FR2913254A1 - Electrical energy producing device for e.g. dwelling, has superimposed wind turbine modules respectively comprising rotors that are rotatably mounted around common vertical axis formed by mast, where rotors are counter-rotative - Google Patents

Abstract

The device (10) has two superimposed wind turbine modules (200, 300) respectively comprising rotors that are rotatably mounted around a common vertical axis (O-O) formed by a vertical support mast (100). The modules respectively have stators surrounding the corresponding rotors, where the rotors are counter-rotative. Each stator has a series of vertical directional vanes whose orientation is adapted to rotate the corresponding rotor.

Description

The present invention relates to the field of wind turbines, that is to say

  devices for generating energy from the driving force of the wind.

  Conventionally, wind turbines intended to produce

  Electricity from the driving force of the wind are generally 5 wind turbines with horizontal axis. They comprise, mounted on a mast, a rotor provided with blades which rotates about a horizontal axis by the action of the wind on the latter.

  The kinetic energy of the wind acting on the rotor blades is transformed into mechanical energy thanks to the rotational movement of the rotor,

  This mechanical energy is then transformed into electrical energy. These horizontal axis wind turbines have limitations. They are very cumbersome when one looks for high powers and are sensitive to high speeds and wind squalls that weaken them. They also require means ensuring a radial orientation

  15 correct rotor relative to the wind direction of incidence. Wind turbines with a vertical axis are also known, that is to say whose rotor which captures the force of the wind rotates about a vertical axis. However vertical axis wind turbines have not experienced significant industrial development until today. These vertical axis wind turbines are also sensitive to high wind speeds and squalls. The applicant has determined in particular that when the wind speed and / or squalls, ie brief and violent gusts of wind, are too great, a gyroscopic effect perpendicular to the vertical axis of rotation of the rotor in operation can

  25 be created, if the wind turbine has significant dimensions. This gyroscopic effect results from the combination of the deflection of the support shaft resulting from the horizontal force applied by the wind and the torque applied simultaneously by the rotors. This gyroscopic effect can lead to a deterioration of the support mast 30 and therefore of the wind turbine. Accordingly, a first object of the present invention is to provide an alternative to existing power generation devices that do not give complete satisfaction.

  Another object of the present invention is to provide a power generation device having a high stability and reliability even in the case of strong winds. Another object of the present invention is to provide a power generation device providing a high power while maintaining a compact structure. Another object of the present invention is to propose a device for producing energy that is simple to install on any type of support. Finally, another object of the present invention is to propose a device

  10 of energy production whose noise pollution is reduced. These objects are achieved in the context of the present invention by means of an energy production device comprising at least two superimposed wind turbine modules each comprising a rotor rotatably mounted about a common vertical axis, characterized in that the rotors of

  Two adjacent wind turbine modules are counter-rotating. The invention will be better understood and other advantages and features will appear on reading the following description given by way of non-limiting examples and with the appended drawings in which: FIG. 1 represents a schematic lateral view of A wind turbine according to the present invention, - Figures 2 and 3 show a similar side view of two wind turbines according to alternative embodiments of the present invention, - Figures 4a, 4b and 5a, 5b show views in horizontal section. of the

  Rotor blades according to variants of the present invention,

  FIG. 6 illustrates a perspective view of a power generation device in accordance with a preferred embodiment of the present invention; FIGS. 7a and 7b show horizontal sectional views of two wind turbine modules of FIG. same device for producing energy according to the sectional planes referenced VIIA-VIIA and VIIB-VIIB in FIG. 6, and - FIG. 8 illustrates a perspective view of an exemplary embodiment of mechanical coupling means between two modules of FIG. wind turbines of a power generation device according to the present invention. FIG. 1 diagrammatically shows a device 10, according to the present invention, for producing energy from the driving force of the wind. As indicated previously, this device 10 comprises at least two wind turbine modules 200, 300 rotatably mounted in opposite directions, around a common vertical axis OO formed for example of a fixed mast 100. According to the arbitrary direction illustrated on FIG. Figure 1, the module 200 rotates in the trigonometric direction while the module 300 rotates clockwise. The number of superimposed modules may be greater than 2. As illustrated in FIG. 2, an even number of superposed identical wind turbine modules 200, 300, in particular having identical diameters and height, is preferably provided. and rotatably mounted alternately in opposite directions about a common vertical axis OO. However, the invention is not limited to this particular provision. Indeed, in the context of the present invention, the number of superimposed modules 200, 300 can be even or odd. The modules 200, 300 rotating in opposite directions may have the same or different diameters and / or identical or different heights and / or different blade structures or dimensions. Furthermore each module 200, 300 may have an identical diameter over its entire height as shown in Figures 1 and 2 or a variable diameter over the height, for example generally frustoconical as shown in Figure 3 for the modules 300a and 200a. Preferably, the number of these modules 200, 300, as well as their diameter and height, are adapted so that the moment of the torques of forces applied to the support structure providing rotational guidance, for example the support mast 100, by the all of the modules 200 rotating in a given direction is equal in absolute value and therefore compensated for, by the moment of the pairs of opposing forces applied on the same support structure 100, by all the modules 300 rotating in the opposite direction.

