A wind turbine blade including an elongate reinforcing structure, the reinforcing structure comprising a plurality of strips of fibre-reinforced polymer arranged into a stack structure, and at least one adjacent pair of the plurality of strips including an infusion promoting layer, wherein the infusion promoting layer is a fabric comprising a plurality of twisted yarns. The invention is also expressed as a method of assembling a wind turbine blade.

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.

Provided is a method for manufacturing tapered root segment sections for a root segment of a turbine blade, in particular a wind turbine blade, wherein the method includes the steps of: (a) winding multiple layers of a fabric around a winding core in a way such that a multilayered structure from the fabric having a shape tapered transverse to a direction of the winding is obtained, (b) applying adhesive to the fabric, (c) curing the adhesive applied to the fabric of the multilayered structure wound around the winding core, so that a cured multilayered structure is obtained, (d) separating the cured multilayered structure from the winding core, and (e) cutting the cured multilayered structure into the tapered root segment sections. A method for manufacturing the root segment of the turbine blade and a method for manufacturing the turbine blade is also provided.

Systems and methods for hydro-electric power generation are disclosed. The system includes a frame or structure positioned in a waterway or channel, with one or more hydro-transition units secured to corners of the frame. The hydro-transition units include a body of reinforced fabric for redirecting water flow towards the inlet of the frame, effectively increasing the current of the water and allowing for turbines within the frame to generate power at an increased rate. Anchors and bracket systems may secure the hydro-transition units to both the waterway and the frame, thereby allowing the body of reinforced fabric to withstanding force from water-flow within the waterway. The system includes various failsafe mechanisms for disengaging or detaching the hydro-transition units from the frame and/or anchor for reacting to high water flow or volumes (e.g., flooding).

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.

A wind turbine noise suppression system can include a sound absorbing batting and a fabric sheet within a column of the wind turbine. The sheet can hang within the column whereas the batting can be placed in at least a bottom and top region. A vibration isolation pad at the top of the column can mitigate a megaphone effect. The pad can be combined with an isolation washer. The pad can be less than a half inch thick, whereas the isolation washer can be less than a quarter inch thick. A sound curtain can be installed at a base of the column to suppress bell resonance. The system can, for example, reduce wind turbine noise up to ninety percent.

A blade protection member includes an adhesive layer, an opaque flexible layer and a porous vortex-suppressing layer. The opaque flexible layer covers the adhesive layer. The porous vortex-suppressing layer covers the opaque flexible layer, is exposed, and has a porous structure for passage of airflow and absorption of airflow. The blade protection member reinforces the trailing edge of the wind turbine blade, absorbs and eliminates vortex, reduces wake turbulence strength, and reduces aerodynamic noise during operation. A wind turbine blade and a wind turbine which have the blade protection member each are further introduced.

There is a system and method for de-icing a wind turbine blade. The system includes a heater for heating air and for attaching to an interior surface of the wind turbine blade, a blower for moving air across the heater to generate a heated airflow, and a flexible duct for receiving the heated airflow and for releasing the heated airflow into the interior of the wind turbine blade. The method includes generating heated air in the interior of a wind turbine blade, moving the heated air into a porous duct within the interior of the wind turbine blade, and passing the heated air through the porous duct and into the interior of the wind turbine blade to heat a surface of the wind turbine blade.

Systems and methods for hydro-electric power generation are disclosed. The system includes a frame or structure positioned in a waterway or channel, with one or more hydro-transition units secured to corners of the frame. The hydro-transition units include a body of reinforced fabric for redirecting water flow towards the inlet of the frame, effectively increasing the current of the water and allowing for turbines within the frame to generate power at an increased rate. Anchors and bracket systems may secure the hydro-transition units to both the waterway and the frame, thereby allowing the body of reinforced fabric to withstanding force from water-flow within the waterway. The system includes various failsafe mechanisms for disengaging or detaching the hydro-transition units from the frame and/or anchor for reacting to high water flow or volumes (e.g., flooding).

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.