An arrangement for generating energy made up of at least two rotating bodies of revolution partially immersed in a dynamic fluid. The at least two rotating bodies of revolution have their longitudinal axis of rotation located perpendicularly to the flow of the fluid, and are further associated to support means and to drive means, being immersed about 30% of their diameter. One of the at least two rotating bodies of revolution is located upstream of said dynamic fluid with its longitudinal axis of rotation located in a longitudinal slider of the support means with the possibility of translation and variable rotation speed. The other of the at least two rotating bodies of revolution is located downstream of the dynamic fluid, with its longitudinal axis of rotation being attached to the support means, and with a rotation synchronized with the flow speed of the dynamic fluid.

A device for use in extracting energy from an incoming fluid flow is presented. The device comprises: an oscillator assembly mounted on a base, the oscillator assembly comprising: a main body for exposing to an incoming fluid flow; and a joining element attached to the main body and configured for anchoring the main body to the base and enabling oscillation of the main body with respect to the base; an operative flow affecting unit comprising at least one flow interacting element located in at least one location respectively on a surface of the main body, the operative flow affecting unit being configured and controllably operable for affecting a separation of streams of the fluid flowing over the surface of the main body; a control unit in communication with the operative flow affecting unit, the control unit being configured and operable for activating and deactivating of each of the at least one flow interacting element of the operative flow affecting unit according to a certain time pattern, the time pattern being selected such that interaction between the flow interacting element and fluid streams creates vortices in the fluid streams at a selected vortex formation frequency causing an increase in oscillation of the main body, thereby enabling conversion of motion from the oscillation into useful energy.

An engine support mount including an airframe structure having a first anchor surface and a length extending along an x-axis, with a second axis defined perpendicularly to the x-axis. A support member is fixed to the airframe structure and defines a first aperture and a second aperture. A mounting assembly includes an elongated arm and first and second primary attachment assemblies respectively attaching the arm to the support member at the first and second apertures, the arm having a second anchor surface. A moment arm reduction feature includes a lug fixed to one of the anchor surfaces and a corresponding fastener fixed to the other of the anchor surfaces. The first anchor surface is positioned on the airframe structure outside of the first and second apertures, and the second anchor surface is positioned on the arm outside of the first and second attachment assemblies.

An engine support mount including an airframe structure having a first anchor surface and a length extending along an x-axis, with a second axis defined perpendicularly to the x-axis. A support member is fixed to the airframe structure and defines a first aperture and a second aperture. A mounting assembly includes an elongated arm and first and second primary attachment assemblies respectively attaching the arm to the support member at the first and second apertures, the arm having a second anchor surface. A moment arm reduction feature includes a lug fixed to one of the anchor surfaces and a corresponding fastener fixed to the other of the anchor surfaces. The first anchor surface is positioned on the airframe structure outside of the first and second apertures, and the second anchor surface is positioned on the arm outside of the first and second attachment assemblies.

A wind turbine includes a rotation axis suited to be positioned in space in any way and N blades indirectly constrained to the axis through one or more radial arms that are integral with the axis, wherein the blades can translate in a radial direction with respect to the axis during the rotation of the blades.

Transport frame and method; the transport frame having a longitudinal, lateral and upright extent, and configured for transporting a root end of a longitudinally extending wind turbine blade having a root face with protruding stud-bolts, said frame comprising a root saddle, said frame further comprising a releasable interface clamp configured for fixing a said blade root in said frame, said interface clamp extending from a forward nose through a rear hinge point in said root frame and, said interface clamp comprising a body with a forward abutment surface and a bearing surface rearward of said abutment surface, said body being hingedly movable into or out of engagement with one or more stud bolts protruding from the root face of a blade when positioned in said saddle, said interface clamp having a retracted position with its body away from said blade root face and away from said protruding stud-bolts, said interface clamp having an engagement position in which its said bearing surface extends transverse and adjacent to one or more said stud-bolts such that a tightening force applied to a said bearing surface pushes said abutment surface against said root face.

Transport frame and method; the transport frame having a longitudinal, lateral and upright extent, and configured for transporting a root end of a longitudinally extending wind turbine blade having a root face with protruding stud-bolts, said frame comprising a root saddle, said frame further comprising a releasable interface clamp configured for fixing a said blade root in said frame, said interface clamp extending from a forward nose through a rear hinge point in said root frame and, said interface clamp comprising a body with a forward abutment surface and a bearing surface rearward of said abutment surface, said body being hingedly movable into or out of engagement with one or more stud bolts protruding from the root face of a blade when positioned in said saddle, said interface clamp having a retracted position with its body away from said blade root face and away from said protruding stud-bolts, said interface clamp having an engagement position in which its said bearing surface extends transverse and adjacent to one or more said stud-bolts such that a tightening force applied to a said bearing surface pushes said abutment surface against said root face.

A ring gate for interrupting the water flow through the water path of a hydraulic machine having a rotor and a spiral. The ring gate includes a first hollow body extending around the rotor axis and is designed to be moved from an open position into a closed position and back in axial direction, whereby no water flow through the hydraulic machine can occur if the first body is in the closed position. The ring gate includes a second hollow body extending around the rotor axis and is designed to be moved from a first position outside of the water path into a second position within the water path and back in axial direction, wherein the second body has openings in its wall through which water can flow when the second body is in the second position and the first body is not in the closed position.

A wind sensor support assembly for a wind turbine is provided. The assembly includes a holding member for holding a wind sensor, and a support structure for supporting the holding member, the support structure being adapted to be fastened to an upper part of a wind turbine, wherein the support structure is adapted to allow adjustment of the position of the holding member relative to the upper part of the wind turbine. Furthermore, a wind turbine, a wind farm and a method of supporting a wind sensor on a wind turbine are described.

There is provided an apparatus for absorbing or converting energy from a moving body of water. The apparatus comprises an energy capture element (3) which, in use, moves in response to movement of the body of water in which the energy capture element (3) is placed, and an elongate guide element (1) defining a guide path along which the energy capture element (3) can move. The energy capture element (3) is a volume. In use, the energy capture element (3) and the guide element (1) are arranged so that the energy capture element (3) moves along the guide path in a substantially horizontal plane in response to differences in water pressure along a length of the energy capture element (3) parallel to the guide path and in response to movement of the body of water surrounding the energy capture element (3).