DE3825241A1 - Wind turbine - Google Patents

Abstract

The wind turbine (10), which is designed for large powers in the megawatt region, has wind-collecting blades (12, 14) which are connected to a hollow shaft (16) via rotor arms (20, 22). The wind-collecting blades and the rotor arms are constructed as hollow box profiles, so that a large strengths and rigidities can be achieved with a low material requirement and thus a low weight. <IMAGE>

Description

The invention relates to a wind turbine with one on one Mast mounted rotor with at least one on rotor arms arranged windscreen.

As alternative energy to coal and nuclear energy Wind energy more and more attractive. This is how wind turbines become built, which provide outputs of several megawatts. A disadvantage of these wind turbines is that they are very large and are heavy, so that self-starting does not is possible and these wind turbines via electric motors or must be started by reversing the polarity of the generator.

The invention has for its object a wind turbine to create that is designed for great performance that comes with it but light yet strong enough to withstand large wind forces to be able to record, and at very low Wind speeds without the support of an electric motor can start up yourself.

This object is achieved in that the Windscreen and the rotor arms as a rigid box are trained.

The formation of the windscreen blades, the very large Dimensions can take over, along with the poor which they are connected to the vertical shaft as Box, allows stiffness with little material To create components that are light but very large can absorb attacking forces.

According to a preferred embodiment, the box is made of the windscreen sheet from tubes and the rotor arms are made also from tubes, so that a stiff overall Construction is created.  

The core of the windscreen blade preferably consists of three side by side tubes, the diameter of the middle tube is larger than that next to this arranged pipe. It is possible with simple Average the required profile of the windscreen blade to train without requiring a large amount of material is required.

The pipes for the windscreen blade and the rotor arms are made preferably made of steel or aluminum. In the latter case preferably consist of extruded Aluminum tubes.

In a development of the invention is in the middle tube Reinforcement core arranged with the rotor arms connected is. The reinforcement core made of steel or Steel wire is particularly provided when the pipes are out Aluminum. The core can correspond to that at the Turbine attacking forces can be adjusted in diameter.

In order to improve the vibration behavior of the wind turbine, are preferably the upper rotor arms on one with the Flywheel connected to the rotor shaft. In order to the turbine runs smoothly, even if the attacking wind forces change.

Preferably, the box is in particular the rotor blades Cross section are approximately rectangular and inside Reinforcement plates arranged. The box can do it have curved outer surfaces that roughly match the profile of the Corresponding windscreen leaf, so that for the cladding of the Box to form the final profile only one little material is required.  

In a development of the invention, the windscreen blades are as Buoyancy profile or designed as a symmetrical profile and the nose, the trailing end and the side faces the windscreen blades are made of plastic, preferably fiber-reinforced plastic.

The rotor shaft is preferably designed as a hollow shaft and rotates around a stationary axis. It is possible to arrange the generator near the ground, so that the Turbine construction overall a great stability provides low material costs.

In a development of the invention are at the ends of the Wind deflector baffles and in the middle area Movable flaps arranged, which makes the self-start the turbine is guaranteed.

The windscreen blades can be rectilinear parallel to the mast, curved in the form of a whisk or diverging with or without a central region that is approximately parallel to the mast be. This makes it possible to create wind turbines that according to the prevailing geographical features and the Perform optimal performance in wind conditions.

The inventive design of the windscreen blades as a box it is possible to optimally balance the turbine, so that no harmful forces occur due to imbalance. When a flywheel is placed on the upper rotor arms the upright effect of a top is achieved. By extending the profiles in a straight line, the Centrifugal force is absorbed by the rotor arms as a tensile load.

According to a further preferred embodiment, the Wind turbine designed as a gyroscope, preferably with two diametrically opposed windscreen blades, each windscreen blade is composed of segments  and the segments on tether, especially made of steel Chain lines are kept. Furthermore, in the radial outermost segments of each draft shield ballast weights arranged.

This embodiment acts as a gyroscope so that the turbine in the run always tends to the vertical position maintain so that with significantly increased torque and higher quick count on the usual elaborate Rope tensioning to the sides can be completely dispensed with can. The gyro effect is increased in that the Ballast weights attached in the outermost segments are, preferably in the form of filling the Center tube of the box arranged in this position Segments, the filling a passage for the Leaving rope.

