DE3903399A1 - Wind power installation - Google Patents

Abstract

A wind power installation having a wind rotor is specified, the vanes of which are mounted on the rotor hub capable of rotation about their longitudinal axis in order to implement a variable angle of incidence. The rotor of an electric generator is seated with the wind rotor on a common shaft and generates electric power (energy) upon rotation of the wind rotor. A control device is used to control the rotational speed of the wind rotor and has a sleeve, which is secure against rotation of the shaft but can be displaced longitudinally, and a jointed connection between each vane of the wind rotor and the sleeve, and permits the setting of a constant rated (basic) speed with the aid of simple means.

Description

The invention relates to a wind turbine a wind rotor, the wings of which are realized a variable angle of attack around its longitudinal are rotatably mounted on the rotor hub, with an electric generator, with a common one seed wave on which the wind rotor and the rotor of the generator are attached, and with a Re Gel device for regulating the speed of the wind rotors.

Such wind turbines are known and serve to convert wind energy into electrical energy put. A major problem here is the Speed control of the system is independent possible from the wind speed and the wind strength Lich should be set constant to swan kung in the frequency of the electrical generated To prevent tension as much as possible. Such be Known regulations are complex, they require additional active modules that provide a supply with external energy or with that from the system generated energy necessary and thus the Reduce system efficiency. In addition, should the overall structure of the plant the efficiency of Impact energy conversion as little as possible.

The object of the invention is therefore a wind power plant of the type mentioned in this way that converting wind energy into electrical Energy possible even with weak winds maximum efficiency and with a simple,  lossless speed of constant control takes place.

This task is the one at the wind turbine solved in accordance with the invention, that the control device rotates one on the shaft fixed and longitudinally displaceable sleeve and a joint connection between each wing and the sleeve ent holds.

The advantages of the invention are in particular that mechanical regulation immediately between the axes of the blades of the wind rotor and the shaft the wind turbine takes place without external energy where due to high operational reliability and maintenance-free unit with a simple, stable structure and a ver equally high constancy of speed at the under various wind speeds is guaranteed.

The blades of the wind rotor are particularly preferably inclined by a predetermined angle of inclination β with respect to a reference plane running perpendicular to the shaft; The wing axes are thus on a cone, the cone angle of which is 90 ° - β to the free end of the shaft. This inclination of the blades ensures that the wind flowing in the direction of the shaft has sufficient turning torque to change the angle of attack of the blades. The entire wind turbine is rotatably mounted on a frame in a known manner, the shaft preferably being oriented approximately horizontally. By suitable design of the fairing of the entire wind turbine, the rotatable wind turbine on the scaffold is aligned under the action of the wind so that the direction of the shaft coincides with the wind direction. Due to the inclined attachment of the wing, which is mounted around its longitudinal axis, to the rotor hub, it is sufficient that the angle of attack of the wing decreases with increasing wind speed and, with decreasing wind speed, decreases again to the maximum angle that is reached when the rotor is stationary or the wind speed is low .

The joint connection particularly preferably contains because a cross arm attached to the wing axis and one articulated between the cross arm and sleeve arranged articulated rod. The link rod is preferred pivoted on the sleeve, between cross arm and the joint rod is preferably a ball joint arranged. The cross arm runs under one variable angle from one of the wing axis and the wave spanned out plane, the Be attachment point of the cross arm and the attachment point of the articulated rod on the sliding sleeve have one relative to each other in the direction of rotation Angular misalignment, so that when the Sleeve a restoring moment from the cross arm to the respective wing axis is exercised.

According to a particularly preferred embodiment According to the invention, the wind rotor sits at one end the shaft, and the generator at the other end the wave. The generator has a special structure according to the invention, which can also be found in others Systems or facilities can be used. The Ge nerator contains an internal stand and an outside runner who - towards the stand turned - several circumferentially spaced permanent  owns magnets. The stand is made of a sheet metal package a large number of thin, ring-shaped sheets det who carry the electrical windings, which appropriately connected to the external connections that are. The laminated core of the stand is preferably seated on a fixed sleeve through which the Shaft is rotatably supported, which with means of an end bracket with the runner is connected.

Advantageous developments of the invention are through characterized the features of the subclaims.

The following is an embodiment of the invention dung explained with reference to the drawing.

Show it:

Figure 1 is a schematic cross section through the wind turbine.

Fig. 2 is a side view of the wind rotor;

Figure 3 is a schematic view of the position of the wing with different wind strength. and

Fig. 4 shows a cross section through the generator.

Figs. 1 and 2 schematically illustrate a wind power plant and the wind rotor. In a housing 1 , which is rotatably mounted on a rotating structure 1 a on a scaffold 1 b , a wind rotor 2 is firmly seated on a shaft 20 which is rotatably supported in the housing 1 . The rotor hub 4 is fixedly connected to the shaft 20 and has a plurality of transversely to the shaft 20 from heat-oriented wing 8 , which are rotatably supported on the rotor hub 4 in bearing bushes 6 about its longitudinal axis 9 . By rotating the wing axis 9 in the bearing bushes 6 , the angle of attack of the wing can be changed depending on the wind speed. The bearing bushes 6 are arranged on the rotor hub 4 such that the wing axes 9 assume a predetermined angle of inclination to a reference plane which is perpendicular to the shaft 20 .

