DE10105864A1 - Centrifugal wind-powered energy plant has weight lifted via centrifugal force dropped for providing rotary torque which can support rotor rotation - Google Patents

Abstract

The wind-powered energy plant uses the centrifugal force provided by at least one centrifugal weight (9) associated with a wind turbine rotor for lifting a vertically-movable weight (10), which is dropped after reaching a given height, for providing a force converted via a shaft and/or a drive into a rotary torque, which can be used for supporting the rotation of the rotor.

Description

The invention relates to wind turbines for using wind energy.

Conventional wind turbines are equipped with rotors that have the energy potential the centrifugal forces occurring during operation are not adequate consider.

The considerable centrifugal forces that have occurred have so far been neglected or otherwise used in energy generation. State of the art see:
DE 195 29 096 A1
DE 40 14 685 A1
DE 31 15 202 C2
DE-PS 79 783
US 4236504
DE 198 45 907 A1
DE 44 35 606 A1
DE 44 28 731 A1
DE 198 40 066 A1

My invention uses the energy potential of centrifugal force during the Rotation phase in order to slide outward attached weights on or in the rotor or to let it roll and to use this energy to move it vertically Weights to be carried upwards on the movable (rotating) rotor-bearing trunk. After the vertically movable weights are attached to the movable (rotating) rotor-bearing trunk have reached a certain height, they will be outdoors and / or controlled transport or case led down again. The one that occurs In the best case, weight can be 9.81 times as high as the original one Weight.  

This enormous weight or energy is integrated into a shaft and / or gear Torque implemented, which is used to set the rotor in motion and / or to support his movement.

explanation

The attached drawings are to be considered as construction examples.

In order to better represent the mechanics and the interaction of the individual components graphically, the rotors were equipped with only two rotor blades or extremities of the rotor or wind catcher ( Fig. 1-5, points 1 and 3 ).

However, it is recommended to use the rotor with at least three, better even four rotor blades or to equip extremities of the rotor or wind catcher.

Preferably, each rotor blade or extremity of the rotor or wind catcher with centrifugally movable weights ( FIGS. 1-4, 8, 9, points 9 and 3 ), via a separately attached, essentially vertically arranged conveyor belt / chain or comparable conveying mechanism, have ( Fig. 1-4, 8, 9, point 16 ) to transport the vertically movable weights on the trunk up or down ( Fig. 1-9, point 10 ). In the following the invention is explained in more detail by way of example and with reference to the accompanying drawings.

According to claim 1, centrifugally movable weights are attached inside the rotor ( FIGS. 1-4 and 8, 9, points 9 and 3 ). When the rotor rotates rapidly, they move outwards due to the centrifugal force ( FIGS. 2 and 4, item 9 / claim 6). This has the advantage that a higher torque is generated due to the inertia of the mass and the speed can be controlled in a certain range. This enables use in stronger winds.

When the rotor is stationary and rotating slowly and thus the centrifugal force is reduced, these weights slide or roll due to an attached slope ( Fig. 1-4 / claims 9 and 10) and / or the attached return rollers (claims 7 and 8) again towards the center of the rotor ( Fig . 1 and 3, pt. 9).

This has the main advantage that the position of the centrifugally movable Weights close to the rotor center, which facilitates the initial rotation and the Initial rotation speed is thus increased.  

A rope is attached to each of these weights, which is connected to the transmission ( FIGS. 1-4 and 8, 9, points 11 and 15 / claim 1).

On the movable (rotating) rotor-bearing trunk ( Fig. 1-5, point 5 ) there is an essentially vertically movable weight ( Fig. 1-9, point 10 ) that has bulges in which rolling elements are integrated ( Fig. 6, points 20 and 18 / claim 4) to keep the frictional resistance as low as possible.

