BE1022102B1 - DEVICE AND METHOD FOR GENERATING WIND ENERGY - Google Patents

Abstract

Device (1) for generating wind energy comprising the following parts: - a wind turbine (10) arranged to be submersible in water (13); - one or more kites (6,7) that can jointly generate sufficient lift to lift the wind turbine (10), the wind turbine (10) being suspended from the one or more kites (6,7); -a base station (2) from which a first connecting cable (5) runs to the one or more kites (6,7).

Description

Device and method for generating wind energy.

The present invention relates to a device and method for generating wind energy.

It is well-known to convert movement energy from the air into electrical energy by means of wind turbines. This energy is further referred to in this document as wind energy.

Since a stronger and more constant wind is generally present at higher altitudes above the earth's surface and above flat parts of the earth's surface, it is advantageous to do such generation of wind energy at higher altitudes and above larger water surfaces such as the sea or large lakes.

However, this has the disadvantage that high, preferably very high and at the same time sturdy structures have to be built, which is obviously expensive.

A system is known in which a helium balloon is used to lift a wind turbine. However, such a balloon requires a great deal of helium and a very large volume to lift the substantial weight of a wind turbine.

Such a system also generates very high drift forces through the volume of the balloon, so that very strong supporting structures and cables must be provided.

Helium leakage is also a problem with such a system.

Complex integrated kites / wind turbines are also being tested. However, these are still under development, far from reliable and rather limited in scale.

The present invention has for its object to provide a solution to the aforementioned and other disadvantages in that it provides a device for generating wind energy comprising the following components: a wind turbine which is adapted to be fully or partially submersible in water; - one or more kites that together can generate sufficient lift to be able to lift the wind turbine, the wind turbine being suspended from the one or more kites; and a base station from which a first connecting cable runs to the one or more pilots.

This has the advantage that a wind turbine can be brought relatively easily to a great height so that a lot of wind energy can be generated, without the need for high and expensive support structures.

Thanks to the submersibility of the wind turbine, this can be done above the sea or a large lake, so that the wind is stronger and so that nuisance is avoided as much as possible, because after too little or too much wind the wind turbine can be lowered into the water.

An additional advantage here, compared to use above land, is that damage to the wind turbine through contact with the ground is avoided.

A wind turbine that is arranged to be partially or fully submersible in water is hereby a wind turbine that is able, or in other words designed, to be partially or fully submerged and, once the immersion has been removed, to work as a wind turbine again, and this repeatedly, whereby the immersion does not lead to damage or a reduction in performance.

The one or more pilots hereby provide sufficient lift for a wind force that exceeds a limit value to bring the wind turbine to a great height.

Hereby a so-called kitoon, which has elements of a kite and also has a closed volume that is filled with a gas, which may or may not be lighter than air, is also considered a kite.

The first connecting cable is in this case a cable primarily to withstand mechanical forces, i.e. lift and drift forces, so that the one or more kites and the wind turbine remain connected to the base station. The generated electrical energy could also be carried away via this first connecting cable from the wind turbine, more specifically via electrical conductors provided for this purpose, but this can also be done via a separate power cable.

Such a cable can be a plastic or steel cable, but can also be wholly or partly a chain, or comprise rigid tie rods.

The wind turbine may be suspended directly from the one or more kites, or may be suspended indirectly from the one or more kites at a point on the first connecting cable between the one or more kites and the base station.

The base station can be, for example, a boat, pontoon, or a natural or artificial island.

In a preferred embodiment the device is provided with a second connecting cable which, during use of the device, runs downwards from the bottom of the wind turbine or a suspension structure or in front of the wind turbine to a downwind of the base station at a distance from the base station wherein the second connecting cable is preferably connected to the ground or to a counterweight that cannot be lifted by the one or more pilots.

Such a second connecting cable stabilizes the wind turbine, so that unwanted pendulum movements can be prevented. Optionally, this second connection cable can also be used for removing generated wind energy.

This second connecting cable can also be primarily a power cable, whereby it will automatically have a stabilizing effect on the wind turbine as a second function due to its own weight.

In a further preferred embodiment the device comprises two or more kites which are successively connected to the base station at an increasingly greater distance from the base station by means of the first connecting cable.

Here, the kite that is located at the greatest distance from the base station or a combination of kites that are adjacent to it, can generate sufficient lift to enable the next kite, viewed in the direction of the base station, to be submerged in water. withdraw air.

With such a succession of kites, it is easy to get the wind turbine back into the air again after it has been lowered, since only the kite has to be made flying or held at the greatest distance from the base station, after which it is released from the next kite the water draws. The two kites at the largest distance from the base station now pull the next kite out of the water, and so on.

In a further preferred claim, the device is provided with a rigid suspension structure for the wind turbine, the suspension structure being movably attached at its top to the first connecting cable, the wind turbine being rigidly suspended, i.e. not hinged, from the suspension structure.

