a mount and a powered driver configured to propel an anchor toward a road surface to selectively secure the vehicle to the road surface. The mount is configured to couple the powered driver to a chassis of the vehicle.

Abstract: Example embodiments disclose an apparatus for inspecting welds in a nuclear reactor. The apparatus may include a body, a rotatable pad on the body, a pair of opposing horizontal pads for moving the device in a vertical direction, a pair of opposing vertical pads for moving the device in a horizontal direction, and an inspection device.

Abstract: Autonomous robotic cleaner (ARC) for cleaning solar panels having an anchoring mechanism including at least one rechargeable power source, at least one cleaning mechanism, a controller and an anchoring mechanism, the cleaning mechanism for cleaning dirt off of a surface of the solar panels, the controller for controlling a cleaning process of the ARC and the anchoring mechanism for magnetically anchoring the ARC to an anchoring surface coupled with a solar panel, the anchoring mechanism including an arm and a drive mechanism, the arm including at least one ferromagnetic end piece and the drive mechanism being coupled with the arm, wherein the drive mechanism moves the arm between a magnetically engaged position with the anchoring surface and a magnetically disengaged position with the anchoring surface.

Abstract: An automated motorized device may be configured to move on a structure for use in assembling operations thereon. The automated motorized device may comprise a plurality of multifunction movement components, which may be attached to one or more movement assemblies. Functions of each multifunction movement component may comprise adhering and moving. The adhering function may be performed using sealing element, which may be used to create seal between corresponding multifunction movement component and structure. The moving function may be performed using a rolling element, which may be configured to allow rolling on the structure. In some instances, one or more of the multifunction movement components may be configured to also provide floating function, which may be performed, e.g., mechanically or pneumatically.

Abstract: A robot comprises a body, at least one traveling device, a suction cup and a pump module. The at least one traveling device disposed in the body is for causing the robot to move on a surface of a plate. The suction cup and the pump module are disposed in the body. The suction cup can move relative to the body. Upon an operation of the robot, the body, the suction cup and the plate form a closed space, and the closed space is kept at a negative pressure by use of the pump module.

Abstract: Systems for cleaning a structure via a robot are described. The robot includes a body. The robot further includes a tool coupled to the body and configured to hold a structural maintenance tool. The robot includes a sensor coupled to the body. The robot includes a drive system configured to allow positioning of the body along the structure, including inverted positioning and vertical positioning. The robot further includes a communication interface coupled to the body. The robot includes a controller coupled to the body. The controller is in communication with the tool, the sensor, and the drive system. The controller is configured to receive an operating instruction through the communication interface. The controller is configured to autonomously position the body via the drive system and to perform a task with at least one of the tool and the sensor according to the operating instruction.

Abstract: A holding table for holding a platelike workpiece which includes a base and an annular holding member attached to the base. The annular holding member has an annular holding surface for holding the outer circumferential portion of the platelike workpiece thereon. Accordingly, a central recess is defined by the base and the annular holding member so as to be surrounded by the annular holding member. The annular holding member is formed with a suction opening exposed to the annular holding surface, a vacuum line having one end communicating with the suction opening and the other end connected to a vacuum source, a discharge opening exposed to the annular holding surface at a position radially outside of the suction opening, and a fluid line having one end communicating with the discharge opening and the other end connected to a fluid source.

Abstract: An aero-contouring apparatus is provided. The aero-contouring apparatus has a housing assembly and a motor assembly disposed therein. The motor assembly has a motor unit and a drive unit. The aero-contouring apparatus further has an engagement force/tilt limiting member coupled to the housing assembly, which has a central opening and a bottom end configured to contact a surface to be aero-contoured of an aerodynamically functional coating applied to a structure. The aero-contouring apparatus further has an abrading unit coupled to the drive unit and inserted through the central opening in non-contact communication with the engagement force/tilt limiting member. The abrading unit is driven by the drive unit in a random orbit motion on the surface. The engagement force/tilt limiting member mechanically limits both an engagement force and any tilting motion of the abrading unit with respect to the surface.

