WO2008101452A1

WO2008101452A1 - Broadband-efficient resonator for vibration and noise reduction of vibration-excited components, in particular of technical components

Info

Publication number: WO2008101452A1
Application number: PCT/DE2007/002073
Authority: WO
Inventors: Thomas Borchert; Emilie Debauche; Katharina Kompe
Original assignee: Fachhochschule Dortmund
Priority date: 2007-02-21
Filing date: 2007-11-16
Publication date: 2008-08-28
Also published as: EP2126899A1

Abstract

The invention relates to a resonator for vibration and noise reduction of vibration-excited components (1), in particular of technical components (1), having at least one substantially beam-shaped resonator element (2) which is arranged on a section (3) of the vibration-excited component (1), wherein a damping layer (6) is arranged at least in some sections at or on the resonator element (2). It has surprisingly turned out that a substantial improvement in the damping properties of the entire resonator can be achieved simply by arranging the damping material (6) over only a relatively small area of the resonator element (2).

Description

Broadband-efficient resonator for vibration and noise reduction of vibration-excited components, in particular of technical components

description

The invention relates to a resonator for vibration and noise reduction of technical systems according to the preamble of claim 1.

During the engine operation of machines, plants, vehicles, ships and aircraft, their relatively large-area plate and shell-shaped chassis components are induced to vibrate with structure-borne noise, since the vibrations occur, for example. a variable speed drive motor transmitted to the chassis components. Meet for example Depending on the speed of the drive motor exciter frequencies with natural frequencies of the chassis components together, it comes in weak system damped cases to relatively large amplitudes of these chassis components that stimulate the ambient atmosphere and thus generate airborne sound that is perceived by the environment or the vehicle occupants as a noise. The radiated sound levels are particularly troublesome when resonating the fundamental modes of the chassis components, since then the vibration-rate dependent internal molecular friction of the chassis materials is relatively small and the sound-generating areas of the chassis components are relatively large. But even higher excited natural frequencies and modes of the chassis surfaces - up to the 5th order - are still acoustically relevant for humans.

Manufacturers of engine-driven and thus harmoniously excited technical systems are now seeking, from an environmental point of view and for comfort optimization, the vibration amplitudes leading to the sound radiation and the oscillating surfaces of the vibrations caused by the vibrations, e.g. the drives excited to minimize components.

Against the generation of noise in the case of resonance, for example, such components of the harmoniously excited technical systems Stiffness manipulations, for example by insertion of struts for vibration suppression of the lower resonance vibration modes,

Mass applications for shifting the position of the first natural frequency below the position of the lowest frequency of the harmonic exciter frequency band,

- System damping increases, z. As by flat adapted films with high internal friction

changed.

Disadvantages of the stiffness and mass changes are the lack of broadband efficiency, i. the effect on a larger frequency spectrum, in all the above-mentioned measures, the relatively high production costs that occur and the resulting additional weights.

Conventional vibration absorbers, such as in US Pat. No. 6,478,110 B1, are also only of limited suitability for vibration and thus noise reduction, since they work only in a monofrequential manner in their block-shaped structure, which is to be considered mechanically as a point mass and is usually mounted on spring elements, ie only are aligned with a frequency and do not calm higher natural vibration orders, bring about a relatively high additional mass and, with the coupling to the component to be soothed, generate new potential resonant frequency positions due to the resulting coupling frequencies of the component / absorber system. For example, by a variable-speed engine, cause new acoustic interference.

From DE 101 63 035 A1 and from many other publications, in particular from the field of vehicle technology, it is known to damp the vibrations of the surfaces of the vibrating components at least partially with damping layers of materials to occupy, which have a high internal friction. Such known in automotive technology as so-called. Antidröhnmatten materials have the disadvantages of high costs and additional masses.

From DE 43 43 008 C2 it is known, resonance absorber for damping structure-borne sound vibrations from packets of unilaterally oscillating arranged Me- form tallzungen that are tuned to different resonance frequencies and between the individual layered tongues inserted damping pads, which in turn dampen the vibrations of the tongues. Such packages of tongue-shaped resonance absorbers are complicated to produce due to the large number of conceivable frequencies to be damped and require a large amount of installation space. In addition, you increase the mass of soothing component significantly. Also, the ability to vibrate the individual layers is limited by the damping layer placed between the layers. Similar constructions of resonance absorbers are known for example from DE-PS 1 071 364, DE 21 63 798 C2 and EP 0 020 284 B1.

