DE10394266T5 - Impedance elements for a wind turbine - Google Patents

Abstract

One Impedance element (1) for a wind turbine, characterized in that the impedance element Vibration energy reflected on its surface.

Description

 Field of the invention

The The invention relates to an impedance element for reducing structurally created noise a construction and in particular an impedance element for Reduction of structural noise of a wind turbine.

background the invention

noise emission of technical installations is a serious problem. The legislation determines the permissible Sound pressure level, which is a source of noise at a certain place may continuously make. regulations Managing these levels varies from country to country. Based in Germany the default values on the VDI standard 2058 and were of the technical Instructions for noise reduction taken, which is prescribed by law. The maximum permissible values hang from the character of the environment and the time of day. For example 65 dB (A) in a usual industrial environment during of the day allowed while only 35 dB (A) in an exclusive Residential environment during the night are allowed. These terms also apply to the operation from wind turbines.

Of the noise generated by wind turbines is partly mechanical and partly aerodynamic. Mechanical noise is mainly from rotating Machinery produced in the nacelle, especially the gearbox and the generator, although there are other contributions from cooling fans, ancillary equipment (such as for example pumps and compressors), bearings and the wind tracking mechanism gives. Mechanical noise is often at an identifiable frequency or tone, for example Example caused by the meshing frequency of a step of the transmission.

In addition to the carry Through the air, mechanical noise can also be transmitted through the system become. Because of the strength and stiffness of the meshing of the gearbox through the gearbox, the bottom plate of the nacelle, transmit the rotors and the tower. Thus, the noise becomes transferred to these structures; In addition, it can be considerable resonance reinforcements of the emitted sound in the structure. A hollow steel tower for example, is just the ideal sound box for radiating by one Structure take over noise, the typically in the range of 0 to 500 Hz. Thus is the transmission is a source of considerable tonal-mechanical noise.

Of the noise generated by the transmission should be steamed so that the sound pressure level of the wind turbine is not exceeds the limits prescribed by law. In general justified the spread of noise through the air no serious problem. It is characterized by suitable sound insulation of Gondola prevents. noise propagation however, it is more difficult to prevent by solid components. Therefore should be the structurally transferred Noise of one Wind turbine to be reduced.

In US 6,224,341 B1 by JR Fricke on May 1, 2001, and filed on Edge Innovations & Technology, LLC, a vibration damped system is described wherein a hollow rotary member is filled with a low density granular material which dampens the vibrations of the rotary member. In DE 199 30 751 A1 F. Mitsch, filed on Jul. 2, 1999, describes a method of reducing vibration of components of a wind turbine. According to this method, a plurality of bearings made of very soft elastomeric material are used for damping the vibrations.

Summary the invention

It An object of the present invention is an impedance element to disposal which is capable of structurally transmitting a noise Reduce wind turbine.

These Task is solved by an impedance element according to claim 1 and a wind turbine according to claim 11, which relate to dependent claims on further embodiments of the present invention.

According to one first embodiments The present invention provides an impedance element, that on its surface Vibration energy reflects.

By using such an impedance element, the noise transmission of a wind turbine can be reduced. The impedance element acts as a resistor in the noise transmission path so that the structurally transmitted noise generated in the engine nacelle, for example by the transmission, is reflected at the interface between the engine nacelle and the impedance element. This effect affects longitudinal (pressure) sound waves as well as transversal (bending) sound waves that are dominant to the total amount of sound generated in the nacelle. Since not only a small part of the vibration energy is reflected at the connection of the engine nacelle and the impedance element, the vibration energy transmitted to the tower is significantly reduced. Typically, it is desirable that 25% or more of the vibrational energy be reflected by the impedance element. Also, reflection coefficients of 0.3, 0.5, 0.75 and even up to 1 can be realized by the impedance element according to an embodiment of the present invention. As a result, the vibration energy that flows from the machine nacelle to the tower, greatly reduced. However, even in the case of a reflection coefficient of 1, evanescent waves are induced in the impedance elements by mechanical vibrations. In any case, as the amplitude of evanescent waves decreases exponentially, little or no vibrational energy is transmitted from the engine nacelle to the steel tower. Therefore, the sound radiation through the steel tower is significantly reduced. Moreover, only a small amount of shear stress is induced in the impedance element by the reflection of the vibration energy. The reflected sound energy is attenuated or dissipated in the nacelle by conventional damping means. In the event that the damping means of the nacelle are insufficient to dissipate the reflected sound energy, additional damping means may be provided.

