NO326491B1 - Device at tidal power plants - Google Patents

Abstract

Device at floating tidal power plant (1) comprising a submerged turbine (8) and a buoyancy body (6) as well as moorings (24, 32), and wherein the tidal power plant (1), at a distance from the buoyancy body (6), is provided with at least one dive counterweight (10) which, in cooperation with the buoyancy body (6), is arranged to be able to balance torque forces to which the tidal power plant (1) is subjected due to the turbine's (8) power output from the water.

Description

DEVICE AT TIDAL POWER PLANT

This invention relates to a tidal power plant. More precisely, it concerns a floating tidal power plant which comprises a submerged turbine and a buoyancy body as well as moorings, and where the tidal power plant, at a distance from the buoyancy body, is provided with a submerged counterweight which, in cooperation with the buoyancy body, is arranged to be able balance torque forces that the tidal power plant is exposed to, due to the turbine's output from the water.

It is known to arrange turbines on fixed structures in areas where there is a significant tidal flow. It is also known to connect a turbine to an anchored, floating object.

GB 204505 describes a submerged tidal turbine which is placed on a column. The column is normally fixed to the bottom, but can also be connected to a float. GB 204505 does not describe any counterweight, since moment forces from the turbine are absorbed by the column via its fastenings and moorings.

Tidal power plants according to known technology are, however, relatively complicated constructions that are relatively expensive. Due to the turbines' submerged position, it can also be difficult to maintain them.

When the turbine is connected to a floating structure, the floating structure must be relatively large and stable in order to absorb the axial and torque forces that occur from the turbine. The construction is thereby significantly exposed to stresses from the prevailing weather and wave forces.

The purpose of the invention is to remedy or reduce at least one of the disadvantages of known technology.

The purpose is achieved according to the invention by the features indicated in the description below and in the subsequent patent claims.

A floating tidal power plant in accordance with the invention comprises a submerged turbine and a buoyancy body as well

moorings, and where the tidal power plant, at a distance from the buoyant body, is provided with at least one submerged counterweight, the tidal power plant being characterized by the fact that the counterweight in interaction with the buoyant body is designed to be able to balance torque forces that the tidal power plant is exposed to due to the turbine's power draw from the water.

Preferably, the counterweight is located at a lower height level

than the buoyancy body, as the turbine is located at a height level between the buoyancy body and the counterweight. When the turbine is rotated about its central axis while drawing power from the flowing tide, the tidal power plant will rotate in the turbine's direction of rotation. By the fact that the center of gravity of the counterweight is then no longer located vertically below the center of gravity of the buoyant body, a first moment arm is formed which is multiplied by the weight of the counterweight,

adjusted for buoyancy forces, seeks to counteract and in operating position to balance the torque from the turbine. The tidal power plant will thereby settle into a balanced, slightly tilted position in the water.

The tidal power plant's mooring is typically two-part, with a first mooring connected to the tidal power plant at a distance from the turbine in the direction of the tide's flow direction, and where a second mooring is connected to the tidal power plant at a distance from the turbine in the direction of the tide's flow direction.

The attachment of the moorings to the tidal power plant means that the first mooring mainly absorbs the mooring forces when the tide flows in a first direction, while the second mooring mainly absorbs the mooring forces when the tide flows in a second direction. The central axis of the turbine thereby remains essentially parallel to the direction of flow both when the tide flows in the first or in the second direction.

The water flowing towards the turbine also exerts a force in the longitudinal direction of the turbine axis. The force in the mooring that absorbs these axial forces has a downward vertical component. This component seeks to rotate the tidal power plant about a horizontal axis that is approximately perpendicular to the turbine's central axis. The rotation is counteracted by the fact that the center of gravity of the counterweight is no longer vertically below the center of gravity of the operating body, whereby a second moment arm is formed. The second moment arm together with the weight of the counterweight, adjusted for buoyancy, seeks to balance the moment from the anchorage.

By assigning the buoyant body a greater flow resistance than the counterweight, the flow-affected rotation of the tidal power plant due to the vertical force component of the anchoring can be reduced to a significant extent.

It is advantageous that each of the moorings is V-shaped, as each of the free end parts of the moorings is connected to its own anchor, while the opposite end parts are connected to the tidal power plant. The tidal power plant thereby maintains a laterally more stable position compared to if each

strain only involves one anchor.

The moorings are advantageously designed so that they can be placed at the installation site before the tidal power plant arrives. The moorings are then connected to the tidal power plant in a manner known per se and tightened to the desired pretension.

The buoyancy body and/or counterweight is typically boat-shaped with a bow and a bow-shaped stern to reduce the force of the flowing tide.

The counterweight is provided with a chamber which can optionally be filled with a liquid, typically water, or a gas, for example air. When the tidal power plant is in its operating position, the chamber is typically filled with water. When the turbine is to be raised to the surface of the water, for example during maintenance, the water is typically driven out of the chamber using compressed air. The counterweight thereby rises in the water, as the tidal power plant takes a horizontal position in the water surface, which significantly improves access to the submerged components in operating position.

In an alternative embodiment, the turbine is placed in a suspension that can be rotated about a vertical axis. The suspension can advantageously consist of a frame which is stored in the buoyancy body and in the counterweight.

The turbine is turned about its vertical axis every time the tide turns, so that the same side of the turbine faces the tidal current when the tide flows in the first direction and in the other direction. As will be known to one skilled in the art, a significant improvement in a turbine's efficiency can be achieved when it can be designed to receive water flow from one direction, compared to if it must be designed to provide an acceptable efficiency with water flow from both of its axial directions.

The invention provides a tidal power plant of a relatively simple construction which can easily be placed in most relevant locations, the tidal power plant being essentially independent of water depth and bottom conditions. The construction enables the cross-section of the buoyant body in the horizontal plane, as well as the freeboard, to be relatively small. The buoyant body is thus relatively little affected by weather and wind.