These bulges fit into the guide rails attached to the trunk ( Fig. 5, item 39 / claim 4 and 13). On the top and bottom of the substantially vertically movable weight, fastening devices for receiving one chain per windscreen / rotor blade are attached ( Fig. 1-9, item 19 / claim 5). These chains form the connection to the gearboxes above ( Fig. 1-4 and 7, 8, item 11 / claim 11 and 12) and to the gearwheel / deflection pulley mounted below. The gears also have a connection to the gear rim on the fixed stem via an emerging shaft which is equipped with a gear ( Fig. 1-4 and 7, 8, item 29 / claim 1).

At the lower end of the movable trunk is an air tank ( Fig. 1-5, item 13 / claim 15 and 17) and in the lay-up device shock absorbers ( Fig. 1-4, item 8 / claim 39 and 40) are attached, the should dampen the case of the vertically movable weight.

At the lower end of the movable trunk, another gear rim is attached (claim 24), which is connected via a gear to a gear, which in turn drives a generator ( Fig. 1-5, points 29 and 11 ).

functionality

During the rotation, the centrifugally movable weights slide outwards due to the centrifugal force and rotate a shaft of the transmission via a cable connection ( FIGS. 1-4, 8, 9, points 11 and 15 ).

This gearbox thus drives another internal shaft ( Fig. 1-4, point 32 ), which is connected via a chain ( Fig. 1-4, point 1b) with the vertically movable weight ( Fig. 1-4, point. 10 ) is connected and thus carries it upwards. An activatable and deactivatable locking device (backstop) is attached to the gearbox ( Fig. 1-4, 7-9, item 36 / claim 26), which prevents the undesired lowering of the vertically movable weight. In the event of insufficient or slow rotation of the rotor, the centrifugally movable weights move / slide back towards the center of the rotor and the rope attached to these weights is wound up via a spring-loaded return roller integrated in the gearbox, which has a freewheeling function in this direction of movement ,

Due to the constant changes in the rotational speeds of the rotor, due to the changing wind speeds or speed control, the process described above is repeated again and again. This has the consequence that the vertically movable weight continues to rise ( Fig. 2 and 4).

From a certain height or if necessary, the backstop on the transmission is deactivated ( Fig. 1-4, 7-9, point 36 claim 26) and the vertically movable weight falls down and drives, at least via the chain connected to it a shaft of the gearbox ( Fig. 1-4, 7-9, point 32 ). This gear drives another internal shaft, which has an output shaft which is fitted with a gear and has a connection to the gear rim on the fixed rotor ( Fig. 1-4, 7-9, points 11 and 29 ) Rotor on and the rotor is set in motion and / or supported in its movement. If the rotor is not driven in this form, the shaft equipped with a gearwheel runs at idle speed. This process is repeated over and over again.

In order to generate an even greater torque and to ensure additional speed regulation, which enables use in even stronger winds, the rotor is designed telescopically ( Fig. 1, 2, point 3 / claim 18, 19, 20). The telescopic rotor blades or extremities of the rotor or wind catcher only move outwards when the centrifugally movable weights have reached a certain position or at the outer end in the rotor (claim 20). This is realized by one or more activatable / deactivatable attached locking devices, which are preferably located in the first third of the rotor blades or extremities of the rotor or windscreen ( Fig. 1-4, item 41 ) and have an electrical connection with at least one sensor , When at least one centrifugally movable weight glides over this sensor, it gives an impulse to the locking devices and the locking is temporarily deactivated and the telescopic rotor can move outwards (claim 20). The energy potential looks mathematically z. B. as follows:
The rotor blade / windscreen mounting arm has a length of 8 m (r).
The peripheral speed is 3 m / s ² (v ² ).
Centrifugal force formula: Fz = m × v ² : r
Gravitational force: 1 g = 9.81
Fall acceleration: 9.81 m / s ²
centrifugally movable weights = 30 kg (m)
vertically movable weight = 100 kg (m)
Fz = m × v ² : r = 30 × 3 ² : 8 = 33.75
33.75: 9.81 = 3.44 g
G = m × g

By means of the centrifugal force of the centrifugally movable weights in the rotor, which was calculated to be 3.44 G, and an intermediate gear, the vertically movably attached weight on the movable rotor-bearing trunk is conveyed upwards. If this vertically movable weight now falls through the deactivated backstop, the following formula applies.

