DE102008046117A1 - Vertical wind power plant for use as periodic work machine for converting wind energy into mechanical operation, has circular rope path constructions guided between pylon at wheels, at which carrier surfaces are fixed at ropes - Google Patents

Abstract

The plant has adjustable carrier surfaces (6) that convert wind energy. The carrier surfaces provided with a rotation axis are fixed at a circular base at both sides. The circular base consists of linear movable, circular rope path constructions, which are guided between a pylon (9) at upper and lower deflection wheels (3), at which the carrier surfaces are fixed at a guiding rope (1) and a power rope (2) of the constructions. The carrier surfaces drive the ropes front and back in a preferred direction. Sensors are provided at the surfaces for calculating flow conditions of the plant. The guiding rope and the power rope are designed as carbon fiber ropes.

Description

The The invention relates to a vertical wind turbine with adjustable, power-generating, wind-energy transforming wings, in the installation position with its axis of rotation vertical, adjustable to circumferential Ropes are attached. This is the first time fossil fuels be adequately replaced by wind energy, as this plant replaced a whole wind farm, while maintaining established, cost-effective Technology is used.

The previously used industrial wind turbines are almost all equipped with rotors, the design can be made only up to a certain rotor diameter. Rotor diameters of more than 100 m require a disproportionately high and uneconomical effort. However, the profitability of a wind turbine depends to a considerable extent on the exploitable, flow-through surface. Wind turbines in the order of magnitude of double-digit megawatt power can only be realized with rotor technology as a wind farm, all of which have known technical problems. A wind turbine that replaces an entire wind farm and could also be cheaper to build can be considered a technical leap. The inventive step is to counteract the structural disadvantages of the rotors while maintaining the buoyancy-generating features such that the rotor is cut and arranged in a frame fore and aft, whereby a rotational movement becomes a linear movement. Technically implemented this idea according to the invention by established cable railway technology. The design features of rope constructions (eg suspension bridges) allow the construction of structures of the largest possible dimensions. Thus, it is easily possible to build spans of 500 m and more and pylon heights of 100 m and higher. The wings stretched between them in an optimal setting result in 100,000 m ^{2 of} surface area, 50,000 m ² each for flow and return, which corresponds to a power output of 15 of the largest commercially available wind turbines (V 90). Dividing the rotor into several segments provides another physical advantage in lift and power draw. The linear movement of the wings avoids the blade tip speed resistance, which causes significant power losses in rotors.

Of Further, by the variety of angles of attack Flow conditions are optimally adapted and optimal for different wind speeds Conditions are created, which in rotor designs is excluded by their rigidity and only for one Speed can be optimized.

In the DE 102 24 32 4 A1 is referred to a vertical rotor with steerable wings. In the construction mentioned, the angle settings are realized by means of push rods, the resulting force causing a rotational movement about an axis of rotation. Although this construction has freely adjustable wings, its design is subject to the constraints of a single-axis design, albeit vertically. The currently possible, computerized sensor technology (mechatronics) enables a cost-effective and precise (stall) stall calculation, which is used according to the invention in each wing, so that a technical maximum lift can be calculated. Future developments in the stable calculation can easily be incorporated here, as the flexibility of the wing ensembles allows this. Rotor blades have no further innovation potential due to their rigidity. Because of the increasing peripheral speed with the rotor length along the rotor blades, the load of the rotor blade increases continuously along its length, up to the load limit of the material used, which is avoided in this construction due to the linear movements. With increasing wind speeds, the rotors must therefore be braked or placed at an angle out of the wind to avoid the destruction of the plant. Particularly vulnerable are the rotor blades, as well as the top of the tower hard to reach gearbox. Damage to these components therefore leads to total damage to the system. (Source: Cost-effectiveness reports on depreciation of wind farm funds) The ratio of high torques to relatively low input speeds for rotor systems generates high loads. In the solution presented here, however, a favorable gear coupling is possible, it can be dispensed with complex converter technology, because the cable speed can be kept constant. Likewise, the acoustic load is reduced many times because no Blatttitzenüberschallgeschwindigkeiten be achieved.

The invention relates to a wind turbine, designed as a periodic, not rotating about a central axis working machine for the conversion of wind energy into mechanical work, which is obtained in the form of circulating linear motion. Characteristics of this plant are: First, the absence of a central axis and Second, the exclusively linear movement of the power-generating wings ( 6 ) and third, the ability of these wings ( 6 ) during the return, by changing the angle of attack by means of servomotors ( 13 ), again force-generating effect to unfold. Taking advantage of the buoyancy and output forces by means of several, angle-adjustable wings ( 6 ) - the narrow side above and below on endless ropes ( 1 / 2 ) are attached by cable cars, wherein a servomotor ( 13 ) in the upper end of each wing ( 6 ) and over the wire ropes ( 1 / 2 ) is supplied with the operating voltage - the movement of "buoyancy generating" volume flows (here wind) is converted into linear motion. Power transmission, the movement caused by buoyancy, on the ropes ( 1 / 2 ) is carried out by means of modified nacelle group holders ( 12 ), since the wings ( 6 ) the same loads on the ropes ( 1 / 2 ) transferred as gondola groups in passenger cable cars. These loads are according to the invention the driving forces of the cables ( 1 / 2 ). Moreover, according to the invention a second nacelle group holder is used, so that the stability is ensured and the driving forces better on two ropes ( 1 / 2 ). This linear movement is converted into electrical energy.