The steel cable arranged in the middle tube of the box takes the tensile load while the wind turbine is running and ensures maximum strength in the Fast forward. With the box consisting of three pipes Windscreen blades can be an ideal shape of the chain line can be achieved so that only tensile forces in operation the windscreen blades occur. This embodiment one simple vertical axis wind turbine consists of a few Sharing is self-controlling without electronics and inexpensive. In addition to the wind direction independence Self-control of the centrifugal wind turbine with one Self-starting from about 2 m / sec wind speed and regulated continuation in storm. The one as a centrifugal turbine Trained wind turbine is both a slow runner high torque as well as a high performance fast runner. This makes it possible to use the least amount of funds highly efficient wind energy system for the future to build.

To compensate for the centrifugal forces and the buoyancy that the  Attacking windscreen blades are preferred Ballast weights on the tether opposite the segments the windscreen blades can be swiveled. This is braking with high buoyancy, i.e. prevented in high-speed, because of the ballast weights are counteracted.

To make the wind turbine self-start even at low To produce wind speeds preferably indicate that radially outer segments of the windscreen blades on the following End hinged flaps on.

The tethers are preferably at the top and bottom Support arms attached and the support arms are on the vertical Hollow shaft arranged.

According to a further preferred embodiment, the Ends of the tethers beyond the support arms to the Hollow shaft guided and attached to this. Around Changes in length in the tether compensate can, are preferably tendons in the tethers arranged and / or at least one end of each tether attached to tension springs, either on the support arms or are attached to the vertical hollow shaft.

According to a preferred embodiment, the segments are the windscreen blades above each other via guide bolts coupled, so that on the one hand the assembly is very simple and on the other hand, individual segments can be easily replaced can.

The support arms of the windscreen blades can be horizontal or be arranged obliquely.

Preferably at the ends of the windscreen blades, i.e. at the end segments, winglets or guide wings arranged, also for the self-start of the Contribute wind turbine.  

The generator, especially as a ring generator is preferably formed at the lower end of the Hollow shaft arranged in a foundation housing.

It is also possible that in the foundation housing in which the Hollow shaft mounted and the generator is arranged, a Device for hydrogen electrolysis is provided.

According to a further preferred embodiment, the Wing formed as a lift profile and are ropes eccentrically arranged in the box of the wings. Through the Bracing the wings designed as a box by means of Rigid tethers provide sufficient strength the wing construction. Due to the eccentric arrangement of the Ropes within the box of each wing in which the main weight of the wing is concentrated, one The turbine has started itself because the blades are in Dependence on the centrifugal force and the lift around the Swiveling tether and thus depending on itself adjust from the wind conditions. By the possibility of pivoting is also achieved in that too large Speeds the pivoting of the wings an amount assumes, in which the wings the the incoming wind offer such a large area of attack that braking the Wing and thus a reduction in rotational speed be achieved so that destruction is avoided.

The tether can be near the inside of the wing or inside be arranged in the front area of the box in the direction of rotation.

Is preferably in the direction of rotation of the wing before Tether a balance weight arranged to be too large To compensate centrifugal and buoyancy forces.

Embodiments of the invention are described below the drawing explained in more detail. It shows:  

Figs. 1-3 show various embodiments of Windtur turbines in "whisk Form",

Fig. 4 is a partially broken away windscreen sheet in an enlarged scale;

Fig. 5 shows another embodiment of a windscreen sheet with connection to the rotor shaft,

Fig. 6 shows a portion of a windscreen sheet in side view,

Fig. 7 shows a wind turbine with extending parallel to the axis of rotation windscreen sheets,

Fig. 8-10 show various embodiments of wind turbines with diverging to the rotor shaft windscreen sheets,

Fig. 11-14 cross-section through windscreen leaves with tubular cores,

Fig. 15 is a profile designed as a buoyancy windscreen sheet in cross section with a box core,

Fig. 16 designed as a symmetrical profile windscreen sheet in cross section with a box core,

Fig. 17 is a formed as a centrifugal wind turbine with approximately arranged on a circular arc windscreen sheets,

Fig. 18 shows a section along the line XVIII-XVIII of Fig. 17 by a windscreen sheet,

Fig. 19 shows a section along the line XIX-XIX of Fig. 17 outward through a hole formed with a pivotable flap radial segment of the windscreen sheet,

Fig. 20 is a wind turbine to the vertical hollow shaft converging towards windscreen sheets,

Fig. 21 a wind turbine similar to the wind turbine according to Fig. 17,

Fig. 22 shows a further embodiment of a wind turbine similar to that of FIG. 17

Fig. 23 in an enlarged illustration the end region of a windscreen sheet according to XXIII of FIG. 22,

Fig. 24 shows a further modified embodiment of a wind turbine,

Fig. 25 an end portion of a windscreen sheet according XXV of Fig. 24,

Fig. 26 is a segment of a windscreen sheet having pivotable hinged subsequent flap,

Fig. 27 shows a section along the line XXVII-XXVII of Fig. 26,

Fig. 28 is a section through a segment of a windscreen sheet,

Fig. 29 shows a section along the line XXVIX-XXVIX of Fig. 28,

Fig. 30 shows a section along the line XXX-XXX of Fig. 28,

Fig. 31 shows a portion of another embodiment of a windscreen sheet,

Fig. 32 is a sectional view taken along the line XXXII-XXXII of Fig. 31,

Fig. 33-36 show various views of a balance weight between adjacent radially outer segments of a windscreen sheet,

Fig. 37 shows a further embodiment of a wind turbine, and

Fig. 38 u. 39 cuts from which the arrangement of the tether can be seen.

