EP2795074A2

EP2795074A2 - Facility and method for damping acoustic vibrations in a corresponding facility

Info

Publication number: EP2795074A2
Application number: EP12786933.7A
Authority: EP
Inventors: Stephan Minuth; Peter Berenbrink; Frank Deidewig; Holger Gedanitz; Dirk Huckriede; Bernd Prade; Horst Uwe Rauh; Stephan Schestag
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2012-02-02
Filing date: 2012-11-07
Publication date: 2014-10-29
Also published as: CN104093943A; EP2623732A1; US20150016951A1; WO2013113417A2; JP5911975B2; JP2015505589A; WO2013113417A3; CN104093943B

Abstract

The invention relates to a facility (2), in particular a power plant (2), comprising a steam turbine (8) and a bypass station (10) for diverting a working medium, as required, for the steam turbine (8) around the steam turbine (8), wherein at least one resonance absorber (20) is provided for the bypass station (10).

Description

description

System and method for damping acoustic vibrations in a corresponding system

The invention relates to an installation, in particular a motor ^¬ plant comprising a steam turbine and a bypass station as needed 'diversion of working medium for the steam turbine to the steam turbine. The invention further relates to a method for damping acoustic vibrations in a corresponding system.

In power stations, there is often a need to take measures to reduce the noise emission of the power plant, so as not to exceed the permitted limits for the noise emission.

For example, in a corresponding power plant

Steam turbines used, it is also typically a Um ^¬ control station for the diversion of a working medium for the steam turbine around the steam turbine provided as needed. As a rule, such a bypass station comprises a pipeline, with the aid of which the working medium is passed directly into a condenser instead of through the steam turbine. In this case, the pressurized working fluid in the pipeline often generates low-frequency sound with a frequency between 125 Hz and 8 kHz, which is transmitted via the pipeline into the condenser. The condenser acts like a loudspeaker, which emits the sound to the environment. This can not only lead to the annoyance of adjacent residential areas, but in the worst case to exceeding the permissible limits, which precludes granting the operating permit of the power plant.

To reduce the noise emission, it is currently customary to construct elaborate throttle systems, for example builds from different perforated sheets to place inside the pipe.

Based on this, the present invention seeks to provide a simpler solution for reducing the noise emission of power plants.

This object is achieved by a system with the features of claim 1. The dependent claims include in part advantageous and in part self-inventive developments of this invention. In addition, the object is achieved by a method having the features of claim 11.

The plant is in particular a power plant for the generation of electrical energy or an assembly of a corresponding power plant. The plant in this case comprises a steam turbine and a diverter for diverting needs ^¬ have a working medium for the steam turbine to the steam turbine around, wherein at least one resonance absorber is provided for the diverter. Resonance absorbers, as they are known in principle to those skilled in the art, are used primarily when it is expected that a sound emission with individual discrete frequencies or a few narrow frequency bands. Since in a system with a diverter station of the type initially mentioned a frequency spectrum of the sound emission is given, which is dominated by individual frequencies or a few narrow frequency bands in the range of less than 500 Hz, sometimes even higher, resonance absorbers are suitable for use in such installations with relative simple technical means to attenuate the noise emission frequency selective, so that the characteristic of the sound absorber modified by the modified sound emission is changed so far that on the one hand, the prescribed limits are exceeded and on the other hand noise pollution adjacent residential areas is avoided.

The resonance absorber is designed as a Helmholtz resonator. Corresponding Helmholtz resonators are well known to the skilled person. Known and used in a variety of technical fields for manipulating the noise emission of devices or the acoustics in rooms. Accordingly, available to ^¬ sive data and experience, on the basis of an adaptation of such a Helmholtz resonator to the realities of the system with reduced technical complexity can be realized.

Expediently, an embodiment of the system in which the bypass station comprises a pipeline and in which the resonance absorber is essentially formed by an at least partially circulating around the pipe chamber, the ^¬ preferably distributed over several preferably evenly on the order ^¬ catch the pipeline Breakthrough openings connected to the pipe conductively. The construction of the construction ^¬ group of pipeline and resonance absorber is thus substantially cylindrically symmetrical, the manufacturing cost of a corresponding assembly is kept low. Alternatively, a variant of the system is provided in which the bypass station comprises a pipeline and in which the resonance absorber is essentially formed by a chamber positioned next to the pipeline, which chamber is connected in a sound conducting manner to the pipeline via a resonator neck. This variant can be realized with a relatively ^¬ low technical effort.

