NO337729B1 - Apparatus and method of wave power plants - Google Patents

Description

DEVICE AND METHOD OF WAVE POWER PLANT

This invention relates to a wave power plant. More specifically, it concerns a device at a wave power plant comprising an essentially horizontally arranged shaft which is rotatably supported in a structure, and where the shaft can be transmission-wise connected to an energy machine, and where at least one buoyancy body, which is arranged to be able to follow a - and downward wave movement, is rotationally attached to the shaft, as the buoyancy point of the buoyant body is located at a radial distance from the center axis of the shaft. The invention also includes a method for wave power plants.

Wave power plants are known in many designs that can use different principles to extract wave energy and convert this into, for example, electrical energy. An example of such a power plant is described in NO 305410 where a wave power plant comprises at least one channel which is delimited externally by a hollow column, and which is supplied with water from below via at least one opening. Inside the hollow column is arranged a piston which is arranged to rise and fall with water inflow or outflow through the opening, as the up and down movement of the piston can be converted into one rotary movement in one and the same direction. The corresponding rotational energy can be converted into, for example, electrical energy.

The device according to NO 305410 is relatively space-consuming, and therefore less suitable, for example, for retrofitting existing installations at sea such as wind turbines and petroleum installations.

US document 2013/0287573 shows a system for collecting wave energy where a float which runs in a vertical track, by means of a crank device, is connected to a horizontal shaft.

GB document 2429045 describes a tidally driven power station where a float joint is connected to an arm on a shaft.

US document 625101 deals with a so-called wave motor where a float, with the help of an arm, is attached to a shaft.

None of these aforementioned devices include features that are considered necessary to achieve the desired degree of efficiency in a wave power plant of this type.

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology, or at least to provide a useful alternative to known technology.

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

A preferably horizontal shaft is rotatably arranged in an existing or new construction. The shaft is provided with at least one buoyancy body where the buoyancy point of the buoyancy body is located at a radial distance from the center axis of the shaft. The buoyant body is located close to a wave surface and, depending on its position, can be above the wave surface, in the wave surface or submerged below the wave surface. The radial distance between the axle's center axis and the buoyancy body's buoyancy point can be adjusted using an actuator.

The buoyant body is designed to be able to follow the wave movement up and down, but also the horizontal velocity component of the waves, and thus adds a reciprocating turning movement to the shaft. This turning movement and the corresponding energy can be converted in a manner known per se into, for example, electrical energy or pressure energy.

The invention is defined by the independent patent claims/the independent patent claim. The independent claims define advantageous embodiments of the invention.

In a first aspect, the invention relates more specifically to a device at a wave power plant comprising an essentially horizontally arranged shaft which is rotatably supported in a structure and is transmission-wise connectable to an energy machine, and where at least one buoyancy body, which is arranged to be able to follow an up- and downward wave motion, is rotationally attached to the shaft, the buoyancy point of the buoyancy body being located at a radial distance from the center axis of the shaft and where the radial distance between the center axis of the shaft and the buoyancy point of the buoyancy body is adjustable, and where the device is characterized by an actuator being connected between the shaft and the buoyancy body and arranged to be able to regulate the said radial distance.

By the buoyant body's buoyancy point is meant here the buoyancy-related center of gravity, which is the center of gravity of the displaced liquid. This is in contrast to the center of gravity of the buoyant body. The buoyancy body's mass center of gravity may be different from the buoyancy point, for example if the buoyancy body is made of materials with different specific gravity. The buoyancy point also changes depending on how deep the buoyancy body is in the water and of course does not exist if the buoyancy body is located above the wave surface.

By rotationally attached to the shaft is meant that the buoyant body rotates together with the shaft. The term "energy machine" is used for a device that is designed to be able to convert energy, for example from mechanical to electrical or pressure energy

In a preferred embodiment where the shaft is continuous in relation to the construction, a buoyancy body is arranged at each of the end parts of the shaft.

