A MEUV that is able to navigate aerial, aquatic, and terrestrial environments through the use of different mission mobility attachments is disclosed. The attachments allow the MEUV to be deployed from the air or through the water prior to any terrestrial navigation. The mobility attachments can be removed or detached by and from the vehicle during a mission.

A tracked, amphibious vehicle, provides at least two, spaced, elongated pontoons disposed generally parallel to one another. A platform structure can be supported by and structurally connects the pontoons, the platform structure including a transom and a lowermost generally horizontally extending panel. A continuous, endless belt can encircle each pontoon engaging bogie wheels on the pontoon. A supplemental, marine drive assembly includes a hydraulic motor having a shaft with an axis, a propeller shaft having an axis, wherein the motor axis and propeller axis are aligned. A universal joint connects the hydraulic motor to the transom. A housing includes a sleeve that contains the propeller shaft.

A connector (1) for transferring a fluid or for applying a pneumatic pressure from an inlet conduit (2) to an outlet conduit (3) that may rotate with respect to the inlet conduit (2), in which the connector (1) comprises a rotating shaft (17) defining the outlet conduit (3) therein, which has an inlet opening (70), said rotating shaft (17) defining a rotational axis (S-S) and comprising a sealing disc (19) extending radially from said rotating shaft; an insertion chamber (5) to which said inlet conduit (2) is sealingly securable, said chamber leading towards said inlet opening (70) of the outlet conduit (3); at least one first cylinder-piston unit (100) comprising a cylinder (9) and a piston (21) slidable in said cylinder (9), said piston (21) having a sealing surface (22) facing the sealing disc (19), and said cylinder (9) being fluidically connected or connectable to said insertion chamber (5); said piston (21) being configured to be selectively actuated between a sealing position in which the sealing surface (22) is at a minimum distance or in contact with the sealing disc (19), in which a fluidic seal is carried out between said insertion chamber (5) and said inlet opening (70) of the outlet conduit (3) of the rotating shaft (17), and a non-sealing position in which the sealing surface (19) is moved away from the sealing disc (19), in which a fluidic seal is absent between said insertion chamber (5) and said inlet opening (70) of the rotating shaft of the outlet conduit (3) of the rotating shaft (17).

A mechanical system includes a curved beam and a motor coupled to the curved beam. The curved beam is configured to buckle at two different locations along the positive and negative portions of its load/displacement curve, corresponding to opposite and equal sense bending directions. The motor is configured to impart a flapping motion to the curved beam.

An amphibious vehicle, in particular military, amphibious vehicle, includes a first end region (2) and a second end region (3) opposite the latter in the longitudinal direction of the vehicle. The first end region (2) is designed as a land driving front and the second end region (3) is designed as a ship's bow for water travel. In a method for operating an amphibious vehicle (1), the main travel direction of the amphibious vehicle (1) is reversed upon transfer between land travel and water travel.

A MEUV that is able to navigate aerial, aquatic, and terrestrial environments through the use of different mission mobility attachments is disclosed. The attachments allow the MEUV to be deployed from the air or through the water prior to any terrestrial navigation. The mobility attachments can be removed or detached by and from the vehicle during a mission.

A vehicle (20) consisting of a frame (22) with a pair of paddles (72) extending longitudinally and rotatably supported by the frame (22) in pendulum fashion for swinging movement between an extended position engaging the surface and a retracted position moved vertically out of engagement with the surface. A pair of foot platforms (74) are operatively connected to the paddles (72). A pair of depressors (84) interconnects the foot platforms (74) and the paddles (72) to rotate the paddles (72) between the extended position and the retracted position. The paddles (72) include a propulsion bar (86) and an oar (88) connected by a lost-motion connection to slide relative to one another between the extended position and the retracted position. The oars (88) have a fin-shape to propel the vehicle (20) over water and include a striker (90) to propel the vehicle (20) over land. The vehicle (20) allows movement over a surface of water and land using an elliptical motion similar to the natural motion of walking.

An amphibian operable in land and marine modes includes a hull, having a discontinuity, and a retractable wheel or track drive assembly at least partially located in the discontinuity. A wheel or track drive of the at least one retractable wheel or track drive assembly is retracted above a lowest point of the hull when operating in marine mode, and the wheel or track drive is protracted below the lowest point when operating in land mode. The hull is a planing V hull having a forward bow section defining a frontal bow surface/area across a beam of the hull. The discontinuity is provided in the forward bow section, and the wheel or track drive of the retractable wheel or track drive assembly is located ahead of and in front of at least a portion of the frontal bow area when protracted.

The present invention provides, with reference to FIG. 1, an amphibian for use in land and marine modes comprising: a planing hull; three wheel stations, two of the three wheel stations being front wheel stations provided one on each side of and in the front half of the amphibian, and the third wheel station being a rear wheel station provided in a central region in the rear half of the amphibian; at least one wheel provided at each wheel station, each wheel being movable between a protracted land mode position and a retracted marine mode position; land propulsion means to propel the amphibian on land in the land mode, the land propulsion means comprising at least one of the wheels; and marine propulsion means to propel the amphibian on water in the marine mode, the marine propulsion means comprising at least two impellers or propellers provided one on each side of the rear wheel station.

A vehicle includes a hull defining one or more holes in a keel of the hull. The one or more holes are provided for ice fishing from the one or more holes. The holes include a hatch or a tube extending upwards, for preventing water from entering the hull. The vehicle also includes continuous track assemblies for providing traction on an ice surface. The continuous track assemblies may also provide a motive force when the vehicle is suspended in water. By the hull design, the vehicle may float on the water, allowing the vehicle to access ice surfaces which may otherwise be inaccessible to ice-fishers. The vehicle also increases safety while fishing during thin or unstable ice conditions.