Provided is a method of installing a transmission cable arrangement of an offshore wind turbine, including step of providing a cable protection assembly, wherein provision of the cable protection assembly includes the steps of installing an outer protective pipe at a marine foundation, which outer protective pipe is realized to extend from a cable hang-off to the seabed; and laying an inner protective pipe through the outer protective pipe to extend from the cable hang-off to a further destination; and wherein the method of installing a transmission cable arrangement further includes a step of loading the transmission cable arrangement into the inner protective pipe towards the further destination. A cable protection assembly and a wind turbine assembly are also provided.

The disclosure provides a cable protection device and a wind generator set. The cable protection device comprises: a fixing ring, which has a through hole extending along a first direction, wherein the fixing ring includes an inner side surface and an outer side surface that are opposite along a radial direction of the fixing ring, the outer side surface comprises two or more attaching surfaces, and a vertical axis is defined in the attaching surface; and a clamping member, which is disposed on the attaching surface, wherein the clamping member is deflectable at least about the vertical axis, the clamping member has at least one penetration hole penetrating along the first direction, and a cable is clamped within the penetration hole and is deflected about the vertical axis relative to the fixing ring within a preset range.

There is provided a method (100) of installing a pitch tube (27) into an electrical power generator (24) for a wind turbine, the method comprising: installing (105a) the pitch tube (27) so that it is coaxial with a rotational axis (R) of the generator (24); supporting (105b) a bearing arrangement (50) associated with the pitch tube (27) at an end of the generator (24) using one or more primary supports (52), wherein each of the primary supports (52) comprises a first end (58) connected to the bearing arrangement (50) and a second end (60) connected to a component (32) associated with a rotating reference frame of the generator (24); and supporting (110) the bearing arrangement (50) using one or more secondary supports (54), wherein each of the secondary supports (54) comprises a first end (62) connected to the bearing arrangement (50) and a second end (64) connected to a component (42) associated with a stationary reference frame of the generator (24).

A protection assembly for mounting in an underwater support structure includes at least one bend protection device coupled to a retaining device so that together they provide a through-going passage for receiving an elongate member which is to be protected. The elongate member passes through a support structure opening, and the retaining device is configured to be received in the support structure opening and to engage with the support structure to resist subsequent withdrawal from it. Installation of the protection assembly includes grasping the protection assembly with a releasable clamp, arranging a pulling line to pass through the support structure opening to the mechanical clamp and securing the pulling line to the mechanical clamp, drawing the retaining device of the protection assembly into the support structure opening using the pulling line and engaging the retaining device with the support structure, and releasing the clamp from the protection assembly.

A tower for a wind turbine is disclosed, said wind turbine comprises the tower, a nacelle and a rotor having at least one rotor blade. The tower is configured for supporting the nacelle and the rotor on a support system. The tower itself may be structured as having an upper top end for supporting the nacelle and a lower support end for being placed on the support system. Electric energy generated is transported via power cables from the nacelle to an electric grid, preferably via power electronic components, switches and/or transformers. Furthermore, the nacelle may rotate around the yaw axis according to the current wind direction. Hence, the rotation of the nacelle introduces a twist into the power cables, wherein said twist causes a deviation (shortening) in the length of the power cables. Furthermore, the tower comprises at least one radial cable guiding device for receiving the cable and a cable support arrangement for supporting the cable in a beneficial manner. Additionally, the tower comprises anti-torsion fixation means configured for reducing and/or preventing a propagation of a cable twist of the cables of a hanging portion into power cables of a loop portion. The power cables comprise a hanging portion having a cable axis, a cable loop portion having a horizontal cable loop, and the supported portion being at least partially supported by the cable support arrangement.

Provided is a method for manufacturing a wind turbine, the wind turbine including a high voltage cable configured to connect a generator of the wind turbine with a switch gear of the wind turbine, the method: a) guiding the high voltage cable inside a tower of the wind turbine from an upper part of the tower to a lower part of the tower, and b) returning the high voltage cable at the lower part of the tower up again. Returning the high voltage cable at the lower part of the tower up again simplifies storing an additional length of the high voltage cable inside the tower.

It is described a method of installing a power cable (5) in a wind turbine tower (1), in particular for transportation, the method comprising: arranging a section (5) of the cable within the tower, the section having a length, in particular by at least an upper excess cable portion, greater than the tower height (h), by forming a cable loop (27, 33) within the tower (1), wherein an angle enclosed between a normal (34) of a cable loop plane and the longitudinal direction (4) of the tower (1) is between 70° and 110°.

A mounting device (110) for an elongate flexible member extending through an aperture (102), comprising: an elongate body (130) having a longitudinal axis; an internal passageway passing through the elongate body (130) parallel to the longitudinal axis, for receipt of the elongate flexible member; a plurality of apertures (132) in the elongate body (130); an engagement member (136) in each apertures (132) and constrained to move along a displacement axis inclined to the longitudinal axis of the elongate body (130); a plurality of actuation members (142), each engaged with a respective engagement member (136), whereby displacement of the actuation member (142) in a first direction displaces the engagement members (136) outwardly to project beyond the periphery of the elongate body (130) and displacement of the actuations members (142) in a second, opposite direction displaces the engagement members (136) inwardly; and biasing means (182) biasing the actuation members (142) in the first direction.

An electric power transmission carrier and a manufacturing method of the electric power transmission carrier and an enclosure are provided. The electric power transmission carrier includes an enclosure and an electric power transmission cable mounted on the enclosure. The electric power transmission cable is in direct or indirect surface contact with an inner wall of the enclosure, and the enclosure functions as a heat sink of the electric power transmission cable. In the present application, the electric power transmission cable or the conductor is mounted on the enclosure such as a tower barrel or a high tower, to perform electric power transmission and take the enclosure as a heat sink. The electric power transmission component takes the enclosure, the “heat sink” having a huge thermal capacity, as a “cold source”.

A cable holder, in particular for a cable of a wind turbine, to a cable harness, to a tower, to a wind turbine and also to a method for fastening a cable. In particular, a cable holder, in particular for a cable of a wind turbine, preferably for a medium-voltage cable connected to a medium-voltage transformer of a wind turbine, comprising a cable mount with a funnel-like cavity and also comprising an elastic insert, which is arranged within the funnel-like cavity, wherein the cable mount and the elastic insert are arranged and designed such that the cable can extend through the funnel-like cavity and the elastic insert can be clamped in between the cable mount and the cable.