NO843027L - DEVICE FOR TRANSFER OF SEA WAVE ENERGY - Google Patents

Description

The present invention relates to a device for transforming energy in sea waves, comprising at least one float which is designed as a container and which is guided vertically in a hollow body, which is designed with openings through which the interior of the hollow body is in contact with the surrounding sea, as the float's specific weight corresponds to the weight of the volume of water it displaces when the water is at rest, and the float is connected to a generator, whereby the downward movement of the float is utilized for energy extraction.

A similar device is known from DE patent document 29 33 330, where optimal performance is achieved by the vertically moving floats, which are moved upwards by the waves, drive the common current generator via their own transmission system and each their own coupling when they move downwards. The downward movement of the float can be delayed by means of a stop device until the wave has subsided by a portion of its wave period.

A device for transforming the energy into waves, comprising a float which is submerged in the water at least partially and which is mechanically connected to a stationary reference point, is known from DE-off.skrift 28 12 618. This device is between the float and the reference point equipped with a locking mechanism,

which at least approximately stops the float in relation to the reference point during certain time intervals of a wave oscillation affecting the device.

With such delays, it is possible not only to convert the vertical oscillation produced by the waves into energy, but also to amplify this vertical oscillation energy by the effect of gravity and thereby increase the energy yield.

But neither in the aforementioned DE patent 29 33 330 nor in the aforementioned DE official publication 28 12 618 is anything stated about the dimensions of the float which is kept afloat exactly in the water surface, so that the utilization of the wave energy at different heights, respectively very high waves, is not optimal.

The purpose of the present invention is therefore to further develop a device of the type indicated at the outset so that the latent energy in sea waves is converted even better.

According to the invention, this is achieved by the float having a constant height, which lies in the area between the average and the maximum height of the sea waves at the place where the device is located.

The advantages achieved with the device according to the invention are in particular that with a device designed in this way, i.e. in particular with a float designed in this way, the wave heights occurring at the place of use of the device are optimally utilized in terms of energy and converted into a transportable form of energy, e.g. electrical energy.

In an advantageous embodiment of the invention, the float has a height that corresponds to the largest occurring wave height on the site, so that even such maximum wave heights can be converted maximally into transportable energy, whereby the device according to the invention is at the same time advantageously able to withstand these highest waves, which will be explained in more detail below.

In order to keep the ratio between the construction costs for the device according to the invention and the energy yield within a realizable framework, the float preferably has a height that is between 1.3 and 0.2 times the largest wave height that occurs on the site. In order to be able to utilize a relatively wide range of the largest wave heights that are possible on the site, the height of the float is preferably between 0.5 and 10 m, so that maximum wave heights in this area are fully utilized. IN

in most application cases it is sufficient to dimension the float with a height of between 1 m and 5 m, as even in areas with greater maximum wave heights such maxima only occur for a relatively short period of time, so that the investment costs would not have been anything reasonable relative to a possibly higher energy yield.

In particular to protect the float against surf, in a preferred embodiment of the invention it is arranged freely vertically movable in a hollow body, which is open above and below and which protrudes from the sea surface. By means of the communicating effect in the downwardly open cavity, the water column in the cavity constantly adapts to the water surface outside, so that the float carries out a vertical movement corresponding to the sea waves.

As a sea wave not only contains movement energy due to up and down movement, but also the wave's horizontal movement, according to an appropriate embodiment, the hollow body is connected on the front to an extension whose side walls are connected to each other by means of front, obliquely upwardly directed guide plates. With such an extension, the horizontal movement that is always present in a wave is converted into a further, even higher water column in the extension, and as a result of the communicating effect between the hole body and the flow-related extension is converted into a corresponding elevation of the water column in the hollow body. By the fact that the building on the side facing the incoming wave is open from the bottom up, the horizontal component of a wave creates a surface pressure that is effective over the entire building, and in particular the strong surface currents are completely absorbed and converted into an increase in the water column . This increase in the water column in the hole body, however, means a corresponding increase and thereby an advantageous increase in the float's potential energy, which is converted into kinetic energy and in the power plant is converted into transportable energy, e.g. electrical energy.

