A wind turbine blade comprising a plurality of spar components extending along the longitudinal axis and providing the main bending stiffness of the wind turbine blade a major principal axis defining a structural pitch angle of at least 1° with respect to a chord line, and including: one or more suction-side spar caps each having a centre line; one or more pressure-side spar caps each having a centre line; and one or more shear webs distributed around a central shear web line and at least one of which being connected to first spar caps, wherein at least one suction-side spar cap centre lines is arranged with a first chordwise distance to the central shear web line, and at least one pressure-side spar cap centre lines is arranged with a second, different, chordwise distance to the central shear web line.

A flow-enhancing fabric extends in a longitudinal direction and in a transverse direction. The fabric includes a plurality of fibre layers including a first fibre layer and a second fibre layer arranged upon each other, the first fibre layer has a first plurality of fibre bundles oriented in parallel in a first fibre direction and has a plurality of first glass fibre bundles and a number of first carbon fibre bundles. The second fibre layer has a second plurality of fibre bundles oriented in parallel in a second fibre direction different from the first direction and has a plurality of second glass fibre bundles and a number of second carbon fibre bundles. At least a number of first carbon fibre bundles intersect and contact a number of second carbon fibre bundles. The fabric has a plurality of monofilaments arranged between the first and second fibre layer along the transverse direction.

A male spar beam for mutually attaching a segmented wind turbine blade and, comprising: a leading-edge part comprising a second upper wall, a second lower wall, and a second shear wall connecting the second upper wall with the second lower wall, the leading-edge part; and a trailing-edge part comprising a first upper wall, a first lower wall, and a first shear wall connecting the first upper wall with the first lower wall. The leading-edge and trailing-edge parts being separately formed integrally in one piece, respectively. An end of the first lower wall is attached to an end of the second lower wall so that the first lower wall and the second lower wall form a lower spar cap of the male spar beam, and an end of the first upper wall is attached to an end of the second upper wall so that the first upper wall and the second upper wall form an upper spar cap of the male spar beam.

The present invention provides a to method for reinforcing a wind turbine blade, such as a root end. The root end comprises a first and a second bushing for attaching the wind turbine blade to a wind turbine hub, the bushings being located between an inner sidewall of the root end and an outer sidewall of the root end, the bushings being separated by retaining material, the method comprising forming a first injection channel in the retaining material; forming a first pressure release channel in the first retaining material, wherein the first pressure release channel is formed to be in fluid communication with the first injection channel in a region between the inner sidewall and the outer sidewall; and injecting adhesive material into the first injection channel at least until adhesive material enters the formed first pressure release channel. The invention also provides a wind turbine blade having a root end that has been reinforced using such a method. Further aspects are provided.

The present invention relates to a method of manufacturing a wind turbine blade shell component (38), the method comprising the steps of providing a plurality of abraded pultrusion plates (64) having abraded edges, arranging the abraded pultrusion plates (64) in layers on blade shell material (89) in a mould (77) for the blade shell component, the layers being separated by electrically conductive interlayers, and bonding the abraded pultrusion plates (64) with the blade shell material to form the blade shell component, wherein each pultrusion plate (64) is formed of a pultrusion fibre material comprising glass fibres and carbon fibres. The invention also relates to a reinforcing structure for a wind turbine blade, the reinforcing structure comprising a plurality of pultrusion plates according to the present invention.

The disclosure relates to a fibre reinforcement fabric for a wind turbine component, the fabric comprising a first plurality of fibre bundles arranged in parallel in a warp direction and stitched together, the fabric having a first outermost fibre bundle defining a first fabric edge parallel to the warp direction and a second outermost fibre bundle defining a second fabric edge opposite the first fabric edge, the fabric having a first tapered portion including the first outermost fibre bundle, wherein a thickness of the fabric in the first tapered portion is tapering from a first fabric thickness to a second fabric thickness in a direction towards the first fabric edge. The disclosure also relates to a spar cap and a wind turbine blade shell part comprising such fabric or fabrics.

The present invention relates to a method of manufacturing a wind turbine blade shell component (38), the method comprising the steps of providing a plurality of pultrusion plates (64), arranging the pultrusion plates (64) on blade shell material (89) in a mould (77) for the blade shell component, and bonding the pultrusion plates (64) with the blade shell material to form the blade shell component, wherein each pultrusion plate (64) is formed of a pultrusion fibre material comprising glass fibres and carbon fibres. The invention also relates to a reinforcing structure for a wind turbine blade, the reinforcing structure comprising a plurality of pultrusion plates according to the present invention.

A wind turbine rotor blade is provided including a reinforcement element embedded in the body of the rotor blade and extending in a longitudinal direction of the rotor blade; a number of piezo-electric transducers arranged between the leading edge of the rotor blade and the reinforcement element; a number of piezo-electric transducers arranged between the reinforcement element and the trailing edge of the rotor blade; and a connector arrangement configured to apply an excitation signal to any one of the piezo-electric transducers, and to transmit a sensed signal from any one of the piezo-electric transducers to an evaluation module. A wind turbine including a number of such rotor blades and a method of measuring strain in a reinforcement element arranged in such a rotor blade is also provided.

A strip for a spar cap is provided, wherein the strip is made from a composite material including a matrix and a reinforcement, and includes a first and second end region connected together in a longitudinal direction by an intermediate region having two mutually opposed longitudinally extending and parallelly disposed intermediate surfaces, wherein a thickness is determinable perpendicular to the two intermediate surfaces and a width is determinable perpendicular to the longitudinal direction and perpendicular to the thickness, wherein at least one of the first and the second end regions is a chamfered end region, wherein the at least one chamfered end region is simultaneously chamfered along the width and the thickness, wherein the at least one chamfered end region has a first edge at the intermediate region and a second edge at its free end, wherein the first edge and the second edge are substantially parallel to one another.

A trailing edge panel is configured to be attached to a trailing edge of a wind turbine blade and includes a base element and a number of protruding aerodynamic elements. The base element has an attachment part configured to be attached to and extend from the trailing edge of the wind turbine blade and to an upstream position on a first blade side of the wind turbine blade. The base element further has a serrated part extending from the second side of the attachment part and configured to project out from the trailing edge of the wind turbine blade, wherein the serrated part comprises a number of serrations, including a first serration and a second serration. The number of protruding aerodynamic elements, including a first protruding aerodynamic element, includes a first protruding part attached to the serrated part of the base element.