FR3079884A1 - WIND TURBINE CONSTRUCTED FROM TWO HORIZONTAL AXLE WIND TURBINES COMPRISING A MOBILE SAILING SYSTEM - Google Patents

Abstract

The present invention relates to a wind turbine (1) built by two horizontal axis wind turbines comprising a movable and adjustable sails system (2) fixed to the ground by a fixed mat (4). Each of the two wind turbines comprising four sails (2) symmetrical and identical. The wind turbine (1), at one instant 'T', is found with two sails (2) in the upper position where the entire surface of the sails (2) is facing the wind, giving maximum energy, and with two sails (2 ) in the low position which will be contrary to the wind but with the minimum wind catch of the two sails (2). For the wind turbine to always face the wind, it has a tail (3).

Description

The present invention relates to a wind turbine built by two wind turbines with a horizontal axis comprising a movable sail system.

Depending on the altitude the wind does not blow at the same speed, when you rise the wind increases.

For the majority of wind turbines which are horizontal, the lower blades brake the upper blades which causes stresses, whistles.

The present invention aims to solve all or part of the drawbacks mentioned above. To this end, the present invention relates to a wind turbine comprising a system of orientable sails which at the instant 'T' is left with two sails in the high position where the entire surface of the sails is facing the wind, gives maximum energy and a position low which will be against the wind but with the minimum wind resistance of the two sails.

The other four sails are in horizontal but oriented intermediate positions.

So we have two wind turbines El and E2 of four sails each, they are strictly symmetrical and rigidly linked by a tree which passes through their center. The eight sails are identical. It is the width of a sail that determines the minimum distance of the two wind turbines El and E2.

When the assembly makes a half-turn, the sails make a relative quarter-turn. When the whole makes a turn the sails return to the starting position and have passed four times through the position of the instant 'Τ ’.

The quarter-rotation movement of the sails merges into the overall movement.

The mast of each sail is centered which removes any rotation constraint, in theory because in practice turbulence is to be expected.

The system I have developed enables solid and controlled sail movement guidance.

The sails are not independent, they are linked two by two in opposite rigidly with an angle of 90 degrees. Below each sail we have an arm bent not in alignment with it but with 15 degrees of offset in the direction of movement. At the end of the arm a roulette wheel whose axis passes through a point. This point is the intersection of the axes of the two sets of sails that we have on each wind turbine El and E2. This wheel is not cylindrical but conical, the shape is not important. It rolls on a set surface, the contact area is a straight line, the orthogonal projection of this straight line on the axis gives the thickness of the wheel. This set area is established for this wheel, this arm, this altitude, etc. .What I call ruled surface is a cubic block with on one side, a passage strip with this shape, in the center a large cylindrical opening giving way to a bearing of the main axis.

On each mast of sails we have opposite and at 90 degrees two sails, two arms, two casters. The mast is blocked in translation, in abutment on two bearings but free in rotation with two degrees of freedom, a roller resting on a surface removes a degree, the wheel opposite 90dg removes the second degree. Movement is blocked.

To use this set surface, we must have the same parameters on each sail mast, however the masts intersect, I used a sleeve drilled on one of the two masts. This piece is found at the intersection of the two masts, on El and on E2. We no longer have a single mast but two small ones connected by this hub .11 is crossed by the other mast. This allows a movement of 91 degrees , that's enough, it takes 90 degrees.

When we have gusts or strong wind the existing wind turbines stop before their blades bend and touch the mast.

If the sails of my windmill sag, they don't touch the mast.

On conventional wind turbines the mast is cylindrical with a small diameter by obligation, it must orient itself facing the wind, be able to turn around the mast.

My wind turbine will be able to turn around the mast but with a cylinder of maximum size corresponding to the space left by the sail in the low position of El and E2. I imagine that by increasing the distance between the El and E2 wind turbines you can install my invention on a cylindrical building (a windmill).

In the event of gusts, a rapid reaction is required, my spring system allows an immediate response. Each sail is made up of two panels articulated around the mast, the two panels are held in a flat position by two springs. Depending on the force recorded, the two panels fold around the axis and offer less wind resistance. At each gust the sails fold back when they are in the high position but when they are in the low position the force is zero and therefore they return to their flat position. Fortunately they straighten up because they would have hit the main mast. The system is simple, flexible and very responsive. The axis of the main mast is between El and E2, and on the main axis which connects the two wind turbines. The assembly is free to rotate thanks to a bearing of tapered bearings and three adjustable rollers. The mast is fixed to the ground, with 3 reinforcements at 120 degrees around the base which respect the space cylinder.

