The disclosure concerns a drone trailer system. The drone trailer system includes a rear door hingedly coupled to a distal end of a trailer. A first track system is disposed on the trailer at a floor thereof. A second track system is disposed on the rear door at an inner surface thereof. A movable platform is slidably engaged with the first track system, the second track system, or both. A drone is configured to sit on top of the moveable platform to allow for fast deployment.

The invention relates to a mobile structure for dispatching and accommodating drones, comprising a landing platform, a lifting unit for adjusting the height of the landing platform, and a storage unit. The lifting unit allows lifting and lowering of the landing platform up to a height from which a drone can take off and land (take-off height), and to a height in which the landing platform can transfer a drone to a storage level of the storage unit or receive the drone from a storage level (storage level height).

The invention relates to a mobile structure for dispatching and accommodating drones, comprising a landing platform, a lifting unit for adjusting the height of the landing platform, and a storage unit. The lifting unit allows lifting and lowering of the landing platform up to a height from which a drone can take off and land (take-off height), and to a height in which the landing platform can transfer a drone to a storage level of the storage unit or receive the drone from a storage level (storage level height).

A drone pod may receive, stow, and launch a drone. The drone pod may include a housing, a canopy movably coupled to the housing, a platform movably coupled to the housing, and a drone bay. The drone pod may be configured to move the canopy to expose the drone bay and raise the platform relative to a floor of the drone bay to receive the drone, lower the platform toward the floor of the drone bay and move the canopy to enclose the drone bay to stow the drone, move the canopy to expose the drone bay and raise the platform relative to the floor of the drone bay to launch the drone. The drone pod may be mounted on a vehicle. A system may include a drone pod and a drone, wherein the drone pod is configured to receive, stow, and launch the drone.

A drone pod may receive, stow, and launch a drone. The drone pod may include a housing, a canopy movably coupled to the housing, a platform movably coupled to the housing, and a drone bay. The drone pod may be configured to move the canopy to expose the drone bay and raise the platform relative to a floor of the drone bay to receive the drone, lower the platform toward the floor of the drone bay and move the canopy to enclose the drone bay to stow the drone, move the canopy to expose the drone bay and raise the platform relative to the floor of the drone bay to launch the drone. The drone pod may be mounted on a vehicle. A system may include a drone pod and a drone, wherein the drone pod is configured to receive, stow, and launch the drone.

The present disclosure relates to a hangar for at least one unmanned aerial vehicle, comprising: an interior, which is delimited by a lower side, an upper side and at least one side part, at least one manipulator arm in the interior, wherein the manipulator arm is designed to transport the at least one unmanned aerial vehicle through a closable opening in the at least one side part from the interior to the outer upper side of the hangar and/or wherein the manipulator arm is configured to transport the at least one unmanned aerial vehicle through a closable opening in the at least one side portion from the outer top of the hangar into the interior, wherein the manipulator arm is programmable and/or adapted to transport different unmanned aerial vehicles having different characteristics. Furthermore, the present disclosure relates to a system comprising at least two hangars.

The present disclosure relates to a hangar for at least one unmanned aerial vehicle, comprising: an interior, which is delimited by a lower side, an upper side and at least one side part, at least one manipulator arm in the interior, wherein the manipulator arm is designed to transport the at least one unmanned aerial vehicle through a closable opening in the at least one side part from the interior to the outer upper side of the hangar and/or wherein the manipulator arm is configured to transport the at least one unmanned aerial vehicle through a closable opening in the at least one side portion from the outer top of the hangar into the interior, wherein the manipulator arm is programmable and/or adapted to transport different unmanned aerial vehicles having different characteristics. Furthermore, the present disclosure relates to a system comprising at least two hangars.

A drone delivery system hub and method for sending for take-off and receiving for landing unmanned aerial vehicles (UAVs). The drone delivery system hub includes a center shaft frame, a parcel-conveying system supported by the center shaft frame, structural arms coupled to and extending outward from the center shaft frame in a spoke-like configuration, drone-conveying systems each supported by one of the structural arms, and a linking conveyor span. The drone-conveying system conveys the UAVs along a length of a correspond one of the structural arms toward and away from the center shaft frame. The linking conveyor span selectably rotates to different orientations between different pairs of the structural arms, selectively conveying a UAV thereon between any two of the structural arms. The linking conveyor span is located above the parcel-conveying system such for the UAV thereon to deposit and retrieve parcels from the parcel-conveying system.

A drone delivery system hub and method for sending for take-off and receiving for landing unmanned aerial vehicles (UAVs). The drone delivery system hub includes a center shaft frame, a parcel-conveying system supported by the center shaft frame, structural arms coupled to and extending outward from the center shaft frame in a spoke-like configuration, drone-conveying systems each supported by one of the structural arms, and a linking conveyor span. The drone-conveying system conveys the UAVs along a length of a correspond one of the structural arms toward and away from the center shaft frame. The linking conveyor span selectably rotates to different orientations between different pairs of the structural arms, selectively conveying a UAV thereon between any two of the structural arms. The linking conveyor span is located above the parcel-conveying system such for the UAV thereon to deposit and retrieve parcels from the parcel-conveying system.

A docking system for unmanned aerial vehicles (UAVs) includes a docking housing that defines a docking compartment, and a docking assembly coupled to the docking housing and configured to suspend the UAV within the docking compartment. The docking assembly may include a guiding feature configured to receive a docking feature of the UAV and direct the UAV toward a first captured position. The docking assembly may further include an advancement assembly operatively coupled with the guiding feature and configured to move the UAV from the first captured position to a second docked position.