In order to be able to optimally utilize the horizontal movement of the wave for the aforementioned increase of the water column in the extension, and thereby in the hole body, the extension is designed with a rear surface facing the hole body which projects upwards at an angle towards the hole body.

According to one embodiment of the invention, the extension is connected to the hollow body via an opening arranged below the extension, so that the communicating effect between the extension and the hollow body is unrestricted.

In order to further improve the communicating effect, the extension in a preferred embodiment of the invention is connected to the cavity via slots which are formed in its rear wall, preferably at the side walls.

According to another embodiment of the invention, the extension is arranged to be rotatable about the vertical longitudinal axis of the hollow body, so that the extension constantly adjusts in the direction of the horizontal flow component and thereby produces a higher water column in the cavity and an increase in the energy output. For that reason, the extension is designed with a guide member, which sets itself in the horizontal direction of flow.

According to the invention, a number of hollow bodies, which at the same time constitute a very effective protection against burning, can support a platform where the power plant is placed. According to one embodiment, the hole bodies are concrete rings, which are arranged on top of each other and designed with slots. In order to compensate for unevenness in the seabed and increase the resting surface, the concrete rings are, according to one embodiment, filled with concrete on the seabed. For static reinforcement of each individual cavity, the concrete rings are, according to another embodiment, filled with a filling material that protrudes to the working height, i.e. to near the lowest possible position of the float.

The invention will be described in more detail below, where, to make the possibilities for energy utilization clearer, some numerical examples have also been included, with reference to the accompanying drawings, where;

Fig. 1 shows two identical hollow bodies with the float in its extreme positions. Fig, 2 shows corresponding hole bodies, which are equipped with extensions, where the float is located in its extreme positions. Fig, 3 shows a plan view of the hole body in fig, 2 with extensions. Fig. 4 shows a plan view corresponding to fig. 3, but with

two floats next to each other in the hole body.

Fig. 1 shows on the left side a hollow body 6, which stands on the seabed 4 and which is made up of concrete pipes 1. The concrete pipes 1 are designed with slots 3 of sufficient size so that a float 2, which is located in the hollow body 6 and which via a rope 13 is connected to a power plant, is freely movable vertically and can adapt to the water column in the hole body and thereby to the conditions outside. The float 2, which is designed as a container, is filled with so much ballast material that it is kept floating exactly on the surface of the water. On the left side in fig, 1 is the float 2, whose height Hbc one, corresponds to the largest wave height HTT at the site, shown in the farthest lower stillinq,

^1W, max ^

i.e. in the wave valley. On the right-hand side of this figure, the float 2 is shown in the position corresponding to the wave crest, i.e. a value HTW7, max higher up, so that here it has a potential energy corresponding to the formula:

and

where

W = the potential energy of the float in Ws

A = the base surface of the float in m 2

W,max = maximum wave height in m at the site.

As a result of the fact that the height of the float 2 is adapted to the wave heights that occur at the site of application, more precisely has a height Kgch which corresponds to the highest wave height at the site, this results for a first design example:

Execution example 1,

The float 2 has the following dimensions:

2

Ground surface 5 m x 10 m = 50 m

Height = 10 m.

The power plant is installed in the North Sea and comprises 50 such floats.