In the case of relatively strong, short waves, it will for example be relevant to operate the wave power plant with a shorter radial distance between the shaft and the buoyant body than in the case of smaller, more elongated waves such as swells. It may also be appropriate to regulate the aforementioned radial distance based on the desired effect from the wave power plant.

Normally, the shafting is located above the wave surface, but cases can also be foreseen where it is appropriate to arrange it close to the wave surface, that is to say in a position where it is washed over by the waves, or below the wave surface.

The shaft can be designed as a crankshaft or be provided with an eccentric ring to facilitate the use of a link connection. The link connection is connected between the shaft's crank, respectively the eccentric ring, and to a mechanism for converting a reciprocating movement into a rotational movement.

A mechanism for converting a five-way and backward rotation to a one-way rotation can be connected to the shaft without first converting the movement to an axial movement.

The mechanism for converting a reciprocating movement into a unidirectional rotation is known to a person skilled in the art, for example from NO 163544, and is not described in more detail. NO 163544 also describes a solution for converting a reciprocating rotation into a unidirectional rotation.

In a second aspect, the invention relates more specifically to a method for wave power plants comprising an essentially horizontally arranged shaft which is rotatably supported in a structure, and is transmission-wise connectable to an energy machine, and where at least one buoyancy body is arranged to be able to follow a up and down wave motion, is rotationally attached to the shaft, the buoyancy body's buoyancy point being located at a radial distance from the shaft's center axis, and where the method includes regulating the radial distance between the shaft's center axis and the buoyancy body's buoyancy point, the method being characterized by connecting an actuator between the shaft and the buoyancy body, and where the actuator is arranged to be able to regulate the said radial distance.

The device and the method according to the invention provide a wave power plant which can relatively easily be assigned to constructions of various kinds for extracting energy from wave movements.

In what follows, an example of a preferred embodiment and method is described which is visualized in the accompanying drawings, where: Fig. 1 shows a perspective and partial cross-section of a wave power plant according to the invention; Fig. 2 shows a wave power plant in an alternative design example;

Fig. 3 shows a wave power plant in a further design example.

Fig. 4 shows a section I-1 in fig. 1; and

Fig. 5 shows the same as in fig. 4, but in a different position.

In the drawings, the reference number 1 denotes a wave power plant which comprises a supporting structure 2 and an approximately horizontal shaft 6 which can be turned to the structure 2 by means of a bearing 4.

At the end parts 8 of the shaft 6, there is each a separate buoyancy body 10 which is connected to the shaft 6 by means of an attachment 12. The attachment 12, which can be adjustable in the radial direction, is arranged to keep the buoyancy body 10's buoyancy-related buoyancy point 14 at a radial distance from the center axis 16 of the shaft 6. The buoyancy-related buoyancy point 14, which is the buoyancy point of the displaced water, changes according to how deep the buoyancy body 10 is in the water.

In this preferred embodiment, see fig. 4 and 5, the attachment 12 is designed with an outer guide part 12a which is attached to the shaft 6, and an inner guide part 12b which is attached to the buoyancy body 10, and where the guide parts 12a, 12b are mutually telescopically displaceable by means of an actuator 17. The actuator 17 can for example be electric,

hydraulically or mechanically driven.

The buoyant bodies 10 are thus rotatable together with the shaft 6, more specifically about the central axis 16 of the shaft 6. The buoyant bodies 10, which are influenced by waves 18 to be lifted by wave crests and to fall back into wave troughs, will at all times occupy a position above the wave surface 20, partially submerged or completely submerged in the wave 18. In the figures, the rotating movement is indicated by the arrows 22, while the buoyancy bodies 10 are located at different depths in the wave 18.

The buoyant bodies 10 are mainly affected by the buoyancy from the waves 18, but also from the horizontal velocity component in the waves 18.

In the embodiment shown in fig. 4 and 5, the buoyancy body 10 is designed so that the buoyancy from the wave 18 acting on the buoyancy body 10 is smaller when the buoyancy body 10 is on the side of the shaft 6 than when it is under the shaft 6. In this way, the moment from the buoyancy body 10 is equalized, which works on the axle 6 somewhat.

