A deck landing system for aircrafts, in particular rotating wing aircrafts, apt to implement a hook between the aircraft and the deck of a ship or of a floating platform, the deck being equipped with a target grid plate, it does not require the use of hydraulic systems and it comprises: a telescopic actuator (1) with a harpoon (3) having, at its own distal end, hooking grippers (7); and a control unit (9) which actuates said telescopic actuator (1), wherein the telescopic actuator (1) comprises a linear electromechanical actuator (8) having: a main battery (13) fed through a unit (12) for converting and conditioning the energy and connected to said telescopic actuator (1); and a device (10) for recovering and releasing the kinetic energy generated by the waves with the aircraft locked on said deck, is of the type acting with super-capacitors, which feeds said main battery (13).

A multicopter system according to one aspect of the present invention includes a multicopter configured to fly in a state of holding a package and a mooring device that is installed at a target position of a flight of the multicopter and includes a linear member that extends in a predetermined direction from the target position, the multicopter including a reception portion that has the shape of a recess including an opening open toward one direction and is configured to receive the linear member via the opening.

A multicopter system according to one aspect of the present invention includes a multicopter configured to fly in a state of holding a package and a mooring device that is installed at a target position of a flight of the multicopter and includes a linear member that extends in a predetermined direction from the target position, the multicopter including a reception portion that has the shape of a recess including an opening open toward one direction and is configured to receive the linear member via the opening.

This document describes a system and method through which unmanned aerial vehicles (UAVs) can be docked, with a device that can secure the UAVs, and information can be transmitted to and from such UAVs. The UAVs are secured through the use of magnetic fields. The system also includes a means for transmitting information between the docking system itself, the UAV(s) and/or between the docking system and a command center, which may be a notable distance from the docking system, or among the docking system, the UAV(s) and the command center.

This document describes a system and method through which unmanned aerial vehicles (UAVs) can be docked, with a device that can secure the UAVs, and information can be transmitted to and from such UAVs. The UAVs are secured through the use of magnetic fields. The system also includes a means for transmitting information between the docking system itself, the UAV(s) and/or between the docking system and a command center, which may be a notable distance from the docking system, or among the docking system, the UAV(s) and the command center.

A material handling robot including a mobile base, a plurality of drones, and a plurality of docking stations on the mobile base for receiving the drones. The mobile base has motorized wheels for driving the mobile base, and a platform for supporting a load. Each drone has a power source and a drone sensor for monitoring environment around the drone. Each docking station has a power charger for recharging the power source, and a launch mechanism for deploying the drone. The robot also includes a controller for communicating with the mobile base and the drones. The controller has: a material handling mode for transporting loads on the platform of the mobile base; and a security mode where at least one of the drones is deployed to conduct surveillance using the drone sensor.

A material handling robot including a mobile base, a plurality of drones, and a plurality of docking stations on the mobile base for receiving the drones. The mobile base has motorized wheels for driving the mobile base, and a platform for supporting a load. Each drone has a power source and a drone sensor for monitoring environment around the drone. Each docking station has a power charger for recharging the power source, and a launch mechanism for deploying the drone. The robot also includes a controller for communicating with the mobile base and the drones. The controller has: a material handling mode for transporting loads on the platform of the mobile base; and a security mode where at least one of the drones is deployed to conduct surveillance using the drone sensor.

Aspects of the disclosure relate to techniques for launching high-altitude balloons. In one aspect, a balloon launching system is provided. The balloon has a balloon envelope, a payload attached to the balloon envelope and a launching projection. The launching system includes a releasable restraint attached to the balloon between an apex and bottom of the balloon envelope. The releasable restraint is arranged to temporarily hold the balloon envelope. The launching system also includes a payload positioning assembly. The payload positioning assembly is configured to position the payload during launch of the balloon and includes a member configured to attach to the launching projection. When attached, the member is also configured to maintain the position of the payload relative to the balloon while the releasable restraint is temporarily holding the balloon envelope.

Aspects of the disclosure relate to techniques for launching high-altitude balloons. In one aspect, a balloon launching system is provided. The balloon has a balloon envelope, a payload attached to the balloon envelope and a launching projection. The launching system includes a releasable restraint attached to the balloon between an apex and bottom of the balloon envelope. The releasable restraint is arranged to temporarily hold the balloon envelope. The launching system also includes a payload positioning assembly. The payload positioning assembly is configured to position the payload during launch of the balloon and includes a member configured to attach to the launching projection. When attached, the member is also configured to maintain the position of the payload relative to the balloon while the releasable restraint is temporarily holding the balloon envelope.

The present invention relates to a system, method and station for docking unmanned vehicles. The system, method and station are particularly relevant, but not limited to dock the unmanned vehicles for autonomous operations. Further the system, method and station are particularly relevant, but not limited to protect the unmanned vehicles from external environments.