DE20019832U1 - Centrifugal wind turbine with pneumatic support for optimized use of wind energy - Google Patents

Description

Eugen Radtke - Buriienstr. 1 - 5£64$ Mcfcenjcjh 300

Description

Centrifugal wind turbine with pneumatic support

The invention relates to wind turbines for the use of wind energy. 310

Conventional wind turbines are equipped with rotors that have a fixed, non-variable, center of gravity.

Their rotors cannot be made larger or smaller during the rotation phase using centrifugal force. The considerable centrifugal forces that occur have so far been neglected in energy generation or used for other purposes.

See patent: DE 195 29 096 Al and DE 40 14 685 Al

My invention is a further development of my patent application no.: 10016513.3 and my utility model no.: 20006113.5.

My invention uses the centrifugal force during the rotation phase to move mass (liquid and/or solid substances)/weights inside and/or outside the rotors and the rotor-supporting trunk.

This centrifugal mass displacement is additionally used to compress air tanks mounted in or on the rotor and/or rotor-bearing trunk according to the bellows principle.

The escaping air is stored in one or more air pressure tanks and, when required, or directly, directed outside the rotor in such a way that the air outlet sets the rotor in motion and/or supports its movement.

Eugen Radtke - Budiengtr. 1 - ^664$ Nicfcenj^hj

Explanation/functional principle:

A balloon filled with air is attached to the end of the rotor blade of a toy wind turbine with a horizontal or vertical plane of rotation. When the mouthpiece of the balloon is opened, the air in the balloon escapes to the outside under pressure. At the same time, the toy wind turbine begins to rotate at a remarkable speed.

My invention works according to this principle.

I gain and use this pneumatic support in my invention by using the existing centrifugal force to compress air with the help of mass/weights and the resulting G-loads and to store it in air pressure containers and, if necessary, direct it outside the rotor or direct it directly outside the rotor.

In the following, the invention according to the claims is explained in more detail by means of examples and with reference to the accompanying drawings.

Basically, this principle can be implemented in three different ways. 1. (see claim 1) Axially movable weights (Figure 1 item 3) and flexible (see claim 6) air tanks (Figure 1 item 28) are mounted inside the rotor. During rotation of the wind turbine, the weights move away from the rotor center due to centrifugal force and thus press the attached air tanks together.

The escaping air is pressed into an air pressure container (Figure 1 item 36) and/or guided to the outside via an air outlet nozzle (Figure 1 item 37) which is attached to the outer end of the rotor blade/wind catcher (Figure 1 item 1). The return of the weights towards the rotor center, with decreasing rotation and resulting decreasing centrifugal force, takes place via a spring-loaded return roller (Figure 2 item 6) and/or by means of an attached gradient towards the rotor center (Figure 2, see claims 29 and 30).

If required (Figure 1,2 item 33, claim 23), the air is led into the compressed air tank via the air outlet opening (Figure 1 item 37) from the rotor in such a way that the rotor is set in motion and/or supported in its movement by the air outlet.

Eugen Radtke - Buphenstr. 2 - 5j

This additional rotation support optimizes the use of wind energy.

Mathematically speaking, this looks like this:

One of the axially movable weights (Figure 1 item 3) has a weight of 30 kg (m).

The rotor blade/wind catcher mounting arm (Figure 1 item 2) 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
Gravity : Ig = 9.81
Gravitational acceleration: 9.81 m/s ²
Fz = mxv ² :r =30x3 ² : 8 = 33.75

33.75 : 9.81 = 3.44g

This means that the existing air in each rotor blade/wind catcher mounting arm designed in this way (Figure 1, item 2) is pressed into the air pressure tanks with an impressive 3.44 G load and/or directed directly outside the rotor.