  Thus, thanks to this arrangement, whatever the speed of the wind and / or the accelerations caused by the squalls, the moments of the pairs of forces applied to the support structure 100 cancel each other out. Therefore, even if the support structure 100 would experience a deflection under the effect of the horizontal force component resulting from the force applied by the wind on all the wind turbine modules, this support structure 100 is no longer subjected to torsion torque invention and avoids any risk of gyroscopic effect encountered on conventional wind turbines vertical axis. Therefore, it is sufficient to size the support structures 100 of the wind turbines according to the present invention to resist the above-mentioned bending. According to the present invention, it is no longer necessary to dimension the support structure 100 to resist a gyroscopic effect. The present invention therefore makes it possible to use support structures 100 having a diameter that is comparatively smaller than the known structures of the state of the art. The present invention also makes it possible to simplify the manufacturing processes, on-site transport, installation and maintenance accordingly. By way of nonlimiting example, FIG. 3 shows an alternative embodiment according to the present invention comprising 4 superposed wind turbine modules 300a, 200a, 300b and 200b rotating alternately in opposite directions, all having diameters and / or or different heights, but dimensionally adapted to apply a resulting torque of zero rotation on the vertical support pole 100. The wind turbine modules 200 and 300 can in themselves be subject to many embodiments. They will not be described in detail later. Each wind turbine module comprises a rotor, such as the rotors referenced 210 and 310 in FIGS. 4, 5, 7a and 7b, composed of a series of at least generally vertical blades 240, 340 distributed angularly about the axis 30 0-0 and extending in a generally radial direction relative to this 0-O axis.

  Different means may be provided for imposing opposing rotational directions on the rotors comprising the wind turbine modules 200 and 300 respectively. We will now describe some non-limiting of these means.

  FIGS. 4a and 4b show diagrammatically a variant embodiment according to which the blades 240, 340 are not plane but curved (for example formed of rectilinear vertical generatrices and of curved horizontal generatrices or of curved vertical generatrices and generatrices rectilinear horizontal), all the blades 240, 340 of the same rotor having their concavity turned in the same peripheral direction, but the direction of the concavity of said blades being inverted from one rotor to another. FIGS. 5a and 5b show another variant embodiment in which all the blades 240, 340 are flat, vertical and radial with respect to the axis OO, and these blades 240, 340 are associated with an asymmetrical screen 242, 342 relative to the axis OO and covering for example alternately the left or right half of a wind turbine module. It should be noted that in this case it is necessary to provide means ensuring an automatic radial orientation of the screen 242, 342 with respect to the direction V of wind incidence.

  FIGS. 6, 7a, 7b and 8 show a preferred embodiment of a wind turbine according to the present invention, in which each rotor 210, 310 composed of a series of vertical blades 240, 340 radial relative to each other. to the axis OO is associated with a respective radially external directional stator 220, 320. The directional stators 220, 320 are designed to direct the flow V of the wind, arriving with identical incidence for all the wind turbine modules 200, 300 , in respective directions inclined in opposite directions, on the blades 240, 340 of the rotors 210, 310. The stators 220 and 320 may also be the subject of many embodiments.

  According to the preferred embodiment illustrated in FIGS. 6 to 8, each stator 220, 320 comprises a series of vertical directional fins 250, 350 regularly distributed in a ring around the axis OO, on the outside of the rotors 210, 310 The directional vanes 250, 350 define driving ducts 252, 352 which channel and direct the flow V of the wind towards each blade 240, 340 of the associated rotors 210, 310. For the same stator 220 or 320, the fins 250, 350 all have the same inclination relative to radial planes erected from the axis O-O.

