A pitch energy module comprising one or more ultracapacitors storing electrical energy for a wind turbine emergency pitch energy event. The pitch energy module replaces at least one battery within a battery housing of a wind turbine and interfaces with the existing battery wiring harness to communicate with a control system of the wind turbine. The pitch energy module is installed without further modification to the battery housing or the battery wiring harness.

A plant for the exploitation of renewable energy sources in open sea. The plant includes: a vertical main pillar including a part over sea level and an immersed part; at least one electric generator that produces electric power exploiting renewable energy sources; a battery storage for storing electric power; and an electrical connector that makes available the electric power to an external user. Furthermore, in the plant, the battery storage is inside the main pillar, develops in the immersed part, and comprises a movable structure configured for allowing the movement of batteries along the main pillar.

A pitch energy module comprising one or more ultracapacitors storing electrical energy for a wind turbine emergency pitch energy event. The pitch energy module replaces at least one battery within a battery housing of a wind turbine and interfaces with the existing battery wiring harness to communicate with a control system of the wind turbine. The pitch energy module is installed without further modification to the battery housing or the battery wiring harness.

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.

A lightning protection system for a wind turbine blade having-a structural element made of fiber reinforced polymer (FRP). The lightning protection system includes a first down conductor extending from a tip end to a tip connection block and a second down conductor extending from the tip connection block between and along the structural element and a pressure side towards a root connection block. A third down conductor extending from the tip connection block between and along the structural element and a suction side towards the root connection block. The second down conductor includes a first expanded foil or a first mesh and the third down conductor includes a second expanded foil or a second mesh. The first expanded foil or first mesh and the second expanded foil or second mesh include a plurality of conductive connection points arranged in the vicinity of the tip and root connection blocks.

A plant for the exploitation of renewable energy sources in open sea. The plant includes: a vertical main pillar including a part over sea level and an immersed part; at least one electric generator that produces electric power exploiting renewable energy sources; a battery storage for storing electric power; and an electrical connector that makes available the electric power to an external user. Furthermore, in the plant, the battery storage is inside the main pillar, develops in the immersed part, and comprises a movable structure configured for allowing the movement of batteries along the main pillar.

The present disclosure relates to a current transfer element (100) configured to be mounted on a first component (300) of a machine, the machine comprising a second component (200) configured to rotate with respect to the first component and the second component comprising an electrical conductor. The current transfer element (100) comprises a floating conductor assembly, and a support (120), and the floating conductor assembly comprises a floating chassis (111) resiliently connected to the support (120), the floating chassis arranged on a roller (112) which is configured to contact the second component (200), and carrying a floating conductor (113) configured to transfer current from the electrical conductor of the second component (200). The present disclosure further relates to generators and electrical machines comprising floating conductor assemblies, and direct drive wind turbines comprising such generators.