BE1026266B1 - Device for generating wind energy - Google Patents

Abstract

Device for generating wind energy, which device (1) comprises a rotatable paddle wheel (2) with a shaft (7) on which blades (8) are arranged, the shaft being intended to be placed horizontally or substantially horizontally, wherein the device (1) further comprises conversion means (3) for converting the rotational movement of the shaft (7) into electrical energy, characterized in that the device (1) is provided with an undercarriage (4) which is movable on a surface ( 12) and on which the paddle wheel (2) is fitted, wherein the undercarriage (4) is also provided with a screen (5) that shields part of the paddle wheel (2) from the oncoming wind, wherein the undercarriage (4) is also provided with has directional means (6) for directing the screen (5) towards the direction (A) of the wind, so that the screen (5), seen from the direction (A) of the wind, partially shields the paddle wheel (2) .

Description

Device for generating wind energy.

The present invention relates to a device 5 for generating wind energy.

It is known that wind turbines are traditionally used to generate wind energy.

Such wind turbines have the advantage that they can generate energy both during the day and at night, in contrast to, for example, solar panels that generate renewable energy from sunlight.

Such a traditional wind turbine consists of a so-called mast, on which a gondola with blades is placed.

The dimensions of such a wind turbine are enormous: the height of the mast is at least 50 to 100 meters and the blades have a length of at least 50 meters.

Such known installations therefore have the disadvantage that they take up a lot of space, with the result that the distance between different wind turbines must also be relatively large. They also cause landscape pollution.

Another disadvantage is that the blades, when rotating, generate annoying and disturbing shadows during the daytime under sunlight with a kind of stroboscopic effect.

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The blades will also generate wind disorder, which means that the known wind turbines must be positioned sufficiently far apart, such that the wind disorder of a wind turbine has no influence on the adjacent wind turbines.

Moreover, the ends of the long blades at higher rotational speeds will move very quickly through the air and thereby produce annoying noises.

The disadvantages mean that wind turbines are not suitable for use in the vicinity of residential areas.

The present invention has for its object to provide a solution to at least one of the aforementioned and other disadvantages.

The present invention has a device for generating wind energy as an object, which device comprises a rotatable blade wheel with a shaft on which blades are mounted, the shaft being intended to be placed horizontally or virtually horizontally, the device further comprising converting means for converting the rotational movement of the shaft into electrical energy, characterized in that the device is provided with a base which is movable on a surface and on which the impeller is mounted, the base also being provided with a screen that forms a part of shielding the paddle wheel from the incident wind, wherein the undercarriage is also provided with directing means for directing the screen towards the direction of incidence of the wind,

BE2018 / 5297 so that the screen, viewed from the direction of the wind, partially shields the paddle wheel.

An advantage is that such a device can be made smaller and more compact than the traditional wind turbines, whereby, among other things, they will only generate limited shade.

Moreover, such a device will not generate wind disturbance, so that they can also be placed closer to each other.

Another other benefit is that the device no annoying noises generate and no disturbing shadows will produce. Another other benefit exists in it that such

layout will only have a minimal impact on the environment in terms of landscape pollution.

An additional advantage is that the screen will screen off a portion of the blades, so that the incident wind can only act on one half of the blade wheel, as seen from the direction of the wind. As a result, a force will only be exerted on one half of the impeller, so that the rotation of the impeller can be started and continued due to this imbalance.

Hereby it is important to note that only the configuration as described in the independent claim will function properly, where desired

BE2018 / 5297 speed is achieved by the impeller. It has thus been found that a vertical axis of the paddle wheel will not lead to the desired result.

The directing means have the advantage that the screen is always positioned correctly with respect to the incident wind, even with a changing wind direction, so that the paddle wheel, as seen from the direction of incidence of the wind, is always partially shielded from the wind. In this way the effect of the screen is always guaranteed.

When both the impeller, as well as the screen, and the directing means are provided on the undercarriage, the directing means will always position the undercarriage correctly.