My wind turbine must always be facing the wind, to do so, I used the tail system. The tail is high to find itself above the sails and thus avoid turbulence, it has a respectable surface and it is found far from the mast to increase the lever arm.

This wind turbine is built to generate current from an alternator. It will be screwed on a cradle welded on the mat. The energy transmission will be by chain pinion. A pinion on the main axis which connects El and E2 with a small pinion on the axis of the alternator, a reduction is mandatory. Before locking the alternator on the subframe, it will be possible to tension the chain.

In any case, the invention will be clearly understood with the aid of the description which follows, with reference to the appended schematic drawings showing, by way of nonlimiting example, an embodiment of this wind turbine.

Figure 1 is a perspective view of a wind turbine comprising a system with two symmetrical wind turbines, the folding sails are in the deployed position.

Figure 2 is a view of the wind turbine, whose foldable sails are in the folded position.

Figure 3 is a view of the wind turbine, in an intermediate position at 45 dg.

Figure 4 is a view of the wind turbine, facing the wind, with maximum wind resistance.

Figure 5 is a detailed view of the rollers on the adjusted surface.

Figure 6 is an isolated view of the axis of the sails.

Figure 7 is an isolated view of the axis of the sails but with a hollowed out hub.

Figure 8 is an isolated view of the intersection of the two axes of sails.

Figure 9 is an isolated view of a sail in the deployed position.

Figure 10 is an isolated view of a sail in the folded position.

Figure 11 is an isolated view of the tray with the outputs of the sail axes.

Figure 12 is an isolated view of the alternator area.

Figure 13 is an isolated view of the 'fixed mast' and 'mobile mast' area with the tail attachment.

Figure 14 is an isolated view of the tail.

Figure 15 is an isolated view of the energy transmission.

Figure 16 is a variant of my invention, on a windmill.

Figure 17 is a variant of my invention, wind turbine of the future.

As illustrated in Figure 1, a wind turbine 1 in isoparametric view comprises a plurality of sails 2. The assembly is oriented by a tail 3 secured to the movable mast, the fixed mast 4 is fixed to the ground.

Figure 2 shows the same view in Figure 1 but with a gust of wind, the plurality of sails 2 with 2 folded sails, the reaction is immediate.

Figure 3 shows the wind turbine 1 in side view, in the intermediate position. The sail area that we have with this side view, gives us the sail surface that we have in front of the wind.

FIG. 4 represents the wind turbine 1 in front view to the wind, on the plurality of sails 2, only two sails operate but at maximum thrust. With a wind of 3 m / s, but without driving anything, the wind turbine rotates.

Figure 5 is an isolated view, it explains the controlled movement of the sails 2, a simultaneous rotation of + 90dg to -90dg of each sail on a turn of the wind turbine.

This movement is controlled in all positions. The originality of this system is due to the definition of the set surface. There is a theoretical point, the intersection of the axes of sails 6 and 7 with in addition the main axis of the wind turbine 10 positioned by 2 bearings "hat" 12. The axis of the pluralities of the rollers 8 pass through this theoretical point. The elements, the plurality of the arms 11 of the rollers 8 are all at the same distance from the axis 10. For 2 degrees of rotation of the wind turbine we have 1 degrees of rotation of the axes of the sails (from 0 to 90 degrees and 90 to 0 degrees). The set area results from all these parameters. Using the smoothing formulas we get a regular movement of the sails.

Figure 6 is an isolated view of a sail axis 7 connecting two sails 2. They face each other at 90 degrees. Each sail is associated with a bent arm and its caster. The 15degree angle that is put between each veil and its arm can be one way or another. The caster is pushing on the set surface or pulling. It is of course an action which is on El and its symmetric E2. By pushing we tend to trap the wind when the sails go to the next level. This increases the efficiency of the wind turbine.

Figure 7 is an isolated view of a sail axis 6 also connecting the two sails 2. Figure 7 resembles Figure 6 with the element 13 in addition. This element which is a hollowed out sleeve, is essential to all my creation. I had as an obligation to build my set area to have a point, the intersection of the axes of sails 6 and 7. The two axes must be on the same plane so that they intersect.

Figure 8 is an isolated view, with elements made invisible to make the area of interest visible. The hollowed-out sleeve 13 forming part of the sail axis 6, is crossed by the sail axis 7.The axes here have a 020. The sail axis 6 has a clearance of 90 degrees, the sleeve will be manufactured with a clearance 91 degrees. We have on the view of this figure the plurality of bearings' hat'14 which must ensure the alignments and the positions of the sail axes 6 and 7. The plurality of locking rings supported on the bearings 14 will guarantee the translation adjustments of the different axes of sail.

