A method includes: loading a vehicle onto a connector boat; loading the loaded connector boat onto the semi-submersible ship; transporting the semi-submersible ship having the loaded connector boat stored thereon to a location; taking water ballast onto the semi-submersible ship at the location; floating the loaded connector boat off of the semi-submersible ship; transporting the loaded connector boat to a second location; unloading the vehicle into water; and transporting the vehicle to a third location.

A method includes: loading a vehicle onto a connector boat; loading the loaded connector boat onto the semi-submersible ship; transporting the semi-submersible ship having the loaded connector boat stored thereon to a location; taking water ballast onto the semi-submersible ship at the location; floating the loaded connector boat off of the semi-submersible ship; transporting the loaded connector boat to a second location; unloading the vehicle into water; and transporting the vehicle to a third location.

To enlarge a collapsible flap and store the collapsible flap appropriately. In an amphibious vehicle (1) in which a flap (13) which receives lift from water in water navigation is provided to be deployable and storable at a front side in a travel direction of a vehicle body (11), the flap (13) includes a lower flap (21) which is stored to come close to a front surface (11a) of the vehicle body (11) and an upper flap (22) which is stored to come close to an upper surface (11b) of the vehicle body (11), and at least one of the lower flap (21) and the upper flap (22) includes a first flap member (31) and a second flap member (32) and is configured such that a flap length (L.sub.13) in a direction orthogonal to a vehicle width direction is variable.

The present disclosure relates to a vessel that comprises at least one super structure configured to at least in part translate relative to said hull between a first position and at least one other position. The at least one superstructure in said first condition at least in part defines a first zone suitable for accommodating at least one person and/or vehicle, and the at least one superstructure in said second condition at least in part defines a second zone suitable for accommodating at least one person and/or vehicle. Preferably the at least one superstructure at least in part separates the first and second zones. Preferably the vessel's centre of mass is aft of mid-ship in the first condition and forward of mid-ship in the second position.

An amphibious pumping vehicle has a floatable vehicle body, a ground engaging propulsion structure, a fluid pump, a plurality of fluid nozzles comprising a first fluid nozzle connected by a fluid conduit to the fluid pump and at least one second fluid nozzle connected to the fluid conduit, a valve structure in the fluid conduit, the plurality of fluid nozzles and the valve structure co-operating to provide directional control and motive power for the vehicle when floating, and a power source configured to provide power to both the ground engaging propulsion structure and the fluid pump.

A trailer pontoon bottom has built in wheels designed to fold under the trailer pontoon to be clear of the water and to extend out and lock for land use and be clear of the pontoons. A pair of swing arms each having a first end attached to an inside axial hub of the wheel are designed to rotate on a boss of the first end. A second end of the swing arm is configured to rotate a maximum of 90 degrees from its folded position into a trailer position. An axis parallel to a back end of the trailer pontoon is configured to attach to each of the pair of swing arms at a respective pivot located a swing arm distance from an edge of the trailer pontoon. The axis is rotatable by less than 90 degrees to enable each wheel to retract against a suspension bumper.

An amphibious vehicle includes a vehicle body; a flap supported at a lower portion in a traveling direction of the vehicle body to be able to swing in a direction in which an upper edge portion approaches and separates from the vehicle body; a support column which has a fluid actuator capable of expanding and contracting in accordance with a pressure of a working fluid to a cylinder chamber, is connected to the flap in at least a first end portion in a longitudinal direction, and performs adjustment of a swinging angle of the flap by expansion and contraction of the fluid actuator; a power source which supplies the working fluid to the cylinder chamber; and a safety valve which communicates with the cylinder chamber, and opens when an internal pressure of the cylinder chamber becomes greater than a predetermined pressure to discharge the working fluid in the cylinder chamber.

The invention relates to design of all-terrain vehicles. The vehicle comprises a gas line which is connected to all of the wheel tires simultaneously and is coupled to a system for inflating the tires. A suspension comprises a wheel springing system connected to the wheel tires, a pneumatic drive and a system for inflating the tires, wherein the wheel springing system is configured in the form of an gas line formed from the cavities of the pipes from which a frame is welded, or is configured outside the frame, forming a closed loop that is connected to each of the tires by means of pipes with closure members, and wherein the pneumatic drive and the system for inflating the tires are constituted by an engine exhaust system which is provided with a baffle and is coupled to the air line by means of a pipe with a closure member.

The invention relates to design of all-terrain vehicles. The vehicle comprises a gas line which is connected to all of the wheel tires simultaneously and is coupled to a system for inflating the tires. A suspension comprises a wheel springing system connected to the wheel tires, a pneumatic drive and a system for inflating the tires, wherein the wheel springing system is configured in the form of an gas line formed from the cavities of the pipes from which a frame is welded, or is configured outside the frame, forming a closed loop that is connected to each of the tires by means of pipes with closure members, and wherein the pneumatic drive and the system for inflating the tires are constituted by an engine exhaust system which is provided with a baffle and is coupled to the air line by means of a pipe with a closure member.

Neutral Axis Duct with Tandem Telescopic Thrust Vectoring Leading and Trailing Edge Propellers for Multi-Mode Spatial Vehicle [NADTVPMSV] is a single monocoque chassis frame for a multi-mode vehicle that can travel in all land, air, over water and under water as a perfect road vehicle, perfect flying machine, perfect speed boat and perfect submarine. NADTVPMSV comprising of a longitudinal and transverse ducts with tandem thrust vectoring leading and trailing edge propellers integrated with at least one concealed or non-concealed leading and trailing bidirectional edge thrust vectoring propeller propellers connected with shaft and power source like motor or engine for providing vertical, horizontal and angular thrust to monocoque chassis frame; retractable under chassis wings with single to multi directional fluid flow design, opening and closing mechanism to control the flight as well as to adapt according to mode of the vehicle; one or more wheel tires and suspension components for the vehicle with at least one steerable wheel to travel on surface; at least one ballast tank to submerge and manoeuvre the vehicle under water.