The wind turbine 10 shown in FIG. 1 is built according to the whisk principle, ie windscreen blades 12 and 14 are bent outwards relative to the mast 16 . The windscreen sheet 12 consists of a box 18 which is rigidly connected at its ends to rotor arms 20 and 22 , which are also box-shaped or in the form of tubes. A nose 24 and a subsequent end 26, preferably made of a fiber-reinforced plastic, are arranged on the windscreen sheet 12 . Flaps 28 , 30 are provided in the central region of the windscreen blade and are pivotably mounted on the box 12 . Baffles 32 and 34 are provided at the ends of the windscreen blade 12 , which enable the wind turbine to start up automatically. The box 18 of the windscreen sheet 12 is made of metal, preferably steel or aluminum, in particular extruded aluminum tubes. The windscreen sheet 14 is designed like the windscreen sheet 12 .

The windscreen blades 12 and 14 are connected to a hollow shaft 36 via the rotor arms. The hollow shaft 36 rotates about a vertical axis 38 , which is held in a foundation on the floor. A ring generator, not shown, is arranged at the lower end of the hollow shaft 36 . The windscreen blades 12 and 14 are additionally held on the hollow shaft 36 by means of guying 40 , 42 and 44 , 46 .

While the wind turbine shown in FIG. 1 has two windscreen blades, the wind turbine 50 shown in FIG. 2 is designed with three windscreen blades 52 , 54 , 56 . The windscreen blades 52 , 54 , 56 are connected via lower rotor arms 58 and via upper rotor arms 60 to a hollow shaft 62 which is rotatably mounted about a vertical axis 64 . The design of the windscreen blades 52 , 54 , 56 and the rotor arms 58 and 60 is analogous to the wind turbine shown in FIG. 1. The upper rotor arms 60 are connected to a flywheel 64 which is attached to the hollow shaft 62 . The flywheel 64 produces a gyroscopic effect so that the stability and the vibration behavior of the wind turbine 50 are improved. The windscreen blades 52 , 54 , 56 , like the windscreen blades 12 and 14 according to FIG. 1, are formed with middle flaps 66 and guide plates 68 , 70 at the ends of the windscreen blades. Fig. 3 shows a wind turbine 70 , which is constructed similarly to the wind turbine 50 of FIG. 2 with the difference that no flywheel is arranged on the upper arms of the windscreen blades.

Fig. 4 shows an enlarged view of a windscreen sheet 72 , which consists of a rigid box 74 , which is coated with a plastic jacket 76 in the form of the profile of the windscreen sheet. In this embodiment, the box 74 consists of a box of approximately rectangular cross section made of a metal sheet.

FIG. 5 shows a section of a windscreen blade 80 which is connected via an arm 82 to a flywheel 84 which is fastened to a hollow shaft 86 . The inside of the windscreen sheet 80 has a box 88 made of sheet steel, which is approximately rectangular in cross section and has stiffening sheets 90 and 92 on the inside. The sheets 90 are zigzag and the sheet 92 is approximately perpendicular to the longitudinal axis of the box 88 , so that overall there is a light but very rigid structural element which is capable of absorbing large forces. The rotor arm 82 is also designed as a hollow box with or without internal stiffeners and is rigidly connected to the box 88 . The box 88 is covered with a plastic profile 94 , which can be designed as a buoyancy profile or as a symmetrical profile. At the end of the arm 80 , a baffle or winglet 96 is arranged which enables the wind turbine to start itself. The windscreen blade 80 is connected to the upper end of the hollow shaft via a tension strut 98 . FIG. 6 shows the central area of the windscreen sheet 80 according to FIG. 5, on which pivotable flaps 100 and 102 are provided. These flaps, which are articulated on the profile 94 , support the self-start of the turbine and control the speed of the turbine at high wind speeds.

