DE19928048A1 - Wind power system enables protection of distant objects at reasonable cost and avoids stroboscopic shadowing - Google Patents

Abstract

The system incorporates a generator gondola (9b), rotatable about a vertical axis. The generator is driven by a rotor (9c) which has several propeller-type blades attached to a hub (9e) with a horizontal axis. An electronic controller can stop the rotor and can also rotate the gondola to face the rotor into the wind direction. A sensor follows the path of the sun above the horizon, and a further sensor monitors the shadow cast by the mast, gondola and rotating blades. A store holds details of nearby places (14) at which a shadow must not occur. A control circuit takes action to avoid the casting of an unpleasant flickering shadow (S) by rotating the gondola, changing the angle of the rotor blades and stopping the rotor in extreme cases.

Description

The invention relates to a wind turbine and a method for Reduction or avoidance of alternating shadows in one Wind turbine.

For wind turbines (WKA) hub heights i are between 30 m and 70 m Height used. The rotor diameter d can be over 50 m. Such wind turbines have a control system, which, if necessary, the rotor stop and adjust the generator nacelle to the wind direction. At Some turbines can adapt to the wind speed Angle of attack of the rotor blades can be changed.

The constant change between light and dark caused by the shadow cast by the rotating rotor 9 c (alternate shadow cast, stroboscopic shadow) is perceived as disturbing. If large wind turbines are to be set up in the vicinity of built-up areas, the argument of the annoyance caused by this stroboscopic shadow leads to the refusal of the building permit or the withdrawal of an already issued operating permit. In some cases, in which a wind turbine was built, the system therefore had to be shut down completely or at least temporarily.

Usually, the wind turbine is only operated when it is temporarily shut down allowed in a set period of time, regardless of whether it is at all can lead to a noteworthy or disturbing shadow cast. In order to avoid disruption to the residents, the requirement at Erection of wind turbines made on the objects in question, e.g. B. the to protect residential buildings that are not exposed to shadows allowed to attach sensors that cast the shadow through the wind turbine should register and the wind turbine depending on the signal of the to switch off installed sensors. In the case of densely built-up areas, this would be the case cause that a corresponding number of sensors are installed, whereby at Large wind turbines also need to be protected, some objects are a hundred meters from the wind turbine.

The object of the invention is to provide protection with reasonable effort to reach distant objects by the wind turbine so is equipped that no annoyance from the stroboscopic shadow can occur.

The solution results from claims 1 and 3.

The solution has the advantage that the wind power plant can be operated autonomously and without networking with sensors placed in the vicinity and the operation can be adapted to the respective climatic conditions in such a way that there is no nuisance to third parties. For this purpose, the system or the method has the following essential features:

• 1. Calculation of the sun's orbit over the horizon and thereby caused shadow cast by the wind turbine,
• 2. Measure the quantity of shadows to determine if there is any a shadow is formed, which is a predefined interference threshold exceeds (disturbing shadow cast);  
• - Identify and store the geographic locations where a disturbing shadows must not occur;
• 3. As a result of steps 1-3: adjustment of the operation of the wind turbine on
• - The disturbing quantity and quality of the shadow cast
• - The position of the shadow or the sun
• - The positions to be protected
  by
• - Twisting the system head or
• - Adjusting the angle of attack of the rotor blades of the rotor to the reduce shadowing area, or
• - If necessary, stop the wind turbine.

With the well-known formula for calculating the sun's orbit from time T, the Inclination of the ecliptic, the latitude of the position of the wind turbine you get the course of the sun orbit over the horizon described by the Coordinates hour angle τ and angle h of height above the horizon. The time T is preferably related to the location of the wind turbine. The swept diameter is first calculated from the rotor diameter d Rotor area R.

Furthermore, the swept rotor area R becomes the angle β between the rotor axis and the hour angle τ and the height angle h the Sun position calculates the position of the effective shadowing area A, which is illuminated by the sun and can therefore cause a shadow. For a simplified procedure, one can always rely on a full orientation of the Rotor to the sun, so that the entire rotor area R as effective area can be viewed.