Abstract: A track system configured to be mounted to a vehicle comprises a drive wheel, a frame assembly, front and rear idler wheels respectively pivotally mounted at the front and rear extremities of the track system, road wheels pivotally mounted along the length of the track system, between the front and rear idler wheels, and an endless traction band disposed about the drive wheel, the idler wheels and the road wheels. The idler wheels and the road wheels are pivotally mounted on tandem frames such that adjacent tandem frames are overlapping. The tandem frames are pivotally mounted to the frame assembly via longitudinally spaced pivoting points.

Abstract: Devices for enabling navigation of a crawler vehicle along an airfoil-shaped body, such as a helicopter blade, in a low-cost fashion with high reliability, especially for swept configuration blades. Using the natural tendency of vacuum adherence devices to adhere to changing surface contours, the crawler vehicle can adhere itself to airfoil-shaped structures in a way that allows the crawler vehicle to easily translate along an airfoil-shaped body while accommodating extreme variations along the surface of the airfoil-shaped body. The crawler vehicle can be designed to eliminate any trailing edge follower wheel, which simplifies the crawler's ability to accommodate trailing edge protrusions, such as trim tabs.

Abstract: To improve the traveling functionality of a traveling device equipped with dual, rotating, negative-pressure suction seals.

Abstract: A method, apparatus, and system for adhering a vacuum to a surface is provided. A seal is positioned relative to a surface. The seal is associated with a structure and is in communication with a channel within the structure. The seal is rotated relative to the structure such that the seal at least partially conforms to the surface. Air is drawn into the channel within the structure through the seal such that the seal adheres to the surface.

Abstract: A traction unit has carrier sections on which suction cups are mounted that are connected to a vacuum source. The carrier units are driven around the frame by a chain driven by a motor. The frame has sections which move relative to one another in order to permit turning control of the traction unit.

Abstract: A method and apparatus for performing operations on a workpiece. A first frame in a frame system may be held on the workpiece by applying a vacuum to the first frame. A second frame in the frame system may be detached from the workpiece by applying a pressure to the second frame. The second frame may be moved to a location on the workpiece. The second frame may be attached to the workpiece by applying the vacuum to the second frame. An operation may be performed on the workpiece.

Abstract: A traction unit has carrier sections on which suction cups are mounted that are connected to a vacuum source. The carrier units are driven around the frame by a chain driven by a motor. The frame has sections which move relative to one another in order to permit turning control of the traction unit.

Abstract: A method, apparatus, and system for adhering a vacuum to a surface is provided. A seal is positioned relative to a surface. The seal is associated with a structure and is in communication with a channel within the structure. The seal is rotated relative to the structure such that the seal at least partially conforms to the surface. Air is drawn into the channel within the structure through the seal such that the seal adheres to the surface.

Abstract: A landing system for an air vehicle with vertical takeoff and landing capability is provided that comprises a set of selectively pressurizeable upper and lower air chambers surrounded by a connecting curtain assembly. The upper and lower air chambers are each continuous having elongated right and left cylindrical center sections interconnected by semicircular sections at each end. The landing system is connected to the air vehicle by a catenary system connected to the upper air chamber. The landing system can adjust pressure in each individual set of landing chambers such that the attitude of the vehicle can be adjusted to clear uneven ground or assist with loading and offloading. The system is capable of absorbing energy during vertical landings. After landing, the system is capable of providing suction between the air vehicle and the ground to stabilize the air vehicle.

Abstract: A traction unit has carrier sections on which suction cups are mounted that are connected to a vacuum source. The carrier units are driven around the frame by a chain driven by a motor. The frame has sections which move relative to one another in order to permit turning control of the traction unit.

Abstract: A method, apparatus, and system for adhering a vacuum to a surface is provided. A seal is positioned relative to a surface. The seal is associated with a structure and is in communication with a channel within the structure. The seal is rotated relative to the structure such that the seal at least partially conforms to the surface. Air is drawn into the channel within the structure through the seal such that the seal adheres to the surface.

Abstract: A robotic climbing platform has a chassis and a carriage adapted to support and move the chassis relative to a climbing surface. An adhesion mechanism provides an adhesion force between the climbing platform and the climbing surface. The adhesion mechanism has one or more suction pads adapted to retain an adhesion force between the climbing platform and the climbing surface during movement of the chassis relative to the climbing surface.