On each wing axis 9 is - between the two bearing bushes 6 - a cross arm 12 is attached, which is articulated via an articulated rod 14 at the end of the cross arm 12 with a sleeve 16 , which rotatably but longitudinally mounted on the shaft 20 . Pre see are also reset devices 18 , z. B. gas springs, which act on the sleeve 16 with an increasing deflection a increasing restoring force. The cross arm 12 and the hinge rod 14 form a Ge joint connection, the end points of which have an angular offset in the direction of rotation of the rotor, so that rotation of the wing about its longitudinal axis, ie a change in the angle of attack via the hinge connection, a displacement of the sleeve against the restoring force of the restoring device Consequence. Articulated joint 12 , 14 , sleeve 16 and return device 18 form a control device that works in the following way: With increasing wind strength, the angle of attack α of the blades of the wind rotor 2 is reduced; by an accompanying rotation of the wing axis 9 , the sleeve 16 is moved against the increasing de restoring force; in the normal operating position, ie with a normal deflection a 0 of the sleeve 16 , a further increase in the wind strength is compensated by the - initiated via the sleeve 16 - transferred to the wing increasing restoring moment so that a constant speed of the wind rotor is observed.

As can be seen in particular from FIGS. 2 and 3, the angle of attack α is at a maximum value in the case of weak wind which flows in the direction of the shaft 20 , the rotor is in the rest position or in the start-up mode. With medium and large wind strengths, a change in the angle of attack is permitted on the control device 10 such that the wind rotor 2 rotates at a constant speed, the nominal speed. With particularly large wind strengths, a negative angle of attack occurs, which leads to the braking of the wind rotor 2 .

In FIG. 4 is a cross section through the generator, able in particular to the Windkraftan is usable, although alternatively, other uses are possible. At the end facing away from the wind rotor 2, the shaft 20 is rotatably guided through a fixed sleeve 46 by means of corresponding bearings 48 and has on the end face a holder 34 to which an external rotor 32 of the generator is fastened. The rotor 32 carries a plurality of permanent magnets at a predetermined, uniform distance. On the fixed sleeve 46 , a laminated core is fastened, which is composed of annular individual sheets and - opposite the permanent magnets 36 - carries electrical windings 44 which form the stand 42 together with the laminated core. Due to the large number of permanent magnets that can be accommodated and the stationary arrangement of the windings on the stator 42 , a particularly robust design of the generator is realized, which is free of centrifugal forces on the windings and therefore does not experience any damage to the windings at excessive speeds due to excessive centrifugal forces. In addition, the generator according to the Invention enables the wind turbine to be realized without a gear between the wind rotor and generator, thereby increasing the efficiency of the wind turbine and making operation possible even at low wind speeds.

The generator according to the invention with external permanent magnet rotor and internal stator windings can also be used in various other devices, it does not require external cooling and - because of the fixed arrangement of the windings - also no slip ring tap.

Claims (8)

1. A wind power plant with a wind rotor, the blades of which are rotatably mounted on the rotor hub about their longitudinal axis in order to achieve a variable angle of attack,
with an electric generator, with a common shaft on which the wind rotor and the rotor of the generator are attached,
and with a control device for controlling the speed of the wind rotor,
characterized in that the control device ( 10 ) contains a sleeve ( 16 ) which is non-rotatable and longitudinally displaceable on the shaft ( 20 ) and an articulated connection ( 12 , 14 ) between each wing ( 8 ) and the sleeve ( 16 ). 2. Wind power plant according to claim 1, characterized in that the sleeve ( 16 ) via the articulated connection ( 12 , 14 ) of the wings ( 8 ) with decreasing angle of attack of the wing an increasing deflection from the initial position against the increasing restoring force of a return adjusting device ( 18 ) receives. 3. Wind power plant according to claim 1 or 2, characterized in that the articulated connection ( 12 , 14 ) an on the wing axis ( 9 ) ten transverse arm ( 12 ) and an articulated between the cross arm ( 12 ) and sleeve ( 16 ) articulated rod ( 14 ) contains. 4. Wind power plant according to claim 1, 2 or 3, characterized in that the articulated rod ( 14 ) on the sleeve ( 16 ) is pivotally mounted, and that between the cross arm ( 12 ) and the Ge steering rod ( 14 ) has a ball joint ( 15 ) is arranged. 5. Wind power plant according to one of the preceding claims, characterized in that the Rückstelleinrich device ( 18 ) contains a spring. 6. Wind power plant according to one of the preceding claims, characterized in that the Rückstelleinrich device ( 18 ) contains at least one gas spring. 7. Wind power plant, in particular according to one of the preceding claims, characterized in that the generator ( 30 ) contains an internal stator ( 42 ) and an external rotor ( 32 ), and that the rotor ( 32 ) has a plurality of poles ( 36 ) made of permanent magnets , and the stator ( 42 ) contains windings ( 44 ) which are led to the outside for the delivery of the induced electrical voltages / currents. 8. Wind power plant according to claim 7, characterized in that the laminated core ( 43 ) of the stator ( 42 ) is arranged on a fixed sleeve ( 46 ) through which the shaft ( 20 ) of the generator is rotatably guided, and that the rotor ( 32 ) is fixedly connected to the end of the shaft ( 20 ) by means of a front-side bracket ( 34 ).