RU2619668C1 - Noise-absorbing structure - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: noise-absorbing construction is made in the form of a set of absorbing resonators, installed with a certain step relative to each other and forming a space lattice. Resonator chambers are made in the form of coaxial cylinders of different diameters, preferably one to three, whose ratio of throat diameter to their length is 1:4-6, and placed in such a way that the distance from the resonator neck to the front side of the enclosing structure does not exceed the resonator length, and the distance between the resonators is not less than 4-6 diameters of the largest chamber of the smallest resonator. The axis of symmetry of the coaxial cylinders of resonators is perpendicular to the direction of the incident wave.

EFFECT: increasing the efficiency of noise absorption and reduce vibration.

2 cl, 3 dwg, 2 tbl

Description

The invention relates to industrial acoustics, in particular to broadband sound absorption and reducing dynamic loads on buildings and structures, and can be used in various industries, in particular in construction: building envelopes, architectural panels and screens; facing of buildings and premises; noise-absorbing building structures for elevator shafts; sound-absorbing building structures along highways; protective structures of hazardous production facilities in other industries.

Existing methods for increasing the soundproofing properties of reinforced concrete floors, at least by 6 dB, require increasing its thickness by about two times. This is also true for walls of any homogeneous material - brick, foam concrete, glass, metal, etc. In this connection, multilayer structures are used that allow to increase the sound insulation of walls and floors without a significant increase in their mass. The vibration level of building structures can be reduced in the following ways: by detuning the structure from resonance (during harmonic vibrations) by changing its rigidity, mass, or structural design (introducing rigid nodes, turning split structures into continuous ones, changing the dimensions of spans, etc.).

Despite the above methods, the application of the method of noise isolation and vibration reduction directly in building envelopes, the authors do not know, since, a priori, this method is still considered a dead end.

The closest analogue to the claimed invention is a sound-absorbing panel according to the patent of the Russian Federation No. 2323793, publ. 05/20/2008, IPC F01N 1/04, containing a frame and a sound-absorbing insert located in its internal cavity.

Known sound-absorbing panel is an additional panel used in conjunction with building envelopes. The sound-absorbing panel of the prototype does not reduce the dynamic load on the building; It has a relatively low noise reduction due to the partial reflection of sound waves from the sound absorber, as well as a relatively narrow (extremely high frequencies> 800 Hz) noise reduction range.

The objective of the invention is to obtain walling, combining the possibility of sound absorption and vibration reduction over a wide range.

The technical result of the claimed invention is to increase the noise absorption efficiency and reduce vibration by creating a noise absorption structure consisting of a set of absorbing resonators, each of which provides damping of waves of a certain frequency.

The technical result is achieved due to the fact that in the building envelope (in the part of the enclosing structure) a noise-absorbing structure is formed, made in the form of a set of absorbing resonators installed with a certain step relative to each other and forming a spatial lattice, while the cavity chambers are made in the form of coaxial cylinders different diameters, preferably from one to three, the ratio of the diameter of the throat of which to their length is 1: 4-6, and placed so that the distance t resonators throat to the front side of the partition structure is less than the cavity length, and the distance between resonators is not less than 4.6 diameter of the largest chamber smallest resonator, wherein the coaxial resonators cylinder axis of symmetry perpendicular to the direction of the incident wave.

To increase the efficiency of absorbing resonators of the enclosing structures, the cavity chambers can be filled with a finely divided fraction, for example, crushed waste from cable products or sodium bicarbonate NaHCO ₃ (baking soda).

Absorbing resonators of a sound-absorbing design provide damping of waves at given frequencies and reduce vibration from exposure to infrasound, sound, ultrasound and shock waves.

Each resonator for the absorbent structure can be made with the number of chambers in the form of coaxial cylinders of different diameters, preferably from one to three.

For a resonator made in the form of two coaxial cylinders, the neck of the resonator is a cylinder with a smaller diameter, and the camera is the next coaxial cylinder with a larger diameter.