The aforementioned directing means can for instance comprise a sensor which will detect the wind direction and a motor which will move the chassis on the basis of the signal.

The directing means preferably consist of one or more flat parallel plates, also called control plates or guide plates, which extend transversely to the axis of the paddle wheel and which are located on the other side of the paddle wheel than the aforementioned screen, the space between the extension of the plates at least partially overlaps with the paddle wheel and whereby the plates cannot move relative to the screen, so that a movement of the plates entails a movement of the screen.

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Such an embodiment of the directing means is completely mechanical and static, i.e. without electronic or moving components, which makes it very robust.

The device itself searches for the wind direction by means of the aforementioned flat plates, that is to say: the device will orient itself properly according to the wind direction.

According to a preferred feature of the invention, the screen can shield the lower half of the screen from the incident wind and is inclined towards the impeller.

In this way, the screen will not only allow the incident wind to operate the paddle wheel by leaving only one half free so that the incident wind can act on the blades located at the free top, but the screen will also serve as a kind of guidance for the incoming wind to guide it to the blades.

With the insight to better demonstrate the features of the invention, a few preferred embodiments of an apparatus for generating wind energy 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 represents a side view of a device according to the invention;

BE2018 / 5297 figure 2 schematically represents a top view of the device from figure 1;

figure 3 schematically represents an alternative embodiment of a device according to the invention.

The device 1 for generating wind energy diagrammatically shown in figures 1 and 2 mainly comprises the following components:

- two paddle wheels 2;

- conversion means 3;

- chassis 4;

- screen 5;

- targeting means 6.

The two blade wheels 2 are rotatably mounted on the chassis 4 and comprise a shaft 7 on which blades 8 are mounted.

The shafts 7 in this case are made up of a central shaft 7a, around which a sleeve 7b is arranged. The sleeve 7b serves as it were as a thickening of the central axis 7a. It is on this sleeve 7b that the blades 8 are arranged.

The shafts 7 extend horizontally or virtually horizontally.

Both blade wheels 2 are attached to each other via an extended portion 9 of their shafts 7. As a result, both axes 7 will rotate at the same speed.

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It goes without saying that the device 1 can also be provided with only one paddle wheel 2 or with more than two paddle wheels 2.

Each impeller 2 is three meters long, meaning that the shaft 7 is three meters long. The shafts 7 can also be, for example, five meters long.

The blades 8 consist of flat plates with a size of three meters, i.e. the length of the shaft 7, and a height of preferably one meter. The diameter of the sleeve 7b is preferably also one meter.

In this case, but not necessarily, each paddle wheel 2 is provided with six paddles 8, but this can also be more or less.

The conversion means 3 will be able to convert the rotational movement of the shaft 7 into electrical energy.

In this case the conversion means 3 are arranged on the chassis 4.

In this case, the conversion means 3 comprise an electric generator 10, which is coupled by means of a transmission 11 to the shafts 7 of the blade wheels 2.

Of course it is clear that the precise coupling can be done in many different ways, which are easy for a person skilled in the art to realize.

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The height of the transmission 11 with the generator 10 is approximately two and a half meters, with the vanes 8 added, the total height is three and a half meters. The total length, measured in the direction of the axes 7, is approximately five meters.

Even though the dimensions of the chassis 4 have to be added, this is in any case much more compact and smaller than the dimensions of the traditional wind turbines.

The aforementioned undercarriage 4, on which in this case the paddle wheels 2 are rotatably mounted and the generator 10 fixed, is displaceable on a base 12.

The chassis 4 is in this case manufactured from a frame 13 on which all parts of the device 1 are mounted or mounted.

The chassis 4 is also provided with wheels 14 which ensure that the chassis 4 is movable over the substrate 12.

Instead of wheels 14, these can also be ball pots.

The device 1 is further provided with a screen 5 which is also fixedly mounted on the chassis 4. This screen 5 will shield part of the paddle wheels 2 from the incident wind, which is indicated by arrow A.

In this case, the screen 5 is not movable relative to the paddle wheel 2 and the lower half 2a of the paddle wheel 2 can shield itself from the incident wind A.