Fig. 7 shows a wind turbine 110 with approximately parallel to a hollow shaft 112 arranged windscreen sheets 114, 116, 118. The windscreen blades 114 , 116 and 118 have an inner box 120 , which can be composed of tubular profiles or, in cross section, is composed approximately rectangular of sheet metal. This box 120 of each windscreen blade is rigidly connected to rotor arms 122 and 124 , which are also box-shaped. The lower rotor arms 124 of each windscreen blade are attached to a flywheel 126 which is rigidly arranged on the hollow shaft 112 . The box 120 of each windscreen sheet is surrounded by a jacket 128 made of fiber-reinforced plastic, which provides the actual profile of the windscreen sheet. The plastic sheath 128 is longer than the box 120 and extends beyond the rotor arms 122 and 124 . In the central region of the casing 128 , a flap 130 is arranged on each windscreen leaf 114 , 116 and 118 at the end following in the direction of rotation.

Fig. 8 to 10 show the wind turbine in which the wind-catching but leaves are each formed in a straight line hinverlaufend to the upper and lower end of the mast. The wind turbine 140 shown in FIG. 8 has two windscreen blades 142 and 144 , which are each formed with an upper section 146 and a lower section 148 . The upper section 146 is connected via an arm 150 and the lower section 148 via an arm 152 to a hollow shaft 154 . The arms 150 and 152 as well as the sections 146 and 148 of the windscreen blades 142 and 144 are designed as box profiles with a plastic covering. The hollow shaft 154 is rotatably supported on a vertical axis 156 , which is held in a foundation 158 . The sections 146 and 148 of the windscreen blades 142 and 144 are connected in the connection area via a bracing 160 to a flywheel 162 which is fastened on the hollow shaft 154 . Upper stays 164 and lower stays 166 between the windscreen blades 142 and 144 and the hollow shaft 154 increase the stability of the wind turbine.

The wind turbine 170 shown in FIG. 9 has wind catcher blades 172 and 174 which are fastened to a hollow shaft 176 . The hollow shaft 176 rotates about a vertical axis 178 , which is received in a foundation 180 . Each windscreen sheet 172 and 174 consists of an upper section 172 which runs obliquely to the hollow shaft 176 , a central section 184 which runs approximately parallel to the hollow shaft 176 and a lower section 186 which runs towards the hollow shaft 176 . Rotor arms 188 and 190 are provided at the connection area between the upper section 172 and the central area 184 and the central area 184 and the lower section 186 . The sections of the windscreen blades 172 and 174 as well as the rotor arms 188 and 190 are designed as hollow box profiles, which are formed with a plastic coating in the form of the windscreen blade profile. This results in the shape of a stiff box with low weight and great strength for absorbing the attacking centrifugal forces for each windscreen blade. In the central area 184 , flaps 192 are arranged on each windscreen blade 172 and 174 , which enable the wind turbine 170 to start up automatically.

The wind turbine 200 shown in FIG. 10 has wind catcher blades 202 and 204 which are connected via upper rotor arms 206 and lower rotor arms 208 to a hollow shaft 210 which is arranged rotatably about a vertical axis 212 . As with the wind turbines according to FIGS. 8 and 9, the vertical axis 212 extends only up to approximately half the height of the hollow axis 210 .

Each windscreen blade 202 and 204 has a central region 214 which runs approximately parallel to the hollow axis 210 . This central region 214 is adjoined by an upper section 216 running obliquely to the hollow shaft 210 and a lower section 218 also running to the hollow axis 210 . The upper rotor arm 206 is fixedly connected at the upper end of the section 216 and the lower rotor arm 208 at the lower end of the section 218 to the box-shaped inner profile of the windscreen 202 or 204 . A strut 220 is arranged on the central section 214 and is fastened to a flywheel 222 which is provided on the hollow shaft 210 . To brace the windscreen sheet 202 , a support 224 is provided in the central region, so that guy cables 226 and 228 , which run from the upper and lower ends of the hollow shaft 210 to the windscreen sheet 202 and 204 , are connected in a straight line to the support 224 can. This results in a rigid construction with a relatively low weight, which is designed to absorb large wind and centrifugal forces.

Fig. 11 shows a cross-section through a windscreen sheet 230th Pipes 232 , 234 and 236 , which are connected to one another, are arranged in the interior of the windscreen blade. The diameter of the tube 232 is larger than the diameter of the tubes 234 and 236 . A reinforcing core 238 is arranged in the interior of the tube 232 and can be adapted to the dimensions and loads of the windscreen blade 230 in cross section. The reinforcement core 238 is provided in particular if the tubes 232 , 234 and 236 consist of aluminum. The reinforcement core 238 is then preferably made of steel. A lug 240 , a trailing end 242 and side surfaces 244 and 246 , which are preferably made of a fiber-reinforced plastic, are arranged on the profile consisting of the tubes 232 , 234 and 236 . The nose, the trailing end and the side surfaces bring the final profile of the windscreen blade.

