NL1030937C2 - Wind energy installation for wind energy comprises housing with at least one entry aperture for air and an outlet aperture for same medium - Google Patents

Abstract

The wind energy installation comprises a housing with at least one entry aperture for air and an outlet aperture for the same medium. The entry and outlet apertures are joined by a throughflow channel. A conversion unit converts the air movement energy of the air in the throughflow channel, whereby this channel at least partly forms a venturi which accelerates the air when it flows through the channel. The covnersion unit is so arranged in the channel that the conversion takes place at a relatively high air speed in relation to the inflow air. The installation is formed on a platform (1), on which are four rails (6), along which winches are displaceable (2). Rope cables (3) extend inclinedly upwards from the winches in the direction of an assembly unit (4) for one or more wind energy recovery units. In the cables are damping components (10) for damping vibrations or fluctuations.

Description

WIND ENERGY WINDING DEVICE, SYSTEM AND BRAND METHOD FOR CONVERTING WIND ENERGY.

The present invention relates to a wind energy recovery device for converting wind energy. The present invention furthermore relates to a system comprising such a wind energy recovery device. Furthermore, the present invention relates to a method for converting wind energy.

Mankind is increasingly using energy for various purposes in society. This energy is increasing, but it appears that in the foreseeable future it can be obtained to a decreasing extent from fossil fuels. In addition to the use of fossil fuels, other forms of energy sources are used such as nuclear energy, solar energy and wind energy. The present invention relates in particular to the use of wind energy. A disadvantage of wind energy such as that which is extracted in a known manner is that the availability is subject to considerable changes even at favorable geographical locations. An important reason for this is, according to the inventor of the present invention, the fact that the known extraction methods and extraction systems carry out the conversion of the energy at a low height above the earth's surface, which height is essentially dependent on the mast height of a windmill and the length of the rotor blades that must be less than the mast height. Especially at these low heights, especially up to 100 meters or incidentally up to 150 and 183 meters (Brunsbiittel, DE) high. Such a windmill has rotor blades of 61 meters. The effective average height is the height of the mast. At these heights, the wind speed is fairly unreliable.

Furthermore, such rotor blade windmills have the drawback that the wind speed is relatively low, whereby the yield of the windmill is related to this speed.

The present invention relates to the more effective use of available wind energy. To this end, the present invention provides a wind power recovery device for converting wind energy, comprising: - a housing comprising at least one inlet opening for admitting air and an outlet opening for outlet of air, - a flow channel connecting the inlet opening and the outlet opening, - a conversion unit for converting movement energy from the air arranged in the flow-through channel for allowing the air to flow through it, wherein - the flow-through channel comprises at least in part a substantially venturi shape for accelerating the air when it flows through the channel and the conversion unit is arranged in the channel such that the conversion is performed at a relatively high air speed relative to the inflow air.

An advantage of such a device according to the present device is that the flow velocity of the air at the level of the conversion unit will be very high relative to the available wind on site. This allows the converter to use this very high speed. A further advantage is that due to the small diameter at the level of the conversion unit, a relatively compact conversion unit can be used with respect to the long rotor blades of wind turbines according to the prior art. A further advantage of this is that the known noise problems of the large rotor blades are prevented in a converter according to the present invention.

In a further preferred embodiment according to the present invention, the device comprises positioning means for positioning the device for use at a height of use with a relatively stable win intensity. An advantage of this is that the wind fluctuates much less at a certain height than closer to the earth's surface. A further advantage is that the average wind speed with associated wind pressure is relatively greater at such heights than at lower heights and is more stable.

In a further preferred embodiment, the positioning means comprise means for providing rising power relative to the earth's surface. With the aid of such means, the device can be brought and held at the desired height. For this purpose, full use can be made of the rising power of the positioning means. It is equally possible that external means are used to get and / or keep the wind power recovery device at the working height. A mast, airplane, helicopter, balloon, etc. can be considered here. The positioning means preferably comprise mounting means for mounting under an aircraft or hover. With the aid of such an aircraft or hover, the device can be brought to the operating height and held there. An advantage of a hover is that no additional energy has to be used. Examples of such gliders are balloons, zeppelins or gliders. A further example of a hover may be a support wing specifically designed for this application.

The positioning means of the device preferably comprise fixing means for fixing the device to a height-providing construction such as a mast or a tower. As a result, such a device can be fixed at a certain height.

For anchoring the device, the device preferably comprises means for attaching the device to a garden construction. Such a garden construction is preferably provided with one or more winches for anchoring the device at variable distances from the soil by means of the tethers. The height can further be varied with the aid of such winches.