The object of the present invention is therefore to further develop a generic resonator in such a way that the above-described disadvantages are eliminated and a possible frequency-independent damping of the components over a large frequency range is made possible.

The solution of the object of the invention results from the characterizing features of claim 1 in conjunction with the features of the preamble. Further advantageous embodiments of the invention will become apparent from the dependent claims.

The invention relates to a resonator for vibration and noise reduction in particular technical components, comprising at least one substantially bar-shaped resonator element, which is arranged on a portion of the component. Such a generic resonator is further developed in accordance with the invention by virtue of the fact that at least sections of a damping layer are arranged on or on the resonator element. It has been found that even by only a relatively small-area arrangement of the damping material on the resonator element, a substantial improvement in the damping properties of the entire resonator can be achieved with neither even self-resonator elements alone with a large occupancy of the components to be damped itself To achieve the damping material so. As a result of the geometric variation of the bar-shaped structure of the resonator element, it is possible, in addition to the tuning of the first resonator natural frequency, to be related to the resonator element. - A -

The natural resonant frequency of the basic system can also be used to tune the higher resonator natural frequencies to the higher natural frequencies of the fundamental system (broadband effect). Its strip-shaped design is acoustically uncritical due to its low Schallabstrahlgrades and also allows a geometrical in situ integration into the component to be damped about by slot, for example in multi-walled body panels of a vehicle in the inner surfaces, which are usually covered , In this way, additional masses are completely avoided. The coupling frequency positions in which the beam-shaped resonator element carries out large oscillation amplitudes and potentially causes the mounting surface of the component to oscillate due to its bearing coupling are calmed by largely reducing this feedback effect by a damping layer applied locally preferably in the bearing region of the resonator (FIG Broadband effect). In order not to impair the eradication efficiency, it is also possible to form the damping layer over the entire surface of the resonator element. To distinguish it from the so-called vibration absorber so-called in the art, a resonator is used in the design described here - also in the sense of its multi-eigenfrequential matching to the resonance frequency positions of the component to be damped. In contrast to the stacked arrangements of several layers of elements capable of vibrating one another, the broadband effect of the resonator through the damping layer is ensured even at a low overall height in the design according to the invention. Compared to the full-surface occupancy of the vibrating component with Antidröhnma- materials can be achieved with much less effort in the design according to the invention, the damping effect. Overall, this makes it possible, in particular for the damping of structural parts such as components on machines or the like, to achieve significant reductions in structure-borne noise and hence in acoustic emission with substantially smaller changes in the components.

In a first conceivable embodiment, the damping layer can be formed from a film-like layer with high internal friction. Such a damping layer dissipates a considerable part of the oscillation energy which is coupled into the resonator element and therefore ensures a corresponding reduction in the oscillation energy of the resonator and via its coupling to the vibration-excited component and the vibration energy of the vibration-excited component. In this case, in a further embodiment, the damping layer may be arranged substantially on one side on the resonator element, for example, the damping layer between the portion of the vibration-excited component on which the resonator is arranged, and the resonator element are arranged. Thus, the contact area between the resonator element and the vibration-excited component is decoupled by the damping layer and the damping layer allows only a part of the oscillation energy to pass between the two. In another embodiment, it is also conceivable that the damping layer is arranged at least in sections on the oscillating region of the resonator element. As a result, the oscillation of the resonator element is influenced in a targeted manner.

The resonator element is particularly efficient when it is designed as a cantilever beam.

In a first embodiment, the resonator element can be formed as a separate structural unit and mechanically coupled to the vibration-excited component. In such an adaptive design as an additional component, the resulting additional mass is low and its height relatively flat, since it consists only of a beam. The material of the resonator element is expediently made of a material which can readily vibrate, e.g. in the case of body components, for example, from the material of the vibration-excited component itself. For technical components steel or steel materials because of their good elastic properties.

In this case, the resonator element with a first end region is fixed on one side mechanically to the vibration-excited component and is freely swinging with its other-side bar-shaped region. By the first, fixed to the vibration-excited component end region, the vibration effects between the vibration-excited component and Resonatorelement mechanically securely coupled to each other, while the free-swinging bar-shaped area causes the desired vibration effects, which then by covering with the Attenuation layer does not transmit kinematic feedback effects to the fundamental system.