2. (see claim 2) The weights axially movable inside the rotor (Figure 4) are connected to the weights movably mounted on the rotor-bearing stem (Figure 4 item 41 and Figure 3 item 41).
Flexible air tanks are attached to the lower end of the trunk (Figure 3, item 28 and Figure 4, item 28). During the rotation of the wind turbine, the axially movable weights in the rotor move away from the center of the rotor due to centrifugal force and thus transport the movably attached weight on the trunk (Figure 4, item 41 and Figure 3, item 41) upwards via a conveyor belt (Figure 3, item 40, claim 13) or via a rope or chain (Figure 4, item 4). According to claims 9, 10 and 11, it is expedient to attach a gear between the weights in the rotor and the weights on the trunk (Figure 4, item 38). By means of an electromagnetic release device (Figure 3, item 42), the weights on the trunk separate from the conveyor belt (Figure 3, item 40) and fall onto the flexible air tanks attached below (Figure 3, item 28). However, it is also possible that

Eugen Radtke - Buphenstr. 2 - 5§5643 Nic&enjoji j

the weights attached to the trunk are transported upwards without a conveyor belt construction, only by means of an intermediate gear (Figure 4), and are allowed to fall onto the air tanks by means of a switchable freewheel/idle function (claim 10), as described in Figure 4. The escaping air is pressed into an air pressure tank (Figure 3 item 36 and Figure 4 item 36) and/or guided outwards via an air outlet nozzle (claim 22, Figure 3 and 4 item 37) which is attached to the outer end of the rotor blade/wind catcher. The return of the weights towards the rotor centre, with decreasing rotation and resulting decreasing centrifugal force, takes place by means of an attached gradient towards the rotor centre (Figure 3, see claims 29 and 30). If required (claim 23), the air in the compressed air tank is led out of the rotor via the air outlet opening (Figure 3,4,5 item 37) in such a way that the rotor is set in motion and/or supported in its movement by the air outlet.

This additional rotation support optimizes the use of wind energy.

Mathematically speaking, this looks like this:

The weights movably attached to the rotor-bearing trunk (Figure 4 Item 41 and Figure 3 Item 41) have a weight of 100 kg (m).
Weight force formula: G = m &khgr; g

Gravity : Ig = 9.81

Gravitational acceleration: g = 9.81 m/s ²

Centrifugal force formula: Fz = m × ν ² . r

Using the centrifugal force formula and an intermediate gear, the weights movably attached to the rotor-supporting trunk (Figure 4, item 41 and Figure 3, item 41) are moved upwards in the rotor by means of the axially movable weights (Figure 4). If this weight falls onto the weights attached to the trunk due to the activated idle function (claim 10), the following formula applies.

Weight force formula: G = m × g = 100 × 9.81 =981 430

This means that the existing air is pressed into the air pressure tanks with an enormous weight due to the acceleration due to gravity and/or is directed directly outside the rotor.

Eugen Radtke - Bitfhenstr. £ - 3664$ Mcjcerp<jh ·

3. (see claim 15) Inside the rotor, the axially movable weights are equipped with valves that function according to the air pump principle (Figure 6 and 7 item 35). During rotation of the wind turbine, the weights move away from the rotor center due to centrifugal force and thus press the air in the wind catcher mounting arm cavity/rotor blade cavity into an air pressure container (Figure 6 and 7 item 36) and/or directly outside the rotor. When the rotation decreases and the centrifugal force decreases as a result, the weights are returned towards the rotor center via a spring-loaded return roller (Figure 6 item 6) and/or by means of an attached gradient (Figure 6 and 7, see claims 29 and 30). The valves attached to the weights open and the wind catcher mounting arm cavity/rotor blade cavity fills with air again. If required (Figure 6.7 item 33, claim 23), the air is led into the compressed air tank via the air outlet opening (Figure 6.7 item 37) from the rotor in such a way that the rotor is set in motion and/or supported in its movement by the air outlet.

This additional rotation support optimizes the use of wind energy.