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The screen 5 is at least as wide as the paddle wheels 2 and in this case it is exactly as wide as the paddle wheels 2.

As can be seen in figure 1, the screen 5 is inclined towards the paddle wheels 2.

Or to put it another way, the screen 5 is not positioned vertically upwards, but is placed at an angle 15 with the horizontal base 15, the underside being further away from the blade wheels 2 than the top side.

It is clear that the screen 5 should not only be seen as a flat or non-flat plate, but that elements or the like with an obliquely rising side such as the aforementioned screen 5 can also serve as 'screen 5'.

According to the invention, the device 1 is further provided with directing means 6 for directing the screen 5 towards the direction of incidence A of the wind, so that the screen 5, viewed from the direction of direction A of the wind, partially shields the paddle wheels 2.

These orienting means 6 are also fixedly provided on the chassis 4.

The aforementioned directing means 6 can for instance comprise a sensor which will detect the wind direction A and a motor which will move the chassis 4 on the basis of the signal.

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In this case, however, the directing means 6 consist of two flat parallel plates 16 which extend transversely to the axis 7 of the paddle wheels 2 and which are located on the other side of the paddle wheels 2 than the aforementioned screen 5, the space between the The extension of the plates 16 at least partially overlaps with the blade wheels 2 and whereby the plates 16 cannot move relative to the screen 5, so that a movement of the plates 16 entails a movement of the screen 5.

It is of course not excluded that there is only one plate 16 or more than two flat parallel plates 16.

The flat plates 16 in this example are preferably placed at a distance of two meters from each other.

The flat plates 16 are also at least two meters long.

Preferably the flat plates 16 come at least as high or higher than the blade wheels 2.

This has the advantage that the flat plates 16 will always receive wind so that the device 1 can always be directed 'with the paddle wheels 2' in the wind '. Indeed, even if the wind Ά comes in from the screen 5 and the flat plates 16 are located behind the paddle wheels 2 as seen from the direction of incidence A of the wind, the flat plates 16 will still catch wind because they are higher than the paddle wheels 2.

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The material from which the device 1 is made can be aluminum or iron, but also, for example, plastic or a combination of more of the aforementioned and / or other materials.

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

The device 1 is placed, by means of the chassis 4, at a location where it is exposed to wind.

As shown in the figures, the wind A will fall on the blade wheels 2, the screen 5 shielding the lower half 2a of the blade wheels 2.

This means that the wind will only be able to act on the upper half 2b of the blade wheels 2, so that only the blades 8 which are situated on this upper half 2b will experience a force due to the incident wind A.

Since the blades 8 located on the lower half 2b do not experience any force, a moment will be exerted by the wind on the blade wheels 2.

As a result of the moment exerted by the wind, the paddle wheels 2 will rotate about their axis 7.

As a result of this rotation, which is transmitted to the generator 10 via the transmission 11, the generator 10 will be driven.

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This allows a force to be developed from one to several electrogens.

When the direction of incidence A of the wind changes relative to the device 1, it will be necessary for the screen 5 and the paddle wheels 2 to be displaced in order to be able to continue to guarantee the operation of the device 1. After all, it must always be ensured that the screen 5 is always situated in front of the paddle wheels 2 in the direction of the direction of incidence A of the wind.

Before the direction of incidence A changed, the plates 16 were aligned parallel to the direction of incidence A of the wind, so that no force was exerted on it.

As a result of the change in the direction of incidence A, the wind will act on the flat plates 16 so that they experience a force.

This force will be such that the plates 16 will move to align themselves back parallel to the direction of incidence A of the wind. Due to the movement of the plates 16, the chassis 4 will also rotate and the screen 5 and the blade wheels 2 will also rotate so that the screen 5 is again located in front of the blade wheels 2 as seen in the direction of incidence A of the wind.

In this way the screen 5 is again in the correct position to allow the wind to exert a moment on the blades 8 of the blade wheels 2 to keep it rotating.