Weight force formula: G = m × g = 100 × 9.81 = 981

This enormous weight can now be converted into torque via a gearbox and set the rotor in motion and / or support it in its movement.

Explanation of the remaining claims:
Claims 3, 14, 16, 21, 22, 23, 25, 35, 36 and 41 are self-explanatory.
Claims 2 and 4 are shown in Fig. 6.
Claim 28 describes the unit that is responsible for the mechanical and / or electrical execution of the gear change or change of the gear ratio.
Claim 29 describes the connection between sensors, control unit and control unit.
Claim 30 describes the equipment and functionality of the control unit, and their connection.
Claim 31 describes an alternative construction to convey the vertically movable weight upwards without gear support.
Claims 32 and 33 describe the attachment of an electrically and / or pneumatically operated motor. This motor offers the possibility to move the vertically movable weights upwards when the wind is very weak and the rotor is stationary. These weights are then lowered again to start the rotor and thus simplify the start of the rotation.
Reason: It takes much more energy to set a stationary rotor in motion than to support a rotating rotor in its movement.
Claim 34 describes the attachment of more than two rotor blades / extremities of the rotor / wind catcher to the rotor, each of which is equipped with centrifugally movable weights and has connections as described in claim 1.
Claim 37 describes the attachment of a plurality of rotors, which are equipped with centrifugally movable weights according to Claim 1, to a trunk.
Claim 38 leaves open the possibility of additionally attaching conventional rotors without centrifugally movable weights.

The advantages of a centrifugal wind turbine with rotation support according to the claims are:

• - Optimized use of wind energy
• - The wind turbine with at least 3 or 4 rotor blades is always favorable to the wind. This eliminates the need for a separate control, as with conventional rotors, to avoid this To move the wind turbine in the wind direction.
• - By the initial position of the centrifugally movable weights in or on the rotor rotation near the center of the rotor is possible even when the wind is weak
• - When the rotor is at a standstill and the wind is weak, the weight transported upwards on the movable trunk can be transported downwards if necessary to generate an initial speed. This has the advantage that the weak wind due to the subsequent own movement of the rotor (inertia of the mass) makes it easier to keep the rotor in motion.
  Reason: It takes much more energy to set a stationary rotor in motion than to support a rotating rotor in its movement.
• - This means that a lower wind speed is required for minimum operation.  
• - With weak wind or low rotation, the centrifugally movable Weights in or on the rotor are guided towards the center of the rotor. This will help weak winds significantly reduced the rotational resistance.
• - The speed is due to the centrifugally movable weights in or on the rotor controllable.
• - Additional speed control using the telescopic principle.
• - thereby using the wind turbine even in strong winds.
• - The centrifugally movable weights in the rotor are created by sliding outwards a larger inherent movement (inertia of the mass) and thus a higher torque.
• - Through the optimized use of leverage due to the telescopic principle additionally increases the torque.
• - The higher the torque the more power (electricity) can removed / generated,
• - Because of the frequent upwards but above all downwards transport of the mobile weights attached to the movable trunk, is due to the recurring Rotation support also during rotation, which improves efficiency.
• - The variation in wind speed is also converted into usable energy converted.
• - The motor can be started by an attached motor.