According to one further embodiments of the The present invention further includes the impedance element a material with a specific speed of sound that much bigger or much less than the specific sound velocity of the material the tower is.

typically, are the tower of the wind turbine as well as the machine gondola, special the bottom plate of such a gondola that the interface too the impedance element is made of steel. If the specific Speed of sound of steel and the specific speed of sound of the impedance element are substantially different, are the impedance element and the bottom plate "detuned". The reflection coefficient for the Sound is expressed in other words mainly by the ratio of specific sound velocities (or the acoustic inertia) the gondola bottom plate and the impedance element determined. If the specific sound velocities (or acoustic inertia) are significantly different, becomes a significant part of the vibrational energy reflected at the interface between the nacelle and the impedance element or bowed. Because the specific speed of sound of steel approximately 5000 m / s, the impedance elements typically have a specific one Speed of sound much larger than 5000 m / s or much less than 5000 m / s. Typically, the specific speed of sound is of the impedance element is less than or equal to 2/3 or larger or equal to 1.5 times the specific sound velocity of the Material of the gondola. Primarily, the relationship between the specific Sound speeds about 0.62, that is, the specific sound velocity of the impedance element is about 3100 m / s. It should be noted that the term specific sound velocity, as used above refers to sound velocities at 20 ° C.

According to one still another embodiment In the present invention, the impedance element also has a damping factor with a logarithmic drop greater than about 0.01 Neper (Np), typically in the range of about 0.015 Np to 0.04 Np and more typically in a range of about 0.022 Np up to 0.035 Np.

One Impedance element made of a material with a damping factor that is a logarithmic drop within the above In addition, it allows the part of the vibration energy to dampen, which is not reflected, but enters the impedance element. The damping The vibration energy happens through the absorption of the vibration energy in the mass of the impedance element. Therefore, the amount of vibrational energy which is transmitted from the gondola to the tower, further reduced. Compared to the damping factor of steel, about 0.002 Np, For example, a material of the type described above has a damping capability, the approximately one to two orders of magnitude is larger. As a result, such a material is suitable, the noise transmission path between the machine nacelle (Gear) and the tower made of steel to interrupt.

According to one another embodiment In the present inventions, the impedance element comprises concrete, preferably a reactive resin concrete.

Concrete, especially reactive resin concrete, is a material that meets the requirements an impedance element according to the present invention Invention satisfied. reactive resin contains typically two components, a binder and an extender. Typically, epoxy resins are used as a reaction resin together with Minerals used to form the reaction resin concrete. Reaction resin concrete needed advantageously no stiffening, since a stiffener usually off Made of steel and provides an undesirable noise transmission path. Thereby that would be Providing a stiffener, the damping capability of the impedance element deteriorate. Since the stiffener is not needed, the damping ability be obtained from reactive resin concrete.

According to one Still another aspect of the present invention further includes the impedance element a fabric or a carbon fiber material.

It is known to have a higher concrete Compressive strength, while it is only a relatively poor Has tensile strength. In principle, this also applies to reactive resin concrete. however the impedance element is not only exposed to compressive forces but can also tensile forces be exposed, for example by rocking movements of the gondola. Therefore, it may be desirable be to improve the tensile strength of the impedance element. This Can be done by using woven materials, for example kevlar or carbon fiber materials. Typically the carbon fiber materials used in unidirectional layers. woven or carbon fiber materials improve the tensile strength of the impedance element strong. Furthermore, they typically have specific sound velocities below that of reaction resin concrete and thus increase the reflection coefficient of the impedance element. Because woven or carbon fiber materials for their low density, however, care must be taken that the entire mass of an impedance element containing these materials contains not too low.

Short description the drawings

For someone with ordinary Expertise is a complete one and sufficient disclosure of the present invention included the best way to perform in the remainder of the description with reference to the attached figures set out in detail, thereby:

1A shows a plan view of an impedance element according to an embodiment of the present invention.

1B shows a side perspective view of the impedance element of 1A ,

2A shows a plan view of an impedance element according to another embodiment of the present invention.

2 B shows a side perspective view of the impedance element of 2A ,

3A shows a cross-sectional side view of an impedance element according to another embodiment of the present invention.

3B shows a plan view of the impedance element of 3A ,

4A shows a cross-sectional side view of an impedance element according to another embodiment of the present invention.

4B shows a perspective view of a first type of flange, which in the embodiments of 4A is used.