Abstract: A method and an apparatus for performing operations on a workpiece is provided. A first frame in a frame system may be held on the workpiece by applying a vacuum to the first frame. A second frame in the frame system may be detached from the workpiece by applying a pressure to the second frame. The second frame may be moved to a location on the workpiece. The second frame may be attached to the workpiece by applying the vacuum to the second frame. An operation may be performed on the workpiece.

Abstract: A traction unit has carrier sections on which suction cups are mounted that are connected to a vacuum source. The carrier units are driven around the frame by a chain driven by a motor. The frame has sections which move relative to one another in order to permit turning control of the traction unit.

Abstract: To improve the traveling functionality of a traveling device equipped with dual, rotating, negative-pressure suction seals.

Abstract: A robot is placed on a first surface of a panel. The robot includes a body and first and second feet connected to the body via joints. A flux conducting device is positioned on an opposing second surface of the panel, opposite the robot, so that each foot of the robot is magnetically coupled to the flux conducting device. The flux conducting device is moved along the exterior surface to pull the robot along the interior surface until an obstacle on the first surface is encountered. The robot decouples one of the feet from the flux conducting device, lifts the decoupled foot above the obstacle, and moves the decoupled foot past the obstacle.

Abstract: The invention provides a system for managing operations on a peripheral surface of a building. The system includes one or more cables wrapped around the peripheral surface of the building. Further, the system includes one or more wheeled devices capable of moving on the peripheral surface of the building. The one or more wheeled devices are operatively connected to the one or more cables. The one or more wheeled devices and the one or more cables are capable of moving on the peripheral surface of the building as an assembly. In addition, one or more instances of the assembly are operatively connected to each other.

Abstract: [OBJECT] To provide a device which is held by vacuum on a wall surface or a window surface of glass of a building, and which is moved along the surface, thereby performing the cleaning operation. [SOLVING MEANS] In three clinging units which are arranged in a row, each of the clinging units includes clinging unit putting forward/backward means for putting the clinging unit in and out in a direction intersecting with the surface. The clinging units adjacent to each other are coupled by transverse expansion and contraction means via the clinging unit putting forward/backward means, so as to constitute a row clinging unit group. In three row clinging unit groups which are arranged in the longitudinal direction, the row clinging unit groups adjacent to each other are coupled by lengthwise expansion and contraction means via the clinging unit putting forward/backward means. Each of the clinging units can be selectively set in one of three states, i.e.

Abstract: A traction unit has carrier sections on which suction cups or suction pads are mounted that are connected to a vacuum source. The carrier units are driven around the frame by a chain or belt driven by a motor. The frame has sections which move relative to one another horizontally and/or vertically in order to permit turning control of the traction unit and allowing for traversing of curved surfaces.

Abstract: A climbing robot for travelling over adhesive surfaces with endless traction mechanisms and, fastened to them at a distance, controllable adhesive feet that circulate with the endless traction mechanisms along guides in the travel plane, by means of which the adhesive sides of their adhesive elements always point towards the travel surface and wherein the adhesive elements that support and move the climbing robot are switched “ON” and lowered onto the adhesive surface and all of the other adhesive elements are switched “OFF” and raised from the adhesive surface. The climbing robot has square running gear, and a foot plate with a guide running around the edges for a multitude of adhesive feet driven by traction mechanisms exists in each of the four corners of the running gear.

Abstract: A climbing robot for travelling over adhesive surfaces with endless traction mechanisms (14) and, fastened to them at a distance, controllable adhesive feet (21) that circulate with the endless traction mechanisms (14) along guides (17) in the travel plane, by means of which the adhesive sides of their adhesive elements (15) always point towards the travel surface and wherein the adhesive elements (15) that support and move the climbing robot are switched “ON” and lowered onto the adhesive surface and all of the other adhesive elements (15) are switched “OFF” and raised from the adhesive surface, wherein the climbing robot has square running gear (11), one foot plate (13) each with a guide (17) running around the edges for a multitude of adhesive feet (21) driven by traction mechanisms is arranged in two diagonally opposite corner areas (18) of the running gear (11), wherein the foot plates (13) are attached to a support bar (12) of the running gear (11) and the adhesive feet (21) and therefore their adhesive