Mathematically speaking, this looks like this:

One of the axially movable weights (Figure 6.7 item 3) has a weight of 30 kg (m). The rotor blade/wind catcher mounting arm (Figure 6.7 item 2) 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

Gravity : Ig = 9.81
Gravitational acceleration: 9.81 m/s ²

Fz = m &khgr; v ² : r = 30 &khgr; 3 ² : 8 = 33.75

33.75 : 9.81 = 3.44g

This means that the existing air in each rotor blade/wind catcher mounting arm constructed in this way (Figure 6,7 point 2) is pressed into the air pressure tanks and/or directed directly outside the rotor with an impressive 3.44 G load of the weight.

EugenRadtke-Buchenstr'2-56645:Nicl«2nipii ···. ···« * · · · ·

Explanations of the other claims:

Claim 3 describes that there must be a direct connection with the essentially axially movable weight and the air tank (Figure 1,2 items 3 and 28).

Claim 4 determines the direction of movement of the weight so that compression of the air tank is ensured (Figure 1,2,4 items 3 and 28).

Claim 5 ensures that when the essentially axially movable weight is returned to the rotor center, the air tank unfolds again and its volume increases (fills up with air again). In doing so, it pulls the air tank apart again through the existing connection (Figure 1,2 points 3 and 28). This is generally applicable when the air tanks are not spring-loaded and do not unfold again on their own.

Claims 6 and 31 describe the technical requirements for the functionality of the air tanks according to the bellows principle (Figure 1, 2, 3, 4, 5 points 28,29).

Claim 7 leaves open the possibility of any openings in the air tank and their possible attachments.

Claim 8 enables the combination of several different rotors on one trunk. E.g.: rotors according to Figures 2, 3 and 7 on one trunk.

Claims 9, 10 and 11 describe the attachment, equipment and functioning of the transmission (Figure 4 item 38).
495

Claim 12 describes the attachment and construction of the guide rails (Figure 5 item 43).

Claim 13 describes the alternative possibility of transporting the weights attached to the trunk via a conveyor belt (Figure 3 item 40).

Eugen Radtke - Buehensfr.»2 - 56645 Nifkepieh ·

Claim 14 describes the equipment and functioning of the conveyor belt (Figure 3 item 40).
505

Claim 16 describes the attachment and functioning of the triggering device (Figure 3 item 42).

Claim 17 ensures that the weights movably attached to the rotor-bearing trunk strike the flexible air containers during fall and/or transport downwards (Figure 3,4,5 item 28).

Claims 18 and 19 open up the possibility of integrating the compressed air tanks into the movably mounted weights due to their own weight (Figure 2,3,4,6,7 item 36).

Claim 20 relates to the installation of the compressed air tanks outside and/or inside the wind turbine (Figure 1 item 36).

Claim 21 refers to the possibility of the air being led directly to the outside, without intermediate storage in the compressed air tank.

Claim 22 relates to the position and manner of mounting the air outlet opening/nozzle in order to accommodate the functioning of the recoil principle.

Claim 23 relates to the valve connection to the air pressure vessel and the functioning of the attached valve control (Figure 1,2 item 33).

Claims 24 and 25 refer to the interaction of the transmission control, the control unit and the sensors attached to the rotor (Figure 1-7, item 7) and thus open up the possibility of adjusting the transmission ratio (Figure 4, item 38) based on the position of the weights (Figure 2,4, item 3) and/or the position of the retractable and/or extendable rotors (Figure 4, 7, 8, item 18) and/or the rotation speed of the rotor.

Eugen Radtke - BufihenStr. *2 - 56645 Ni&eijiph ; ··*· ···· ··· «·· ·· ..

There is the option of using a control unit to address all or several gearboxes, which then change their gear ratio.

Claim 26 relates to the retractable and/or extendable rotors (Figure 4, 7, 8 item 18), which can increase their diameter with increasing speed and thus increasing centrifugal force.

Claims 27 and 28 relate to the installation of a synchronization device to avoid imbalances during the rotation phase (Figure 8).