Explanations to Fig. 1-9

1

windcatcher

2

Wind catcher attachment arms

3

telescopic windscreen mounting arm

4

fixed rotor-bearing trunk

5

movable (rotating) rotor-bearing trunk

6

Aufliegevorrichtung

7

Axial ball bearings

8th

shock absorber

9

Centrifugally movable weight mounted on rollers

10

vertically movable weight

11

transmission

12

generator

13

flexible air tank (bellows)

14

weight Carriage

15

rope

16

Chain

17

toothed belt

18

integrated ball bearing

19

fastening device

20

bulge

21

flange

22

sliding

23

roll

24

vertically movable, embracing the trunk, weight

25

vertically movable weight alternative construction

26

inside

27

outside

28

sensors

29

ring gear

30

wave

31

role

32

gear

33

feather

34

Valve

35

electrically / pneumatically operated motor

36

activatable / deactivatable locking device (backstop)

37

Control unit for changing the gear ratio

38

control unit

39

guide rail

40

bracket

41

activatable / deactivatable locking device for the telescopic extension of the rotor blade or windscreen arm

Claims (41)

1. Centrifugal wind power plant with rotation support for optimized use of wind energy, characterized in that the rotor is equipped with at least one weight movably attached internally in the rotor and / or at least one weight externally on the rotor. This or these movably attached weights are attached in such a way that they move outwards during the rotation phase due to the centrifugal force. Preferably at least 2 or all of the rotor blades or extremities of the rotor or wind catcher / wind catcher arms of the rotor should each be equipped with at least one of these internally and / or at least one of these externally attached movable weights, which move during the rotation phase due to the centrifugal force move outside. (In the further course and in the following claims, these weights are referred to as centrifugally movable weights.)
These centrifugally movable weights are connected via at least one rope and / or chain and / or toothed belt and / or V-belt and / or another mechanical connection with at least one additionally attached gear or an already existing gear (see below), preferably via a shaft emerging from the gearbox, which is equipped with a gear or roller, connected.
At least one essentially vertically movable weight is attached to the movable (rotating) rotor or rotor-bearing trunk.
Inside and / or outside the movable (rotating) rotor- or rotor-carrying trunk there is additionally at least one, preferably two, essentially vertically arranged conveyor belts and / or conveyor chains and / or toothed belts and / or V-belts and / or ropes and / or chains and / or other transport mechanisms attached, which are fixedly or releasably connected to the essentially vertically movable weights, on the movable (rotating) rotor or rotor-carrying trunk. These essentially vertically arranged conveyor belts and / or conveyor chains and / or toothed belts and / or V-belts and / or ropes and / or chains and / or the alternative conveying mechanism is / are constructed and attached in such a way that

• a) in the movement of these conveyor belts and / or conveyor chains and / or toothed belts and / or V-belts and / or ropes and / or chains, and / or the alternative conveying mechanisms, in one direction, the or the substantially vertically movable weight attached to it is / are transported on the rotor or rotor-carrying trunk in such a way that the distance between the ground and this weight or weights increases and / or
• b) they can temporarily be moved in only one direction of rotation. At least one locking device with locking function (backstop) acts in the other direction of rotation. This locking function can be equipped with at least one electrical and / or mechanical control, via which this locking function can be activated and deactivated. If the locking function is deactivated, a freewheel device with a freewheel function or idling function and / or acts in the previous locking direction
• c) there is a connection to at least one gear, to which the centrifugally movable weights are connected, preferably via an additional shaft emerging from the gear which is equipped with a gear or roller.