It is advantageous in this case if the resonator element is coupled to the vibration-excited component by means of an adapter which has a small area relative to the dimensions of the resonator element. If, as proposed in this variant, the resonator element is arranged as an additional structural unit, it is to be provided with a relatively small adapter which is to be formed at least to the same extent as the resonator element itself so that the oscillation amplitudes of the beam-shaped section can be freely performed. The connections between resonator element and adapter as well as between adapter and vibration-excited component can be z. B. run with a high strength industrial adhesive.

It is also possible that the damping layer is formed in the region of the adapter as a damping foil with a one-sided or two-sided adhesive layer, on the adhesive surfaces of which the resonator element and / or the vibration-excited component are glued. The damping layer on the resonator element can be formed only in the region of the adapter, for example by a damping foil with one-sided or two-sided adhesive surface, which in addition to the damping ability also solves the task of fixing resonator element and vibration-excited component together.

In a second embodiment, it is conceivable that the resonator element is formed from the structure of the vibration-excited component itself. The resonator has by its such surface integrative design option no independent and thus possibly disturbing height. As an integrative unit of the vibration-excited component also no additional mass is added, but the resonator element is generated from the vibration-excited component itself. Potential tuning changes with respect to the resonator target frequencies are negligible. In a further embodiment, it is conceivable that the resonator element is integrally formed with the first region from the vibration-excited component and connected to the vibration-excited component and is arranged freely swinging with its opposite bar-shaped region of the vibration-excited component. In this case, the resonator element approximately directly connected in one piece with an end portion of its bar-shaped longitudinal extent with the vibration-excited component and separated over essential parts of its circumference by slots of the vibration-excited component such that the free end of the resonator excited by the vibration to be damped vibration of the vibrated component can oscillate substantially free ,

It is conceivable both in the adaptive and in the integrative embodiment of the resonator element, for example, that the bar-shaped resonator element has a mass between 1/5 and 1/20, preferably 1/10 of the mode-related oscillating mass of the vibration-excited component. The bar-shaped resonator element then has e.g. about 4% of the oscillating mass of each component to be calmed.

Furthermore, it is conceivable that the dimensions of the resonator element in terms of area achieve a larger surface portion of the vibration-excited component than in the case of a bar-shaped embodiment of the resonator element. When the resonator element is tuned to higher natural frequencies of the vibration-excited component, it may be necessary to leave the relatively narrow and long beam dimensions and to provide plate-shaped, spatially significantly larger resonator elements whose sound radiation behavior is likewise uncritical due to the 1/10 modal mass relation. The mounting location of the resonator element is in this case to be positioned between the targeted vibration modes of the vibration-excited component while avoiding layers in vibration node lines.

It is furthermore advantageous if the resonator element tuned to the first resonant oscillation mode is arranged with respect to its arrangement on the vibration-excited component at the location of the fundamental maximum of the respective section of the vibration-excited component. Since the vibrations of the vibration-excited component to be damped are greatest here, the damping effect of the resonator element can best be achieved.

It is particularly advantageous if the resonator element damps the natural vibration of the vibration-excited component multifrequently. Compared to the known from the prior art, conventional measures for vibration reduction, the resonator consistently consistent broadband efficient without additional mass and manufacturing technology is easy to train. The resonator can also be designed from existing vibration-excited components such as chassis elements of vehicles (bifunctionality concept).

In the case of an integrative embodiment of the resonator, it is advantageous for the damping layer to extend beyond the latter into the vibration-excited component at a level of approximately 10% of the length of the resonator element. To optimize the efficiency of the eradication process, the further application should extend over the entire surface of the resonator element.

It is also conceivable to fix more than one beam-shaped resonator element substantially at the same point of the vibration-excited component, preferably with a common adapter on the vibration-excited component, so that these resonator elements in different spatial directions, e.g. From the common adapter projecting freely swinging. As a result, a targeted vibration damping, for example, in complicated designed vibration-excited components.

A particularly preferred embodiment of the resonator according to the invention is shown in the drawing.

Show it:

FIG. 1 shows a schematic representation of the basic construction of a resonator element integrated into the vibration-excited component,

FIG. 2 shows a schematic representation of the basic construction of a resonator element fixedly mounted on the vibration-excited component via an adapter,

FIG. 3 shows a resonator element integrated in the vibration-excited component according to FIG. 1 with a damping layer largely applied over its entire area; Figure 4 - on the vibration-excited component according to Figure 2 firmly over a

Adapter applied Resonatorelementes with a substantially full-surface applied damping layer,

FIG. 5 shows a plot of the oscillation amplitude versus the frequency of an oscillatory system in the form of a plate without a resonator, with an undamped resonator and with a damped resonator according to the invention.

