The present disclosure provides a launching mechanism for a drone that is housed within a container. The launching mechanism is also housed within the container and is disposed at the bottom portion of the container such that the effect of its activation causes the drone to move along a container axis defined by the longitudinal axis of the container, at a direction towards a top cover of the container and eject therethrough during the launching process. The launching mechanism includes two elements, each has a receptacle portion, wherein the receptacle portion of one of the elements is received within the receptacle portion of the second element. The two receptacle portions, when one is received within the other, confine an inner space. One of the elements is a static element that is fixed to the container, and the other element is a dynamic element that upon application of force along the container axis in the direction of the top cover is free to move in the force direction and to push the drone that is disposed between it and the top cover of the container. A pressure generator of the launching mechanism is configured for controllably causing an abrupt increase of pressure in the inner space, thus generating a propelling force along the container axis in the direction of the top cover that pushes the drone and causing its launching out of the container. The dynamic element is detachably attached to the static element such that when the propelling force exceeds a certain value, the two elements detach one from the other and the dynamic element continues to move along the container axis.

This disclosure is generally directed to systems and methods for lifting drones to a desired height before launching. In one exemplary embodiment, a drone elevator system includes a looped cable that is engaged to a pair of pulleys. A first pulley of the pair of pulleys is coupled to a lighter-than-air craft and the second pulley is attached to a motor. The lighter-than-air craft moves upwards so as to raise the first pulley skywards and place the looped cable at an angle with respect to the ground. The motor is then operated to rotate the second pulley for moving the looped cable. The cable includes a set of tethers each of which is used to tether a drone. Each tether includes an extension arm that prevents the tethered drone from making contact with the cable when being lifted. Each tethered drone can be launched after being lifted to a desired height.

This disclosure is generally directed to systems and methods for lifting drones to a desired height before launching. In one exemplary embodiment, a drone elevator system includes a looped cable that is engaged to a pair of pulleys. A first pulley of the pair of pulleys is coupled to a lighter-than-air craft and the second pulley is attached to a motor. The lighter-than-air craft moves upwards so as to raise the first pulley skywards and place the looped cable at an angle with respect to the ground. The motor is then operated to rotate the second pulley for moving the looped cable. The cable includes a set of tethers each of which is used to tether a drone. Each tether includes an extension arm that prevents the tethered drone from making contact with the cable when being lifted. Each tethered drone can be launched after being lifted to a desired height.

A ground vehicle-based aircraft launching system automatically adjusts aircraft pitch and yaw during a ground vehicle-based launching operation, and automatically releases the aircraft upon attainment of a pre-designated lift angle with respect to the ground vehicle and the launching system. The launching system transfers primary thrust direction loads, allowing the aircraft to freely pitch and yaw based on prevailing wind and aerodynamics. A latch mechanism on the launching system moves within both the yaw and pitch directions with the aircraft, and maintains a positive lock on the aircraft prior to its release from the launching system. A yaw mechanism allows passive zeroing of sideslip winds, which in turn may avoid yawing, rolling, and/or yaw-roll coupled induced roll forces.

The present invention discloses an integrated airport design. The runways are designed in an elevated curved shape. The middles of landing runways and take-off runways are designed as an overhead parking apron, and the terminal building is below the runways. Therefore, the usable area of the whole airport is increased. The length of each elevated curved runway is lengthened comparing to the traditional straight runway within the same area. In addition, the downhill take-off runway can enhance take-off operation and reduce the fuel consumption. Thus, the existing land resources can be used to the maximum extent.

An unmanned aerial vehicle (UAV) storage and launch system, including: a UAV pod having an interior; and a telescoping UAV landing surface disposed in the interior of the UAV pod; where the telescoping UAV landing surface may translate up toward a top opening of the UAV pod, translate down into an interior of the UAV pod, or rotate relative to the UAV pod.

An unmanned aerial vehicle (UAV) storage and launch system, including: a UAV pod having an interior; and a telescoping UAV landing surface disposed in the interior of the UAV pod; where the telescoping UAV landing surface may translate up toward a top opening of the UAV pod, translate down into an interior of the UAV pod, or rotate relative to the UAV pod.

An unmanned aerial vehicle launch tube that has a tube, a sabot disposed in an interior of said tube, said sabot having a first clasp tab, and a clasp detachably coupled to said first clasp tab and contacting an inner circumferential wall of said tube so that said clasp is rotationally constrained by the inner circumferential wall and said first clasp tab.

An unmanned aerial vehicle launch tube that has a tube, a sabot disposed in an interior of said tube, said sabot having a first clasp tab, and a clasp detachably coupled to said first clasp tab and contacting an inner circumferential wall of said tube so that said clasp is rotationally constrained by the inner circumferential wall and said first clasp tab.

A modular flying car includes a ground vehicle and a flight vehicle. The ground vehicle includes a chassis, a first cabin and a landing platform for landing the flight vehicle. The flight vehicle includes a second cabin and a flight driving device. The flight vehicle is capable of landing and taking off vertically on the landing platform and connected with the ground vehicle by interlocking. Users can choose to travel by the ground vehicle or the flight vehicle, and can transfer between the ground vehicle and the flight vehicle, to solve the traffic jam problem and make the realization of the flying car more feasible. A flying car system and a flying car sharing method are also disclosed.