FR2507696A1 - Wind turbine with deformable inflated blades - uses plastics envelopes filled with helium as blades of turbine and has inflation pressure control - Google Patents

Abstract

The wind turbine is formed from a rotor assembly mounted at the top of a tower. The rotor has multiple blades and its shaft is coupled to a machine which consumes the converted wind energy. The blades (13) radiate from the horizontal shaft (12) and are formed from envelopes of a supple or deformable material inflated to a pressure greater than that of the external air. The preferred inflating medium is a gas, for example helium, and the preferred blade material is plastic, which is welded to form a sealed envelope fitting over rigid shaping elements. The blades deform under increasing wind force and thus reduce the generated torque to prevent overspeed damage.

Description

 The present invention relates to an improvement with fluid motors of the type having a plurality of blades mounted to rotate about an axis of rotation under the action of a fluid, in particular a gaseous fluid such as air. In particular, the invention relates to an improvement in wind turbines but the invention is also applicable to other motive machines with gaseous fluid or possibly liquid.

 The development of wind turbines as an energy source has encountered a number of difficulties which, so far, have not been completely overcome. One of these difficulties resides in the considerable variations in the wind speed, and therefore in the energy available, the range going from zero to very high values in the case of strong winds. wind speeds, currently known wind turbines are not set in motion so that they provide no energy at these low speeds, which is obviously detrimental since the winds are maintained at a low or very low speed for a proportion of very important time.

On the other hand, wind turbines have a relatively high cost price, which, if we consider the importance of periods of low or very low wind, makes them all the less interesting. Finally, in strong winds, the blades are made to rotate at extremely high speeds, which often causes them to rupture and consequently the destruction of a significant part of the wind turbine without taking into account the significant risks of accidents due to the projection of the parts thus torn off. In an attempt to avoid these drawbacks, it is then necessary to oversize the blades or to provide expensive means of immobilization or protection in the event of strong wind
The present invention proposes to remedy these various drawbacks and to improve the fluid power machines, in particular wind turbines, so as to lower their cost price, to make them efficient even in the event of very low fluid energy and to avoid the risk of accidents or to limit the consequences thereof. In addition, the invention proposes to provide such machines in which an adaptation of the conformation of the wind turbine to the force of the wind can be made if necessary, thereby increasing the efficiency at various rotation speeds and minimizing the risks. of destruction.

 The subject of the invention is an improvement to fluid power machines, in particular wind turbines, comprising, on a structure, a rotor provided with a plurality of blades, said rotor being connected or reliable to a consuming machine such as for example a pump. or an electric current generator, characterized in that the blades consist of flexible or deformable envelopes inflated with the aid of a fluid at a pressure higher than the pressure of the surrounding fluid.

 The fluid used to inflate the blades is advantageously a light fluid such as a gas. Thus in the case of a wind turbine, the fluid can advantageously be helium but other gaseous fluids can be used such as air, nitrogen or the like.

 The envelope of a blade of a machine according to the invention is preferably made of a relatively flexible plastic material. This envelope has, in the inflated state, a shape of a blade, the length, width and thickness of which are determined as a function of the flow characteristics of the working fluid, for example the wind.

 If necessary, stiffening elements, either coming in one piece with the envelope, or added, can be provided.

 The thickness of the envelope, its flexibility, the stiffening means and the value of the internal overpressure can be advantageously chosen either to form relatively non-deformable blades, for example by using a significant overpressure, or on the contrary to form blades capable of deform when the force to which they are subjected increases. Thus we can in particular provide wind turbine blades which, when the wind is weak or no, form a significant angle with the direction of the wind and which, when the wind becomes more important, gradually tend to fade to decrease this angle so as to gradually decrease the apparent surface so as to maintain a good performance at different wind speeds or forces while reducing the stress to which they are subjected in the event of strong winds.

 In another variant, means can be provided, housed in the rotor or connected to it, to modify the value of the internal overpressure as a function either of the determinate wind speed thanks to a suitable sensor, or of the speed of rotation determined using a speed sensor. These means may for example include in particular a variable pressure switch.