Fig. 12 shows a cross-section through a windscreen sheet 250 with a core of tubes 252 and 254 and a half-tube 256th A reinforcing core 258 made of steel is arranged in the tube 252 . On the half pipe 256 , a flap 260 is pivotally arranged on a bearing 262 . A weight 264 is attached to the end piece 260 , the center of gravity of which lies in front of the bearing 262 . Like the windscreen blade 230 , the windscreen blade 250 is provided with a nose 266 and side panels 268 and 270 . The wind Fing sheet 250 corresponds to the central portion of the wind turbines shown in the previous Fig., That is, the portions on which are provided flaps.

Fig. 13 shows in cross section a windscreen sheet 280 in the form of a lift profile. The core of the windscreen blade 280 is formed from a box 282 consisting of a tube 284 , around which a box profile 286 which is approximately rectangular in cross section is arranged. The end faces of the box 286 are connected to the tube 284 via struts 288 and 290 . A nose 292 is arranged at the front end of the box 282 and a flap 294 is arranged at the rear end. The flap 294 is rotatably provided about a bearing 296 and has a counterweight 298 lying within continuations of the side surfaces of the box 282 . Different positions of the flap 294 in FIG. 13 are indicated by dashed lines.

The cross-sectional profile 300 of a windscreen blade shown in FIG. 14 essentially corresponds to the profile shown in FIG. 13. A tube 304 is fastened within a box 302 , which is approximately rectangular in cross section with curved side surfaces. A nose 306 made of plastic is arranged at the front end of the box 302 . A flap 308, also made of plastic, is provided on a bearing 310 at the rear end of the box 302 . The flap 308 has a tube 312 in which a weight 314 is arranged. A stop 316 is arranged on the outside of the tube 314 , which limits the pivoting angle of the flap 308 when it comes into contact with stops 318 and 320 which are arranged on the box 302 .

Fig. 15 shows in cross section a windscreen sheet 330 which is formed as a lift profile. The windscreen sheet 330 has a box 332 which is approximately rectangular in cross section and on which a plastic nose 334 is arranged at the front. At the rear end, a tube 336 is mounted on the box 332 via a bearing 338 . A flap 340 made of plastic is arranged on the tube 336 , the outer surfaces 342 and 344 of which are asymmetrical, so that the buoyancy effect is achieved. On the outside of the tube 336 , stops 346 and 348 are arranged, by means of which pivoting of the flap 340 is limited.

The windshield blade 350 shown in cross section in FIG. 16 corresponds in structure to the windshield blade 330 according to FIG. 15 with the difference that a flap 352 hinged at the rear end has symmetrical outer surfaces 354 and 356 . The formation of an inner box, the nose and the flap 352 is analogous to FIG. 15.

Fig. 17 shows a wind turbine 360, which is formed as a centrifugal turbine. Lower rigid support arms 364 and upper rigid support arms 366 are fastened to a rotatably mounted vertical hollow shaft 362 . Steel cables 368 and 370 are guided through the ends of the support arms 364 and 366 , the ends of which are in turn fastened to the hollow shaft 362 . Segments 372 and 374 are lined up on the steel cables 368 and 370 in such a way that they are arranged in the form of a chain line. The segments 372 and 374 are box-shaped with three tubes arranged inside, the steel cables 368 and 370 being guided through the inner tube 376 and 378 , as can be seen from FIGS. 18 and 19. The inner tube 376 or 378 is also filled with a heavy material 380 or 382 , in order to bring about the centrifugal effect of the turbine, particularly in high-speed.

Fig. 18 shows a section through a segment of a windscreen blade, which is designed as a rigid lift profile, while Fig. 19 shows a section through a segment 374 of the windscreen blade, the trailing end 384 of which is in the form of a flap, so that the self-start of the turbine is guaranteed. As can be seen from FIG. 17, the turbine 360 is braced only in the lower area, whereas the otherwise necessary bracing of the mast tip could be dispensed with, since the wind turbine is held in the vertical position due to the gyroscopic effect.