The system consists of at least two monobloc group cocks (cable cars) mounted one above the other at a maximum distance between two steel cables ( 11 ) guyed pylons ( 9 ) are mounted. The distance of the pylons ( 9 ) should be, according to the dimensions of cable cars and suspension bridges, to the maximum length, with one of the pylons ( 9 ) the generator units ( 5 ) - at least one per (upper and lower) deflection wheel ( 3 ), While at the other the rope tensioning devices ( 4 ) and deflection wheels ( 3 ) of the cableway technology are attached.

Instead of the gondola groups perform between the ropes ( 1 / 2 ) of the cable cars at the gondola group holders ( 7 ) mounted, upended, aerodynamically shaped wings ( 6 ) - designed in lightweight construction from sections - a linear circulation, the wings ( 6 ) the volume flow ( 8th ) always turn to the same angle-adjustable narrow side. The gondola group holders ( 12 ) are modified in such a way that they are connected to the drive shaft of the drive-adjusting angle of attack in the wing (FIG. 6 ) built-in servo motor ( 13 ) are flanged. The use of servomotors ( 13 ) allows a smooth 90 ° rotation of the wings ( 6 ) during the 180 ° rotation on the pulleys ( 3 ), so that the optimal wing position is also possible in the return. The power supply of the servomotors ( 13 ) is replaced by the upper ( 2 ) and lower ( 1 ), endless guide rope ( 1 / 2 ), which also for the RF frequencies of, the wing ( 6 ) also extending lengthwise, data lines ( 19 ) be used.

These data lines ( 19 ) connect 4 rows of stall sensors ( 14 ) which are on both sides of the wing ( 6 ) in the front and rear over the entire length of each wing ( 6 ) and according to the invention information about flow state and imminent stall to a likewise in each wing ( 6 ) contained microprocessor ( 17 ) - with this microprocessor ( 17 ), which on the one hand the control lines of the servomotor ( 13 ) and on the other hand via the circulating cables ( 1 / 2 ) communicates with a central computer, so that on the one hand always stable can be calculated, on the other hand the control becomes internet-enabled. A data bus with TCP / IP protocol ( 19 ).

The at the upper and lower pulleys ( 3 ) electric motors connected below the systems ( 5 ) act as motors at the start of the system and are later replaced during operation by switchable generators ( 5 ) or as generators ( 5 ) operated. The system is made stable according to the rules of technology (eg bracing). Should, due to the different force on the wings ( 6 ), give different cable positions, the generators ( 5 ) if necessary by means of "electrical wave" (resolver) communicate. There are achievements in the double-digit megawatt range possible, due to dimension due to the largest possible flow areas. According to the invention, the support-producing airfoils are symmetrical designs of the NACA specifications, which are calculated with optimized flow at their narrow ends. The design of the pressure sensors ( 14 ) is calculated in accordance with the specification of the aircraft construction. The combination ( 7 ) from servomotors ( 13 ) and gondola group holders ( 12 ) are in accordance with the invention [ 1.1 ] and [ 1.1.1 ] produce.

Servomotors ( 13 ) with high torque allow the even 90 ° rotation of the wings ( 6 ) during the 180 ° rotation on the pulleys ( 3 ), so that the optimal hydrofoil adjustment is also possible in return. The wings ( 6 ) are composed in lightweight construction of sections.

A system replaces an entire wind farm with one-off installation and transport costs. Returning surfaces are also buoyant, doubling the area flowed through. The offshore capability of the system is another conceived area of application that can be made economically feasible by pontoon assembly and cable guying without expensive foundations on the seabed. Floodable pontoons and rope anchoring, or the use of unprofitable ships allow easy position changes and reduce costs. Low susceptibility to corrosion and soiling by applied ropeway technology, on the pulleys ( 3 ), the wings ( 6 ) are serviced and cleaned. Easily exchangeable components The cost of repairs is due to the use of sophisticated circulating ropeway technology. The principle of the modular system, including the wings ( 6 ), avoids heavy transport. Self-supporting wings ( 6 ) each of which is controlled by its own optimal angle of attack by microprocessor ( 17 ) controlled sensors ( 14 ) and adjustment electronics in each wing ( 6 ), as well as the data storage / processing for a Windantizipator "Computer Thinking Forward", a central computer assumes the prediction for coarse adjustment of each single wing ( 6 ). Bidirectional equal running direction depending on the wind direction is possible, the system is not rotatable about an axis. There is a proportional increase in performance by increasing the number of wings.