4C shows a perspective view of a second type of flange, which in the embodiments of 4A is used.

5 shows a side view of a wind turbine, which includes an impedance element according to an embodiment form of the present invention.

detailed description

It will now be described in detail on the various embodiments of the invention Reference is made to one or more examples thereof in the Figures explained become. Each example is provided to illustrate the invention and not as a limitation to understand the invention. For example, features that can be part of an embodiment explained or described for or used in conjunction with other embodiments to give yet another embodiment. It it is envisaged that the present invention will be such modifications and variations.

1A shows a plan view of a disc-shaped impedance element 1 according to an embodiment of the present invention. A side view of this impedance element is shown in FIG 1B shown, wherein the height H of the impedance element is also marked.

The impedance element 1 will typically have a height (H) in the range of about 0.5 m to 2 m, typically from about 1 m to 1.5 m. Typically, the impedance element is made of a reactive resin concrete, eg EPUMENT 145 / B, EPUMENT 140 / 8B or AMPLEX 140/5 available from EPUCRET Polymertechnik GmbH & Co. KG, Daimlerstrasse 18-26, D-73117 Wangen.

The elastic modulus of these materials is within about 30 kN / mm ² to about 45 kN / mm ² , the tensile strength or flexural strength is within about 30 N / mm ² to about 40 N / mm ² , and their compressive strength is within about 130 N / mm ² to 150 N / mm ² . The damping factor of these materials has a logarithmic drop within the range of about 0.022 Np to about 0.035 Np. The height H of the impedance element is about 1500 mm for a tower of 80 m to 100 m height. Accordingly, the mass of the impedance element is between about 2000 to 5000 kg. Typically, the specific sonic velocity of such an impedance element is between about 2900 m / s and 3200 m / s. Accordingly, the ratio of the specific sound velocities of the impedance element and the nacelle Bo plate between 0.58 and 0.64.

Farther is the impedance element with carbon fiber material (not shown) strengthened that while the manufacturing process of the impedance element in unidirectional Added layers has been. Alternatively, kevlar can be used during added to the manufacturing process become. This compares the tensile strength of the impedance element increased to an impedance element without carbon fiber reinforcement. Additionally reduced the reinforcement with tissues or carbon fiber materials the speed of sound of the impedance element.

2A and 2 B show an alternative embodiment of the present invention, wherein the impedance element 1 is annular and has a central opening O. The materials used for the impedance element may be the same as those described in the above embodiment. Typically, the height H of the ring-shaped impedance element is greater than the height of the disc-shaped impedance element to still provide an impedance element of sufficient mass to effectively dampen structurally transmitted noise. In addition, the annular impedance element of increased height can carry greater mechanical loads than an annular Intendanzelement of smaller height.

Even though the impedance element is shown with a circular cross-section is, other forms are possible, z. Eg polygons shapes like a hexagon or an octagon. Farther For example, the impedance element is not necessarily cylindrical but can also have a conical shape. Thus, the respective form of the impedance element to the respective requirements of an individual wind turbine be adjusted.

alternative can all of the embodiments described above also be realized by using concrete without reaction resin becomes. In this case, the height likes H of the impedance element, if necessary, must be increased to to compensate for the absence of the reaction resin.

The Impedance element can either be prefabricated or can be on site to be produced. When a casting of the impedance element is considered on site, a must appropriately adapted form be made available. After Making the impedance element can be attached to adjacent parts of the Wind turbine, for example the upper section of the steel tower and the lower part of the machine nacelle, cemented by one Connection or a flange connection are attached. By doing Case that the impedance element is prefabricated in a factory, may be the production of the impedance element under controlled conditions and with high quality be performed. Typically, a prefabricated impedance element with at least a flange for forming a flange connection with an adjacent one Part of the wind turbine provided. Hereinafter Such impedance elements with flanges are described in detail.

3A shows a cross-sectional view of another embodiment of the present invention. Therein are in the impedance element 1 at least one lower and one upper flange 2 . 3 made available. The impedance element 1 can be attached to upper and lower parts of a wind turbine using these flanges. For example, the upper flange 2 be fixed to the bottom plate of the machine nacelle and the lower flange 3 can be fixed to the upper part of the steel tower. Upper and lower flanges 2 . 3 are typically made of steel. Therefore, it is important that the flanges 2 . 3 do not touch, otherwise they will have a noise transmission path through the impedance element 1 would form. This would reduce the damping capability of the impedance element 1 be reduced.