FIGS. 1 to 4 each show very schematic representations of the resonator according to the invention, in which a resonator element 2 is arranged on a vibration-excited component 1 shown as a planar sheet for the sake of simplicity. It goes without saying that both the dimensions and the shape of vibration-excited component 1 and resonator 2 are shown only simplified and are tuned for each case of application of the resonator according to the invention to the respective vibration behavior of the vibration-excited component 1.

FIG. 1 shows diagrammatically a beam-shaped longitudinally extended resonator element 2, which is integrally formed from the material of the vibration-excited component 1 in that a contiguous slot 4 is introduced into the material of the component 1 on three sides of the resonator element 2 and the resonance natorelement 2 so that tongue-like projecting from a fixing area 3 of the component 1. As a result, the resonator element 2 surrounded by the slot 4 and delimited by the component 1 can oscillate freely, the excitation for this oscillation being due to the externally coupled oscillations of the component 1, which are caused, for example, by a drive motor (not shown), which is typically harmonic Vibration on the component 1 transmits.

Due to the free vibration capability of the resonator element 2, this can, coupled to the component 1 as a two-mass system perform a natural vibration and thus in turn affect the vibration of the component 1 in the manner described above. FIG. 2 shows an alternative embodiment of the resonator with a resonator element 2 applied on the component 1 as a separate structural unit, which is spaced apart and arranged essentially parallel to the plane of the component 1. The distance is produced by an adapter 5, which is arranged at one end between component 2 and resonator element 2 and defines, for example, an adhesive connection between component 1 and resonator element 2 to one another. As a result of the region of the resonator element 2 which freely projects away from the adapter 5 at a sufficient distance from the component 1, the resonator element 2 with its cantilevered region can oscillate freely and operate as in the case of the resonator element 2 according to FIG.

If, as shown in FIGS. 3 and 4, the resonator elements 2 shown in FIGS. 1 and 2 are each coated with a high internal friction damping layer 6, such as by adhering a film-like damping layer to the resonator element 2, the oscillation behavior of the resonator element 2 is Elementes 2 in the manner described above improved so that the resulting by the resonator-basic system coupling new coupling natural frequencies are advantageously damped and thus a thorough improvement of the generation of sound can be achieved. The damping layer 6 can be arranged wholly or partially on the surface of the resonator element 2, and it is also conceivable to arrange the damping layer 6 at the point of contact between component 1 and resonator 2 between component 1 and resonator 2 and thus component 1 and resonator 2 vibrationally to decouple from one another to a certain extent.

FIG. 5 plots an oscillation amplitude of an oscillatory system in the form of a plate over the frequency without a resonator (curve a), with an undamped resonator (curve b) and with a resonator of the invention dampened with different materials (curves c and d) which is intended to illustrate a qualitative assessment and illustration of the achievable with the resonator according to the invention damping.

The undamped plate is expected to produce the largest amplitude with a unique maximum at about 122 Hz. When mounting an undamped reso- nators, the maximum amplitude is already significantly reduced with two maxima at approx. 110 Hz and approx. 140 Hz. When a first damping material is attached, the maximum of the amplitude shifts to approx. 135 Hz with a simultaneous significant reduction of the amplitude maximum. By mounting another improved attenuating material, the maximum of the amplitude can be further reduced and, at the same time, a large smearing of the amplitude values over a larger frequency range can be achieved, whereby the acoustic emission can be further reduced.

These values applied only qualitatively clarify the advantageous effect of the inventive design of the resonator impressively.

Part number list

- Resonance element - Resonator element - Fixing section Resonator element / vibration - excited component - Slit - Adapter - Damping layer

Claims

claims

1. resonator for vibration and noise reduction of vibration-excited components (1), in particular of technical components (1), comprising at least one substantially bar-shaped resonator element (2), which on a

Section (3) of the vibration-excited component (1) is arranged,

characterized in that

an attenuation layer (6) is arranged at least in sections on or on the resonator element (2).

2. Resonator according to claim 1, characterized in that the damping layer (6) is formed of a film-like layer with high internal friction.

3. Resonator according to one of claims 1 or 2, characterized in that the damping layer (6) is arranged on one side substantially on the resonator element (2).