Abstract: A suction toy assembly and its method of operation. The suction toy assembly has a chassis. The chassis has a front end, a rear end, side surfaces and a base plate. A fan opening is formed through the base plate. A motorized fan is mounted to draw air through the fan opening from the surrounding area. This creates a low pressure condition under the base. A drive wheel is used to propel the assembly. A linkage element is coupled to the drive wheel. At least one extraneous element is provided that protrudes outwardly away from the chassis as a cantilever. The extraneous elements are articulated by movements of the linkage element when the drive wheel rotates, or the chassis moves. Appendages may be mounted on a flexible member to allow for the illusion of climbing.

Abstract: In an arrangement for strengthening the road grip for a vehicle, particularly for a passenger car, air can be sucked from a vacuum chamber arranged under the vehicle and closed off with respect to the ambient atmosphere. As a result, a vacuum can be generated in a vacuum chamber arranged in a braking plate, and the latter can be changed from an inoperative position away from the ground into a operative position close to the ground, as a result of the generated vacuum.

Abstract: A robot drive system preferably used for a vessel hull cleaning and/or inspection robot includes a first frame portion rotatably supporting a first axle with a first wheel thereon, and a second frame portion rotatably supporting a second axle with a second wheel thereon. A joint connects the first frame portion to the second frame portion and defines an expendable and contractible portion between the first frame portion and second frame portion. An actuator subsystem is configured expand and contract the expandable and contractible portion to move the first frame portion relative to the second frame portion at the joint to angle the first axle relative to the second axle to steer the robot.

Abstract: A traction unit has carrier sections on which suction cups or suction pads are mounted that are connected to a vacuum source. The carrier units are driven around the frame by a chain or belt driven by a motor. The frame has sections which move relative to one another horizontally and/or vertically in order to permit turning control of the traction unit and allowing for traversing of curved surfaces.

Abstract: A magnetic adhesive and braking system for a remote controlled vehicle adapted for traversing across ferromagnetic surfaces of a steel shipping container including the vertical walls and ceiling. The magnetic wheel system allows the vehicle to traverse vertical grades. The magnetic braking system both securely holds the vehicle when stopped on a vertical surface, and exerts enough attractive force between the vehicle and the shipping container to allow a vehicle mounted drill to operate. The magnetic brake design uses mechanical advantage such that the force required to roll the vehicle vertically downward is heightened to the force required to detach the vehicle in a perpendicular vector from the container's surface.

Abstract: A traction unit has carrier sections on which suction cups are mounted that are connected to a vacuum source. The carrier units are driven around the frame by a chain driven by a motor. The frame has sections which move relative to one another in order to permit turning control of the traction unit.

Abstract: A hybrid electric work vehicle having an electric traction motor driven power take off used in conjunction with a control system that monitors the hydraulic system for pressure deltas and trend vectors, and that has learning capabilities, is provided for use with a vehicle for operation on the ground. The system is usable for both open center and closed center hydraulic systems. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. 37 CFR 1.72(b).

Abstract: A Bernoulli-type non-contact adhesion pad comprises a pad area which includes an outer section of the pad area and an inner section of the pad area which is undercut relative to the outer section, at least one aperture in the inner section of the pad area for introducing a pressurised fluid flow from the aperture in use between the pad area and a surface for non-contact adhesion of the pad to the surface, an element extending from the aperture beyond the periphery of the aperture, but not the outer section of the pad area, so that the flow of fluid from the aperture is between and around the element and the periphery of the aperture, the element including an edge around the element at or beyond the aperture. A wall climbing robot using the Bernoulli-type non-contact adhesion pads is also disclosed.

Abstract: The moving carrier which sticks to the surface is provided with easy transverse movements on the surface. The moving carrier has at least two sets of driving wheels or one set of caterpillar on each of its right and the left sides relative to its traveling direction. One of the driving wheels is situated in the vicinity of the center of the sticking force; and another of the driving wheels is situated away from the center of the sticking force. The moving carrier can pivot at contact area as the pivot axis; at the contact area, one of the driving wheels situated in the vicinity of the center of the sticking force is contacted with the surface; and one of the moving units is driven and another moving units is not driven.