A transition piece (140) for a wind turbine tower (110) is provided, that is configured to be installed on a tower foundation (111) and to carry a tower piece (113). It comprises a high voltage joint (10) with grid input and output terminals (11, 12) and WTG connecting input and output terminals (14, 13). The grid input terminal (11) is configured for receiving and connecting to an array cable (21) from a power grid (20). The WTG connecting output terminal (13) is operatively connected to the grid input terminal (11) for receiving and connecting to an input cable (23) leading to a switchgear (30). The WTG connecting input terminal (14) is configured for receiving and connecting to an output cable (24) from the switchgear (30). The grid output terminal (12) is operatively connected to the WTG connecting input terminal (14) for receiving and connecting to an array cable (22) leading to the power grid (20). Further, installation, testing, connecting and maintenance methods taking advantage of the high voltage joint (10) are provided.

Wind turbine installation (1) comprising a tower (2), a nacelle (3), —a liquid immersed power electrical device (6) having an expansion vessel (7), an air dehydrating breather (8) comprising a moisture absorbing agent (9), and a conduit (10) fluidly connecting the expansion vessel (7) and the air dehydrating breather (8), wherein the wind turbine installation (1) comprises a barrier (11) separating a restricted zone (12) from a non-restricted zone (13) in said wind turbine installation (1), wherein the electrical device (6) is located in the restricted zone (12), wherein the air dehydrating breather (8) is located in the non-restricted zone (12) and wherein the conduit (10) extends through the barrier (11) and a method of maintaining a wind turbine installation (1).

A transition piece (140) for a wind turbine tower (110) is provided, that is configured to be installed on a tower foundation (111) and to carry a tower piece (113). It comprises a high voltage joint (10) with grid input and output terminals (11, 12) and WTG connecting input and output terminals (14, 13). The grid input terminal (11) is configured for receiving and connecting to an array cable (21) from a power grid (20). The WTG connecting output terminal (13) is operatively connected to the grid input terminal (11) for receiving and connecting to an input cable (23) leading to a switchgear (30). The WTG connecting input terminal (14) is configured for receiving and connecting to an output cable (24) from the switchgear (30). The grid output terminal (12) is operatively connected to the WTG connecting input terminal (14) for receiving and connecting to an array cable (22) leading to the power grid (20). Further, installation, testing, connecting and maintenance methods taking advantage of the high voltage joint (10) are provided.

The resonance wind turbine (1) comprises: a base assembly (10, 12, 18) for the fixing of the wind turbine (1) to a base surface (2), on the base assembly being located an oscillating element (3) provided with a proximal portion (4) associated with the base assembly (10, 12, 18) and a distal portion (5) opposed to the proximal portion (4) and adapted to oscillate, due to the effect of the incident wind blowing along a direction of propagation (A), in which the oscillation of the oscillating element (3) occurs along a main direction (B) substantially horizontal and perpendicular to the direction of propagation (A); and an electro-magnetic induction assembly (6, 7) associated with at least one of the base assembly (10, 12, 18) and the oscillating element (3), comprising a magnetic element (6) and an electrical winding (7) arranged in the proximity of the magnetic element (6) and adapted to produce electrical energy by means of the relative motion of the magnetic element (6) and the electrical winding (7) along the main direction (B);
wherein the base assembly (10, 12, 18) comprises a fixed portion (10) adapted to rest on the base surface (2) and a moveable structure (11) associated with the fixed portion (10) by means of oscillation means (18) adapted to allow the resonance oscillation of the moveable structure (11) along the main direction (B) due to the effect of the oscillation of the oscillating element (3).

A light-emitting assembly with a micro hydraulic power generator includes a power generation module and a light-emitting module. The power generation module includes a housing, a coil module and an impeller. An accommodating space inside the housing is divided by a transverse baffle therein into two cavities, respectively a coil cavity and an impeller cavity. A side wall of the impeller cavity is provided with at least one water inlet. At least one internally recessed portion is provided at a connection portion between the transverse baffle and an outer wall of the coil cavity, and the transverse baffle defines a water outlet at a portion positionally corresponding to the internally recessed portion. The coil module is arranged in the coil cavity in a sealed manner by a colloidal material. The impeller is placed in the impeller cavity, the impeller can be rotated by an external force.

A rotary machine includes a rotor rotatable about a rotation axis and a stator mechanically divided into stator segments, each covering a respective section in relation to the rotation axis. Coils of one individual multi-phase rotary system are respectively arranged in the stator segments, each having terminals which connect phase lines of an individual multi-phase rotary system and are connected to the coils. A converter unit includes multiple subunits operated independently of one another, each forming an individual multi-phase rotary system. The number of phases of the subunits corresponds to the number of stator segments. The terminals of the stator segments are each connected to a subunit. The stator segments form groups of directly successive stator segments when viewed about the rotation axis. The terminals of the stator segments are connected to the same sub-unit within each group, but connected to different sub-units from group to group of stator segments.

A rotor blade for a wind turbine is disclosed, comprising a root section, a tip section, a middle section, a blade skin, an electric heating arrangement having a heating strip, and a blade portion of an energy transfer arrangement being electrically connected to the heating arrangement. The blade further comprises a lightning arrangement having one lightning receptor mounted to the tip section and being electrically connected to the heating strip, wherein electrical energy of a lightning strike can be conducted from the lightning receptor into the heating strip. Furthermore, the lightning arrangement comprises a grounding device which is mounted to the root section, which is configured for conducting electrical energy received from the lightning receptor via the heating strip into a grounding arrangement. The heating strip has a width-thickness relation of at least 50:1, is flexible, arranged with the blade skin and extends over 50% of a total length of the rotor blade. The design of the heating strip is chosen that an adhesive bonding between ice and the blade skin can be terminated by electrically heating a respective surface of the blade skin, and lightning caused currents of at least 10 kA can be conducted without causing damage to the rotor blade.

A wind turbine blade is provided including at least one laminate structure, and at least one connection terminal element, wherein the laminate structure includes a panel core embedded between at least one first laminate layer and at least one second laminate layer, wherein the connection terminal element is arranged in a corresponding opening of the panel core between the first laminate layer and the second laminate layer, wherein the connection terminal element includes at least one first connection portion connected to an embedded electrical conductor embedded in the laminate structure and/or at least one second connection portion adapted to be connected to at least one further electrical conductor arranged outside of the laminate structure.

The present disclosure relates to a wind turbine comprising a wind turbine rotor with a plurality of blades supported on a support structure, a generator operatively coupled to the wind turbine rotor for generating electrical power, a power electronic converter for converting electrical power generated by the generator to a converted AC power of predetermined frequency and voltage, and a main wind turbine transformer having a low voltage side and a high voltage side for transforming the converted AC power to a higher voltage. One or more electric filters are connected to the high voltage side of the main transformer, wherein the electric filters are arranged in the support structure. The present disclosure also relates to wind farms, and particularly offshore wind farms, and to methods for operating wind farms.

A blade for a wind turbine including heating means connected to power cables, a lightning protection system including a down conductor, and surge protection devices is provided. The heating means include a first radiant element and a second radiant element arranged adjacent to each other around a leading edge of the blade, the first radiant element being connected to the power supply cables through respective electrical connectors at the respective connection points, and the down conductor is connected to each power supply cable at the connection points through the respective surge protection device, the second radiant element being connected to the first radiant element so that the second radiant element is electrically supplied only through the first radiant element.