A ground-effect amphibious hovercraft vehicle having a system of retractable wings (8), which are retracted (parking mode) by retracting arms (17a and 17b) of both wings by a head (19). At the same time, the vehicle acts as a ground-effect hovercraft vehicle when the wings (8) are extended (flight mode), which is done by extending the arms (17a and 17b) of both wings by the head (19). The head (19) is extended/retracted using a cylinder (22) moved by a drive motor (18), which may be an electric motor, a hydraulic motor or a mechanical motor, or manually using cables and pulleys.

A ground-effect amphibious hovercraft vehicle having a system of retractable wings (8), which are retracted (parking mode) by retracting arms (17a and 17b) of both wings by a head (19). At the same time, the vehicle acts as a ground-effect hovercraft vehicle when the wings (8) are extended (flight mode), which is done by extending the arms (17a and 17b) of both wings by the head (19). The head (19) is extended/retracted using a cylinder (22) moved by a drive motor (18), which may be an electric motor, a hydraulic motor or a mechanical motor, or manually using cables and pulleys.

The invention discloses a hovercraft using single ducted fan with vectoring propulsion, including a hull and a single ducted fan arranged on the hull, wherein the single ducted fan comprises barrel shaped shell and oar-blade component arranged in chamber of the shell, a first air outlet is disposed on one side of shell towards the tail end of the hull, diversion rudders enabling to block the first air outlet are disposed on the shell, two first air guide all connected with chamber of the shell is disposed on both sides of the shell, a second air outlet towards external of the single ducted fan is disposed on the first air guide, and the second air outlet and the first air outlet are arranged in reverse or with an included angle greater than 0 degree.

In one aspect, there is provided a combination vehicle system, including a drone and a hovercraft body. The drone has a plurality of motor-driven rotors and a controller. The hovercraft body defines a ground-facing chamber having a hover air inlet, and includes a mount for the drone. The drone is removably connectable to the mount in a mounted position so as to form a hovercraft. The controller is programmed to drive the plurality of rotors to maintain stable flight of the drone without the hovercraft body connected thereto. The controller is programmed to drive the first rotor to at least partially lift the hovercraft off a support surface and to drive the second rotor to propel the hovercraft along the support surface.

In one aspect, there is provided a combination vehicle system, including a drone and a hovercraft body. The drone has a plurality of motor-driven rotors and a controller. The hovercraft body defines a ground-facing chamber having a hover air inlet, and includes a mount for the drone. The drone is removably connectable to the mount in a mounted position so as to form a hovercraft. The controller is programmed to drive the plurality of rotors to maintain stable flight of the drone without the hovercraft body connected thereto. The controller is programmed to drive the first rotor to at least partially lift the hovercraft off a support surface and to drive the second rotor to propel the hovercraft along the support surface.

A pneumatic ship and a pneumatic ship system are provided. The pneumatic ship includes a floating body which is suitable for floating on a water surface and a pneumatic propulsion device arranged on the floating body, wherein the pneumatic propulsion device is suitable for forming airflow to generate a propulsive force, so as to push the floating body to move. Technical solutions of the present invention have a higher flexibility.

A pneumatic ship and a pneumatic ship system are provided. The pneumatic ship includes a floating body which is suitable for floating on a water surface and a pneumatic propulsion device arranged on the floating body, wherein the pneumatic propulsion device is suitable for forming airflow to generate a propulsive force, so as to push the floating body to move. Technical solutions of the present invention have a higher flexibility.

In one aspect, there is provided a combination vehicle system, including a drone and a hovercraft body. The drone has a plurality of motor-driven rotors and a controller. The hovercraft body defines a ground-facing chamber having a hover air inlet, and includes a mount for the drone. The drone is removably connectable to the mount in a mounted position so as to form a hovercraft. The controller is programmed to drive the plurality of rotors to maintain stable flight of the drone without the hovercraft body connected thereto. The controller is programmed to drive the first rotor to at least partially lift the hovercraft off a support surface and to drive the second rotor to propel the hovercraft along the support surface.

In one aspect, there is provided a combination vehicle system, including a drone and a hovercraft body. The drone has a plurality of motor-driven rotors and a controller. The hovercraft body defines a ground-facing chamber having a hover air inlet, and includes a mount for the drone. The drone is removably connectable to the mount in a mounted position so as to form a hovercraft. The controller is programmed to drive the plurality of rotors to maintain stable flight of the drone without the hovercraft body connected thereto. The controller is programmed to drive the first rotor to at least partially lift the hovercraft off a support surface and to drive the second rotor to propel the hovercraft along the support surface.

A hovercraft assembly includes a vehicle that may be driven. A pair of propulsion units is provided and each of the propulsion units is coupled to the vehicle. Each of the propulsion units may urge air outwardly from the body. Thus, the vehicle may levitate with respect to support surface. Each of the propulsion units may direct the air in a selected direction with respect to the body. Thus, the propulsion units may urge the vehicle along the support surface in a selected direction. Each of the propulsion units is operationally coupled to the handlebars such that the handlebars control operational parameters of each of the propulsion units.