At least one gear wheel and / or gear rim encompassing the trunk is attached or integrated to the fixed rotor or rotor-bearing trunk. At least one gear is attached to the movable (rotating) rotor- or rotor-carrying stem and / or to the rotor in such a way that it is equipped with at least one gear or roller, preferably via a shaft emerging from the gear and / or, via at least one gear and / or at least one chain and / or at least one toothed belt and / or at least one V-belt and / or another connection for power transmission, is movably connected to the gear and / or gear rim on the stationary rotor or rotor-bearing trunk. This or this gear is additionally, preferably via an additional shaft emerging from the gear which is equipped with at least one gear or roller and / or, via at least one gear and / or roller, with at least one conveyor belt and / or conveyor chain running over it and / or toothed belt and / or V-belt and / or rope and / or chain, and / or another connection for power transmission, to which the / the substantially vertically movable weights are attached to the movable (rotating) rotor or rotor-bearing trunk , connected. 2. Centrifugal wind turbine with rotation support for optimized use of the Wind energy according to claim 1, characterized in that at least one, preferably all, essentially vertically movable weights, on the movable (rotating) rotor- or rotor-bearing trunk, are constructed in such a way that they enclose the movable (rotating) rotor- or rotor-bearing trunk or include. 3. Centrifugal wind turbine with rotation support for optimized use of the Wind energy according to claim 1 and / or claim 2, characterized in that the or the essentially vertically movable weights, on the movable (rotating) rotor- or rotor-bearing trunk, weigh at least 30 kg. 4. Centrifugal wind power plant with rotation support for the optimized use of wind energy according to claim 1 and / or claim 2, characterized in that the or the substantially vertically movable weights, on the movable (rotating) rotor or rotor-carrying trunk, on the inside at least one, preferably two, flanges and / or at least one, preferably two, bulges are attached to which rolling elements are attached or integrated.
Alternatively, the flanges and / or bulges on the sides can be equipped with sliding areas. In connection with claim 13, the flanges and / or bulges, including the rolling elements or sliding areas, are constructed in such a way that they can be inserted into the guide rails. 5. Centrifugal wind turbine with rotation support for optimized use of the Wind energy according to claim 1 and / or claim 2, characterized in that on essentially vertically movable weight, on the movable (rotating) rotor or rotor-bearing trunk, at least one, preferably two, Fastening devices on the top and at least one, preferably two, Fasteners are attached to the bottom. This Fasteners are designed in such a way that at least one on them Rope and / or conveyor belt / conveyor chain and / or toothed belt and / or V-belt and / or chain can be attached. 6. Centrifugal wind turbine with rotation support for optimized use of wind energy according to claim 1, characterized in that

• a) at least one, preferably all, centrifugally movable weights are mounted internally in the rotor and / or externally on the rotor, on at least one rolling element and / or are equipped with sliding areas and / or
• b) sliding areas are mounted internally in and / or externally on the rotor or internally in and / or externally on the rotor blades or windscreen arms or extremities of the rotor, on which the centrifugally movable weights move.