A still further embodiment of the present invention is disclosed in 3B shown a top view of the impedance element 1 is. Therein are the upper flanges 2 and the lower flanges 3 distributed along the circumference of the impedance element. Typically, an upper flange 2 horizontally along the circumference of the impedance element 1 from a lower flange 3 spaced to provide improved isolation of the flanges from each other. In this embodiment of the present invention, the lower flanges 3 and the upper flanges 2 offset by about 45 ° from each other. This offset is typically 360 ° divided by the total number of flanges to evenly distribute the flanges along the circumference of the impedance element. Thereby, no noise transmission path through the impedance element becomes 1 is generated so that the noise generated on the upper side of the impedance element by, for example, the transmission, only in strongly damped form to the lower side of the impedance element 1 , that is, the steel tower of the wind turbine, is transmitted.

Alternatively, the flanges 2 . 3 be constructed with cylindrical heads, as it is in 4A is shown. Furthermore, the shank parts of the flanges 2 . 3 be threaded, as in the 4B and 4C is shown. In particular, a male thread ( 4B ) or a female thread ( 4C ) to provide.

Ultimately shows 5 a wind turbine, in accordance with an aspect of the present invention, comprising a steel tower 4 , a machine gondola 5 and a rotor 6 with rotor blades 7 includes. The rotor 6 is due to the buoyancy of the rotor blades 7 driven and is connected to a rotor shaft (not shown). The rotor shaft is coupled to a gearbox (not shown) in the machine nacelle 5 is arranged. The noise of the transmission, which is generated during operation, is transmitted through the machine nacelle 5 to the impedance element 1 transfer. There, a significant portion of the vibration energy to the machine nacelle 5 reflected back. Only part of the mechanical energy penetrates into the volume of the impedance element 1 one. Its damping capacity, that is a damping factor with a logarithmic drop between 0.022 Np and 0.035 Np, reduces the mass of the damping element 1 the structurally transmitted noise generated by the transmission continues. As a result, little or no noise is made to the steel tower 4 via the impedance element 1 transmitted; Thus, the total emission of structurally transmitted noise of the wind turbine is effectively reduced.

After this Thus, the invention has been described in detail, it should be obvious that a lot of modifications to the can be made without departing from the spirit and the scope of the following claims departing.

Summary

An impedance element for reducing the structurally transmitted noise of a wind turbine is provided, wherein the impedance element reflects vibration energy on its surface. Preferably, the impedance element ( 1 ) between a machine nacelle ( 25 ) and a tower ( 4 ) arranged a wind turbine.

Claims (12)

An impedance element ( 1 ) for a wind turbine, characterized in that the impedance element reflects vibration energy on its surface. The impedance element ( 1 ) according to claim 1, further comprising a material having a specific sound velocity much greater or much smaller than the specific sound velocity of the material of the tower ( 4 ). The impedance element ( 1 ) according to one of the preceding claims, further comprising a material having a damping factor with a logarithmic drop greater than 0.01 Np, preferably in the range of 0.015 Np to 0.04 Np and more preferably in the range of 0.022 Np to 0.035 Np. The impedance element according to one of the preceding claims including a concrete, preferably a reactive resin concrete. The impedance element according to one of the preceding claims, further including a fabric or a carbon fiber material. The impedance element according to one of the preceding claims, wherein the impedance element ( 1 ) is disc-shaped. The impedance element according to one of the preceding claims, wherein the impedance element ( 1 ) is annular. The impedance element according to one of the preceding claims, wherein the impedance element ( 1 ) a height (H) in the range of 0.5 m to 2 m, preferably 1 m to 1.5 m, and a diameter in the range of 1.5 m to 4 m, preferably 2.8 m, Has. The impedance element according to one of the preceding claims, further comprising at least one upper flange ( 2 ) for attachment to an upper part ( 5 ) of the wind turbine and at least one lower flange ( 3 ) for attachment to a lower part ( 4 ) of the wind turbine, wherein the at least one upper and the at least one lower flange are not in direct contact with each other. The impedance element according to claim 9, wherein the at least one upper flange ( 2 ) and the at least one lower flange ( 3 ) horizontally along the circumference of the impedance element ( 1 ) are spaced. A wind turbine comprising at least one Impedance element according to a the claims 1 to 10. The wind turbine according to claim 11, wherein the at least one impedance element ( 1 ) between a machine nacelle ( 5 ) and a tower ( 4 ) of the wind turbine is arranged.