Claim 29 relates to an attached incline of the rotor blades/wind catcher arms in the direction of the rotor center, in the horizontally attached rotor, in order to enable or support the automatic return of the retractable and/or extendable rotors (Figure 4, 7, 8 item 18) and the attached essentially axially movable weight (Figure 2,4 item 3) when the rotation and thus the centrifugal force decrease.

Claim 30 relates to an attached gradient of the substrate of the essentially axially movable weight (Figure 2.4 item 3) in the direction of the rotor center in order to enable or support the automatic return of the attached essentially axially movable weight (Figure 2.4 item 3) when the rotor is mounted horizontally, with decreasing rotation and thus decreasing centrifugal force.

(They will then roll back to their original position.) 560

Claim 32 relates to the different possible combinations of claims 1 to 31.

E.g.:

Figure 4 = Combination of claims
1,2,4,6,7,9,10,11,12,17,18,22,23,24,25,26,27,28,29,30 and 31.

Figure 2 = Combination of claims

1,3,4,5,6,7,19,20,21,22,23,28,29,30 and 31.

Eugen Radtke - Buchenste* 2 - 56645»NicKenfcii J

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

■ optimized use of wind energy

■ pneumatic rotation support based on the recoil principle (compressed air) ■ thereby generating a higher torque, which can be converted into electrical energy

■ The air stored in the pressure vessel can be directed outside if necessary in order to keep the rotation speed of the rotor constant at least temporarily in light winds. This has the advantage of a constant power reduction in temporarily light winds.

■ When the rotor is stationary and the wind is light, the air stored in the pressure vessel can be directed outside if necessary to generate an initial speed. This has the advantage that the light wind has an easier time keeping the rotor moving due to the subsequent movement of the rotor (inertia of the mass). Reason: It takes significantly more energy to set a stationary rotor in motion than to support the movement of a rotating rotor.

■ This means that a lower wind speed is required for minimum operation.

Eugen Radtke - BuöhensVr. 1 - 56645 Ni&eeich

16 Explanations for Figure 1-8

1 Windcatcher

2 wind catcher mounting arms

3 weight mounted on rollers

4 Fastening rope

5 Weight holder

6 Spring-loaded return roller

7 Windcatcher mounting arm and weight position detection sensors

8 Support device

9 Axial ball bearings

10 rotating wind catcher mounting sleeve (see also 22) 11 fixed holding device (see also 21)

12 Gear ring

13 electric/ mechanical transmission

14 Wave

15 Generator

16 extension limiters

17 fixed wind catcher arm

18 retractable/extendable wind catcher arm

19 inward curved wind catcher

20 outward-curving wind catcher 21 fixed rotor-bearing trunk

22 rotating rotor-bearing trunk

23 Gearbox mount

24 roll holders

25 Return spring
26 Brackets

27 Gear

28 flexible air tank (bellows)

29 Spring

Eugen Radtke - Buehenstr.»2 - £664*> Ni|kepiph ·

30 Line for air flow towards air outlet opening

31 Line for air flow towards pressure vessel

32 Bypass line

33 electrical/ mechanical valve control

34 pressure gauge

35 Valve

36 Pressure vessel in which the compressed air is stored

37 Air outlet opening/nozzle

38 Gearbox with control and regulation unit

39 pulley

40 Conveyor belt

41 Weight

42 Electromagnet (triggering device)

43 Guide rail

·

Claims (31)