From data from the German Hydrographic Institute in Hamburg "Die Nordsee", the following data can be read: At a wave height H^= 2 m, the duration of the wave's period is T = 6 seconds, and at a wave height HTw7 = 5 m, the period is T = 11 seconds . This results in performance per float in kW as follows:

and and

With fifty such floats, a theoretical power plant performance is thereby achieved:

and Fig, 2 shows a hollow body 6 with an extension 7, which is connected to each other through an opening 8. The extension 7 is open on the front side throughout its entire height and is laterally delimited by side walls 10. The two side walls 10 are stably connected to each other by with the help of front, obliquely upwardly extending guide plates 11. The rear wall 9 of the extension 7, which abuts against the wall 1 of the cavity 6, runs obliquely upwards. This rectilinear or curved rear wall and the front, obliquely upward guide plates 11 transform the horizontal velocity component in each wave into a vertical velocity component, which in the extension leads to an increased height Hv, which is proportional to the square of the vertical velocity component. On the right-hand side of this figure, the float is shown in the upper position, which results from the maximum wave height H and the increased height E^. This increased height, which depends on the inflow rate, can amount to 30 cm per m height of the extension 7. As a result of the extension 7's connection with the hole body 6 via the opening 8, and the thereby possible communicating effect, the water column in the cavity 6 involuntarily follows the water column in the extension 7, so that the float 2 is not only lifted to the maximum wave height, but moreover to the increased height Hv. In order to make better use of the communicating effect, a number of longitudinal channels 12 can be arranged on the sides of the rear wall 9 near the side walls 10, which form a connection between the extension 7 and the cavity 6. At a height H + H = 1.3. Hwhar the float 2 a potential energy

This results in a second design example:

Execution example 2.

The float has the same dimensions as in example 1. The power plant is also calculated assuming the same application site with the same wave parameters. This results in the following benefits per float in kW:

and and

M4d fifty such floats, the following theoretical power plant performance is achieved:

As can be seen from these design examples, a strong increase in performance of approx. 70% without a significant increase in the investment costs for the plant.

Fig. 3 and 4 show a hollow body 6 in which a float 2 (fig. 3) and two floats 2 next to each other with large cross-sectional dimensions are respectively arranged (fig. 4). On the front of the walls 1, which delimit a body with a rectangular cross-section, two side walls 10? which are mechanically connected to each other by means of parallel, inclined guide plates 11, Extension 9 is equipped with a guide member 13,

so that the device, which is rotatably stored about a vertical axis, always aligns itself in the direction of a wave's horizontal flow component and converts this flow energy into additional potential energy. In the rear wall of the extension 7, longitudinal slits 12 have been designed to optimize the communicating effect between the extension 7 and the hollow body 6.

Claims (8)

1. Device for transforming energy in sea waves, comprising at least one float which is designed as a container and which is guided vertically in a hollow body, which is designed with openings through which the inside of the hollow body is in contact with the surrounding sea, the specific weight of the float being equal to the weight of the volume of water it displaces when the water is at rest, and the float is connected to a generator, whereby the downward movement of the float is utilized for energy extraction, characterized by the fact that the float (2) has a constant height, which lies in the area between the average and the maximum height of the sea waves at the place where the device is located. 2. Device in accordance with claim 1, characterized in that the hole body (6) for the vertical guidance of the float (2) is equipped with an extension (7), which is delimited by two side walls (10) and if from the hole body (6) facing side is open, as the two side walls (10) are connected to the hole body (6) and to each other by means of front, obliquely upward guide plates (11). 3. Device in accordance with claim 2, characterized in that the extension (7) is equipped with a rear wall (9) which borders the hole body Co) and which runs obliquely upwards and in the direction of the hole body (6), 4. Device in accordance with one of claims 1-3, characterized in that the extension (7) is connected to the interior of the hollow body (6) via an opening (8) which is arranged below the extension (7). 5. Device in accordance with one of claims 2 - 4, characterized in that the extension (7) is connected to the interior of the hollow body (6) via slots (12) which are formed in the side walls (10) at its rear wall. 6. Device in accordance with one of claims 2-5, can be characterized in that the hole body (6) is rotatable together with the extension (7) about the hole body's vertical longitudinal axis. 7. Device in accordance with one of claims 2-6, characterized in that the extension (7) is equipped with a guide device (13) which aligns itself in the horizontal flow direction of the wave, 8. Device in accordance with one of the preceding claims, characterized in that the hole body (6) consists of concrete rings (1) which are placed on top of each other and which are equipped with slots (3).