A climbing robot vehicle comprises a vehicle (2) and the front and rear ends of the vehicle body are provided with wheels (3). The end of the vehicle body facing towards the wall is fixedly connected to a sucking mechanism. The sucking mechanism comprises a body, the body being a hollow cylinder (4). A cover plate (5) is provided above the hollow cylinder. The upper end face of the cover plate is fixedly connected with the vehicle body and the lower end face of the cover plate is fixedly connected with the outer edge of the upper end face of the hollow cylinder by means of the first blocks (43) spaced from each other. The inner wall of the hollow cylinder is provided with tangential nozzles (41). The space between the first blocks (43) forms a first exhaust duct (44) between the outer edge of the upper end face of the hollow cylinder and the lower end face of the cover. A gap is formed between the lower end face of the hollow cylinder and the wall, and the gap forms a second exhaust duct (42) between the outer edge of the lower end face of the hollow cylinder and the wall. The climbing robot vehicle can be sucked on various kinds of walls and has a strong sucking ability and a wide application range.

A jet-powered sled has a body having a control cockpit with control apparatus for an operator to control the jet sled, a set of surface runners adapted to engage a surface upon which the sled is operated, the surface runners removably engaged to spindles coupled to swing arms coupled to the jet sled, and an engine compartment having a jet engine removably mounted in a manner to direct thrust to a rear of the jet sled to propel the jet sled. The jet sled is characterized in that the sled may be adapted specifically to run on water, ice or snow by installing runners adapted for water, ice or snow on the spindles of the swing arms.

A climbing robot vehicle comprises a vehicle (2) and the front and rear ends of the vehicle body are provided with wheels (3). The end of the vehicle body facing towards the wall is fixedly connected to a sucking mechanism. The sucking mechanism comprises a body, the body being a hollow cylinder (4). A cover plate (5) is provided above the hollow cylinder. The upper end face of the cover plate is fixedly connected with the vehicle body and the lower end face of the cover plate is fixedly connected with the outer edge of the upper end face of the hollow cylinder by means of the first blocks (43) spaced from each other. The inner wall of the hollow cylinder is provided with tangential nozzles (41). The space between the first blocks (43) forms a first exhaust duct (44) between the outer edge of the upper end face of the hollow cylinder and the lower end face of the cover. A gap is formed between the lower end face of the hollow cylinder and the wall, and the gap forms a second exhaust duct (42) between the outer edge of the lower end face of the hollow cylinder and the wall. The climbing robot vehicle can be sucked on various kinds of walls and has a strong sucking ability and a wide application range.

A climbing robot vehicle comprises a vehicle (2) and the front and rear ends of the vehicle body are provided with wheels (3). The end of the vehicle body facing towards the wall is fixedly connected to a sucking mechanism. The sucking mechanism comprises a body, the body being a hollow cylinder (4). A cover plate (5) is provided above the hollow cylinder. The upper end face of the cover plate is fixedly connected with the vehicle body and the lower end face of the cover plate is fixedly connected with the outer edge of the upper end face of the hollow cylinder by means of the first blocks (43) spaced from each other. The inner wall of the hollow cylinder is provided with tangential nozzles (41). The space between the first blocks (43) forms a first exhaust duct (44) between the outer edge of the upper end face of the hollow cylinder and the lower end face of the cover. A gap is formed between the lower end face of the hollow cylinder and the wall, and the gap forms a second exhaust duct (42) between the outer edge of the lower end face of the hollow cylinder and the wall. The climbing robot vehicle can be sucked on various kinds of walls and has a strong sucking ability and a wide application range.

There is provided an amphibious vehicle for use on land and water comprising lateral floaters which increases the stability of the vehicle when in water. While on land, the lateral floaters may be retracted within the body of the vehicle to reduce the width of the vehicle.

Ground vehicles that may include flight capability are described. In some examples, a vehicle frame may include a main support and at least two auxiliary supports, with the main support disposed substantially along the centerline of the vehicle, and the at least two auxiliary supports extending upward and outward from the main support. In some examples, vehicles may include an inflatable airfoil, such as a ram air parachute, that includes stiffeners on or about a leading edge of the airfoil. In some examples, vehicles may include a front wheelbase attached to the main support and/or auxiliary supports, a rear wheelbase attached to the main support and/or auxiliary supports, a ground steering mechanism connected to the front wheelbase and/or the rear wheelbase, a motor connected to a propeller, and a propeller shroud at least partially encircling the propeller.

Ground vehicles that may include flight capability are described. In some examples, a vehicle frame may include a main support and at least two auxiliary supports, with the main support disposed substantially along the centerline of the vehicle, and the at least two auxiliary supports extending upward and outward from the main support. In some examples, vehicles may include an inflatable airfoil, such as a ram air parachute, that includes stiffeners on or about a leading edge of the airfoil. In some examples, vehicles may include a front wheelbase attached to the main support and/or auxiliary supports, a rear wheelbase attached to the main support and/or auxiliary supports, a ground steering mechanism connected to the front wheelbase and/or the rear wheelbase, a motor connected to a propeller, and a propeller shroud at least partially encircling the propeller.

A vehicle capable of multiple varieties of locomotion having a main body; a plurality of motors and blades providing flying capability; each motor being associated with and powering a blade assembly; two legs extending from opposing sides of the main body creating a ground propulsion system. The ground propulsion system having two legs; each leg connected to a track body at the opposing leg end; each track body comprised of a plurality of drive gears; each track body connected to and retaining a track providing ground propulsion. The vehicle can either drive or fly based on its base structure, in additional to carrying a payload. The payload is carried below the main body of the vehicle and between the tracks or running gear. When the vehicle is in flight, the tracks are able to rotate up into a fly/flight mode to protect the blades during flight.

A vehicle capable of multiple varieties of locomotion having a main body; a plurality of motors and blades providing flying capability; each motor being associated with and powering a blade assembly; two legs extending from opposing sides of the main body creating a ground propulsion system. The ground propulsion system having two legs; each leg connected to a track body at the opposing leg end; each track body comprised of a plurality of drive gears; each track body connected to and retaining a track providing ground propulsion. The vehicle can either drive or fly based on its base structure, in additional to carrying a payload. The payload is carried below the main body of the vehicle and between the tracks or running gear. When the vehicle is in flight, the tracks are able to rotate up into a fly/flight mode to protect the blades during flight.

Inspection vehicle for under water inspection of coating, marine growth, structural integrity and corrosion on ferromagnetic ship hulls and other ferromagnetic structures. The inspection vehicle is distinctive in that it comprises a non-magnetic element, at least one magnetic wheel or device operatively arranged to the element, and a watertight camera for visual inspection attached to the element or other structure of the inspection vehicle, wherein the inspection vehicle comprises one coupling side where the at least one magnetic wheel or device is operatively arranged for the inspection vehicle to couple magnetically through coating, any marine growth and corrosion products and allow rolling the inspection vehicle on said structure, in horizontal to vertical to upside down-orientation while holding the inspection vehicle attached to the structure, and one non-coupling side oriented in substance in opposite direction to the coupling side, where the at least one magnetic wheel is not operatively arranged and the non-coupling side will not couple magnetically to said structure. A method for operating the inspection vehicle is also provided.