DE1036780B - Device for automatically reducing the blade position with high-speed wind turbines - Google Patents

Description

Device for automatically reducing the wing position at Schnell Running wind turbines It is well known that high-speed wind turbines are the most powerful with a relatively low pitch of their wings, d. H. at an angle of attack from about 12 ° to the mean wing normal to the blowing direction. This However, a flat angle of attack is quite unfavorable for the start-up of the wind turbines because. the best starting torque is achieved at an angle of attack of around 45 °. Further exists with such a flat setting of the wing pitch at high wind speeds the risk of excessive speed and an impermissibly high level associated with damfit Stress on the system. This can again be done by increasing the wing pitch, if necessary up to 90 °, prevent. In order to meet all requirements, is thus a change in the wing pitch during the operation of high-speed ones Wind turbines required, in the sense that first the pitch of the blades receives the most favorable value for this of about 45 ° when starting up. then the normal Schnellaufbetrieb-, reduced and finally above the maximum permissible limit speed grows again. These. Adjustment is expediently automatic depending on the speed.

There are already known wind turbines, the next to fixed also have adjustable wings or all of the wings are adjustable are set up and their adjustable wing counteracts under the influence of centrifugal force adjust the action of springs. The adjustable wings are around their longitudinal axis rotatably mounted. The setting is preferably done automatically, with the standing forces can be generated by the centrifugal force of the wings themselves or by special centrifugal masses. In such devices, however, the adjustment of the wings takes place in only one Direction of rotation either towards smaller or larger angles of attack.

Furthermore, a control device for high-speed wind turbines has become known, with the two coupled centrifugal governors of different sensitivity The rods act on the wings in this way. that both for running quickly running wind turbines necessary adjustment directions, @ 7reduction of the blade pitch in the liver duct from the drain to the rapid installation and enlargement of the same above a critical speed. The bearings and lever joints of a However, such control devices are subject to high wear and tear therefore require careful maintenance. With such a thing is, however, special almost never to be expected overseas, the main area of application for such wind turbines. The many Bearings and joints also cause considerable backlash in the wings, the flapping and triggers shock loads, often leads to fluttering movements and that anyway high wear of the moving control elements accelerated.

According to the invention, a particularly advantageous and operationally reliable Device for automatically reducing the wing pitch during start-up high-speed wind turbines when transitioning from a favorable starting position to the the most favorable operating position and for the automatic increase of the wing pitch at Exceeding a certain limit speed, using adjustable vanes, which adjust under the influence of centrifugal force against the action of springs, achieved in that the wing with its wing root in a known manner is mounted adjustable about a radial axis in a holder and that the holder in turn around an axis in the wind turbine hub that is arranged parallel to the blade adjustment axis is pivotable.

The rotary movement around the vane axis is preferably limited by stops in the most favorable starting position and in the most favorable operating position, but it is useful that these stops h - i can be exceeded by very large adjusting forces. An embodiment is shown in Figures 1 and 2; 3 shows the various positions which the blade can assume as a result of the adjustment movement; Fig. 4 shows a particular embodiment of the wing dar; L xA.W Fig. 5 shows an exemplary embodiment, in which- ' different, symmetrically arranged Pairs of wings are partially fixed or perform various adjustment movements.

The direction of flow is denoted by L 'in the drawings, in Fig. 1, the blade 1 can be rotated with its shaft 2 (blade axis) in the holder 3 stored. The shaft 2 is pre-tensioned and turned off Spring 4 in the start-up position, so when the wind engine is at a standstill, so from stops kept that the angle of attack of the blade is that of the best starting torque, about 45 °. The spring 4 counteracts the flyweight 5, which the Immediately after the start-up of the wind turbine, the wing is twisted so far that it is the largest possible Receives a lift coefficient, corresponding to an angle of attack of about 12 °. The bracket 3 is firmly connected to the hub axle 6, which is rotatable in the hub 7. The wing axis is therefore offset from the axis of the hub shaft. so that there is a force-fit Crank system results.

