Systems and methods related to landing unmanned aerial vehicles (UAVs) are provided. In one example, a method includes receiving a UAV on a surface of a landing platform. The method may further include operating a positioning device disposed under the surface to locate the UAV. The method may further include operating the positioning device to move the UAV to a location and/or an orientation on the surface. The UAV may comprise landing gear having a plurality of legs, where each leg comprises a shock absorption system. The method may further include operating the shock absorption system during the receiving operation to reduce force received at stress areas of the UAV, and after the receiving operation, operating the shock absorption system to dampen movement by the UAV. Related devices and systems are also provided.

An apparatus for supporting a ceiling mounted unmanned aerial vehicle docking station in a premises security system is provided for a premises including a ceiling grid and a support structure disposed above the ceiling grid. The apparatus includes an unmanned aerial vehicle docking station mounting bracket including a top surface and a bottom surface which is affixable to an exposed surface of a ceiling element in the ceiling grid by a first plurality of fastening elements. The bottom surface of the bracket is affixable to the ceiling mounted unmanned aerial vehicle docking station. The apparatus further includes a panel including a top surface and a bottom surface which is affixable to a concealed surface of the ceiling element by the first plurality of fastening elements. The top surface of the panel includes at least one anchoring element for physically coupling the panel to the support structure.

The invention relates to a logistics station for drones, which can be adapted to different drones (12) and comprises at least one landing zone including means for holding a drone, a robot (30) for replacing the drone batteries and/or charging the drone, and a battery store (20).

The invention relates to a logistics station for drones, which can be adapted to different drones (12) and comprises at least one landing zone including means for holding a drone, a robot (30) for replacing the drone batteries and/or charging the drone, and a battery store (20).

Disclosed is a smart mailbox receptacle and drone docking station for deposit of items/goods delivered by a robot, drone by landing or tethering packages, or courier each to a secured receptacle. Items can be delivered to a receptacle at a curb, mailbox, post, or porch. Features include communication systems between the station and drone; security; hot and cold temperature control and preservation of the goods before and after delivery; battery charging and exchange station; a collector to identify explosive materials, anthrax, etc.; ultraviolet system to eradicate disease, virus and harmful materials; an ozone applicator to eradicate disease, virus and harmful materials; weather monitoring; tag and track of vehicles and packages; facial recognition camera and software for pets and humans; and local two-way speakers; LED lights that strobe flash, and a flood light.

Disclosed is a smart mailbox receptacle and drone docking station for deposit of items/goods delivered by a robot, drone by landing or tethering packages, or courier each to a secured receptacle. Items can be delivered to a receptacle at a curb, mailbox, post, or porch. Features include communication systems between the station and drone; security; hot and cold temperature control and preservation of the goods before and after delivery; battery charging and exchange station; a collector to identify explosive materials, anthrax, etc.; ultraviolet system to eradicate disease, virus and harmful materials; an ozone applicator to eradicate disease, virus and harmful materials; weather monitoring; tag and track of vehicles and packages; facial recognition camera and software for pets and humans; and local two-way speakers; LED lights that strobe flash, and a flood light.

The present invention relates to a hat sweatband tape device comprised of an inner core that houses a roll-like body, which is preferably manufactured from a fabric material. The material is absorbent and/or moisture wicking to absorb or wick away excess sweat, and is also preferably padded for comfort. The body material is preferably rectangular in shape and is stored on a paper or cardboard-based, circular inner core. The bottom surface of the body further has a peelable adhesive layer. To apply the device to a hat, a user can unroll a portion of the body from the inner core to obtain the desired length of the body for use, and then cut or tear the body to said length. Then, a user can remove the peelable cover layer and place the adhesive bottom surface on or behind the sweatband or in another interior area of a hat.

A thermally controlled payload container for carrying payloads by an Unmanned Aerial Vehicle (UAV) comprising an inner wall and an outer wall. The inner wall forms a chamber having an open end and a closed end. The payload container also comprises a thermal control body adjacent to the inner wall and disposed between the inner wall and the outer wall. The payload container also comprises a thermoelectric cooler (TEC) extending through the outer wall from a first side of the TEC to a second side of the TEC, the first side adjacent the thermal control body and the second side coupled to an external heat sink.

A canister is coupled to a delivery vehicle using a rail bracket. The canister comprises a securing channel having a first securing channel volume and a second securing channel volume. A width of the first securing channel volume is less than a width of the second securing channel volume. The rail bracket comprises a rotational shaft having a finger at one end. The rail bracket is inserted into the securing channel, and the rotational shaft is rotated. When rotated, the finger inhibits removal of the rail bracket from the securing channel, thereby providing a mechanism by which the canister can be releasably coupled to the rail bracket. The rail bracket may be provided on a delivery vehicle, such as an unmanned aerial vehicle (UAV) to transport the canister and contents within it.

A system for swapping one or more batteries includes a battery holder configured to store a first battery, wherein the battery holder further includes retainers positioned proximate a front end and a rear end of the battery holder, the retainers having a first position and a second position such that the retainers, in the first position, are configured to engage the first battery in order to dispose the first battery in a storage position in the battery holder and, in the second position, are configured to disengage from the first battery to allow the first battery to move from the storage position. The system further includes cartridges having a front end and a rear end configured to couple to at least one of the front end and the rear end of the battery holder and further configured to hold a second battery in the second enclosure.