1. The centrifugal wind turbine with pneumatic support is characterized in that the rotor is equipped with at least one essentially axially movable weight attached internally in the rotor and/or at least one externally on the rotor and with at least one air tank attached internally in the rotor and/or at least one externally on the rotor in a fixed or detachable manner.
The volume of this or these air tanks can be varied by means of the essentially axially movable weight mounted internally and/or externally in/on the rotor. 2. The centrifugal wind turbine with pneumatic support is characterized in that at least one air tank and one or more movably mounted weights are attached to the rotor or rotor-supporting stem. This movably mounted weight or these movably mounted weights on the rotor or rotor-supporting stem are connected directly and/or indirectly via a rope and/or a chain and/or another connection to at least one essentially axially movable weight attached internally in the rotor and/or at least one externally on the rotor. 3. The centrifugal wind turbine with pneumatic support according to claim 1 is characterized in that at least one air tank mounted internally in the rotor and/or at least one air tank mounted externally on the rotor is fixedly or detachably connected to at least one essentially axially movable weight mounted internally and/or externally in/on the rotor. 4. The centrifugal wind turbine with pneumatic assistance according to claim 1 is characterized in that at least one substantially axially movable weight mounted internally and/or externally in/on the rotor, upon sufficient rotation, moves outward in such a way that at least one air tank mounted internally in the rotor and/or at least one air tank mounted externally on the rotor is compressed so as to reduce its volume. 5. The centrifugal wind turbine with pneumatic assistance according to claim 1 is characterized in that at least one air tank mounted internally in the rotor and/or at least one externally on the rotor is connected to at least one substantially axially movable weight mounted internally and/or externally in/on the rotor and is designed in such a way that it increases its volume as soon as one or more of these substantially axially movable weights mounted internally and/or externally in/on the rotor move towards the rotor center. 6. The centrifugal wind turbine with pneumatic support according to claim 1 and/or claim 2 is characterized in that at least one air tank internally in the rotor and/or externally on the rotor and/or at least one air tank on the rotor or rotor-bearing stem is/are completely and/or partially flexible. 7. The centrifugal wind turbine with pneumatic support according to claim 1 and/or claim 2 is characterized in that the air container(s) have at least one opening in which at least one valve and/or at least one nozzle and/or at least one hose and/or at least one component is fastened and/or can be fastened by means of an attached receiving device. 8. The centrifugal wind turbine with pneumatic assistance is characterized by the combination of several rotors according to claim 1 and/or claim 2 and/or claim 15. 9. The centrifugal wind turbine with pneumatic support according to claim 2 is characterized in that at least one essentially axially movable weight attached internally in the rotor and/or at least one externally on the rotor and at least one movably attached weight on the rotor or rotor-bearing stem are connected to one another via at least one gear. 10. The centrifugal wind turbine with pneumatic support according to claim 9 is characterized in that the gear or gears are designed in such a way that they can only rotate in one direction at times and at least one attached locking device with a locking function (backstop) acts in the other direction of rotation. This locking device is equipped with at least one electrical and/or mechanical control via which this locking function can be activated and/or deactivated.
If the locking function is deactivated, a freewheel device with a freewheel function or idle function operates in the previous locking direction. 11. The centrifugal wind turbine with pneumatic assistance according to claim 9 is characterized in that at least one transmission is equipped with at least one electrical and/or mechanical control unit for changing the gear ratio of the transmission. 12. The centrifugal wind turbine with pneumatic support according to claim 2 is characterized in that the rotor or rotor-bearing trunk is equipped with at least two vertically extending guide rails.
These guide rails are designed to guide the movably attached weight or weights on the rotor or rotor-bearing trunk in their specified direction during transport upwards and/or during free and/or controlled fall downwards. 13. The centrifugal wind turbine with pneumatic support according to claim 2 is alternatively characterized in that at least one conveyor belt is mounted in the rotor or rotor-bearing trunk, which is directly and/or indirectly connected, fixedly or detachably, to at least one movably mounted weight on the rotor or rotor-bearing trunk.