In addition, an embodiment of the system is advantageous in which the Helmholtz resonator is designed as a controllable Helmholtz resonator, wherein the resonance frequency of the Helmholtz resonator is adjustable. The adjustment of the resonance frequency is preferably carried out by varying the volume of a Helmholtz resonator Reso ^¬ nanzkörpers of, by example, a piston is displaced in a cylinder. In this way, the resonance absorber in the installed state on the system in which it is installed, vote, so that according to the common parts principle for different systems, a single resonance absorber type can be used. In addition, an embodiment of the system is expedient in which a plurality of resonance absorbers are provided for damping one frequency or one narrow frequency band. In addition, depending on the design variant, the resonance absorbers are additionally coupled with absorption silencers, so that a specific damping behavior which is particularly well tuned to the respective installation is provided. The absorption silencers are thereby formed typically by an absorbent material such as mineral wool or stainless steel wool ^¬ comprising at ^¬ least one resonance absorber is incorporated in at least one resonant body.

Is expedient further a variant of the plant, wherein the resonance absorber between a cooling medium injection and a capacitor is positioned, as in this particular Be ^¬ experience has shown that the sound generation is rich. In general, the resonance absorber is preferably at the location of the highest

Sound pressure arranged.

Another advantage is a variant of the system in which the resonance absorber has a resonator and wherein a tempering system is provided for the resonant body, with a substantially uniform temperature for the entire resonator is specified. By controlling the temperature of the resonator uniform edge ^¬ conditions and consequently a given by the geometry of the resonator natural frequency spectrum can be specified ^differently for this. In exactly this frequency spectrum then takes place the attenuation of the sound emission by the resonance absorber.

In an advantageous embodiment of the resonance body to specify the uniform temperature is flowed through an additional supply line from the working fluid. In this case, the working medium used to specify the uniform temperature for the resonant body is preferably taken from a position in the line system for the working medium before the cooling medium injection. The removal takes place here in particular dere with the help of a simple spur line, so that the effort to realize the tempering plant is at a very low level. Moreover, it is advantageous if the resonance body for draining condensate has drainage openings. This variant is especially advantageous if as

Working medium water vapor is used, since in this case it can be assumed that otherwise condensate would accumulate in the resonant bodies, whereby the damping characteristic of the resonance absorber would gradually deteriorate.

Embodiments of the invention will be explained in more detail with reference to a schematic drawing. Show:

1 in a block diagram representation of a bypass station with a resonance absorber, FIG 2 in a sectional view of the structure of the resonance absorber and

3 shows a sectional view of an alternative diverter station with an alternative resonance absorber.

Corresponding parts are provided in all figures with the same reference numerals. In the embodiment described below, the On ^¬ position 2 is part of a power plant for generating electrical energy and for this purpose comprises a steam generator 4, a condenser 6, a steam turbine 8, a diverter 10 and a substantially constructed from piping management system 12, which comprises connects individual previously mentioned modules together and which is used to conduct a working ^¬ medium, here water and water vapor. As shown in FIG 1, are given by the conduit system 12 for the water or the What ^¬ serdampf two possible routes, being passed in a load operation of the steam through the steam turbine 8 and wherein in a load-free operation of the water vapor through the diverter station 10 is headed.

A very expedient design variant of the Umleitsta ^¬ tion 10 is shown in FIG 2 in the manner of a block diagram Darge ^¬ represents. Constructed, the diverter station 10 from a Lei ^¬ processing pipe 14, which is connected via a controllable diverter valve 16 to the conduit system 12th By an appropriate control of the diverter valve 16, a Wech ^¬ sel between the two relevant here operating modes of the system 2, ie load operation and no-load operation, make so if necessary, the steam generated in the steam generator 4 instead of the steam turbine 8 through the Umleitsta ^¬ tion 10 and thus passed through the conduit 14. Downstream of the diverter valve 16 is a ^{Wassereinsprit ¬} tion 18, which is used if necessary for cooling the water vapor flowing through the conduit 14. After this

Flow through the diverter 10 or the steam turbine 8, the water vapor is introduced into the condenser 6 and brought there for condensation. Finally, the water thus returned to the condenser 6 is subsequently returned to the steam generator 4 by means of a water pump.