As Figure 2 illustrates, the lever arm sits firmly on the hub shaft 6 8, which acts on the spring plate 10 via the articulated lever 9 against the spring 11. During rotation, following the centrifugal force, the wing strives to twist so far that that the axis X of the holder 3 with the axis Y lying in the plane of rotation the hub shaft 6 covers. The bias of the spring 11 is dimensioned so that the adjustment forces of the crank system only after the maximum permissible speed and rated power have been reached of the wind engine take effect. The blades then turn in the opposite direction Direction of rotation of the direction of rotation exercised by the flyweight 5 and the first adjustment process regulating and so far out of the wind that overspeeding is definitely prevented. Through the hollow shaft 12 (main axis) is provided with a thrust bearing and on the spring plate 10 seated connecting part 13 connected to the pull cord 14, the to a lever attached to the mast of the system and any parking of the wind engine.

Fig. 3 shows the blades from the start of the wind motor until it swings out fully in the event of a storm or shutdown. In position A, the starting position, the blades have the best starting torque, corresponding to an angle of attack of about 45 °. Immediately after the wind turbine starts up is the flyweight 5 or the wing due to its special training own centrifugal force effective, and the blade rotates in the direction of the arrow a until the position B and a corresponding to the highest lift coefficient Attack angle of about 12 ° is reached. Exceeds the speed of the wind motor the optimally permissible value, the adjustment forces of the crank system are effective and turn the wing out of the wind in the direction of arrow b, to avoid storms or shutdown position C of the system.

By appropriate training of the wing blades, these can be known even supply the adjustment forces required for the first switching process, see above that the flyweight 5 (see Fig. 1) can be omitted. Like such a wing blade 4 illustrates.

You can also make the construction of wind turbines so that only one Part of the symmetrically lying pairs of wings performs both adjustment movements while the other part is fixed in the hub or only performs an adjustment movement.

Such a control device, which is particularly useful for larger wind turbines shows Fig.5. Here the blades 1 rotatable in the mountings 3 are symmetrical Fixed in the wing hub seated wing blades 1 a assigned. The wing blades 1 are inserted in such a way that they can be used in the event of excessive wind speeds and the resulting too high speeds of the wind turbine above that corresponding to position C in FIG. 3 Zero lift value are turned away and thereby one of the fixed wings 1 a obtain opposite direction of rotation and brake the wind motor. That way is a "runaway" of the wind engine impossible, be it in hurricane-like storms or in the event of a sudden load interruption in generator systems.

Claims (5)

PATFNTAN $ PR (1 (: iIE: 1. Device for automatically reducing the Blade pitch during the start-up of high-speed wind turbines at the transition off a favorable start-up position in the most favorable operating position and for automatic Increase in the wing pitch when a certain limit speed is exceeded, below Use of adjustable wings, which are counter to the action of centrifugal force Adjust the effect of springs, characterized in that the wing (1) with its Wing root (2) adjustable in a manner known per se about a radial axis in a holder (3) is mounted and that the holder (3) in turn by a parallel Axis (6) arranged in relation to the blade adjustment axis in the wind turbine hub (7) is pivotable is. 2. Device according to claim 1, in which the wing counteracts by a centrifugal mass a spring is adjusted, characterized in that the wing shaft holder (3) the centrifugal forces counteract the masses it carries and its own a spring (11) is adjusted. 3. Device according to claim 2, characterized in that that the spring (11), which is connected to the wing shaft halving (3), is so biased is that it is only actuated at a much higher speed than the spring (4). 4th Device according to Claim 1, characterized in that the rotary movement of the blade (1) in the most favorable starting position and / or the most favorable operating position, based on the basic position of the wing shaft holder (3). limited by stops is. 5. Device according to claim 1, characterized in that d @ ate out the wind turbine Wing groups arranged mirror-inverted to the wind turbine shaft, each of the same design exists and that the wings of a group are firmly connected to the hub or only in the Areas of one of the two adjustment movements (best starting position to best Operating position or most favorable operating position up to overspeed position) adjustable are, while the wings of the other group are adjustable in the range of both adjustment movements are. 6. 4j7indrad according to claim 1 to 5, characterized in that the blades of one group beyond the zero lift position up to the positions. pivotable are, in which a braking torque is generated with respect to the wind turbine shaft. Into consideration Drawn pamphlets: German patents nos. 908 840, 860 030, 862 280, 906 440, 584 505, 895 128; U.S. Patent No. 2,215,456.