Of these, at least one conveyor belt is mounted in such a way that, when the conveyor belt moves in one direction, at least one movably attached weight on the rotor or rotor-bearing trunk is temporarily conveyed in such a way that the distance between the ground and this weight or these weights increases. 14. The centrifugal wind turbine with pneumatic support according to claim 13 is characterized in that the conveyor belt(s) can temporarily move in only one direction of rotation.
In the other direction of rotation, at least one attached locking device with locking function (backstop) acts.
This locking function is equipped with at least one electrical and/or mechanical control via which this locking function can be activated and/or deactivated. If the locking function is deactivated, a freewheel device with a freewheel function or idle function is activated in the previous locking direction. 15. The centrifugal wind turbine with pneumatic support is alternatively characterized in that one or more seals and/or one or more valves are attached to at least one essentially axially movable weight attached internally in the rotor. This or these attached valves are designed and attached in such a way that they close according to the air pump principle when one or more essentially axially movable weights attached internally in the rotor are moved away from the rotor center and open when one or more essentially axially movable weights attached internally in the rotor are moved towards the rotor center.
At least one air outlet opening is provided on the rotor, preferably at the outer ends of the rotor, through which the air can escape directly. Alternatively, the escaping air can be directed into an attached pressure-resistant container for storing the compressed air. 16. The centrifugal wind turbine with pneumatic support according to claim 13 is characterized in that at least one movably attached weight on the rotor or rotor-bearing stem is equipped with at least one electrical and/or mechanical triggering device.
This release device is designed in such a way that when the release mechanism is activated, this or these weights temporarily separate from the conveyor belt. 17. The centrifugal wind turbine with pneumatic support according to claim 2 and/or claim 12 and/or claim 16 is characterized in that at least one movably attached weight on the rotor or rotor-bearing trunk is transported downwards or moves downwards in free and/or controlled fall such that it falls onto at least one air tank attached to the rotor or rotor-bearing trunk. 18. The centrifugal wind turbine with pneumatic support according to claim 2 is characterized in that at least one pressure-resistant container for storing compressed air is integrated in at least one weight movably attached to the rotor or rotor-bearing stem, and the escaping air from at least one air container attached to the rotor or rotor-bearing stem is fed to this via at least one hose and temporarily stored there. 19. The centrifugal wind turbine with pneumatic support according to claim 1 and/or claim 2 and/or claim 15 is alternatively characterized in that at least one pressure-resistant container for storing compressed air is integrated in at least one essentially axially movable weight attached internally in the rotor and/or at least one externally on the rotor, to which the escaping air from at least one air container attached internally in the rotor and/or at least one externally on the rotor and/or the escaping air from at least a part of the rotor cavity is fed via at least one attached hose and/or at least one attached valve and is temporarily stored there. 20. The centrifugal wind turbine with pneumatic support according to claim 1 and/or claim 2 and/or claim 15 is alternatively characterized in that at least one pressure-resistant container for storing compressed air is mounted in and/or on the rotor or rotor-bearing stem and/or in and/or on the rotor, to which the escaping air from at least one air container mounted internally in the rotor and/or at least one externally on the rotor and/or the escaping air from at least a part of the rotor cavity is fed via at least one attached hose and/or via at least one attached valve and is temporarily stored. 21. The centrifugal wind turbine with pneumatic assistance according to claim 1 and/or claim 2 and/or claim 4 and/or claim 15 and/or claim 17 is alternatively characterized in that the escaping air from at least one air tank mounted internally in the rotor and/or at least one air tank mounted externally on the rotor and/or the escaping air from at least a portion of the rotor cavity and/or the escaping air from at least one air tank mounted on the rotor or rotor-supporting stem is directed via at least one mounted air outlet opening on the rotor and/or via at least one mounted valve and/or via at least one mounted nozzle on the rotor and/or via at least one mounted hose outside the rotor. 