FIG. 9 is an isolated view of a plurality of sails 2, they are all 8 identical and stitched on the veil axes 6 and 7.

Each sail here consists of two leaves 17 and 18 which are articulated around a tube 030 exter .. It is an equipped nut which by being tightened on the tube 030 gives the orientation to the sail 2. The plurality of springs 20, the inside 0 of which will be adjusted to the outside 0 of the tube. These springs 20 will press the two leaves 17 and 18 on the nuts fitted. Fine adjustment can be made using the 2 M8 screws at the end of the fitted nuts.

The leaves 17 and 18 will be mechanically welded frames with 30/30 square tubes and on one side two knobs also welded, to allow rotation around the sail axis 21. The frame will be covered with aluminum sheet thick. 0.8 which will be riveted to the frame by 'pop rivets'. In the knobs we will adjust polymer bearings with a collar.

Figure 10 is figure 9 with a gust of wind. Only the two springs are tightened by the thrust of the wind on the leaves 17 and 18. The point of balance will be a given to define according to the spring and the thrust of the wind, We can increase decrease the resistance of each spring by modifying the number of turns their section, if necessary add some.

Figure 11 is Figure 8 but without elements made invisible. The connection of the axis 10 (see Figure 5) with the plate 15 must also allow the crossing of the sails axes 6 and 7. I used a steel hub 22 centered on the 'cap' bearing 12 with a pierced aluminum spacer on the periphery by 4,020 allowing the passage of the sail axes. These are 4 'M12 LD 90' screws which fix the aluminum plate 15 by crossing the spacer 23 and screwing onto the hub 12.

Figure 12 is an isolated view with elements made invisible for the understanding of the view. It is the main beam 24 which supports the assembly, of the two 'hat' bearings 12 which themselves allow the sails and the arms bends to evolve. The main beam 24 is fixed to the cap 5.25 by a system of flanges and threaded rods. This link is adjustable to allow adjustment of centering, eccentricity. This beam supports the adjusted surface 9. is also adjustable in all directions, in particular with these aluminum triangles 27 and these steel bars 28 which, once positioned, allow rigid positioning .11 should be noted that when the rollers push on one side on the set surface 9 of El we have in opposition the caster on the set surface of E2, the forces are neutralized The cap 5,25 also has another use, it blocks an assembly of tapered roller bearings. This type of bearing gives good centering with good resistance to axial thrust. In cage 5.26 we have two bearings in opposition with adjustment shims which are supported on the end of the fixed mast 4. The inner rings of the two bearings will be locked and tightened on a spacer by a large nut. The cage 5.26 will be welded to a long tube, the termination of which will be shown in Figure 13.

Figure 13 represents the termination of 5. I chose ex-centric rollers28 to allow me to remove any play and strengthen the support of the tail 3. It is attached to the movable mast 5. A 48.3 aluminum tube 0 which the tail is fitted into a steel cock welded to the movable mast 5. An M10 screw links the assembly.

Figure 14 is the tail 3, it is at the end of the aluminum tube. A steel tube with a welded plate. This round steel 31 is fitted into the aluminum tube, with a connection by riveting. On the other side of the sail the same tube with the welded plate 30, shorter. To connect these two tubes 30 and 31 four plates 29 of two different lengths. The connection will be made by rivets. Sail 32 an aluminum sheet thick. 0.8 will be riveted to the dishes of the tubes. This system seems rigid and will avoid any rotation around the tube 31.

Figure 15 is the transmission of energy. On the tube 10 a pinion of 20 teeth 33 is pinned. This pinion 33 is attached to the pinion 35 of 9 teeth. On the same tree we have this pinion 33 with the pinion 34 of 40 teeth. The shaft is blocked in space by two cap bearings 37. The 'tread' on the bearings is given by lights which makes it possible to adjust the chain tension. The pinion 34 is hooked to the pinion 36 of 9 teeth. The pinion 36 is mounted on the shaft of the alternator 37.The alternator is mounted on the tube of part 5.26 of the movable mast 5.11 is mounted in a cradle with here also a 'pie-tage' with oblong holes this which will allow you to adjust the chain tension. It should be noted that on the cap 5.25 we have a hole 020 which allows the passage of a cable, a pipe.

Figure 16 is a windmill that can be equipped by my invention, there are already systems that can orient the roof and the sails. The upper sails raised to the maximum give an impression of power.

Figure 17 is the wind turbine of the future, it will be compact, able to withstand storms and I am sure it will perform well.

Claims (1)

Original document published without claims.