In what follows, a non-limiting example of a preferred embodiment is described which is illustrated in the accompanying drawings, where: Fig. 1 schematically shows a side view of a tidal power plant according to the invention; Fig. 2 schematically shows a plan view of the tidal power plant; Fig. 3 schematically shows an end view of the tidal power plant;

and

Fig. 4 schematically shows a side view of the tidal power plant i

an alternative embodiment.

In the drawings, the reference number 1 denotes a tidal power plant which floats in the water 2 and which is anchored to the seabed 4 by means of anchorages not shown. The tidal power plant 1 comprises a boat-shaped buoyancy body 6 which lies relatively deep in the water 2, a submerged turbine 8 and a counterweight 10 which is located at a lower height level than the buoyancy body 6.

The buoyancy body 6, the turbine 8 and the counterweight 10 are interrelated

connected by means of a support frame 12. The support frame 12 is connected to the buoyancy body 6 at its upper part in the use position and to the counterweight 10 at its lower part. The turbine 8 is connected to the support frame 12 between the buoyancy body 6 and the counterweight 10.

The turbine 8 comprises a rotor 14 with turbine blade 16 which is connected to a power machine 18 in the form of an electric generator or a fluid pump. The rotor 14 is rotatable about the central axis 20 of the turbine 8. Generated electrical energy or pressure fluid is led away from the power machine 18 in a manner known per se.

At a horizontal distance from the turbine 8 at a height close to the center axis 20, the support frame 12 is provided with a first mooring attachment 22 which is connected to a first mooring 24. The first mooring 24 continues from the first mooring attachment 22 via guides 26 and up to a first tightening device 28 which is located on the buoyancy body 6.

Correspondingly, the support frame 12 is provided with a second mooring attachment 30 which is located at a horizontal distance from the turbine 8 in the opposite direction relative to the first mooring attachment 22. The second mooring attachment 30 is connected to a second mooring attachment 32 which via guides 26 leads to a second tightening device 34.

The moorings 24, 32 can by means of their respective tightening devices 28, 34 be pre-tensioned to the desired tension in order to achieve an appropriate force distribution in the moorings 24, 32. When the tidal power plant 1 is to be rotated to its maintenance position, see below, the moorings 24 are slackened, 32.

The counterweight 10 comprises a counterweight weight 36 and a chamber 38. The chamber 38 is at least partially filled with water when the tidal power plant 1 is in its operating position. By evacuating the water from the chamber 38, for example by means of compressed air, the counterweight 10 is brought to float up and thereby turn the tidal power plant 1 to a position where it floats approximately horizontally in the water surface. This position is favorable for inspection and maintenance of the tidal power plant 1.

When the tidal power plant 1 is in operation, see fig. 3, the rotor 14 is rotated about its central axis 20. Due to rotational resistance from the power machine 18, the tidal power plant 1 is also rotated in the same direction, here clockwise. The center of gravity 40 of the counterweight 10 is thereby no longer vertically below the center of gravity 42 of the buoyant body 6, but at a horizontal distance A from this. By center of gravity 40, 42 is meant in this context a resulting center of gravity of mass and buoyancy in the respective body.

A torque is thereby set up which seeks to turn the tidal power plant 1 in a counter-clockwise direction. During operation, the tidal power plant 1 positions itself at an angle in relation to the vertical position where the aforementioned torques balance each other.

An equalization of torque from the downward component of the force in the relevant upstream mooring 24, 32 will be equalized in a similar way by a rotation of the tidal power plant 1 about a horizontal axis not shown which is approximately perpendicular to the center axis 20.

In an alternative embodiment, see fig. 4, the turbine 16 is placed in a suspension 44 in the form of a rotating frame which is located between the buoyancy body 6 and the counterweight 10.

The rotor 14 is here stored in an external, preferably water-lubricated turbine bearing 46 and in the power machine 18. The suspension 44 is rotatable about a vertical axis 50 by means of bearings 48. The suspension 44 is adjusted to, by means of not shown turning machinery in the buoyancy body 6, to be able to be turned so that the tide flows towards the turbine blades 16 from the same side regardless of whether the current comes in a first or a second direction.

The aforementioned rotation is preferably carried out now that there is no tidal current and the rotor 14 is not rotating. In the embodiment shown, the turbine blades 16 must also be in an approximately vertical position during rotation.

Claims (6)

1. Device for a floating tidal power plant (1) comprising a submerged turbine (8) and a buoyancy body (6) as well as moorings (24, 32), and where the tidal power plant (1) at a distance from the buoyancy body (6) is provided with at least one submerged counterweight (10), characterized in that the counterweight (10) in cooperation with the buoyant body (6) is designed to be able to balance torque forces that the tidal power plant (1) is exposed to due to the turbine's (8) power draw from the water. 2. Device according to claim 1, characterized in that the counterweight (10) is located at a lower height level than the buoyancy body (6), the turbine (8) being located at a height level between the buoyancy body (6) and the counterweight (10). 3. Device according to claim 1, characterized in that the mooring (24, 32) is two-part, a first mooring (24) being connected to the tidal power plant (1) at a distance from the turbine (8) in the direction against the direction of the tide's flow, and where a second mooring (32) is connected to the tidal power plant (1) at a distance from the turbine (8) in the direction of the tide's flow direction. 4. Device according to claim 1, characterized in that at least one of the buoyancy body (6) and the counterweight (10) is boat-shaped. 5. Device according to claim 1, characterized in that the counterweight (10) is provided with a chamber (38) which can optionally be filled with liquid or gas. 6. Device according to claim 1, characterized in that the turbine (8) is placed in a suspension (44) rotatable about a vertical axis (50).