Fig. 20 shows a wind turbine 390 with two diametrically opposed windscreen sheets 392 and 394 which are arranged arrow-shaped and diverge to a hollow shaft 396 toward. The windscreen blades 392 and 394 are in turn composed of segments which are lined up on steel cables 398 and 400 . The steel cables 398 and 400 run through the ends of an upper support arm 402 and a lower support arm 404 and are fastened to the hollow shaft 396 . Ballast weights 406 and 408 , respectively, are arranged in the apexes of the windscreen blades 392 and 394 , which support the gyro effect of the turbine 390, particularly in the high-speed mode. The ballast weights 406 and 408 can be pivoted with respect to the segments of the windscreen blades 392 and 394 , so that they can compensate for the centrifugal and buoyancy forces of the windscreen blades during the run. Bracing is also not required in the wind turbine shown in FIG. 20.

FIG. 21 shows a wind turbine 410 which is configured similarly to the wind turbine according to FIG. 17.

In the wind turbine 420 shown in FIG. 22, tether cables 422 and 424 for the segments 426 of the windscreen blades 428 and 430 are attached at one end to the hollow shaft 432 and at the lower end to a lower support arm 434 . The tether 422 and 424 are passed through the ends of an upper bracket 436 . Tensioning elements 438 can be arranged in the holding cable 422 or 424 between the fastening point on the hollow shaft 432 and the upper support arm 436 . The lower ends of the tether 422 and 424 are attached to compression springs 440 so that changes in length of the tether can be compensated and the close contact of the segments 426 of the windscreen blades 428 and 430 is maintained. The hollow shaft 432 is mounted in a foundation housing 442 , in which a generator 444 is also arranged. Furthermore, a device for hydrogen electrolysis can be provided in the foundation housing 442 , so that the energy obtained by the wind turbine 420 can be converted immediately.

Fig. 23 shows the upper region of the windscreen blade 430 of the wind turbine 420 of Fig. 22. It will be appreciated that the windscreen sheet 430 of segments 446, 448, 450 is so formed as a box and internally with two tubes 452 and 454 are provided. The tether 424 is guided through the tube 452 . The segments 446 , 448 , 450 are coupled to one another via pins 456 , which are each fastened to one of the segments and engage in receiving bores in the respectively adjacent segment. A winglet or guide wing 458 , which is important for the self-starting of the wind turbine 420 , is arranged on the segment 446 .

The wind turbine 460 shown in FIG. 24 corresponds essentially to the wind turbine according to FIG. 22 with the difference that the upper support arms 462 and lower support arms 464 are not arranged horizontally but at an angle to the hollow shaft 466 . The arrangement of tethers 468 and 470 and the design of the windscreen blades 472 and 474 correspond to the embodiment shown in FIG. 22.

Fig. 25, the upper end shows an enlarged view of the windscreen blade 472 of the wind turbine 460 of FIG. 24. The windscreen sheet 472 is composed of segments 474, 476, etc., which are box-shaped and inside three tubes 478, 480 and 482 have. The tether 470 is guided through the middle tube 480 .

Fig. 26490 shows in section a segment of a windscreen sheet. The segment 490 is arranged in the radially outer position and has a subsequent pivotable end 492 . Tubes 494 , 496 and 498 are arranged in the segment 490 , a tether 500 being guided through the middle tube 496 . The tube 498 , to which the tapered end of the subsequent end 492 is fastened, can be pivoted via pins 502 in adjacent segments. A ballast weight 504 is arranged on the front of the tube 498 of the pivotable end, which contributes to the centrifugal effect of the turbine to which such segments are arranged. A pin 506 is arranged on the upper side of the segment 490 and a bore 508 is arranged on the lower side, via which a coupling with adjacent segments takes place.

Fig. 28 shows a segment 510, which is formed as a rigid buoyancy profile. Stiffening tubes 512 , 514 and 516 are arranged in the box-shaped segment 510 , the tether being arranged through the central tube 514 . The segment 510 has pins 518 and 520 on the upper side and bores 522 and 524 on the underside, via which the coupling with adjacent segments takes place, the pins 518 and 520 engaging in bores on the segment arranged above and the bores 522 and 524 are arranged to receive pins of a segment arranged underneath.

Fig. 31 shows another embodiment of a windscreen sheet 530 composed of segments 532, 534. The segments 532 and 534 are arranged at the radially outermost position of the windscreen blades and contain a ballast weight 536 on the inside, so that the gyro effect of the wind turbine is achieved. The ballast weight 536 is received inside a tube 538 , which together with the tubes 540 and 542 forms the rigid box of the segments 532 and 534 . A tether 542 is guided through the ballast weight 536 . The end 544 of the segment 532 or 534 lagging during the run is pivotably arranged with the tube 542 on an upper or lower end face of the segment. On the leading side of the tube 524 , a counterweight 546 is arranged, which brings about an automatic adjustment of the flap depending on the speed of rotation.

