A coordinated support system for drones includes support units that have the shape and size of a common container and can be easily moved by using common road tractors, so to position a drone fleet close to a fire, possibly recover the aircraft at the end of the mission, and enable transfer during the mission to areas of strategic interest or priority importance to effectively fight the spreading of fire fronts in real time. Coordination and control are carried out through a control unit. The drones are powered by batteries, the automated replacement and recharging of which extends flight autonomy. The system enables an initial filling and subsequent multiple refills of the drones with an extinguishing liquid contained in small dispersible containers, which can be hooked and unhooked from the drones by remote control so to perform multiple missions.

A method of deploying an unmanned aerial vehicle (UAV) includes launching a UAV and deploying at least one portion of a wing assembly from a stowed configuration to a deployed configuration in which the at least one portion of the wing assembly extends away from a body of the UAV. Deploying the portion of the wing assembly, which may be an outboard portion of a wing assembly, includes deflecting an aerodynamic control surface on the at least one portion of the wing assembly to cause an aerodynamic force to move the portion of the wing assembly into the deployed configuration without assistance from a spring or motor. An unmanned aerial vehicle (UAV) includes a UAV having a body and a plurality of wing assemblies carried by the body, at least a portion of a wing assembly is deployable using aerodynamic forces and without assistance form a spring or motor.

A UAV package delivery system includes a cabinet for deployment inside a merchant facility. The cabinet is configured for storing and charging UAVs on-site at the merchant facility remote from a command and control of the UAVs. The cabinet includes a plurality of cubbies, power circuitry, communication circuitry, and a controller. The cubbies are each sized and shaped to receive one of the UAVs. The power circuitry is configured for charging the UAVs when the UAVs are stowed within the cubbies. The communication circuitry is configured for communicating with the UAVs when the UAVs are proximate to the cabinet or stowed within the cubbies and for communicating with the command and control. The controller causes the UAV package delivery system to retrieve status information from the UAVs, relay the status information to the command and control, and relay mission data between the command and control and the UAVs.

A method and apparatus for scalable and fast deployment of drones are presented. The method is based on packing multiple drones within a cell structure that provides means for changing, communication and fast deployment of drones as well as environmental protection. Multiple cells can be combined the further scale up the number and rate of drones being deployed. In a preferable arrangement, individual drones are equipped with special contacts that allow them to connect to the cell and optionally with other drones for power supply, diagnostic and communication.

Systems, devices, and methods including a launch control box; a multi-pack launcher (MPL) box; and a cable connecting the launch control box and the MPL box, where the cable comprises: an outer jacket, a shielded braid, a first wire, a second wire, a third wire, and a fourth wire, where the first wire and the second wire are shielded by the shielded braid, where the third wire and the fourth wire are outside of the shielded braid, and where the third wire and the fourth wire act as an antenna.

An unmanned aerial vehicle (UAV) module includes a UAV having foldable wings coupled to a body of the UAV, a UAV case having length and width dimensions that is constructed and arranged to operate in (i) a closed configuration that stores and protects the UAV while the UAV module is transported within the UAV case between locations with the foldable wings in a folded configuration, and (ii) an opened configuration that provides a base from which the UAV launches vertically from within the UAV case while the foldable wings of the UAV remain in the folded configuration. The UAV is constructed and arranged to automatically unfold the foldable wings outwards from the body of the UAV to form a fixed wing that extends beyond the length and width dimensions of the UAV case for fixed wing horizontal flight after the UAV is airborne.

An unmanned aerial vehicle (UAV) module includes a UAV having foldable wings coupled to a body of the UAV, a UAV case having length and width dimensions that is constructed and arranged to operate in (i) a closed configuration that stores and protects the UAV while the UAV module is transported within the UAV case between locations with the foldable wings in a folded configuration, and (ii) an opened configuration that provides a base from which the UAV launches vertically from within the UAV case while the foldable wings of the UAV remain in the folded configuration. The UAV is constructed and arranged to automatically unfold the foldable wings outwards from the body of the UAV to form a fixed wing that extends beyond the length and width dimensions of the UAV case for fixed wing horizontal flight after the UAV is airborne.

Apparatus for releasing a payload from an air vehicle (14), the apparatus comprising a generally tubular holding device (10) mounted on, or formed integrally with, said air vehicle, said holding device (10) having an open end facing in a direction substantially opposite to the direction of travel (16) of said air vehicle (14), in use, the apparatus further comprising a container (18) for housing said payload and configured to be at least partially received within said holding device (10), at least one releasable retaining device (20) for releasably retaining said container (18) within said holding device (10), and an actuation device for selectively actuating said at least one releasable retaining device to release said container from said holding device, said container (18) having thereon at least one drag inducing device (22) configured to induce drag in a direction substantially opposite to that of said direction of travel (16) of said air vehicle, in use, so as to act to drag said container (18) from said holding device (10) through said open end.

An unmanned aerial vehicle (UAV) launch tube that comprises at least one inner layer of prepreg substrate disposed about a right parallelepiped aperture, at least one outer layer of prepreg substrate disposed about the right parallelepiped aperture, and one or more structural panels disposed between the at least one inner layer of prepreg substrate and the at least one outer layer of prepreg substrate. An unmanned aerial vehicle (UAV) launch tube that comprises a tethered sabot configured to engage a UAV within a launcher volume defined by an inner wall, the tethered sabot dimensioned to provide a pressure seal at the inner wall and tethered to the inner wall, and wherein the tethered sabot is hollow having an open end oriented toward a high pressure volume and a tether attached within a hollow of the sabot and attached to the inner wall retaining the high pressure volume or attach to the inner base wall. A system comprising a communication node and a launcher comprising an unmanned aerial vehicle (UAV) in a pre-launch state configured to receive and respond to command inputs from the communication node.

A coordinated support system for drones includes support units that have the shape and size of a common container and can be easily moved by using common road tractors, so to position a drone fleet close to a fire, possibly recover the aircraft at the end of the mission, and enable transfer during the mission to areas of strategic interest or priority importance to effectively fight the spreading of fire fronts in real time. Coordination and control are carried out through a control unit. The drones are powered by batteries, the automated replacement and recharging of which extends flight autonomy. The system enables an initial filling and subsequent multiple refills of the drones with an extinguishing liquid contained in small dispersible containers, which can be hooked and unhooked from the drones by remote control so to perform multiple missions.