4. Resonator according to one of the preceding claims, characterized in that the damping layer (6) between the portion (3) of the vibration-excited component (1) on which the resonator element (2) is arranged, and the resonator element (2) is arranged.

5. Resonator according to one of the preceding claims, characterized in that the damping layer (6) is arranged at least in sections on the oscillating region of the resonator element (2).

6. Resonator according to one of the preceding claims, characterized in that the bar-shaped resonator element (2) is designed as a cantilevered beams.

7. Resonator according to one of the preceding claims, characterized in that the resonator element (2) is designed as a separate structural unit and is mechanically coupled to the vibration-excited component (1).

8. A resonator according to claim 7, characterized in that the resonator element (2) with a first end portion on one side mechanically fixed to the vibration-excited component (1) and freely swinging with its other side bar kenförmigen area.

9. Resonator according to one of claims 7 or 8, characterized in that the resonator element (2) by means of a comparison with the dimensions of the resonator element (2) small-area adapter (5) to the vibration-excited component (1) is coupled.

10. A resonator according to claim 9, characterized in that the Adaptero (5) is formed at least in the same thickness as the thickness of the resonator element (2).

11. Resonator according to claim 9 or 10, characterized in that the

Connections between resonator element (2) and adapter (5) as well as between adapter (5) and vibration-excited component (1) can be produced by means of an adhesive connection 5.

12. Resonator according to one of claims 9 to 11, characterized in that the damping layer (6) in the region of the adapter (5) is designed as a damping film with a one-sided or two-sided adhesive layer on the adhesive surfaces of the resonator (2) and / or the vibration-excited component (1) are glued.

13. Resonator according to one of claims 1 to 6, characterized in that the resonator element (2) from the material of the vibration-excited component (1) itself is formed.

14. A resonator according to claim 13, characterized in that the resonator gate element (2) integrally formed with a first region of the vibration-excited component (1) and connected to the vibration-excited component (1) and swinging freely with its opposite bar-shaped portion of the vibration-excited component (1) is arranged separately.

15. A resonator according to claim 14, characterized in that the resonator element (2) with an end portion of its bar-shaped longitudinal extent with the vibration-excited component (1) is connected directly in one piece and over substantial parts of its circumference through slots (4) of the swing

5 supply-excited component (1) is separated such that the free end of the resonator element (2) excited by the vibration to be damped vibration of the vibratory component (1) can oscillate substantially free.

16. Resonator according to one of the preceding claims, characterized in that the beam-shaped resonator element (2) has a mass between 1/5 and 1/20, preferably 1/10 of the mode-related oscillating mass of the vibration-excited component (1).

17. Resonator according to one of the preceding claims, characterized in that the dimensions of the resonator element (2) in terms of area reach a larger surface portion of the vibration-excited component (1) als5 in bar-shaped configuration of the resonator element (2).

18. Resonator according to one of the preceding claims, characterized in that the tuned to the first resonant mode resonator (2) with respect to its arrangement on the vibration-excited component (1) at the location of the fundamental maximum of the respective Ab-o cut of the vibration-excited component (1) is.

19. Resonator according to one of the preceding claims, characterized in that the resonator element (2) damps the natural vibration of the vibration-excited component (1) multifrequently.

20. A resonator according to claim 19, characterized in that the beam-5-shaped configuration of the resonator element (2) are tuned to the vibration of the vibration-excited component (1) such that the higher natural frequency positions of the resonator element (2) to the higher natural frequency positions of the vibration-excited Components (1) are tuned.

21. Resonator according to one of the preceding claims, characterized in that the damping layer (6) on the resonator element (2), preferably the damping layer (6) between the vibration-excited component (1) and the resonator element (2), the vibration frequencies of the vibrationally excited component (1), in which the bar-shaped resonator element (2) large

Performs vibration amplitudes and the base of the vibration-excited component (1) potentially with animated to vibrational movements, dampens.

22. Resonator according to one of the preceding claims, characterized in that more than one bar-shaped resonator element (2) substantially at the same point of the vibration-excited component (1), preferably with a common adapter (5) on the vibration-excited component (1). is fixed and these several resonator elements (2) in different spatial directions of the vibration-excited component (1) projecting freely swing.

23. Resonator according to one of the preceding claims, characterized in that the damping layer (6) on the integrally formed resonator (2) at least partially, preferably at least 10% of the length of the bar-shaped resonator element (2) on the vibration-excited component (1) itself extends.