7. Centrifugal wind turbine with rotation support for optimized use of the Wind energy according to claim 1, characterized in that at least one centrifugal movable weight, internally in the rotor and / or externally on the rotor, with one Return mechanism in the form of an attached spring loaded return roller, which is connected to this weight via a rope and / or chain. This return roller is preferably as close as possible to or at the rotor center the rotor blade attachment / wind catcher arm attachment or in one existing gear integrated. The spring-loaded return roll winds due to the Spring force with little or no rotation, the rope or chain attached to it and pulls the movable weight attached to the other end of the rope towards it Rotor center. The spring force of the return roller is dimensioned so that at Rotor standstill or low rotation the centrifugally movable connected with it Weights are pulled as close as possible to the center of the rotor. 8. Centrifugal wind turbine with rotation support for optimized use of the Wind energy according to claim 7, characterized in that each centrifugally movable weight, internally in the rotor and / or externally on the rotor, with one Return mechanism in the form of an attached spring loaded return roller Is provided. This return roll is centrifugal to the rope or chain movable weight connected. 9. The centrifugal wind turbine with rotation support for optimized use of wind energy and substantially vertical axis of rotation according to claim 1 is characterized in that at least one extremity of the rotor (or rotor blade / windscreen / windscreen mounting arm) is attached so that there is a gradient in the direction The center of the rotor is welded on.
This slope towards the center of the rotor is between 0.5 cm and 30 cm per meter. 10. The centrifugal wind turbine with rotation support for the optimized use of wind energy and substantially vertical axis of rotation according to claim 1 is alternatively characterized in that the surface with which the internally and / or externally attached in / on the rotor movable weights come into direct contact, is constructed in such a way that this subsoil at least partially has a slope towards the center of the rotor.
This slope towards the center of the rotor is between 0.5 cm and 30 cm per meter. 11. Centrifugal wind power plant with rotation support for optimized use of wind energy according to claim 1, characterized in that in the upper half of the movable (rotating) rotor or rotor-carrying trunk or on / in the rotor at least one, preferably for each rotor blade or extremity of the rotor or wind catcher / wind catcher arm of the rotor, which is equipped with at least one internally and / or externally attached centrifugally movable weight, at least one deflection roller and / or gear is movably attached.
Alternatively, this deflection roller and / or gearwheel can be attached / integrated in a gearbox. Preferably via a shaft emerging from the gearbox on which this deflection roller and / or gearwheel is fastened. 12. Centrifugal wind power plant with rotation support for optimized use of wind energy according to claim 1, characterized in that in the lower half of the movable (rotating) rotor or rotor-bearing trunk at least one, preferably for each substantially vertically arranged conveyor belt and / or conveyor chain and / or toothed belt and / or rope and / or chain and / or V-belt and / or another conveying mechanism, at least one deflection roller and / or gear is movably attached.
Alternatively, this deflection roller and / or gearwheel can be attached / integrated in / in a transmission. Preferably via a shaft emerging from the gearbox on which this deflection roller and / or gearwheel is fastened. 13. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 is characterized in that the movable (rotating) rotor- or rotor-bearing trunk with at least two essentially vertically running guide rails. These guide rails are like this constructed so that it is essentially weight or vertically movable the movably attached weights, on the movable (rotating) rotor or rotor-bearing trunk, when transported upwards and / or when free and / or controlled fall down, in their given direction. 14. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 13 is characterized in that the Conveyor mechanics to move the or the substantially vertically attached weights on the movable (rotating) rotor or rotor-bearing Trunk to move up or down, is integrated in the guide rails. 15. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 and / or claim 13 and / or claim 14 characterized in that in the lower third of the movable (rotating) rotor  or rotor-carrying trunk at least one flexible air tank is attached to the has at least one opening. 16. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 13 and / or claim 14 and / or claim 15 characterized in that the guide rails are attached such that at least one essentially vertically movably attached weight on the rotor or rotor-carrying trunk is transported down in the manner or in the free and / or controlled case that it moves to at least one, in lower third of the movable (rotating) rotor- or rotor-bearing trunk attached, flexible air container falls. 17. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 15 is characterized in that the or Air tanks are spring loaded in the way that they are after the reduction its volume and subsequent relief, independently again completely or can partially expand into its original form. (Bellows principle) 18. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 is characterized in that the focus and the lever arm (leverage) of the individual rotor blades or extremities of the Rotor or wind catcher arms, in the case of rotors with an essentially vertical axis of rotation, by shifting the centrifugally movably attached weights during the rotation due to the centrifugal force move / slide and thereby at least temporarily shifting at least parts of the rotor blade or Effect the extremity of the rotor or wind catcher arm in the direction of its longitudinal axis and thus enlarge the rotor diameter (enlarge the lever arm) when Operation can be changed. 19. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 18 is characterized in that the rotor is telescopic. 20. The centrifugal wind turbine with rotation support for optimized Use of wind energy according to claim 18 and / or claim 19 is thereby characterized that inside and / or outside of the rotor blades or extremities of the rotor or wind catcher arms, preferably in the first third, at least one activatable and deactivatable locking device is attached, the telescopic extension of the rotor blade or extremity of the rotor or Wind catcher arm enables or prevents. Preferably on the outer third at least one sensor and / or lever and / or button attached to the touch by the centrifugally movable weights or gliding over the centrifugally movable Weights, by means of an electrical and / or mechanical connection, an impulse to the locking device, which thereupon at least the locking function temporarily deactivated and thus the telescopic extension of the rotor blade or Extremity of the rotor or wind catcher arm or rotor enables or releases. 21. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 and / or claim 18 and / or claim 19  and / or claim 20 is characterized in that on the rotor, preferably on the rotor blades or windscreen arms or extremities of the rotor, sensors are attached, the position of at least one, preferably all, centrifugally Movable weights determined and / or the telescopic retraction and extension of the Monitors the rotor. On the moving (rotating) rotor or rotor-bearing trunk there is at least one sensor attached that detects the position of at least one, preferably all, essentially vertically movable weights on the movable (rotating) rotor- or rotor-bearing trunk determined. In addition, at the Wind turbine at least one sensor attached to the Rotation speed determined at least one rotating part of the rotor. 22. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 18 and / or claim 19 and / or claim 20 and / or claim 21 is characterized in that in and / or on the rotor and / or in and / or on the movable (rotating) rotor or rotor-bearing Trunk at least one synchronization device is attached. This Synchronizer is designed to be synchronous Moving apart and / or moving together of the telescopic rotor allows. 23. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 is characterized in that in and / or on Rotor and / or in and / or on the movable (rotating) rotor or rotor-carrying trunk at least one synchronization device is attached, which is designed to move the synchronous movement of at least two, preferably all essentially and internally and / or externally mounted in / on the rotor axially movable weights away from the rotor center and / or to Rotor center possible. 24. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 is characterized in that in the lower third, preferably at the lower end, of the movable (rotating) rotor or rotor-bearing tribe, a gear wheel comprising this tribe and / or Gear rim is attached. 25. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 is characterized in that at least one, preferably all, gearbox is / are designed to be his / her Gear ratio during the rotation of the rotor and / or when the Rotors can change if necessary. 26. The centrifugal wind turbine with rotation support for the optimized use of wind energy according to claim 1 is characterized in that at least one / e gear and / or roller and / or shaft of the transmission, which is connected to at least one essentially vertically arranged conveyor belt and / or conveyor chain and / or toothed belt and / or V-belt and / or rope and / or chain and / or an alternative conveying mechanism on the movable (rotating) rotor or rotor-bearing trunk, is constructed in such a way that it is temporarily intermittent can rotate in only one direction. In the other direction of rotation, at least one locking device (backstop) with a locking function is attached to the shaft or gear or gear. This locking device is equipped with at least one electrical and / or mechanical control, via which this locking function can be activated and deactivated.
If the locking function is deactivated, a freewheel device with a freewheeling function or idling function acts in the previous locking direction. 27. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 is characterized in that the gear and / or roller and / or shaft of the gearbox, which has a direct connection with at least one rope and / or chain and / or toothed belt and / or V-belt and / or another mechanical connection at which the centrifugally movable Weights are internally and / or externally attached to the rotor, constructed in the manner and is equipped that internally in the rotor / rotor blade during the direction of movement or wind catcher arm and / or externally on the rotor / rotor blade or wind catcher arm attached centrifugally movable weights to the rotor center, one Freewheel device with freewheel function or idle function works. 28. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 and / or 25 is characterized in that at least one transmission with variable transmission ratio, preferably all transmissions with variable translation, with at least one electrical and / or mechanical Control unit equipped to change the gear ratio of the transmission is. 29. The centrifugal wind power plant with rotation support for optimized use of wind energy according to claim 28 is characterized in that at least one electrical and / or mechanical control unit for changing the transmission ratio of the transmission is equipped or connected with at least one electrical and / or mechanical control unit attached to the wind turbine is. This control unit is connected via an electrical and / or mechanical connection, in connection with claim 21