For a resonator made in the form of three coaxial cylinders, the neck of the resonator is the cylinder with the smallest diameter, and the chamber is the next two coaxial cylinders.

In this case, the axis of symmetry of each resonator should be located perpendicular to the incident noise or vibrational wave to ensure the greatest efficiency of the absorbing resonator.

The resonator, made in the form of from two to three coaxial cylinders of different diameters, it is more expedient to perform when the ratio of the diameter of the throat of the resonator to its height in the ratio 1: 4 ... 6. This ratio was established experimentally.

The mutual arrangement of the resonators in the body of the building envelope is selected from the condition that the distance between the resonators should be at least 4-6 diameters of the largest chamber of the smallest resonator. This ratio is due to the exclusion of the mutual influence of scattering of the allocated frequencies on neighboring resonators.

Filling the resonator chambers, forming a noise-absorbing structure, for example, with crushed cable waste products or NaHCO ₃ sodium bicarbonate, increases the sound-absorbing properties due to the increase in heat losses in the resonator chambers due to the transfer of noise wave energy to thermal energy.

The substances for filling the cavity chambers were selected experimentally on the basis of experimental tests. To prevent the precipitation of substances from the chambers of the resonators, the bottom of the resonator is closed with a stopper, for example, sealed with paper, or encapsulated during manufacturing or construction.

The invention is illustrated by photographs: in FIG. 1 is a photograph of a longitudinal section of a sound-absorbing structure made in a building envelope with resonators in the form of three coaxial cylinders of different diameters.

In FIG. Figure 2 shows a photograph of a sound-absorbing structure in which the resonators are filled with shredded waste from cable products and staggered.

In FIG. Figure 3 shows a photograph of a standard brick made with two-chamber resonators filled with waste cable products.

A sound-absorbing structure with resonators absorbing various given frequencies, for example, the natural frequencies of buildings, structures, the noise frequency of an urban environment, impact noise, can be formed in the body of a building envelope by various methods.

For example, resonators can be made in the nodes of a plastic (for example, polyethylene) grid. In this case, the noise-absorbing structure made in the form of a mesh can be attached to the outside of the building envelope. After that, a layer of plaster is applied to it, 2 times the length of the resonators, which provides the condition for placing the resonators in the body of the structure.

Absorbing resonators can be formed in the plates of enclosing structures, representing a spatial lattice and located in the nodes of this lattice, during construction work by placing them in the body of the structure together with the reinforcement, followed by pouring concrete. The dimensions of the spatial lattice and the location of the resonators in its nodes are determined at the design stage.

In addition, a set of resonators for absorbing one or more frequencies can be performed in building stones, in particular in bricks. In this case, to implement noise absorption and reduce dynamic loads, they create a project for laying resonators in the form of cladding a building (structure) with building stones, the structure of which includes the presence of resonators that suppress noise and dynamic loads in a given frequency range (package).

Sound-absorbing design works as follows.

The inventive sound-absorbing design provides an increase in the dissipative ability of sound absorption directly in the building envelope, including the supporting. This allows you to abandon a number of design schemes that do not ensure the operation of the applied additional noise absorbing materials throughout the life cycle of the building and structure. A sound wave (vibration) is dissipated directly in the body of the building envelope.

A sound (shock) wave incident on a building envelope, passing through its body, is destroyed when absorbed by resonators due to the transfer of the energy of sound and vibration waves to thermal energy. Absorbing resonators are selected based on the requirements determined on the basis of the design characteristics and conditions of the building or structure, as well as on the results of measured, predicted impacts on the building envelope to ensure the safety of users.

The operation of the sound-absorbing structure with various substances filled in the cavity chambers in the form of a fine fraction depends on the density of these substances, that is, on the adiabatic compressibility of the medium. From the point of view of the goal of reducing noise, the purpose of using fillers is to reduce the quality factor of the resonator, the result of the latter is the absorption of noise and converting it into thermal energy.