In a further preferred embodiment the device comprises at least one, possibly nestable, holder for a gas with a lower density than the ambient air in a location of use. The device can hereby be brought up to date and / or a contribution can be made to raising the height. It is possible that the housing serves as the wall of the holder. It is also possible that a number of, for example balloon-like, holders are placed in the housing. It is furthermore possible to arrange a number of balloon-like holders into each other such that when one of them leaks, the remaining balloons can continue to exert their upwardly directed force.

Such a device preferably comprises a vacuum generator for generating a lift-causing vacuum on at least a part of the outer surface of the device by means of disintegrating air molecules. Such a vacuum generator is known per se in relation to VTA-type aircraft. A disadvantage of VTA propulsion in aircraft is that a relatively large amount of electrical energy is required. When applying the VTA principle in a device according to the present invention, this disadvantage is not present since, when electricity is generated by means of device according to the present invention, sufficient electrical energy is generated in the device or is available from the electricity supply. electricity grid (for example when taking off when the energy conversion has not yet started). A further embodiment comprises a wing shape for generating elevator. Use is made here of air flowing along the wing shape, whereby lift is generated at the top of the wing in a manner known from aircraft practice.

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The device preferably comprises means for varying the orientation angle of the wing shape with respect to the air flow. This allows it to be optimized for the wing shape and the speed of the air flow.

Alternatively or additionally, it is possible to optimize this lift of the wing by varying the curvature line and / or the curvature value of the wing shape and / or by applying flaps.

The conversion unit preferably comprises one. electricity generator comprising, for example, a worm wheel or a turbine with at least one fin wheel. Such generators are suitable for high speeds that can be achieved by means of the venturi operation.

For contributing to the lift, the device preferably further comprises means for deflecting the air flowing out of the channel. If it obtains a downward component, this downward component can be used to overcome gravity.

Preferably, a wing further comprises fins for providing desirable behavior of the device in air currents.

For the purpose of controlling the energy to be converted, the device preferably comprises a control member for controlling the size of the passage opening of the channel and / or a valve member for controlling the inlet and / or outlet opening of the channel . This makes it possible to vary or even shut off the air flow for the sake of, for example, safety or an even energy generation and / or adjusting the amount of converted energy to the (current) energy demand.

A further aspect of the present invention relates to a system for converting wind energy comprising: 1030937 6 - an apparatus according to one or more of the preceding claims, - an anchoring for anchoring the apparatus relative to the earth's surface at a particular or Variable height, - a transport member for transporting energy from the conversion unit to the earth's surface.

Such a system offers the possibility to use the wind energy generating device floatingly independently, whereby it can be anchored at a desired location and height.

For this purpose, the system is preferably provided with at least two winches for anchoring the device by means of cables or cable and with variable distances from the ground. The device can also be lowered or lowered by means of such winches. The system preferably further comprises at least one guide member for varying the anchoring over the bottom. Such a guide member can be designed as a rail system along which the winches can be moved.

To prevent undesired or dangerous vibrations, if desired, the system is provided with a damping member, for example per cable cable, for damping vibrations or voltage variations in the anchoring.

In a further embodiment, the system comprises an energy storage system for storing the extracted energy. This allows wind variations that can occur even at the working height to be absorbed if this energy is released when the converted wind energy temporarily falls below an average value.

The system preferably comprises a mast for supporting the wind energy extraction device with respect to a building or the earth's soil. As a result, height can be obtained without providing lift in, for example, aerodynamic manner or light gases according to previous embodiments. The mast is furthermore preferably variable in length, such as, for example, telescopic.

In a further embodiment the system comprises a transfer member for transferring rotational energy from the energy converter to a turbine outside the axis or on the earth's surface. A dynamo or turbine next to the axis or an energy converter on the earth can be considered here. The energy can be transferred via energy transfer means known per se, such as hydraulic, rotating flexible or rigid shafts or compressed air.

A further aspect according to the present invention relates to a method for converting wind energy, comprising steps for: - flowing air into a venturi channel, - accelerating the air in the venturi channel, - recovering energy from the accelerated air,

Advantages of such a method have been described in the foregoing on the basis of the device embodiments. Further advantages, features and details of the present invention will be further described with reference to the embodiments with reference to the figures, in which: - FIG. 1 is a schematic overview representation of a first embodiment of the present invention; FIG. 2 is a perspective view of an embodiment of a wind power generator according to the present invention; FIG. 3 is a cross-sectional view of a further embodiment of a wind power generator; FIG. 4 is a front view of an embodiment of a valve member.

A first preferred embodiment of the present invention in FIG. 1 relates to a system for converting wind energy into electrical energy. The whole unit is built on a platform 1. On this platform 1 there are four rails 6 on which winches 2 are mounted in a manner movable along the rails. From the winches, garden cables 3 extend obliquely in the direction of a mounting unit 4 for mounting one or more wind power generating devices as shown, for example, in Figures 2 and 3. In the garden cables 3, damping members 10 are arranged for damping vibrations or fluctuations.