  However the inclination of these fins 250, 350 relative to the aforementioned radial planes is reversed for the two stators 220, 320. Thus, as seen in Figures 7a and 7b, the directional vanes 250 of the stator 220 are inclined in the direction when they are scanned radially outwards and vice versa, the directional wings 350 of the stator 320 are inclined in the counterclockwise direction when they are traversed radially outwards. The directional fins 250 and 350 may have a fixed inclination. However, preferably the fins 250 and 350 are adjustable in peripheral inclination, for example depending on the wind speed, in order to optimize the efficiency of the system. Many tilt adjustment means can be provided for this purpose. By way of nonlimiting example, one of the ends of the fins 250, 350, for example the radially inner vertical end, can be articulated between two horizontal separation trays, for example a lower separation tray 260 and a tray upper separation member 262 for the stator 220 and the lower separation tray 262 and an upper separation tray 264 for the stator 320, while the other end of the fins 250, 350, for example the radially outer vertical end, may be associated with an orientation ring 270, 370. For this purpose for example the radially outer end of the fins 250, 350 may be provided with a projecting lug, or any equivalent means, engaged in a groove (which can be the object of many embodiments, for example radial or inclined on a radius, rectilinear or curved for example helically) formed on said orientation ring 270, 370. The man of the It will be understood that a controlled rotation of the orientation rings 270, 370 with respect to the plates 260, 262 and 264 and the axis O-O makes it possible to modify the inclination of said directional fins 250, 350.