The rotor of the device according to the invention may comprise either a central rotor of the hub type to which the blades extend, or a tubular peripheral rotor to which the peripheral ends of the blades are connected, or both, the blades then being fixed at their two central and peripheral ends
As a variant, a central rotor can be provided with, at the periphery of the blades, simple means making it possible to connect them together, for example cables.

Other advantages and characteristics of the invention will appear on reading the following description, given by way of nonlimiting example and referring to the appended drawings.
The figure. 1 shows a schematic view of a machine rotor in a first embodiment of the invention.

 Figure 2 shows a front view of this rotor.

 FIG. 3 represents a schematic view on an enlarged scale of a blade of this rotor.

 Figure 4 shows a top view of this blade.

of the invention.

 FIG. 6 represents a front view of the rotor of FIG. 5.

Figure 5 shows a schematic view
partial realization of a rotor in another form of / of the invention.

 FIG. 7 represents a partial schematic perspective view of a rotor according to another embodiment of the invention.

 FIG. 8 represents a view of a blade according to another embodiment of the invention.

 We first refer to Figures I to 4.

 The wind turbine shown has a rotor shown schematically and designated by 1. This rotor, of the hub type, has a rounded end or in a warhead 2 on the wind side and comprises all the usual means for being rotatably mounted on a wind turbine structure and to be able to drive an electric generator.

 This rotor has three blades, 3 having a generally elongated rectangular shape.

 With particular reference to FIGS. 3 and 4, it can be seen that the plain blade 3 consists of a relatively flexible plastic envelope, obtained from a sheet of plastic material suitably folded back on itself at the edge. anterior attack 4 of the blade. The other three edges, namely the upper edge 5, the posterior edge 6- or trailing edge and the lower edge 7, are welded on a continuous line so as to determine an envelope having a sealed interior volume 8 capable of communicating with the 'exterior by a suitably attached tubing 9. The lower edge 7, obtained by superposition of the folded edges of the sheet, has a width significantly greater than that of the edges 5 and 6 and continues for example with a plurality of orifices 10 allowing the attachment of the payroll to the rotor 1. Advantageously, the lower end of the blade enters a suitable slot in the rotor 1 up to a level shown in broken lines 11 in FIG. 3.

 The blade can either be inflated in advance using for example helium, after which the passage 9 is sealed or closed using a suitable stopper or valve. The overpressure depends on the desired effect and can, for example, range between 0.2 and 1.5 atmospheres.

When the blade 3 is inflated, it takes the most visible configuration in FIG. 4 which shows that it has at this time a certain thickness. In addition, the overpressure prevailing inside gives the blade a relatively rigid determined shape.

 When the blade is mounted on the rotor 1, its lower part enters the slot of the rotor, the edges of the slot coming into contact with the blade at the level of line II so that an inflated portion of the blade is located at inside the rotor. As a result, the blade retains its radial position in the rotor both at rest and when the blade is subjected to the thrust of the wind.

 The plastic material used can be any suitable plastic material, but, as a variant, the blade can also be made of an elastic material such as rubber or an elastomer.

 The thickness of the material forming the blade can be variable depending on the dimensions of the blade, the forces to which it will be subjected on the part of the wind, the desired internal overpressure and the greater or lesser deformability of the blade to the inflated state that we are looking for. The thickness can possibly vary according to different zones of blades.

 By way of example of plastic material used, mention may be made of nylon and polyesters, but other usual plastic materials can also be used.

The thickness of the plastic material can, in practice, either be very thin, for example in the case of a blade made practically in the form of a beam
some druche, either go up to / millimeters or more.

It will be understood that a rotor has thus been produced which has a very great lightness and a particularly low inertia. This rotor can therefore be driven by the wind even when the wind speed is extremely low and therefore be used to produce energy with a low delivered power but for long periods of time. him
Furthermore, the lightness of the blade / makes it possible to properly resist centrifugal force in the event of rotation at very high speed in very strong winds. In addition, the vibrations usually present when the blade rotates at a high speed are damped or completely absent in the case of a rotor according to the invention.

 If, in addition, the force of the wind is such that the blade can tear, its projection will create practically no damage due to its nature.

 We now refer to Figures 5 and 6.