From the hour angle τ, the height angle h of the sun position, the Hub height i of the rotor above the ground and the position of the effective area A the area S is calculated on which the shadow S caused by the rotor hits the ground.

With a device according to claim 2 it is determined whether it is to form a Shadows can come from wind turbines. Only with sufficient intensity sunlight can cause shadows and thus annoyance by alternating light and dark.

Exemplary embodiments of the invention are described below with reference to the drawing described.

The drawings show:

Fig. 1 shows a map of a wind turbine 9 in a plan view and a side view.

Fig. 2 shows a device according to claim 2 for determining the quality and quantity of the shadow cast

Fig. 3 is a block diagram of an electronic circuit 6 and a computer 7..

Fig. 4 shows the structure of a wind turbine.

14 denotes an object that should not be hit by the stroboscope shadow by the wind turbine 9 . The sun rays 15 fall from the direction of the hour angle τ and at the height angle h onto the rotor 9 c of the wind turbine 9 . The known angle β between the rotor axis 9 f and the hour angle τ and the swept area R of the rotor result in the effectively illuminated area A. With the hub height i, this gives the position of the shadow S.

The device for determining the quality and quantity of the shadow cast has two sensor surfaces 23 and 24 . In the event of light, an electrical signal Ua is generated by sensor surface 23 and an electrical signal Ub by sensor surface 24 . Sensor surface 23 is protected from environmental influences by a transparent housing 25 . Likewise, the sensor surface 24 is protected from environmental influences by a largely transparent housing 26 . In addition, an opaque marking 29 is provided on the housing 26 of the sensor surface 24 in such a way that a shadow falls from the marking 29 onto the sensor surface 24 when light enters. As a result, with the same intensity of light incident on the two sensor surfaces 23 and 24 , the electrical signal Ub generated by the sensor surface 24 is lower than the electrical signal Ua of the sensor surface 23 .

In the electronic circuit 6 is measured to determine the brightness in the part 6 a first that of sensor surface 23 generated electrical signal Ua. Only when the measured brightness and thus the electrical signal Ua exceeds a certain reference value U3 can a shadow be cast. As an indicator of the output signal U4 6 a serving of the circuit part. In part 6 b of the circuit is the difference of the electrical signals Ua and Ub of the two sensor surfaces formed as the output of U5. The difference is a measure of the quality of the shadow.

In the circuit part 6 c, this difference signal U5 is compared with a reference value U6. The result is signal U7. Finally, in the circuit portion 6 d, the output signal U8 of the circuit generated which becomes active when first, determines sufficient via the signal U4, brightness, and second, determined by the signal U7, the quality of the shadow has exceeded a certain value.

A downstream computer 7 with built-in clock 7a calculates or determines the position of the sun and the position of the shadow S caused by the wind turbine 9 using a table in which the position of an object 14 is stored, which should not be hit by the stroboscopic shadow , A signal U9 is generated by the computer 7 , which can be evaluated by the control of the wind turbine.

Wind turbine 9 with the mast 9 a, the generator nacelle 9 b, the rotor 9 c, consisting of the rotor blades 9 d and the hub 9 e and the associated control 8 is shown in FIG. 4. Via the controller 8 of the rotor blades can firstly depends on the wind speed the pitch angle will be changed 9 d, the second generator nacelle are rotated b 9 depending on the wind direction and thirdly, the rotor 9 c of the wind turbine to be stopped. 9 With the output signal U9 of the computer 7 and the circuit 6 can in such a way to the controller 8 of the WKA be acted in that, for reduction of the effective shadow-casting area A of the rotor 9 c, the generator nacelle is rotated b 9 or the rotor 9 c of WT 9 is stopped .