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Figure 3 shows a variant embodiment, in which case a gear box 17 is arranged between the two blade wheels 2. The transmission 11 transfers the movement of the paddle wheels 2 to a belt transmission 18 with a belt 18a and a wheel 18b.

The belt transmission 18 in turn leads to a clinic 19 with a shaft 20.

In turn, one to four policies can be placed on this axis 20.

These are provided at the bottom of the chassis 4, i.e. approximately at the level of the substrate 12.

A generator 10 can be placed on each clinic 19 which is driven via the clinic 19.

Although in the example shown and described above, the chassis 4 is freely movable on a base 12, it is not excluded that the chassis 4 is anchored at the location of a center point, wherein the chassis 4 is provided with ball pots that are movable in a circular rail such that the device 1 rotates about the center point.

In other words: when the directing means 6 will direct the device 1 to the incident wind, the chassis 4 will rotate around the center point, whereby the ball pots will move in the aforementioned rails.

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The present invention is by no means limited to the embodiments described by way of example and shown in the figures, but a device for generating wind energy according to the invention can be realized in all kinds of shapes and dimensions without departing from the scope of the invention.

Claims (14)

Conclusions. Device for generating wind energy, which device (1) comprises a rotatable blade wheel (2) with a shaft (7) on which blades (8) are arranged, the shaft being intended to be placed horizontally or virtually horizontally wherein the device (1) further comprises converting means (3) for converting the rotational movement of the shaft (7) into electrical energy, characterized in that the device (1) is provided with an undercarriage (4) which is movable on a base (12) and on which the paddle wheel (2) is arranged, wherein the undercarriage (4) is also provided with a screen (5) which shields a part of the paddle wheel (2) from the incident wind, the undercarriage (4) ) is also provided with directing means (6) for directing the screen (5) towards the direction of incidence (A) of the wind, so that the screen (5), viewed from the direction of incidence (A) of the wind, the impeller (2) ) partially shielded. Device according to claim 1, characterized in that the screen (5) is not movable relative to the impeller (2) and can shield the lower half (2a) of the impeller (2) from the incident wind. Device according to claim 1 or 2, characterized in that the screen (5) is at least as wide as the blade wheel (2). BE2018 / 5297 Device according to one of the preceding claims, characterized in that the screen (5) can shield the lower half (2a) of the impeller (2) from the incident wind and is inclined towards the impeller (2). Device according to one of the preceding claims, characterized in that the directing means (6) consist of one or more flat parallel plates (16) which extend transversely to the axis (7) of the paddle wheel (3) and which extend to the other side of the impeller (3) than the aforementioned screen (5), wherein the space between the extension of the plates (16) at least partially overlaps with the impeller (2) and the plates (16) cannot move relative to the screen (5) such that a movement of the plates (16) entails a movement of the screen (5). Device according to claim 5, characterized in that there are two flat plates (16) which are placed at a distance of two meters from each other. Device according to claim 5 or 6, characterized in that the flat plates (16) are at least two meters long. Device according to one of the preceding claims, characterized in that the conversion means (3) are arranged on the chassis (4). BE2018 / 5297 Device according to one of the preceding claims, characterized in that the conversion means (3) comprise an electric generator (10) which is coupled to the shaft (7) of the impeller (2) by means of a transmission (11). Device according to one of the preceding claims, characterized in that the device (1) is provided with two paddle wheels (2), which are attached to each other by means of an extended portion (9) of their shafts (7). Device according to one of the preceding claims, characterized in that the paddle wheel (2) is two meters long. Device according to one of the preceding claims, characterized in that the undercarriage (4) is made of a frame (13) on which all parts of the device (1) are mounted or mounted. Device according to one of the preceding claims, characterized in that the undercarriage (4) is provided with ball pots or wheels (14) which ensure that the undercarriage (4) is movable over the base (12). Device as claimed in any of the foregoing claims, characterized in that the undercarriage (4) is anchored at the center of a center point, wherein the undercarriage (4) is provided with ball pots that are movable in a circular rail, such that the device ( 1) can rotate around the center point.