A further embodiment of the invention provides, the circulating cables ( 1 / 2 ) as carbon fiber cables to increase the possible spans and to the sagging of the circulating cables ( 1 / 2 ) to reduce. Another embodiment of the invention provides to mount the system on floating pontoons, which are partially floodable. Another embodiment of the wings ( 6 ) provides to make them inflatable and provided with a flexible surface, for. B. Artificial silk. A further embodiment of the invention provides, the plant around the center of their pylons ( 9 ) to be mounted under bridges without obstructing the passageway. Another embodiment of the wings ( 6 ) envisages fanning them out according to findings of bionics on the narrow-side wing ends.

1 Sketch of the wind turbine

1.1 Support surface with servomotor, stabilizer, power & data line, microprocessor

1.1.1 Wing sensors, engine section

1

Führungsseil unten

2

Kraftseil oben

3

Umlenkräder

4

Seilspannvorrichtung

5

Antriebs- und Generatoreinheiten

6

Tragfläche

7

Anstellwinkel Einstelleinheit (Stabilisator und Servomotor mit Elektronik)

8

Hauptwindrichtung

9

Pylone

10

Seilstütze

11

Abspannung

v

zur Verdeutlichung angenommene Bewegungsrichtung

2 Top view variant more wing (s)

1

Guide rope below

2

Power cable above

3

guide wheels

4

Rope tensioner

5

Drive and generator units

6

wing

7

Angle adjustment unit (stabilizer and servomotor with electronics)

8th

Prevailing wind

9

pylons

10

cable support

11

guying

v

assumed direction of movement

12

Stabilisator (modifizierter Gondelgruppenhalter)

13

Servomotor

14

Sensoren (4 Reihen)

15

Datenleitungen

16

Steuerleitungen

17

Mikroprozessor

18

Stromleitungen

19

Datenleitung HF Signal ( ISA-Bus TCP/IP )

1.1 Support surface with servomotor, stabilizer, power & data line, microprocessor

12

Stabilizer (modified nacelle group holder)

13

servomotor

14

Sensors (4 rows)

15

data lines

16

control lines

17

microprocessor

18

power lines

19

Data line HF signal ( ISA bus TCP / IP )

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• DE 10224324 A1 [0004]

Cited non-patent literature

• - ISA Bus TCP / IP [0012]

Claims (12)

Vertical wind turbine with adjustable, power-generating, wind energy-converting wings, which are mounted in the installed position with its axis of rotation perpendicular, adjustable on both sides of rotating bases, characterized in that the circulating bases, which consist of linearly movable, circulating cable car constructions between pylons ( 9 ) on upper and lower pulleys ( 3 ), in which the, the ropes in the preferred direction of the driving front and back driving back, adjustable angle adjustable wings ( 6 ) at upper ( 2 ) and lower ( 1 ) Circulating ropes ( 2 / 1 ) of the circulating cable cars are attached. Vertical wind turbine with power generating wings according to claim 1, characterized in that at least 10 power generating, adjustable wings ( 6 ) are provided, which are equally spaced from each other via the circulation path on the cable construction ( 1 / 2 ) are arranged so that the surface filling degree of the front flow-through surface corresponds to the surface filling degree of the rear flow-through surface. Vertical wind turbine with power-generating wings according to claims 1 or 2, characterized in that the direction of movement of the set by the power-generating wings in motion ropes ( 1 / 2 ) is reversible. Vertical wind turbine with power-generating wings according to claims 1 to 3, characterized in that the travel of the power-generating wings except for the deflection wheels ( 3 ) is linear. Vertical wind turbine with power generating wings according to claim 1, characterized in that each power generating wing ( 6 ) frontally a servomotor ( 13 ) or stepper motor via the modified nacelle group holder ( 12 ) with the circulating cable ( 1 / 2 ) is connected. Vertical wind turbine with power-generating wings according to claim 1, characterized in that the power-generating wings ( 6 ) lengthwise over 4 rows of pressure sensors ( 14 ), 2 rows on each side near the outside edges for flow measurement. Vertical wind turbine with power generating wings according to claims 5 and 6, characterized in that each power generating wing ( 6 ) via a microprocessor unit ( 17 ) and its associated control line ( 16 ) to the servomotor ( 13 ) and an RF data line ( 19 ). Vertical wind turbine with impulse generating wings according to claims 5 to 7, characterized in that in each microprocessor ( 17 ) of each impulse generating surface ( 6 ) a control program is implemented. Vertical wind turbine with power generating wings according to claims 5 to 8, characterized in that a central computer with TCP / IP protocol all recorded data of the respective microprocessors ( 17 ) of the respective power generating wings ( 6 ) and calculates therefrom the most probable angle of attack constellation for all the impulse generating wings of the anticipated revolution. Vertical wind turbine with power generating wings according to claims 1 to 9 characterized in that the power generating wings ( 6 ) in their profile design according to the findings of bionics fanned wing ends on the attachment sides. Vertical wind turbine with power generating wings according to claim 1, characterized in that the power supply of the power generating wings ( 6 ) over the upper and lower circulating cables ( 2 / 1 ) he follows. Vertical wind turbine with power-generating wings according to claim 1, characterized in that the foundation of the pylons ( 9 ) can be done on pontoons and off-shore capability is assured.