Reference list Fig. 1

9

Wind turbine (WKA)

9

a mast

9

b Generator pod

9

c rotor

9

d rotor blades

9

e hub

9

f axis

14

Object that should not be hit by the strobe shadow
τ hour angle
β angle between axis

9

f and hour angle T
A effective illuminated area
S shaded area
i hub height
d rotor diameter
h The angle of the sun's height above the horizon
N north direction

Fig. 2

21

,

22

Carrier plates

23

,

24th

photosensitive sensor surfaces

25th

,

26

transparent housing

27

,

28

Connecting lines

29

opaque marking on the housing of the sensor surface

24th

Fig. 3

Among other things, electrical signal from sensor surface 1
Ub electrical signal from sensor surface 2
U3 Reference value for the minimum brightness
U4 output signal: brightness greater than reference
U5 output signal: Ua-Ub
U6 Reference value for the minimum difference
U7 output signal: minimum difference above reference
U8 output signal: shadow formation has a certain quality
U9 output signal: shadow lies in the area of a certain object

6

electronic switch

6

a Comparator: brightness over reference

6

b Subtractor: Ua-Ub

6

c Comparator: difference over reference

6

d Link: U4 & U7

7

computer

7

a o'clock

Fig. 4

2nd

a sensor surface

2nd

b shaded sensor surface

6

electronic switch

7

computer

8th

Control of the wind turbine

9

Wind turbine

9

a mast

9

b Generator pod

9

c rotor

9

d rotor blades

9

e hub

9

f axis

10th

Brake to stop the rotor

11

Motor for adjusting the angle of attack of the rotor blades

12th

Motor for turning the generator nacelle.

Claims (8)

1. Wind power plant ( 9 ) with a generator nacelle, which is rotatable about a vertical axis, with a generator which can be driven by a rotor ( 9 c) which can be rotated about a substantially horizontal axis, with rotor blades, and with a control system by which the Rotor can be stopped and through which the rotational position of the generator nacelle can be adjusted to the wind direction; Mark:

• 1.1 device for determining the solar path above the horizon and the resulting shadow cast by the wind turbine,
• 1.2 measuring device for measuring the quantity and quality of the shadow cast (disturbing shadow cast);
• 1.3 facility for determining and storing the geographical locations where a disturbing shadow may not occur;
• 1.4 Control device for adapting the operation of the wind power plant to the disturbing quantity and quality of the shadow cast as well as the position of the shadow or the sun and the positions to be protected, in particular by turning the generator nacelle and / or adjusting the angle of attack of the rotor blades of the rotor and / or if necessary Stopping the wind turbine.

2. Wind power plant according to claim 1, characterized in that the measuring device has two sensor surfaces ( 23 , 24 ) of which one ( 23 ) serves to determine the intensity of the direct solar radiation, while in front of the second ( 24 ) sensor surface an object at a certain distance ( 29 ) is positioned such that the object casts a shadow of direct sunlight on the sensor surface ( 24 ) and that the measuring device further comprises a comparison device for the output signals of the sensors, so that the quantity and quality can be compared by comparing the output signals of the two sensors the shadow cast is determinable. 3. A method for operating a wind turbine in the area of an object in which a disturbing shadow cast by the rotating rotor is to be avoided, characterized in that the position of the sun is determined by calculation or measurement and from the technical data of the wind turbine ( 9 ), in particular hub height (i) and rotor diameter (d), the geographical area (S) is calculated, into which the shadow of the rotor ( 9 c) of the wind turbine is projected and that the wind turbine ( 9 ) is put into another operating state, e.g. B. Stopping, changing the rotor blade position and / or changing the orientation to the sun when the shadow projected by the rotating rotor ( 9 c) hits the object ( 14 ). 4. The method according to claim 3, characterized in that the geographical location of the shadow (S) is calculated at runtime of the wind turbine in a computer ( 7 ). 5. The method according to claim 3 or, characterized in that the geographical location of the shadow (S) is created in a table which is stored in a computer ( 7 ). 6. The method according to claim 3, characterized in that the operating states, which result from the geographical location of the shadow (S), are created in a table as a function of time, and that the wind turbine ( 9 ) is set in a time-dependent manner in the respectively predetermined operating state. 7. The method according to claim 3 to 6, characterized in that The change in the operating state only takes place when the measurement of the Quantity and quality of the shadow cast an annoying shadow cast results, especially if a predetermined limit value of the shadow cast is reached and exceeded. 8. The method according to claim 3 to 6, characterized in that the quantity and quality of the shadow cast is recorded instantaneously and over a certain period of time and that a change in the operating state of the WKA ( 9 ) takes place when the course of the shadow cast reaches and exceeds a predetermined Limit value can be expected.