 In this embodiment, there is shown a rotor 12 provided with blades 13 in the shape of a petal. We see in Figure 5 that these blades occupy the entire surface offered to the wind. Such a wind turbine is particularly suitable for wind at low and very low speed for les guelselle has a high efficiency.

 The blades 13 can be made in the manner of blades 3.

 As a variant, the blades 13, as well as the blades 3 or the other blades according to the invention, can no longer be produced by folding back, or superposition of plies and peripheral welds, but on the contrary in one piece, for example by injection. blowing or extrusion and blowing, the blowing taking place at the material deformation temperature in a mold whose imprint has the desired shape of a blade. Such a process allows manufacturing in very large quantities at a particularly low cost price of the blades.

 The invention can, of course, be the subject of a large number of variants.

 Thus in Figure 7, there is partially shown a rotor part. This comprises two metal hoops of small diameter 14 coaxial, arranged one behind the other, and two hoops of large diameter 15, concentric with the hoops 14. The hoops 14 can be connected to the hoops 15 by radial bars, just as the hoops 14 and 15 can be connected to each other by bars in the manner of a squirrel cage.

 In the rotor thus constructed, which has a particular lightness, it is possible to mount blades made up of envelopes in the form of inflated cushions, these blades being able to have a helical or other suitable shape by judiciously arranging the pointed points 18, 19 of the pale on the respective hoops. Of course, blades could be attached to other rotor structures in this way. So instead of using hoops 15, one could use a peripheral cylindrical ring doing the same job. Likewise, the small diameter hoops 14 can be replaced by another type of rotor hub.

Referring to Figure 8, there is shown an envelope forming a blade 20, having a generally rectangular shape, suitably inflated. This envelope is held by a front lateral extension, by a section 21 forming the leading edge, this section having for example on the rear side a fork-shaped opening in which the front edge of the blade 20 fits.
which, therefore, / can practically not move relative to the profile 21. The profile 21 is fixed to a rotor by its projecting end 22.

 It is also possible to provide, in order to increase the rigidity of a blade, instead of an exterior profile, interior profiles or stiffening blades arranged in any suitable manner outside, inside or in the material itself. even from the envelope.

 In wind turbines intended to rotate at high speed, in which the gaseous fluid contained inside the blade and ensuring the overpressure can be driven out by centrifugal effect, provision may be made to make the blades in the form of several superimposed envelopes or an envelope with a number of independent internal compartments, each pressurized. Similarly, in these cases, it is possible to provide greater stiffening towards the centripetal part of the blade.

 Although the invention has been described with regard to particular embodiments, it is understood that it is in no way limited thereto and that it can be made various modifications of shape or material without departing from it. neither of its frame, nor of its spirit.

Claims (10)

 1. Improvement of fluid power machines, in particular wind turbines, comprising, on a structure, a rotor provided with a plurality of blades, said rotor being connected or connectable to a consuming machine, characterized in that the blades (3, 13 , 16, 20) consist of flexible or deformable envelopes inflated with the aid of a fluid at a pressure higher than the pressure of the working fluid.  2. Improvement according to claim 1, characterized in cd that the blade is inflated by a gas, in particular helium.  3. Improvement according to one of claims 1 and 2n characterized in that the blade comprises an envelope made of a relatively flexible plastic.  4. Improvement according to one of claims 1 and 2, characterized in that the blade comprises an envelope made of an elastic material.  5. Improvement according to one of claims 3 and 4, characterized in that the envelope is closed, on its periphery, by a welding line on its edge (5, 6, 7).  6. Improvement according to one of the reve cations 3 and 4, characterized in that the envelope is obtained by injection or blow molding.  7. Improvement according to any one of claims 1 to 6, characterized in that the blade (20) comprises stiffening elements (21)  8. Improvement according to any one of claims 1 to 7, characterized in that, in the inflated state, the blade is susceptible to deform with increasing speed of the working fluid to decrease the angle it done with the direction of this fluid.  9. Improvement according to any one of claims 1 to 8, characterized in that the rotor (1, 12) comprises means for modifying the overpressure of the blade.  10. Improvement according to any one of claims 1 to 9, characterized in that the blade is made in the form of several envelopes or an envelope having several independent internal compartments to oppose the centrifugation of the fluid under pressure.