22. The centrifugal wind turbine with pneumatic support according to claim 1 and/or claim 2 and/or claim 15 is characterized in that at least one air outlet opening and/or at least one valve and/or at least one nozzle is mounted on at least one outer end of the rotor and/or in the last outer third of at least one end of the rotor (or rotor blade/wind catcher/wind catcher mounting arm) in such a way that the opening or openings are located substantially opposite to the direction of rotation of the rotor. 23. The centrifugal wind turbine with pneumatic support according to claim 18 and/or claim 19 and/or claim 20 is characterized in that at least one pressure-resistant container in which the compressed air is temporarily stored is connected directly and/or via at least one hose to at least one valve. At least one of these valves is equipped with at least one electrical and/or mechanical control via which this valve can be fully or partially opened and/or fully and/or partially closed. This valve or these valves is/are connected via at least one hose or directly to at least one air outlet opening and/or at least one valve and/or at least one nozzle on the rotor. 24. The centrifugal wind turbine with pneumatic support according to claim 11 is characterized in that at least one electrical and/or mechanical control unit for changing the gear ratio of the transmission is equipped with an electrical and/or mechanical, externally or internally mounted control unit. This control unit is connected via an electrical and/or mechanical connection to 1. a.) at least one sensor attached to the rotor for determining the position of the essentially axially movable weights in the rotor and/or 2. b.) in conjunction with claim 26, with at least one sensor attached to the rotor for monitoring the telescopic retraction and/or extension of the rotor and/or 3. c.) connected to at least one attached sensor for determining the rotational speed of at least one rotating part of the rotor. 25. The centrifugal wind turbine with pneumatic support according to claim 24 is characterized in that the control unit is designed in such a way that, depending on the electrically and/or mechanically received pulses from the sensors attached to the rotor, it sends one or more electrical and/or mechanical pulses to the control unit for changing the gear ratio of the transmission, which then changes the gear ratio. This control unit is further designed in such a way that it is electrically and/or mechanically variably adjustable when, for the different combinations of the electrically and/or mechanically received pulses from the individual sensors attached to the rotor, it sends a pulse to the control unit for changing the gear ratio of the transmission to increase or decrease the gear ratio of the transmission. Alternatively, this control unit can be designed in such a way that it simultaneously transmits its pulses to several control units for changing the gear ratio of the transmission. 26. The centrifugal wind turbine with pneumatic assistance according to claim 1 and/or claim 2 and/or claim 15 is characterized in that the rotor or rotors are telescopic and, with sufficient rotation, move outwards and thus change the size of the rotor diameter(s). 27. The centrifugal wind turbine with pneumatic support according to claim 26 is characterized in that at least one synchronization device is mounted in and/or on the rotor and/or in and/or on the rotor or rotor-bearing stem. This synchronization device is designed in such a way that it enables the telescopic rotor to move apart and/or into one another synchronously. 28. The centrifugal wind turbine with pneumatic support according to claim 1 and/or claim 2 and/or claim 15 is characterized in that in and/or on the rotor and/or in and/or on the rotor or rotor-bearing stem at least one synchronization device is mounted, which is designed to enable the synchronous movement of at least two substantially axially movable weights mounted internally and/or externally in/on the rotor away from the rotor center and/or towards the rotor center. 29. The centrifugal wind turbine with pneumatic assistance according to claim 1 and/or claim 2 and/or claim 15 is characterized in that at least one extremity of the rotor (or rotor blade/wind catcher/wind catcher mounting arm) is mounted such that it has a gradient towards the rotor center.
This applied gradient towards the rotor center is in the range between 0.5 cm and 30 cm per meter. 30. The centrifugal wind turbine with pneumatic support according to claim 1 and/or claim 2 and/or claim 15 is characterized in that the ground with which the substantially axially movable weights mounted internally and/or externally in/on the rotor come into direct contact is constructed in such a way that this ground at least partially has a gradient towards the center of the rotor.
This applied gradient towards the rotor center is in the range between 0.5 cm and 30 cm per meter. 31. The centrifugal wind turbine with pneumatic support according to claim 1 and/or claim 2 is characterized in that at least one air tank is spring-loaded in such a way that after the reduction of its volume and subsequent relief it can automatically expand completely or partially back to its original shape.