As a result, the first connecting cable can take any angle, for example as a result of different wind speeds, while nevertheless the suspension construction, and therefore the wind turbine, assume a fixed orientation with respect to the earth's surface.

The invention also relates to an installation for the desalination of salt water, which is situated at a certain distance from the nearest coast and is at least partially supplied with energy by a device as mentioned above.

The problem with desalination plants is that, although they produce desalinated seawater, they also produce a significant amount of water with a greatly increased salt content. This can lead to local disruption of the ecosystem. It is therefore desirable to place such a desalination plant relatively far from a coast, so that this extra salt water can be diluted quickly.

However, there is then a potential problem with the energy supply of such desalination plants. When a wind energy generating device according to the invention is used to provide a desalination plant with energy, a synergy advantage is thereby created.

The invention also comprises a method for generating wind energy, wherein a wind turbine is lifted by one or more kites to a certain height, wherein the one or more kites are connected by means of a first connecting cable to a base station, the base station being surrounded by water deep enough to submerge in the wind turbine.

With the insight to better demonstrate the features of the invention, a few preferred applications of a device according to the invention are described below as an example without any limiting character, with reference to the accompanying drawings, in which: figure 1 schematically shows a device according to the invention; represents the invention in an operating condition; and Figure 2 shows the device of Figure 1 in a non-working condition.

The device 1 shown in Figure 1 mainly consists of a ship 2, which is anchored via an anchor cable 3 and therefore serves as a base station.

On the ship 2 there is a reel 4 on which a first connecting cable 5 can be wound, which first connecting cable 5 in Figure 1 is largely unwound.

Five kites are attached to the end of the first connecting cable 5, all at different distances from the ship, more specifically four large kites 6 and finally a smaller kite 7. In Figure 1 these kites 6,7 are in flying condition in the air displayed.

A part of the first connecting cable 5 is designed as a tie rod 8 below the kites 6,7, i.e. between the kites 6,7 and the ship 2. A wind turbine 10 is suspended from this tie rod 8 by means of a suspension structure 9.

Of course, the number and size of the kites 6,7 is chosen such that they are capable of lifting the wind turbine 10 to the desired height.

For the sake of simplicity, the suspension structure 9 is shown as a single rod, but can also be a more complex, rigid structure. The suspension structure 9 is hinged to the drawbar 8 by means of a hinge 11.

A second connecting cable 12 is attached to the bottom of the suspension structure 9. This is further connected to a container 14 located in the water 13 that is filled with water.

The second connecting cable 12 is essentially a power cable for diverting wind energy generated by the wind turbine 10, but is strong enough to withstand significant tensile forces.

The wind turbine 10 is arranged to be submersible in water. In practice, this means that electrical components are completely shielded from water, for example by embedding in resin, and that the mechanical components are made of corrosion-resistant material. These are, for example, systems similar to those used in underwater turbines for converting water flow into electrical energy.

The operation of the device 1 is simple and as follows.

Here the wind direction is from left to right according to arrow P.

The kites 6,7 provide sufficient lift to pull the wind turbine 10 up, typically to a height of a few hundred meters.

As a result, the wind turbine 10 is placed at a height where a strong wind almost always prevails, so that the wind turbine 10 can work a great percentage of the time in optimum conditions.

The wind energy generated by the wind turbine 10 is discharged via the second connecting cable 12 to a location where it can be used effectively.

Due to the own weight of the second connecting cable 12, supplemented by the counterweight formed by the water-filled container 14, a possibly unstable movement of the suspension structure 9 and the wind turbine 10 is damped.

Due to the fact that the suspension structure 9 is pivotable with respect to the first connecting cable 5, the wind turbine 10 can always be used in an optimum or almost optimum orientation, despite the fact that the angle of the first connecting cable 5 with the horizon depends on the wind strength .

It is noted here that in Figure 1 the blades of the wind turbine 10 extend vertically and parallel to the suspension structure 9. It can be experimentally determined which angle the suspension structure 9 adopts with the horizon during use, so that the angle of the blades relative to the suspension structure 9 can of course be adjusted to have as much a vertical orientation as possible of the blades of the wind turbine 10, also as the suspension structure 9 assumes an angle as a result of the wind forces.

The kites 6,7 and the wind turbine 10 can of course adjust their orientation with respect to the ship 2 to the prevailing wind direction.

When the wind speed is too low for the kites 6,7 to generate sufficient lift or is higher than design limits of the wind turbine or the kites, the wind turbine 10 and the kites can be overtaken by overtaking or having the first connecting cable 5 6,7 at a different height with a more suitable wind speed.

If this measure is not sufficient, the wind turbine 10 and the kites 6,7 can be lowered into the water 13, as shown in Figure 2, so that the wind turbine 10 is immersed in the water 13.