To reduce the noise emission of the system 2 into the diverter station 10, a resonance absorber 20 is integrated, which as indicated in FIG 3 by way of example of three along the Lei ^¬ tung tube 14 arranged in a row Helmholtz resonators is constructed 22nd Each Helmholtz resonator 22 is formed by a hollow-cylindrical resonating body or an at least partially circumferential resonance chamber, which is connected in a sound-conducting manner to the conduit 14 via a plurality of ^elongated holes 24 distributed over the circumference of the conduit 14. In addition, for each resonator chamber of the corresponding Helmholtz resonator 22, at least one drainage tion opening 26 is provided, via which a resulting in the resonance chamber condensate can flow with gravity support. An alternative embodiment of the resonance absorber 20 is shown in FIG. Here, a single Helmholtz resonator 22 is provided with a single cylindrical resonance chamber, which is positioned between the water injection 18 and the condenser 6, as viewed in the flow direction of the steam, and is arranged next to the conduit 14. The Helmholtz resonator 22 is in this embodiment via a single acting as a resonator neck 28 opening conductively connected to the conduit 14 sound conducting. Furthermore, as indicated in FIG. 4, the Helmholtz resonator 22 is embodied as a controllable Helmholtz resonator 22 in which the resonant frequency or rather the resonant frequency spectrum can be set. For this purpose, the volume of the resonance chamber is varied by a change in position of a stamp 30 by means of a controlled electric motor to ^¬ 32nd In this way, the resonance absorber 20 can on the structural conditions of the system 2 on the one hand and the current Betriebsbe ^¬ conditions fine-tune on the other hand.

In addition, water vapor, if necessary, with the aid of a controllable pump 34, is introduced into the resonance chamber of the Helmholtz resonator 22, wherein the corresponding Was ^¬ serdampf is removed via a stub 36 at a position in front of the water injection 18 from the conduit 14. As a result, the walls of the Helmholtz resonator 22 with relatively little technical effort such tempe ^¬ ration that a uniform temperature for the entire Helmholtz resonator 22 is given and the penetration of steam / water mixture or steam with possibly changing temperature is prevented in the resonator.

The invention is not limited to the above described example from ^¬ guide. Rather, other variants of the invention can be derived therefrom by the person skilled in the art without departing from the scope of the invention. In particular, furthermore, all the individual features described in connection with the exemplary embodiment can also be combined with each other in other ways, without departing from the subject matter of the invention.

Claims

claims

1. Annex (2),

in particular power plant (2),

comprising a steam turbine (8) and a bypass station (10) for bypassing, as required, a working medium for the steam turbine (8) around the steam turbine (8),

wherein at least one resonant absorber (20) is provided for the bypass station (10),

characterized in that

the resonance absorber (20) is designed as a Helmholtz resonator (22).

2. Plant (2) according to claim 1,

characterized in that

the bypass station (10) comprises a pipeline (14) and in that the resonance absorber (20) is essentially formed by a chamber (22) revolving at least partially around the pipeline (14) and extending over several of the circumference of the pipeline

Pipeline (14) distributed through openings (24) to the pipe (14) is conductively connected.

3. Plant (2) according to claim 1,

characterized in that

the bypass station (10) comprises a pipeline (14) and in that the resonance absorber (20) is essentially formed by a chamber (22) positioned next to the pipeline (14) and communicating with the pipeline (14) via a resonator neck (28) ) is connected sound conducting.

4. Plant (2) according to one of claims 1 to 3,

characterized in that

the Helmholtz resonator (22) as a controllable Helmholtz resonator (22,30,32) is listed, in which the Resonanzfre ^acid sequence is adjustable.

5. Plant (2) according to one of claims 1 to 4, characterized in that

a plurality of resonance absorbers (20) are provided for damping each of a narrow frequency band.

6. Plant (2) according to one of claims 1 to 5,

characterized in that

the resonance absorber (20) is positioned between a cooling medium injection (18) and a condenser (6).

7. Plant (2) according to one of claims 1 to 6,

characterized in that

the resonance absorber (20) has a resonance body (22),

wherein for the sound box (22) a tempering system

(34,36) is provided, with a substantially uniform temperature for the entire resonator (22) is specified.

8. Plant (2) according to claim 7,

characterized in that

the resonance body (22) for setting a uniform temperature via an additional supply line (36) from

Working medium is flowed through.

9. Plant (2) according to claim 7 and 8,

characterized in that

the working medium used to specify the uniform temperature for the sound box (22) is taken from a position in the line system (12) for the working medium before the cooling medium injection (18).

10. Plant (2) according to claim 7,

characterized in that

the resonance body (22) for draining condensate drainage openings (26).

11. A method for damping acoustic vibrations in systems (2) with a steam turbine (8) and with a Umleit ^¬ station (10) for diversion of a Arbeitsmedi ums for the steam turbine (8) to the steam turbine (8) around, characterized in that

for damping at least one in the bypass station (10) integ rierter resonance absorber (20) is used.