For the purpose of discharging electricity from the wind power extraction device, an electricity cable 7 extends from the mounting plate to the earth. For keeping the cable 7 under pretension, a tensioning mechanism 9 is provided on the underside thereof. For the sake of the height variations of the wind power generating device, a kind of winch can also be provided here, but suitable for carrying electricity cables. A control center 5 is provided for controlling the electricity generation and its delivery to the network and further control functions for the correct operation of the system.

In FIG. 2 schematically shows a wind power recovery device 11 that can float through a number of measures. Under the wing 16 are 4 gondolas 12,13,14,15 mounted. A turbine is located in each gondola in a manner similar to that shown in FIG. 3.

The wing 16 is lifted by means of the shape similar to the normal airplane wings. The bottom side is flat and the top side is convex, which shape is embodied by the boiling 19 and the sloping top wall 20, causing upward lift in an air flow. Furthermore, there is a space in the wing that is filled with a light gas, at least a gas that is lighter than the air on the outside of the wing. This gas can be kept in a space but also, for example, in a number of balloons arranged in the wing. The wing is bounded on either side by 1030937 9 side walls 17, 18 which protrude upwardly from the wing body at the rear and thus form fins for providing stability. Furthermore, such fins make a contribution to keeping the gondola in the wind.

The operation of the gondolas of FIG. 2 is analogous to that of FIG. 3. However, this gondola 31 is integrated in a wing-shaped housing, whereby the similarities are limited to the operation of the interior. The interior is bounded by walls 38, 39, 42 defining a venturi-shaped channel 32 (A, B) through which wind blows for generating energy through the turbine 35. The air from the wind flows in the direction of the arrows C through the opening 33 into channel 32 via channel part 32A. This channel part is shaped as the narrowing of a venturi, as a result of which the speed of the air will increase considerably, for example by a factor of 5 to 20, but more is possible.

The air then reaches the narrowest part of the venturi where the turbine 35 is arranged. The turbine can be of a type known per se with a central axle with wheels fitted around it. rotate by the air flow. The rotation is then converted into electrical energy via a dynamo function of, for example, a stator around a rotor arranged around the axis, arranged stator arranged around the venturi channel.

After the air has passed the turbine, it enters the channel part 32B, which channel part forms the widening part of the venturi. In this channel part, the air flow 30 will again slow to substantially the ambient speed of the wind. The air outflow opening 43 is preferably slightly larger than the inflow opening so that no unnecessary energy loss occurs on the outflow side. The outflowing air leaves the venturi channel in the direction of the arrow C.

In this embodiment, the venturi channel is integrated with a wing-shaped housing. This wing-shaped housing 1030937 has substantially the same lift-providing function as that of FIG. 2. The bottom side is therefore flat and the top side has a convex shape so that the lift is generated in conjunction with an air flow. A light gas may be provided in the hole 5 chambers 36 and 37 to promote the lift capacity of the wing.

Alternatively, the wing shape can be replaced with one or more balloons or zeppelins to provide lift to the wind power generator. Such floating bodies can be attached directly to the frame 4 or via a cable. It is also possible to place a number of venturi channels in a zeppelin. It is equally possible to place one or more rows of venturi channels in a frame under one or more balloons or zeppelins. The zeppelins or balloons can be of double-walled design so that a leak in one of the walls will only have a limited influence on the lift of the whole.

Fig. 4 shows a control slide 44 which is applicable, for example, along the line IV-IV in Figs. 3. In the open state of the sliders 45, 46 slidably mounted on the frame 47, air can freely flow through the venturi channel 32. If the sliders are moved in the direction of the arrows A and B, the sewing is gradually closed. This is possible up to any desired variable opening size. When the slides are closed, naturally no air flow is possible and therefore the turbine is switched off. Furthermore, the turbine can be controlled with the sliders depending on energy demand and weather conditions.

Furthermore, the balloons may be reinforced with, for example, fibers such as carbon fibers, directly in the gas container material or in a protective cap. An advantage of using such fibers is that structures are possible in many forms including integrated reinforcements for necessary components such as the channel or the converter.

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A further advantage of a system according to the present invention is that the height can be varied. In this way the device can be brought to a safe height in case of stormy weather and further function where existing windmills have to be switched off since they have a fixed height or can at least not be set lower than the length of the blades.

In a further embodiment, bird-deterring equipment such as laser light and / or specific sound frequencies can be provided.

The use of removable or inflatable float devices offers the possibility of temporarily deploying such a system at a location and moving it from location to location.

