An amphibious vehicle comprises a buoyant hull, a boat motor affixed to the hull to propel the amphibious vehicle in water, two or more powered wheel assemblies affixed to the hull to propel the amphibious vehicle on land, and two or more selectively rotatable arms affixing each wheel assembly to the hull. One or more of the wheel assemblies are affixed to opposing sides of the hull. Two or more selectively rotatable arms affix each wheel assembly to the hull. The arms affixing each respective wheel assembly are selectively rotatable in unison to move the respective wheel assembly between a lowered position and a raised position.

A dual mode vehicle that operates on both guided rails and roadways includes a capsule, a carriage, a left motor, a right motor, a road drive system, a rail drive system, a pod control unit, and at least one battery. The carriage includes a spherical frame-housing, a left wheel housing, and a right wheel housing. A spherical cabin of the capsule is attitudinally mounted within the spherical frame-housing. The left motor is adjacently mounted to the left wheel housing. The right motor is adjacently mounted to the right wheel housing. The left and right motors are operatively coupled with the road drive system through the at least one battery and the pod control unit to operate a roadways transportation mode. The left and right motors are operatively coupled with the rail drive system through the at least one battery and the pod control unit to operate a railway transportation mode.

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.

Disclosed herein is a railcar-moving vehicle having a highway mode for operation on roadways, and a rail mode for operation on rails. The railcar-moving vehicle including a support system, at least one drive axle with rubber tried drive wheels, and at least one pair of steering tires and two spaced apart rail bogies suspended by the support system. The railcar-moving vehicle including a weighted sled frame slidably mounted to the support system, the sled frame translatable between the front end and the rear end of the support system for optimizing weight distribution for increasing traction by the bogies when in rail mode. The bogies retained in an elevated and stowed position during highway mode and in a lowered position when in rail mode.

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.

A dual-mode vehicle, wheels for the vehicle, and a method of transitioning the vehicle from a land mode to a flight mode. In the land mode, the method includes rotating a pair of spaced wheel arms about a central pivot to lower a body of the dual-mode vehicle to a ground surface. Each wheel arm extends from the central pivot to a wheel. The method also includes rotating the central pivot about a longitudinal vehicle axis to raise the wheel arms and the wheels above the ground surface. After raising the wheel arms and wheels above the ground surface, the method includes rotating the wheel arms about the central pivot to position the wheels for use as rotors in the flight mode. In the flight mode, the method includes rotating the wheels in order to extract rotor blades positioned within the wheels to extend beyond the wheels.

An amphibious vehicle such as a tug boat, comprising a running gear configured to be at least positioned in a deployed position suited to the rolling of the vehicle, and at least one retracted position suited to the navigation of the vehicle. The running gear comprises a fairing element rigidly connected to the running gear, so that the fairing element advantageously serves as an anti-projection device in the deployed position of the running gear. According to one option, the vehicle comprises a semi-rigid shell.

A wheel suspension system for mounting a wheel on a vehicle body, such as a flying car, the system comprising: an upright assembly for mounting the wheel; a lower arm assembly comprising: a lower control arm; and a storage arm; a mounting structure connecting the lower arm assembly to the upright assembly; an upper control arm; and an adjustable suspension assembly pivotally connected to the upright assembly or lower control arm assembly and pivotally connected to the body; wherein one end of the lower control arm is pivotally connected to the body, and the other end of the lower control arm is connected to the mounting structure to be pivotable about a first axis; the mounting structure is connected to the upright assembly to be pivotable about a second axis that is substantially perpendicular to the first axis; the storage arm is pivotally connected to the lower control arm at one end, and is moveably connected to the body under control of an actuator at the other end; and the upper control arm having a pivot connection to an upper part of the upright assembly at one and, and a pivot connection to the body at the other end; and wherein the lateral position of the upright assembly with respect to the body is adjustable by movement of the actuator of the storage arm with respect to the body, and the vertical position of the upright assembly with respect to the body is adjustable by operation of the adjustable suspension assembly.

A dual mode vehicle that operates on guided rails and roadways includes a capsule, a carriage, a front left drive system, a front right drive system, a rear left drive system, a rear right drive system, a pod control unit, and at least one battery. The carriage includes a spherical frame-housing and a base. A spherical cabin of the capsule is attitudinally mounted within the spherical frame-housing. The front left drive system, the front right drive system, the rear left drive system, and the rear right drive system each includes a motor, a drive axle, a road wheel, and a rail wheel. The road wheel and the rail wheel are axially mounted to the drive axle. The motor that is mounted to the base is operatively coupled with the drive axle through the at least one battery and the pod control unit to operate a roadway or railway transportation mode.

A convertible ducted fan engine and mounting system. The convertible ducted fan engine has a shroud encircling a mechanical fan. The convertible ducted fan engine includes a fluid-propulsion configuration in which the mechanical fan rotates freely with respect to the shroud to produce thrust through fluid flow, and a drive-wheel configuration in which the shroud rotates about the rotational axis.