A wind turbine blade, extending longitudinally root end to tip end, having a load carrying structure, a shell body and a lightning protection system is described. The load carrying structure is fiber-reinforced polymer in a plurality of stacked layers comprising electrically conductive fibers. The lightning protection system comprises a lightning receptor arranged freely accessible in or on the shell body and a lightning down-conductor electrically connected to the lightning receptor and is configured to be electrically connected to a ground connection. The blade further comprises a potential equalisation system providing a potential equalising connection between a number of the electrically conductive fibers of the load carrying structure and the lightning protection system. The system comprises a dissipating element made of an electrically conductive material which in turn comprises at least one transverse connector arranged to extend transverse through a thickness of the stacked fiber layers and configured to dissipate.

This invention relates to a wind turbine blade with retrofitted coating in and around areas where the blade is especially exposed to erosion damages, which is established by the coating including a glue layer, a fiber reinforced polymer layer and one or more non-reinforced polymer layers over the fiber reinforced layer, since the polymer layers stretch themselves out over the fiber reinforced layer and includes areas of the wind turbine blade's surface, which are less exposed to erosion damages. A method for creation of such a wind turbine blade and creation of such a coating and the coating itself, is also established with the invention.

Among other things, the present disclosure relates to a wind turbine rotor blade that can be assembled at the site of its wind turbine. The blade includes an internal structure which may be pre-fabricated with connections to the shell skin prior to being transported to the site of its wind turbine. A filler material may be injected into the layers of fabric making up the shell skin at the wind turbine site and allowed to harden at approximately atmospheric conditions.

A wind turbine blade comprises an external skin comprising tensioned fabric supported along a majority of the length of the wind turbine blade by two or more elongate fabric supporting members. The external skin is connected to each of the two or more elongate fabric supporting members.

The present subject matter is directed to methods for manufacturing rotor blades and/or components thereof of a wind turbine. In one embodiment, the method includes forming the rotor blade component and covering at least a portion of the rotor blade component with at least one coating material. In addition, the coating material includes at least one additive having a changeable pigment. After the component is formed, the method includes inspecting the rotor blade component for defects. After inspection, the method further includes activating the additive to change the pigment from a transparent finish to a colored finish.

The wind harnessing device includes an axle, a number of radially outward extending first and second poles respectively arranged at equal intervals around a first end and a second end of the axle, a number of blade assemblies, and a rack to which the axle is rotatably mounted. Each first pole is aligned with and parallel to a second pole. Each blade assembly includes a first beam, a second beam, and a flat blade. The first and second beams are respectively attached to and along a first edge and an opposite second edge of the blade. The first beam's two ends are pin joined to the outer ends of a pair of corresponding first and second poles so that the blade is able to swing about the first beam. The wind harnessing device thus structured is of lower weight, reduced cost, and easy maintenance.

A frame which includes adjacent, spaced-apart segments that define adjacent, spaced-apart, and parallel closed-loop tracks supporting two or more articulated foils between the adjacent frame segments. Opposite distal ends of the foils cooperate with opposite tracks of the frame segments so that the foils can traverse along the tracks when current lifts the foils and pushes them along the tracks.

The present invented device is mounted on tower at seashore, desert or mountaintops. The device is mounted on the rotating stand, which is on the tower. As the air will be released into a long tunnel (tail), the device will automatically arrange in wind facing direction and the running air will continuously enter into the device. The entered inner part of the device has air collection chambers, so when the wind will get concentrated it will create air pressure. The pressured air will be released into a tunnel, where the turbine is mounted into the tail part to generate energy. And pressurized air will be released from the tail. The multiple device will be placed on high tower as high as a general windmill is mounted.

The present disclosure provides a defect-detectable fiber fabric, including a plurality of bunches of fibers and a plurality of braided threads configured to respectively fix together fibers of each bunch of fibers. The plurality of braided threads include first braided threads each having a color different from a color of any of the plurality of bunches of fibers, and a respective distance between every two adjacent first braided threads is configured to make wrinkle defects that could be formed in fabric layers detectable. After the curing and molding, the positions of the defects and the layer(s) where the defects are formed can be determined according to the states of the first braided threads.