To provide lift, the top of the wind power generator can be provided with a cathode ray generator. For this purpose, a plurality of such generators are preferably provided in the surface in the form of a plurality of separate cells. The cathode rays emanating from the surface cause the molecules of the air above the surface to disintegrate, creating a negative pressure due to residual particles disappearing. The underpressure provides an upward lift that contributes to the rising capacity or offers this in itself to a sufficient extent. With normal aircraft it is a disadvantage that such a vacuum drive requires electrical energy, but this is largely available in this application because of the generation of electricity and the connection to the network.

One of the more important advantages of the invention is that use can be made of the much more stable wind energy that is present in higher air layers than is the case with known wind turbines that are placed on the ground.

The present invention has been described above with reference to non-limiting preferred embodiments. Aspects of various preferred embodiments may be freely combined in a manner known to those skilled in the art from this text and must be considered as such learned from this text. The requested rights are determined by the appended claims.

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Claims (28)

A wind energy recovery device for converting wind energy, comprising: 5. a housing comprising at least one inlet opening for admitting air and an outlet opening for discharging air, - a flow channel connecting the inlet opening and the outlet opening, 10. a conversion unit for converting motion energy from the air arranged in the flow channel to cause the air to flow therethrough, wherein the flow channel comprises at least in part a substantially venturi shape for accelerating the air as it passes through the channel flows and the conversion unit is arranged in the channel such that the conversion is carried out at a relatively high air speed relative to the inflow air. 20 Device as claimed in claim 1, comprising positioning means for positioning the device for use at a height of use with a relatively stable wind intensity. 25 Device as claimed in claim 2, wherein the positioning means comprise means for providing rising power relative to the earth's surface. Device as claimed in claim 2, wherein the positioning means comprise mounting means for mounting under an aircraft or hover. 5. Device as claimed in claim 2, wherein the positioning means comprise fixing means for fixing the device to a height-providing construction such as a mast or a tower. 1030937 Device as claimed in one or more of the foregoing claims, comprising means for attaching the device to a garden construction. 5 Device as claimed in one or more of the foregoing claims, comprising at least one, possibly nestable, container for a gas with a lower density than ambient air in a location of use. 10 8. Device as claimed in one or more of the foregoing claims, comprising a vacuum generator for generating a lift-producing vacuum on at least a part of an outer surface of the device by means of the disintegration of air molecules. Device as claimed in one or more of the foregoing claims, comprising a wing shape for generating lift. 20 Device as claimed in claim 9, comprising means for varying the orientation angle of the wing shape with respect to an air flow. Device as claimed in claim 9 or 10, comprise the means for varying the curve line and / or the curve value of the wing shape, and / or flaps. 12. Device as claimed in one or more of the foregoing claims, wherein the conversion unit comprises an electricity generator, comprising for instance a worm wheel or a turbine with at least one fin wheel. 13. Device as claimed in one or more of the foregoing claims, comprising means for deflecting air flowing out of the channel. 1030937 Device as claimed in one or more of the foregoing claims, comprising fins for providing a desirable behavior of the device in air flows. 5 15. Device as claimed in one or more of the foregoing claims, comprising a control member for controlling the size of the passage opening of the channel and / or a valve member for controlling the inlet and / or outlet opening of the channel. 16. Wind energy conversion system comprising: - a device according to one or more of the preceding claims, - an anchor for anchoring the device relative to the ground at a specific or variable height, - a transport device for transporting energy from the converter unit to the surface of the earth. 17. System as claimed in claim 16, comprising at least one winch for anchoring the device by means of cables or trenches with variable distances from the ground. 18. System as claimed in claim 16 or 17, comprising at least one guide member for varying the anchoring over the bottom. A system according to claim 16, 17 or 18, comprising a damping member for damping vibrations or voltage variations in the anchoring. 35 1030937 20. System as claimed in one or more of the claims 16-19, comprising an energy storage system for storing extracted energy. System according to one or more of the preceding claims, comprising a mast for supporting the wind energy extraction device with respect to a building or the earth's soil. The system of claim 21 wherein the mast is length variable, such as, for example, telescopic. 23. Device as claimed in one or more of the foregoing claims, comprising a transfer member for transferring rotational energy from the energy converter to a turbine outside the axis or on the earth's surface. 24. Method for converting wind energy, comprising the steps of: 20. flowing air into a venturi channel, - accelerating the air in the venturi channel, - recovering energy from the accelerated air, The method of claim 21 using a device or system according to one or more of claims 1-23. A method according to claim 24 or 25, comprising the steps of stabilizing the movement of the device. 27. Method as claimed in one or more of the claims 24-26, comprising steps for adjusting the channel opening with respect to the wind. 1030937 Method according to one or more of claims 24-27, comprising steps for tuning the channel passage with respect to the wind. 1 03093 7