Figs. 33 to 36 show a mass or counterweight 550, the radially outer between two segments 552 and 554 is disposed. The mass weight 550 is pivotable on a tether 556 relative to the segments 552 and 554 . In order to achieve this, slide bearings 558 and 560 are arranged between the mass weight and the segments 552 and 554 , and the mass weight 550 can be pivoted about a bearing 562 about the tether 556 . As can be seen from FIG. 34, the segments 552 and 554 converge towards the hollow shaft to which the steel cable 556 is attached. Therefore, the mass weight 550 is formed radially inward with a tapered end 564 . At the ends of the segments 552 and 554 facing the mass weight 55 there are levers 566 and 568 , respectively, which are provided at the ends with guide bolts 570 and 572 , respectively, so that guidance between the mass weight 550 and the segments 552 and 554 of the windscreen blade is achieved becomes.

Fig. 36 shows a section along line XXXVI-XXXVI of FIG. 34, from which the position of the mass weight to the vane segment 554 and the arrangement of the link lever 568 and the guide pin 572 to the segment 554 and the engagement of the guide pin 572 in a 550 Groove 574 in the ballast weight 550 can be seen. By the arrangement, as shown in FIGS. 33 to 36, a low-friction pivoting of the mass or ballast weight 550 with respect to the segments 552 and 554 is possible, at the same time the mass of the weight is prevented from swinging.

Fig. 37 shows a wind turbine 580 with two windscreen sheets 582 and 584, which may consist of segments, the segments via tethers 586 and 588 are clamped. At the ends, the windscreen blades 582 and 584 are supported by arms 590 and 592 , respectively, which are fastened to a vertical rotary shaft 594 . The rotary shaft 594 is supported in a foundation 596 . A ring generator (not shown in detail) can be arranged in the holding arm 292 , via which the rotary energy is converted into electrical energy.

The windscreen blades 582 and 584 diverge towards the vertical shaft 594 and have weights 598 and 600 at the central intersection, which act in the form of a gyroscope and stabilize the wind turbine 580 .

FIG. 38 shows a section through a windscreen blade 602 , which is designed as a lift profile and has a box 604 indicated inside by a circle. A counterweight 606 , which can be rigid or self-adjusting, is arranged in front of the box 604 in the direction of rotation. A tether 608 is passed through the box 604 , near the inside 610 of the windscreen sheet 602 . Due to the eccentric arrangement of the tether 608 in the box 604 or the profile of the windscreen blade 602 , a self-adjustment of the windscreen blade is achieved since pivoting about the tether 608 is possible, so that depending on the wind strength, the position of the profile automatically follows the incoming wind .

Fig. 39 shows a section through a windscreen sheet 612 which is formed as the windscreen sheet 602nd Only the arrangement of a tether 614 is different, since in the windscreen blade 612 the tether 614 is arranged in the direction of rotation in the front region of the box 616 . The windscreen blade 612 acts like a wind vane and also adjusts itself automatically as a function of the wind speed, so that self-starting and optimal utilization are ensured.

Claims (30)

