The invention relates to an emergency support robot for polar UAVs, belonging to the technical field of emergency support robots for polar UAVs. The technical problem to be solved is to improve the structure of the existing emergency support robots for polar UAVs. The technical scheme adopted is as follows: the robot is of a car body structure; a support table is arranged on the upper side of the chassis of the car body; a traveling mechanism is arranged on both sides of the chassis of the car body; the two sides of the support table are hinged with a pair of casings through hinged buckles and push rods; the casings are also provided with a wind power plant; the support table is provided with a launching guide rail.

A system for basing drones is described. A network of geographically diverse hangars provides storage and charging locations as well as backhaul communications infrastructure and video monitoring. As drones are needed, a central command point tasks an available drone, which may or may not already be located in proximity to a target. If additional drones are needed, drones can be flown to the area of interest and continuous coverage provided by charging drones while an active drone is conducting the mission, then rotating charged drones into the active mission. Structures for the hangars, the overall system, and methods of operation are described.

A system for basing drones is described. A network of geographically diverse hangars provides storage and charging locations as well as backhaul communications infrastructure and video monitoring. As drones are needed, a central command point tasks an available drone, which may or may not already be located in proximity to a target. If additional drones are needed, drones can be flown to the area of interest and continuous coverage provided by charging drones while an active drone is conducting the mission, then rotating charged drones into the active mission. Structures for the hangars, the overall system, and methods of operation are described.

Systems and methods include UAVs that serve to assist carrier personnel by reducing the physical demands of the transportation and delivery process. A UAV generally includes a UAV chassis including an upper portion, a plurality of propulsion members configured to provide lift to the UAV chassis, and a parcel carrier configured for being selectively coupled to and removed from the UAV chassis. UAV support mechanisms are utilized to load and unload parcel carriers to the UAV chassis, and the UAV lands on and takes off from the UAV support mechanism to deliver parcels to a serviceable point. The UAV includes computing entities that interface with different systems and computing entities to send and receive various types of information.

A universal hitch adapter system includes a universal hitch adapter with at least one force sensor operable to measure push-and-pull forces and coupled to a) one of a front end and a rear end of an aircraft tractor and b) an aircraft tow bar coupled to a nose gear of an aircraft. The system also including a memory; a user input interface operable to receive a user's selection of one of a plurality of aircrafts stored in the memory and a user's input associated with one of a shear pin; a processor operably configured to determine at least one shear pin breaking force threshold for each of the plurality of aircrafts based on the user's input; and an indicator operable to emit an alert as a result of the force sensor measuring a force that meets or exceeds the at least one shear pin breaking force threshold.

A universal hitch adapter system includes a universal hitch adapter with at least one force sensor operable to measure push-and-pull forces and coupled to a) one of a front end and a rear end of an aircraft tractor and b) an aircraft tow bar coupled to a nose gear of an aircraft. The system also including a memory; a user input interface operable to receive a user's selection of one of a plurality of aircrafts stored in the memory and a user's input associated with one of a shear pin; a processor operably configured to determine at least one shear pin breaking force threshold for each of the plurality of aircrafts based on the user's input; and an indicator operable to emit an alert as a result of the force sensor measuring a force that meets or exceeds the at least one shear pin breaking force threshold.

In some embodiments, a system and/or method a may include a helicopter transport system. The helicopter transport system may include a support frame. The support frame may be substantially rectangular. The helicopter transport system may include a first pair of wheels. In some embodiments, the first pair of wheels may be positioned on opposing sides of the outer perimeter of the support frame towards a first end of the support frame. The helicopter transport system may include a second pair of wheels. The second pair of wheels may be positioned adjacent one another within the perimeter of the support frame towards a second end of the support frame. The first end of the support frame may be positioned opposite the second end of the support frame. The helicopter transport system may include a lift mechanism coupled to the support frame. The lift mechanism may elevate, during use, a helicopter above the support frame.

In some embodiments, a system and/or method a may include a helicopter transport system. The helicopter transport system may include a support frame. The support frame may be substantially rectangular. The helicopter transport system may include a first pair of wheels. In some embodiments, the first pair of wheels may be positioned on opposing sides of the outer perimeter of the support frame towards a first end of the support frame. The helicopter transport system may include a second pair of wheels. The second pair of wheels may be positioned adjacent one another within the perimeter of the support frame towards a second end of the support frame. The first end of the support frame may be positioned opposite the second end of the support frame. The helicopter transport system may include a lift mechanism coupled to the support frame. The lift mechanism may elevate, during use, a helicopter above the support frame.

An apparatus, system, and method are disclosed for moving an aircraft. The apparatus includes an elongated support frame, at least one tug wheel and a loading platform. The elongate support frame includes a wheel receiving recess shaped to receive a wheel of an aircraft. The tug wheel(s) support the elongated support frame. The loading platform is positioned within the wheel receiving space and is configured to support the aircraft wheel. The loading platform is positioned at a height relative to the elongated support frame that is sufficient to avoid interference between a propeller on the aircraft and the elongated support frame when the aircraft wheel is positioned on the loading platform.

An apparatus, system, and method are disclosed for moving an aircraft. The apparatus includes an elongated support frame, at least one tug wheel and a loading platform. The elongate support frame includes a wheel receiving recess shaped to receive a wheel of an aircraft. The tug wheel(s) support the elongated support frame. The loading platform is positioned within the wheel receiving space and is configured to support the aircraft wheel. The loading platform is positioned at a height relative to the elongated support frame that is sufficient to avoid interference between a propeller on the aircraft and the elongated support frame when the aircraft wheel is positioned on the loading platform.