Hereby it is easy, in contrast to a use of a comparable device above land, to prevent mechanical damage to the wind turbine 10 as a result of the lowering.

Note that such situations occur relatively rarely because of the relatively constant and strong air currents at higher altitudes. Even when maintenance or repair is required, the wind turbine 10 and the kites 6,7 can be lowered.

At a low wind speed this lowering will happen automatically, because the kites 6,7 can no longer generate sufficient lift. Hereby it may be desirable to partially or completely overtake the first connecting cable 5 to prevent it from becoming entangled in itself or other parts of the device 1.

At a higher wind speed, it will be necessary to overtake the wind turbine 10 and the kites 6, 7 by means of the reel 4, or to provide one or more of the large kites 6 with surfaces that are controlled by a remote control of orientation. can be changed so that the amount of lift generated by this kite or kites 6 can be reduced, whereafter the wind turbine 10 and the kites 6,7 will slowly sink into the water 13.

Depending on the situation, a number of kites 6, 7 can then be kept flying, so that bringing the device 1 back into operating condition, i.e. pulling the wind turbine 10 up again, can easily be done without further external aids.

The small kite 7 is therefore specifically designed to be able to continue flying at a large number of wind speeds, as shown in figure 2. With sufficient wind speed, this small kite 7 can then pull the adjacent large kite 6 out of the water 13, whereafter these two kites 6 7 can jointly pull the next large kite 6 out of the water 13, until all large kites 6 are out of the water 13 and they can together lift the wind turbine 10 out of the water 13 again so that it can start operating again.

Alternatively or additionally, to operate the device, a balloon, a drone, a helicopter or other device that can fly independently may be deployed to pull the device, or at least one or a few kites thereof, out of the water so that sufficient lift power can be generated thanks to the wind.

The present invention is by no means limited to the embodiment described as an example and shown in the figures, but a device according to the invention can be realized in all shapes and dimensions without departing from the scope of the invention.

Claims (14)

Conclusions. A device (1) for generating wind energy comprising the following components: a wind turbine (10) adapted to be submersible in water (13); - one or more kites (6,7) that together can generate sufficient lift to be able to lift the wind turbine (10), the wind turbine (10) being suspended from the one or more kites (6,7); -a base station (2) from which a first connecting cable (5) runs to the one or more pilots (6,7). Device according to one of the preceding claims, characterized in that the base station (2) is surrounded by water (13) that is deep enough to allow the wind turbine (10) to be partially or completely submerged. Device according to claim 1 or 2, characterized in that it is provided with a second connecting cable (12) which, during use of the device (1), from the bottom of the wind turbine (10) or from a suspension structure (9) before the wind turbine (10) runs down to a downwind of the base station (2) at a distance from the base station (2). Device according to claim 3, characterized in that the second connecting cable (5) is connected to the ground or to a counterweight (14) that cannot be lifted by the device (1). Device - according to one of the preceding claims, characterized in that it comprises two or more kites (6, 7) which are successively connected to the base station (2) at an increasing distance from the base station (2) first connection cable (5). Device according to claim 5, characterized in that the kite (7) located at the greatest distance from the base station (2) or a combination of kites (6,7) placed next to each other comprises this kite (7), can generate sufficient lift to pull the next kite (6), viewed in the direction of the base station (2), into the air immersed in water (13). Device according to one of the preceding claims, characterized in that the wind turbine (10) is suspended between the base station (2) and the kite (6) of the one or more kites (6,7) closest to the base station (2). Device according to one of the preceding claims, characterized in that it is provided with a rigid suspension structure (9) for the wind turbine (10), the suspension structure (9) being hingedly attached to the first connecting cable (5). Device according to claim 8, characterized in that the wind turbine (10) is not movably suspended from the suspension structure (9). Device as claimed in any of the foregoing claims, characterized in that at least one of the one or more kites (6,7) is adapted to change its shape on the basis of an external signal and thereby the amount of lift that the at least one kite (6.7) can generate change. 11. Saltwater desalination plant, characterized in that it is located at a certain distance from the nearest coast and that it is at least partially supplied with energy by a device (1) according to one of the preceding claims. Installation according to claim 11, characterized in that it is surrounded by water (13), the installation being provided with a device (1) according to claim 2 or a claim dependent thereon. 13. - Method for generating wind energy, wherein a wind turbine (10) is lifted by one or more kites (6,7) to a certain height, wherein the one or more kites (6,7) by means of a first connecting cable (5) are connected to a base station (2), characterized in that the base station (2) is surrounded by water (13) that is deep enough to partially or completely submerge the wind turbine (10). Method according to claim 13, characterized in that when the wind speed is outside a certain interval, the wind turbine (10) is partially or completely submerged in the water (13).