1. Wind turbine with a rotor mounted on a mast with at least one windscreen blade arranged on rotor arms, characterized in that the windscreen blade ( 12, 14; 52, 54, 56; 72; 80; 114, 116, 118; 142, 144; 172 , 174; 202, 204; 230; 250; 280; 300; 330; 350 ) and the rotor arms ( 20, 22; 58, 60; 82; 122, 124; 150, 152; 188, 190; 206, 208 ) as rigid box are formed. 2. Wind turbine according to claim 1, characterized records that the box of windscreen blades consists of pipes.   3. Wind turbine according to claim 1 or 2, characterized in that the core of the windscreen blade ( 230 ) consists of three tubes ( 232 , 234 , 236 ) arranged side by side. 4. Wind turbine according to claim 3, characterized in that the diameter of the central tube ( 232 ) is larger than that of the tube ( 232 ) arranged next to this tube ( 234 , 236 ). 5. Wind turbine according to one of claims 1 to 4, characterized in that the tubes ( 232 , 234, 236 ) consist of steel or aluminum. 6. Wind turbine according to one of claims 3 to 5, characterized in that in the central tube ( 232 ) a reinforcing core ( 238 ) is arranged, which is connected to the rotor arms. 7. Wind turbine according to claim 6, characterized in that the reinforcing core ( 238 ) consists of steel or steel wire. 8. Wind turbine according to one of claims 1 to 7, characterized in that rotor arms ( 60, 82, 124, 188, 190 ) or guy lines ( 160, 220 ) on one with the rotor shaft ( 62 , 86 , 112 , 154 , 176 , 210 ) connected flywheels ( 64 , 84 , 126 , 162 , 222 ) are connected. 9. Wind turbine according to claim 1, characterized in that the box ( 88 ) is approximately rectangular in cross section and has reinforcing plates ( 90 , 92 ) inside. 10. Wind turbine according to one of claims 1 to 9, characterized characterized that the windscreen blades as a buoyancy profile or as a symmetrical profile are trained and that the nose, the trailing end and the side surfaces made of plastic, preferably fiber-reinforced plastic, are formed. 11. Wind turbine according to one of claims 1 to 10, characterized in that the rotor shaft is designed as a hollow shaft ( 16 , 62 , 86 , 112 , 154 , 176, 210 ). 12. Wind turbine according to one of claims 1 to 11, characterized in that at the ends of the windscreen blades ( 12 , 14 ) baffles ( 32 , 34 ) and in the central region movable flaps ( 28 , 30 ) are arranged. 13. Wind turbine according to one of claims 1 to 12, characterized in that the windscreen blades ( 114 , 116 , 118 ) rectilinearly parallel to the mast ( 112 ), curved in the manner of a whisk ( 12, 14, 52, 54, 56, 72, 80 ) or diverging ( 142, 144, 172, 174; 202, 204 ) with or without a central region ( 184 , 214 ) approximately parallel to the mast. 14. Wind turbine according to one of claims 1 to 9, characterized in that it is designed as a gyroscope ( 360 , 390 , 410 , 420 , 460 ). 15. Wind turbine according to claim 14, characterized in that two diametrically opposed windscreen blades ( 392 , 394 , 428 , 430 , 472 ) are arranged, that each windscreen blade from segments ( 372 , 374 , 446 , 448 , 450 , 474 , 476 ) is composed, and that the segments are held approximately on a chain line by means of tethers ( 368 , 370 ; 398 , 400 ; 422 , 424 ; 468 , 470 ), in particular made of steel. 16. Wind turbine according to claim 14 or 15, characterized in that ballast weights are arranged in the radially outermost segments ( 374 ) of each windscreen blade. 17. Windscreen sheet according to claim 16, characterized in that the ballast weight ( 550 ) relative to the segments ( 552 , 554 ) of the windscreen sheet is pivotable. 18. Wind turbine according to one of claims 14 to 17, characterized in that the radially outer segments ( 490 ) of the windscreen blades have pivotable flaps ( 492 ) at the subsequent end. 19. Wind turbine according to one of claims 14 to 18, characterized characterized that the tethers on upper and lower arms are attached and that the Support arms are arranged on a vertical hollow shaft. 20. Wind turbine according to claim 19, characterized in that the ends of the tethers ( 368 , 370 ) on the support arms ( 364 , 366 ) out to the hollow shaft ( 362 ). 21. Wind turbine according to claim 19 or 20, characterized in that in the tether ( 422 , 424 ) tendons ( 438 ) are arranged and / or that at least one end of the tether is attached to springs ( 440 ). 22. Wind turbine according to one of claims 14 to 21, characterized in that the segments ( 446 , 448 , 450 ) of the windscreen blades ( 430 ) are coupled to one another via guide bolts ( 456 ). 23. Wind turbine according to one of claims 14 to 22, characterized in that the support arms ( 364 , 366 ; 402 , 404 ; 434 , 436 ) are arranged horizontally or ( 462, 464 ) at an angle. 24. Wind turbine according to one of claims 14 to 24, characterized in that winglets or guide vanes ( 458 ) are arranged at the ends of the windscreen blades ( 430 ). 25. Wind turbine according to one of claims 14 to 24, characterized in that a generator ( 444 ) is arranged at the lower end of the hollow shaft ( 432 ). 26. Wind turbine according to one of claims 14 to 25, characterized in that a device for hydrogen electrolysis is provided in the foundation housing ( 442 ) in which the hollow shaft ( 432 ) is mounted and the generator ( 444 ) is arranged. 27. Wind turbine according to one of claims 1 to 26, characterized in that the wings ( 582 , 584 , 602 , 612 ) are designed as a lift profile and retaining cables ( 586 , 588 , 608 , 614 ) eccentrically in the box ( 609 , 616 ) Wings are arranged. 28. Wind turbine according to claim 27, characterized in that the tether ( 608 ) is arranged near the inside of the wing ( 602 ). 29. Wind turbine according to claim 27, characterized in that the tether ( 614 ) is arranged in the front region of the box ( 616 ) of the wing ( 612 ) in the direction of rotation. 30. Wind turbine according to claim 27 and 28, characterized in that a counterweight ( 606 ) is arranged in the direction of rotation of the wing ( 602 , 612 ) in front of the tether ( 608 , 614 ).