• 1. a.) At least one, preferably all, sensors attached to the rotor for determining the position of the centrifugally movable weights in the rotor and / or
• 2. b.) At least one, preferably all, sensors attached to the rotor for monitoring the telescopic retraction and / or extension of the rotor and / or
• 3. c.) At least one, preferably all, attached sensors for determining the rotational speed of at least one rotating part of the rotor, and / or
• 4. d.) At least one, preferably all, sensors attached to the movable (rotating) rotor- or rotor-bearing trunk to determine the position of the essentially vertically movable weight.

30. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 29 is characterized in that the control unit is designed to be dependent on the electrical and / or mechanical  received impulses, the sensors attached to the wind turbine, one or several electrical and / or mechanical pulses to the control unit for change of the gear ratio of the transmission, which thereupon the Gear ratio changes. This control unit is further designed so that it is electrically and / or mechanically variably adjustable when they are in the different combinations of the electrically and / or mechanically received Impulse, the individual sensors attached to the rotor, an impulse, for Increase or decrease the gear ratio of the gearbox to which Control unit for changing the gear ratio of the transmission there. Alternatively, this control unit can be designed in such a way that it can be used by several Control units to change the transmission ratio of the transmission their impulses forwards. 31. Alternatively, the centrifugal wind turbine with rotation support optimized use of wind energy according to claim 1, characterized in that the centrifugally movable weights without gear, but via at least one attached rope and / or chain and / or toothed belt and / or another Connection, with at least one attached pulley and / or gear connected is. At least one of these pulleys and / or gears has one additional connection, preferably via a shaft with at least one additional gear or roller is equipped with at least one inside and / or outside the moving (rotating) rotor or rotor bearing trunk in the essentially vertically arranged conveyor belt and / or conveyor chain and / or Timing belt and / or rope and / or chain and / or V-belt and / or another Transport mechanics. 32. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 is characterized in that at least one Motor on the moving (rotating) rotor- or rotor-bearing trunk or on / in Rotor is attached, which drives at least one gear in such a way that at least one essentially vertically movable weight, on movable (rotating) rotor- or rotor-bearing trunk, upwards is transported. Alternatively, the motor can be mounted so that it directly turns on Conveyor belt / conveyor chain or toothed belt or V-belt or chain or rope in the Way drives that at least one essentially vertically movable attached Weight, on the movable (rotating) rotor or rotor-bearing trunk, after is transported above. 33. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 32 is characterized in that the motor is driven electrically and / or pneumatically. 34. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 is characterized by the attachment of 3 or more rotor blades or extremities of the rotor or wind catcher / wind catcher arms on Rotor, their equipment, function and connections identical to claim 1 and / or claim 18 and / or claim 19 and / or claim 20.   35. The centrifugal wind turbine with rotation support for optimized use The wind energy according to claim 1 is characterized in that the intern and / or externally on the rotor blades or extremities of the rotor or Wind catcher / wind catcher arms attached centrifugally movable weights, in and / or on each rotor blade or extremity of the rotor equipped therewith Wind catcher / wind catcher arm are equally heavy. 36. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 and / or claim 35 is characterized in that that the internally and / or externally on the rotor blades or extremities of the rotor or wind trap / wind trap arms attached centrifugally movable weights, in and / or on each rotor blade or extremity of the rotor equipped therewith Wind catcher / wind catcher arm are identical. 37. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 is characterized by the attachment of several Rotors, their equipment, function and connections identical to claim 1 and / or claim 18 and / or claim 19 and / or claim 20. 38. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 and / or claim 37 is characterized by that additional attachment of one or more conventional rotors (without centrifugal movable weights) with an essentially vertical axis of rotation. 39. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 1 is characterized in that between the movable (rotating) rotor- or rotor-bearing trunk and the fixed one rotor or rotor-bearing trunk shock absorbers are attached. Are preferred the shock absorbers on the support device of the fixed rotor or attached rotor-bearing trunk on which the movable (rotating) rotor or rotor-bearing trunk. 40. The centrifugal wind turbine with rotation support for optimized use the wind energy according to claim 39 is characterized in that the shock absorbers dampen the shock pneumatically and / or hydraulically and / or by spring force. 41. The centrifugal wind turbine with rotation support for optimized use is characterized by all possible combinations of Claims 1 to 40.