  These fins 250, 350 are thus adjustable to enable the speed of rotation of the rotors 210, 310 to be regulated as a function of the wind speed, by varying their angle of attack on the blades 240, 340 of the rotors 210, 310. number of blades 240, 340 composing each rotor 210, 310, as well as their particular dimensions (height and radial extension) and particular geometry (possibility of curvature), are adapted to optimize the operation of the system, in particular according to the diameter of the rotor 210, 310. The central mast 100 which supports the device 10 may also be the subject of many embodiments. It may contain technical means such as scale or elevator type means for easy access to each stage of the wind turbine modules 200, 300 for the maintenance of the latter. The mast 100 may also carry radially external technical compartments referenced 230 and 330 in FIGS. 7a and 7b. These compartments 230, 330 are delimited by radial partitions 232, 332. Such technical compartments 230 and 330 may for example accommodate means for energy conversion and / or energy accumulation. In this case, the rotors 210 and 310 are rotatably mounted on the outside of the technical compartments 230 and 330. In a variant, the aforementioned technical compartments 230 and 330 can be secured to the rotors 210 and 310. In this case, they are the technical compartments. 230 and 330 which ensure the rotational guidance of the rotating structure around the central mast 100. Moreover in this case the technical compartments 230 and 330, and the elements they house, participate in the definition of the rotary structure and therefore the definition of the inertia of this structure and the stability of the speed of rotation, including in case of fluctuation of the wind speed. Of course, if the energy accumulator means are housed in the rotary technical compartments 230, 330, it is necessary to provide means for transmitting the energy between the rotary structure and the fixed central structure, for example if these are means for accumulating electrical energy, contact transmission means, for example based on rubbing brushes on tracks, or contactless transmission means, for example based on an electromagnetic wave or by means of coupling. capacitive or inductive. Moreover, each of the blades 240, 340 of the rotors 210, 310 and / or each of the blades 250, 350 of the directional stators 220, 320 may be covered with a coating, for example a lint, for example silicone, in order to reduce the noise pollution of the wind turbine modules 200, 300. Such fluff are for example formed of long velvet lying down in the wind direction. The wind turbine modules 200, 300 are associated with energy conversion means. These can be the subject of many embodiments. It is preferably a means for converting mechanical energy into electrical energy, for example based on alternators or equivalents whose rotors are connected to the rotors 210, 310 and whose stators are connected to the fixed mast 100 or an element linked to it. However, the invention is not limited to this particular arrangement and includes any other suitable energy conversion means, such as for example a mechanical / mechanical conversion means. Furthermore, a power conversion means, for example an alternator, associated respectively with each wind turbine module 200, 300 may be provided. However, preferably in the context of the present invention, a conversion means of energy common to several wind turbine modules 200 and 300, or even a single energy conversion means common to all of the wind turbine modules 200 and 300, for example the lower module, subject to mechanically coupling the groups of modules wind turbines associated with a common energy conversion means. The mechanical coupling means 400 may also be the subject of many embodiments. These mechanical coupling means 400 between two adjacent wind turbine modules 200, 300 are intended to add the movements of each of the adjacent wind turbine modules 200, 300 in order to accumulate the power produced by each of them. According to the non-limiting illustration given in the attached FIG. 8, such mechanical coupling means 400 are formed of toothed gears or rollers 410 with chevrons or any equivalent means, interposed between two adjacent counter-rotating wind turbine modules 200, 300 and in engagement with toothed tracks or integral annular racks of said wind turbine modules 200, 300. These pinions 410 may be independent of the mast 100 provided that they are held radially by the aforementioned racks formed on the modules 200, 300. variant be mounted free to rotate on shafts 420 connected to the fixed mast 100 and extending perpendicularly to the vertical axis of rotation OO. Each of these shafts 420 can connect the mast 100 to the radially inner periphery of the separating plates 260, 262 and 264 and thus serve as a support for these trays. In a variant, the shafts 420 and the associated pinions 410 may be placed in lobed cutouts formed on the inner periphery of the separating plates 260, 262 and 264, these being connected directly to the mast 100. The mechanical coupling means 400 between two adjacent wind turbine modules 200, 300 are not limited to those described above in connection with the illustrated figures but may be replaced by any suitable means. Thus one can provide mechanical coupling means 400 adapted to ensure a variable gear ratio between two adjacent wind turbine modules 200, 300 to ensure identical rotational speeds to these modules including in the case where they receive the variable efforts. Such mechanical coupling means with variable gear ratio, for example based on bevel gears or the like, can be controlled electronically by a rotation speed sensor of the rotors 210, 310, or mechanically if, for example, the pinions comprising the mechanical coupling means 400 are sensitive to the centrifugal force of the rotors 210, 310. Preferably, the outer periphery of the discs forming the plates 260, 262 and 264 is bevelled in order to concentrate the flow of wind V on the wind turbine modules 30 200, 300. Furthermore, according to an alternative embodiment of the present invention the trays 260, 262 and 264 can be fixed on external fixing means suitable for ensuring the rigidity of the entire power generation device 10 An alternative embodiment of the present invention also proposes complementary means adapted to preserve fauna, in particular birds, by prohibiting the latter from penetrating the rotors 210, 310. Such protection means may comprise ultrasonic means known in themselves adapted to move the birds, or nets with appropriate mesh and fine wire or equivalent means covering the power generation device 10. If necessary, these means can be supplemented by perches provided on the top of the device and encouraging the birds to access this summit rather than attempting to enter the rotors 210, 310. In accordance with the invention, the power generation device 10, n mechanically coupled wind turbine modules are thus stackable one above the other along the axis of rotation OO, n being an integer preferably even or even odd, the rotors of two adjacent wind turbine modules being counter-rotating. When the wind is blowing, it is directed by means of the directional vanes 250, 350 of the stators 220, 320 of the wind turbine modules 200, 300 towards the blades 240, 340 of the associated rotors 210, 310 and cause them to rotate around the rotor. vertical axis OO of the mat 100. Thanks to the invention, the moments of the forces applied by the rotors offsetting each other, the gyroscopic effect of the wind turbine modules which tends to twist the mat 100 disappears, which makes it possible to obtain a 10. The cancellation of the gyroscopic effect, thanks to the present invention, also makes it possible to produce wind turbine modules with a very large diameter and thus delivering very high power, which was previously inconceivable according to the state of the art. The superposition of several wind turbine modules with the rotors of the adjacent modules rotating in the opposite direction also makes it possible, thanks to the mechanical coupling means, to increase the power collected by the power generation device 10 while limiting the dimensions. of the latter and without risk of embrittlement of the structure by a gyroscopic effect. A power generation device 10 according to the present invention can find many applications, for example and not limited to the small apparatus placed on the roof of a house of an individual comprising some wind turbine modules, to the apparatuses. used industrially, for example in the mountains, at the seaside, or on rocks at sea, with a much larger number of wind turbine modules.

