Methods, systems and devices for optical structural health monitoring of a subject, including the utilization of pointillism to provide a design or painting of the surface of the structure to be monitored, which also serves as a mechanism for conducting SHM, implementing digital image correlation (DIC) by applying a pattern comprising a random dot pattern and/or codes. The subject is imaged using imaging equipment to capture images of the pattern. For some applications, the captured images of the pattern and codes are stored in a CAD file that represents the subject or portion thereof to which the pattern and codes are applied, and includes the locations of the pattern and codes. Indicia applied to a structure may be applied using a paintjet or inkjet, or robotic mechanism, while some applications implement pre-patterning of a composite sheet that is used to form the structure.

One example method of operation may include identifying a likelihood of an object presence at one or more locations within a predefined distance of locations explored by a drone during one or more monitoring actions performed by the drone during a mission including a number of mission requirements, selecting one or more new monitoring actions to perform by the drone based on the likelihood of the object presence to satisfy the mission requirements, and performing the one or more new monitoring actions by the drone.

An unmanned aerial vehicle (UAV) having an envelope and a drone body capable of delivering packages is disclosed. Methods for utilizing UAVs to deliver packages and systems for housing UAVs are also disclosed. In one aspect, a UAV includes a dual cavity envelope having an ellipsoid shape with a first internal cavity and a second internal cavity, the first internal cavity configured to hold a lighter than air gas, the second internal cavity configured to hold a heated gas, and a drone body attached to and located below the dual cavity vertical envelope.

The invention relates to a platform (28) for the take-off and landing of an aircraft (12) for generating electric power by means of a generator (24) and comprising: a stationary support (30); a receiving structure (32) that is intended to accommodate the aircraft (12) and is connected to the stationary support (30); The receiving structure (32) is mounted pivotably relative to the stationary support (30) by means of an orientable turntable (38) so as to allow the receiving structure (32) to be positioned according to the wind direction. The receiving structure (32) for accommodating the aircraft (12) comprises an air-permeable net (34) that is stretched between arms (36) belonging to the receiving structure (32).

Embodiments include an atmospheric water harvesting system and method for using the same. Aspects include receiving atmospheric data corresponding to a harvest area of the atmospheric water harvesting system and determining, based at least in part on the atmospheric data, that atmospheric conditions in the harvest area are conducive for atmospheric water harvesting. Aspects also include deploying an unmanned aerial vehicle (UAV) including a fog harvesting fabric into the harvest area and receiving, by a water reservoir tethered to the UAV by a tubing configured to transfer water from the fog harvesting fabric to the water reservoir, harvested water.

A method of using a bagged power generation system comprising windbags and waterbags integrated with drones and adapting drone technologies for harnessing wind and water power to produce electricity. An extremely scalable and environmentally friendly method, system, apparatus, equipment, techniques and ecosystem configured to produce renewable green energy with high productivity and efficiency.

A rotor for use with an airborne wind turbine, wherein the rotor comprises a front flange, a can, a rear flange, and a rigid insert comprising a propeller mount, wherein the front flange, can, and rear flange comprise one of carbon fiber and spun aluminum, wherein a rear end of the front flange is attached to a front end of the can, and the rear flange is mounted to a rear end of the can, wherein the rigid insert is bonded to the front flange; and wherein the rigid insert comprises a tube that axially extends within the rotor to allow for the positioning of a driveshaft therethrough.

The invention concerns an airborne device comprising at least three supporting wings and a linking device, the wings being linked to each other by first flexible cables, each wing being further linked to the linking device by a second flexible cable, the linking device being linked to a third flexible cable intended to be linked to a base, the first second, and third cables being tensioned when the airborne device is carried in the wind.

An energy kite may be coupled to a tether and ground station. The tether or other cables may need to be terminated, where one or more components of the cable need to be separated and terminated individually. In energy kite systems, it is common for the tether (or other cables) to have small mass and diameter. The termination may also include a first potted region with a softer potting material and a second potted region with a harder potting material.

A method of using a bagged power generation system comprising windbags and water-bags for harnessing wind and water power to produce electricity to meet the escalating energy needs of mankind. Windbags integrated with aerodynamically shaped inflatable bodies filled with lighter-than-air gas: HAV, UAV, airplanes; enabling the apparatus to attain high altitude to capture and entrap high velocity wind. Water-bags integrated with hydrodynamic shaped bodies HUV, UUV, Submarine-boats; enabling the apparatus to dive, capture and entrap swift moving tidal-currents. Attached tether-lines pulling on the rotating reel-drums and generators to produce electricity. Active control surfaces, turbo-fans, propellers provide precision control of the apparatus. A system configured to maximize fluids capture, retention and optimized extraction of its kinetic energy. An extremely scalable and environmentally friendly method, system, apparatus, equipment and techniques configured to produce renewable green energy with high productivity and efficiency.