In fig. 4, the buoyancy body 10 is located at a relatively small distance from the shaft 6, while in fig. 5 is located at a relatively large distance from the axle 6.

In fig. 1, the shaft 6 is provided with a crank 24. A supported crank rod 26 transfers the movement from the shaft 6 to an up and down axial displacement of a pair of axial rods 28. The axial rods 28 are displaceable in guides 30.

The axial struts 28 are connected to a mechanism 32 for converting a reciprocating axial displacement or rotation into a unidirectional rotation. An energy machine, not shown, can be connected to the mechanism 32, for example, by means of a transmission element, not shown.

In an alternative embodiment shown in fig. 2, the shaft is provided with two eccentric rings 34. The reciprocating rotation of the shaft 6 is converted into a reciprocating axial displacement of the axial struts 28 by means of pulleys 36 which rest against the eccentric rings 34, as well as the spindle 38 of the pulleys 36 which is connected to the axial struts 28.

The crank 24, the crank rod 26 and the axial struts 28 as shown in fig. 1, respectively the eccentric rings 34, the pulleys 36, the spindle 38 and the axial struts 28 as shown in fig. 2 constitute different link connections 40.

In a further embodiment shown in fig. 3, the mechanism 32 is transmission-wise connected to the shaft 6 by means of a belt drive 42 which drives a stored upper spindle 44. The mechanism 32 is connected to the upper spindle 44. The mechanism 32 can be mounted directly on the shaft 6 if desired.

It should be noted that all of the above embodiments illustrate the invention, but do not limit it, and those skilled in the art will be able to devise many alternative embodiments without departing from the scope of the dependent claims. In the requirements, reference numbers in brackets should not be seen as limiting. The use of the verb "to comprise" and its various forms does not exclude the presence of elements or steps not mentioned in the claims. The indefinite articles "an", "ei" or "et" before an element do not exclude the presence of several such elements.

Claims (9)

1. Device at a wave power plant (1) comprising an essentially horizontally arranged shaft (6) which is rotatably supported in a structure (2), and is transmission-wise connectable to an energy machine, and where at least one buoyancy body (10) is arranged to could follow an up and down wave movement, is rotationally attached to the shaft (6), the buoyancy point (14) of the buoyancy body (10) being located at a radial distance from the center axis (16) of the shaft (6), and where the radial distance between the (6) center axis (16) and the buoyancy point (14) of the buoyancy body (10) is adjustable, characterized in that an actuator (17) is connected between the shaft (6) and the buoyancy body (10) and arranged to be able to regulate the said radial distance. 2. Device according to claim 1, where the shaft (6) is located above the wave surface (20). 3. Device according to claim 1, where the shaft (6) is located close to the wave surface (20). 4. Device according to claim 1, where the shaft (6) is located below the wave surface (20). 5. Device according to claim 1, where the shaft (6) is provided with a crank (24). 6. Device according to claim 1, where the shaft (6) is provided with an eccentric ring (34). 7. Device according to claim 5 or 6, where a link connection (40) is connected between the crank (24) of the shaft (6), respectively the eccentric ring (34), and to a mechanism (32) for converting a reciprocating movement to a unidirectional rotation. 8. Device according to claim 1, where a mechanism (32) for converting a reciprocating rotation into a unidirectional rotation is connected to the shaft (6). 9. Method for a wave power plant (1) comprising an essentially horizontally arranged shaft (6) which is rotatably supported in a structure (2), and is transmission-wise connectable to an energy machine, and where at least one buoyancy body (10) is arranged to could follow an up and down wave movement, is rotationally attached to the shaft (6), the buoyancy point (14) of the buoyancy body (10) being located at a radial distance from the center axis (16) of the shaft (6), and where the method comprises regulate the radial distance between the center axis (16) of the shaft (6) and the buoyancy point (14) of the buoyancy body (10), characterized in that the method further comprises connecting an actuator (17) between the shaft (6) and the buoyancy body (10), the actuator (17 ) is arranged to be able to regulate the said radial distance.