  Of course, the present invention is not limited to the particular embodiments which have just been described but extends to any variant within its spirit. In particular, the present invention is not limited to the embodiments illustrated in the accompanying drawings. If necessary, it is possible to provide means making it possible, by disengaging the rotors 210 and 310 with respect to the energy conversion means, to freely rotate the wind turbine modules 200 and 300 around the support mast 100, in large numbers. wind to prevent damage to the system. In a variant, it is possible to provide controlled shutters for the channels 252, 352.

  The invention may also be associated with any energy storage means during the off-peak hours of consumption, for example based on electric accumulators. According to a particular embodiment, these energy storage means comprise means proceeding by compression of gas during off-peak hours of consumption and able to restore the energy thus accumulated during hours of heavy consumption. Such means proceeding by compression of gas can release the pressurized gases, possibly heated to an optimum temperature by means of energy accumulation means then working by Joule effect, on appropriate turbines, or even directly on the rotors 210, 310. It suffices for this to provide pipes connecting the pressurized gas storage means (for example located in the technical compartments 230, 330) and nozzles placed opposite the rotors 210, 310.

  The top of the device according to the present invention can be terraced, and the device can be equipped with any suitable means adapted to ensure the flow of water, for example in the central mast 100 or in amounts that support the separations 260 , 262 and 264. Embodiments have already been described in which the rotors 210, 310 are rotatably guided by the central mast 100. In a variant, rotational guidance of the rotors 210, 310 can be provided by the external component structure the directional stators 220, 320. In this case, it is also possible to eliminate the separation plates 260, 262 and 264 between the wind turbine modules 200, 300 by directly stacking the modules 200 and 300 together. on others. The wind turbine modules 200 and 300 then rest directly on each other, via the interposed mechanical coupling means 400.

  Those skilled in the art will understand that the device according to the present invention offers many advantages over devices known from the state of the art. In particular, the present invention makes it possible to deliver large electrical powers over a relatively small area. The present invention also allows a wide variety as to the size of the height and / or width or diameter of the wind turbine and therefore a large capacity for integration in all types of sites and respect for the environment. Moreover, compared with horizontal axis wind turbines, the present invention does not require means for orienting the wind turbine as a function of the direction of wind incidence.

Claims (14)

  A power generation device (10) comprising at least two superimposed wind turbine modules (200, 300) each comprising a rotor (210, 310) rotatably mounted about a common vertical axis (OO), characterized in that the rotors (210, 310) of two adjacent wind turbine modules (200, 300) are counter-rotating.   2. Device according to the preceding claim, characterized in that it comprises a set of n superimposed wind turbine modules, n being an even integer, the rotors (210, 310) of two wind turbine modules (200, 300) adjacent being counter-rotating.   3. Device according to one of claims 1 or 2, characterized in that the number and the structure of the wind turbine modules (200, 300) are adapted so that the moments of the forces applied by the modules (200, 300) rotating respectively in opposite directions, compensate each other.   4. Device according to one of the preceding claims, characterized in that at least one wind turbine module (200, 300) comprises a stator (220, 320) surrounding its respective rotor (210, 310) and having a series of vertical directional fins (250, 350) whose orientation is adapted to rotate the associated rotor (210, 310) in the appropriate direction.   5. Device according to claim 4, characterized in that it comprises means (270, 370) for adjusting the orientation of the directional fins (250, 350).   6. Device according to one of claims 1 to 5, characterized in that it comprises a power conversion means associated with each wind turbine module (200, 300) .30   7. Device according to one of claims 1 to 5, characterized in that it comprises a power conversion means associated with a group of wind turbine modules (200, 300).   8. Device according to one of claims 1 to 5 and 7, characterized in that it comprises a single energy conversion means associated with all of the wind turbine modules (200, 300).   9. Device according to one of the preceding claims, characterized in that it further comprises mechanical coupling means (400) between two adjacent wind turbine modules (200, 300).   10. Device according to the preceding claim, characterized in that the mechanical coupling means (400) comprise a set of pinions (410).   11. Device according to one of claims 9 or 10, characterized in that the mechanical coupling means (400) define a variable gear ratio according to the wind speed.   12. Device according to one of claims 1 to 11, characterized in that it comprises technical compartments (230, 330) secured to the rotors (210, 310). 25   13. Device according to one of claims 1 to 12, characterized in that it further comprises energy accumulation means based on compressed air.   14. Device according to one of claims 1 to 13, characterized in that it comprises means for disengaging the rotors (210, 310) of the wind turbine modules and to put these in freewheel, by large vent.20