Table 1 presents the results of experimental studies of the absorption of noise by resonators on the models of building envelopes with various types of absorbing resonators. Number 1 is a layout without a resonator.

Based on the results of tests with a sound-absorbing design with 2- and 3-chamber resonators in the form of coaxial cylinders, the results of which are presented in table. 1, prove a high degree of noise absorption in the frequency range 31.5 - 16000 Hz.

Table 2 presents the results of tests on the sound absorption of resonators made in brick with and without aggregates (Fig. 3). Seven 2-chamber resonators in the form of coaxial cylinders with diameters of 8 and 12 mm were made in the facing brick. The length of the chambers is taken equal to its four diameters, the volume of the resonator (second chamber) is 5.42592 ⋅ 10 ^-6 m ³ .

As can be seen from the table for different frequencies, different placeholders should be selected. So, placeholder No. 1 worked effectively at frequencies of 37.5, 63, 125, and 8000 Hz, and placeholder No. 2 turned out to be more effective only at a frequency of 8000 Hz. The presence of experimental data makes it possible to identify the most effective combinations of resonators with or without various fillers.

In addition, vibration damping tests were carried out with a sound-absorbing design with three-chamber resonators with chamber sizes: diameter of the first chamber 6 mm, length of the first chamber 5 mm; the diameter of the second chamber = 8 mm, the length of the second chamber 5 mm; the diameter of the third chamber is 10 mm, the length of the third chamber is 5 mm and a single-chamber resonator with a chamber diameter of 4 mm and a length of 16 mm, which completely dampens the vibration at a frequency of 8 Hz. In other samples studied at this frequency, a decrease in vibration from 5.7 to 28.4 decibels was observed. The efficiency of the resonators at different frequencies changed with a change in the set of resonators with a different number of chambers, which confirms the need for preliminary selection of resonators to create a sound-absorbing structure taking into account the required absorption frequencies to expand the absorption band of noise and vibration.

In the case of the location of sound-absorbing resonators in the nodes of the plastic mesh, it can be used as a geogrid for asphalt concrete used in road construction, which will reduce road noise.

Building envelopes, for example, buildings that separate the internal space of the room from the external environment, and also divide the space into adjacent rooms (partitions, ceilings, walls, etc.), both external (or external) and internal are designed taking into account the arrangement of resonators in them for frequency dissipation.

The use of a sound-absorbing structure can provide not only an increase in the life of a building and structures, but also ensure its stability in the event a calculated shock wave is exposed to the building, since part of the energy of the shock wave will be dissipated in the resonators and will be converted into thermal energy. Due to what the transition time of a building (structure) into resonance at the frequencies of natural vibrations from loads arising from the action of a shock wave (Δр_f ∙ Δt) will increase. Thus, ceteris paribus, buildings (structures) in which the project provides for the suppression of natural frequencies with the help of resonators placed in the body of enclosing structures will withstand a greater load from the shock wave than a building (structure) that does not use a system for damping natural vibrations.

Claims (2)

1. Sound-absorbing design made in the form of a set of absorbing resonators installed with a certain step relative to each other, forming a spatial lattice, while the cavity chambers are made in the form of coaxial cylinders of different diameters, preferably from two to three, the ratio of the diameter of the throat of which to their length is 1: 4-6, and placed in such a way that the distance from the neck of the resonators to the front side of the enclosing structure does not exceed the length of the resonator, and the distance between the resonators is At least 4–6 diameters of the largest chamber of the smallest resonator, the axis of symmetry of the coaxial cylinders of the resonators is perpendicular to the direction of the incident wave. 2. The sound-absorbing structure according to claim 1, characterized in that the cavity chambers are filled with a finely divided fraction, for example, crushed waste from cable products or sodium bicarbonate.

Images