RU68008U1 - SILENCING PANEL - Google Patents

Abstract

The invention relates to construction, in particular to devices designed to protect against sound waves (noise), as well as waves of other radiation and their absorption, and can be used in noise screens.

The objective of the invention is to increase the absorption capacity of the panel.

This problem is solved due to the fact that the noise-absorbing panel contains a perforated panel, a blind panel, a noise absorption element located between the perforated and deaf panels, covers for connecting the perforated and deaf panels, and the perforated panel is made with holes in the form of slotted traps with reflectors turned in the side of the noise absorption element, and the perforated panel contains at least two slotted traps, in which the reflectors are located at different angles to the plane of the perforation ovannoy panel.

When carrying out the invention, the following technical result will be achieved: intensification of the interference of sound waves and waves of other radiation inside the noise absorption element with attenuation of their amplitudes.

Description

The invention relates to construction, in particular to devices designed to protect against sound waves (noise), as well as waves of other radiation and their absorption, and can be used in noise screens. State of the art

Noise-absorbing panels are known, consisting of a housing with slotted traps and noise absorption elements located inside the housing. The mechanism of sound absorption consists in the passage of sound and other waves through slot traps into the body, deformation of the noise absorption element due to the action of waves on it and the dispersion of energy from sound and other waves on the noise absorption element. Such panels include those described in RF patents No. 2266997, No. 2222662, No. 2176005, etc.

An analogue of the invention is the “Acoustic panel of a noise shield” according to the patent of the Russian Federation No. 2173372 of 09/10/2001, containing a housing formed by a rectangular frame, rear and front walls and sound-absorbing plates integrated into the housing. This design has the disadvantage that it does not interfere with sound waves and other radiation waves inside the sound-absorbing material due to the fact that the waves inside the sound-absorbing material move parallel to each other.

The closest analogue (prototype) to the claimed invention is a sound-absorbing panel described in RF patent No. 2155252 “Soundproofing screen” dated 08.27.2000. The prototype is made in the form of a parallelepiped and contains a perforated panel, a blank panel, a noise absorption element located between the perforated and blank panel panels, covers for connecting perforated and dull panels, and the perforated panel is made with holes in the form of slotted traps with reflectors turned to the side of the noise absorption element. The panels are made of U-shaped metal sheets. The panel is equipped in the upper and lower parts with vibration damping clamps made in the form of covers with trough-like cross sections that are inserted with an interference fit into the cavity of each panel. The set of essential features similar to the claimed invention can be formulated as follows: a sound-absorbing panel contains a perforated panel, a blank panel, an element

noise absorption, located between the perforated and deaf panels, covers for connecting perforated and deaf panels, and the perforated panel is made with holes in the form of slotted traps with reflectors turned towards the noise absorption element. The disadvantage of the prototype is that it does not interfere with sound waves and waves of other radiation inside the noise absorption element due to the fact that the waves inside the noise absorption element move parallel to each other.

Disclosure of invention

The objective of the invention is to increase the absorption capacity of the panel.

This problem is solved due to the fact that the noise-absorbing panel contains a perforated panel, a blind panel, a noise absorption element located between the perforated and deaf panels, covers for connecting the perforated and deaf panels, and the perforated panel is made with holes in the form of slotted traps with reflectors turned in the side of the noise absorption element, and the perforated panel contains at least two slotted traps, in which the reflectors are located at different angles to the plane of the perforation ovannoy panel.

The invention differs from the closest analogue by the following features:

"... the perforated panel contains at least two slotted traps, in which the reflectors are located at different angles to the plane of the perforated panel."

When carrying out the invention, the following technical result will be achieved: intensification of the interference of sound waves and waves of other radiation inside the noise absorption element with attenuation of their amplitudes.

By means of reflectors inclined at different angles to the surface of the perforated panel, sound waves and waves of other radiation passing through the perforation into the panel are guided to the noise absorption element at various angles, which causes intense interference of sound waves and waves of other radiation inside the noise absorption element with attenuation of their amplitudes . Thus, the mechanism of sound absorption consists not only in the deformation of the noise absorption element and the dissipation of wave energy on it, but also in the mutual damping due to the interference of waves deflected by the reflectors.

The noise-absorbing panel is made in such a way that the ratio of the total perforation area to the wall area of the perforated panel is from 0.2 to 0.4 (it has been experimentally confirmed that this range is most optimal for solving the problem of noise absorption and ensuring panel strength). The wall of the panel is blank and the wall of the perforated panel provides reflection from its surfaces

sound waves and waves of other radiation and the direction of radiation inside the noise absorption element.

The sound-absorbing panel is designed in such a way that the sound-absorbing element is made with a thickness of 30 mm to 100 mm. It has been experimentally confirmed that such a thickness of a noise absorption element made of mineral wool or foam provides the most effective noise absorption at small dimensions. The noise absorption element is placed in a polyethylene shell with a thickness of 0.1 mm to 3 mm. The polyethylene sheath is also involved in the process of absorption of radiation waves of short lengths and, in addition, provides protection for the noise absorption element from getting wet and clogged, for example, by dust.

The sound-absorbing panel is designed so that the wall area of the perforated panel is between 100,000 mm ² and 1,000,000 mm ² . This panel size is convenient to produce, transport, carry and mount in noise-absorbing screens.

Brief Description of the Drawings

In Fig.1 shows a sound absorbing panel.

Figure 2 shows a diagram of the mechanism of noise absorption due to interference of waves.

The implementation of the invention

The sound-absorbing panel (see Fig. 1) contains a perforated panel 1, a blind panel 2, a noise absorption element 3 located between the perforated and blind panels, covers 4 and 5 for connecting the perforated and blind panels, the perforated panel having holes in the form of slotted traps with reflectors 6, 7, 8 and 9, turned inward of the body towards the noise absorption element 3. Perforated panel 1 contains two slot traps, in which reflectors 6 and 7 are located at different angles 10 and 11 (see figure 2) to the perforated plane panel.

The perforated panel is made in cross section (section AA, Fig. 1) in the form of a U-shaped sheet containing a wall 15 and shelves 16 and 17. The wall and shelves of the perforated panel are conjugated at an angle of 75 ° -100 °. The specific value of this angle in the manufacture of the experimental batch was 90 °. The dull panel is also made in cross section in the form of a U-shaped sheet (section AA, FIG. 1) comprising a wall 18 and shelves 19 and 20. The wall and shelves of the dull panel are joined at right angles. The shelves of the walls of the perforated panel and the blank panel are overlapped. The distance 21 between the walls of the perforated panel and the blank panel is from 30 mm to 100 mm. The specific value of this distance in the manufacture of the experimental batch was

51.8 mm. Perforated panel shelves are made of the same or different lengths. In the manufacture of the pilot batch, the length of each shelf of the perforated panel is the same. Shelves of the blind panel are also made of the same or different lengths. In the manufacture of the pilot batch, the length of each shelf of the dull panel is the same.

The noise absorption element is made of URSA mineral wool of type M-15G TU 5763-002-00287-697-97, P-75 GOST 9573-96 with a water-repellent coating in the form of a polyethylene shell. The thickness of the noise absorption element 3 in figure 1 is indicated by 21. The thickness of the noise absorption element is from 30 mm to 100 mm. The specific value of this thickness in the manufacture of an experimental batch of panels was 51.8 mm. The noise absorption element can be made of PSB-S-25 foam according to GOST 15588-86.

The sound-absorbing panel is designed in such a way that:

- the ratio of the total perforation area to the wall area of the perforated panel is 0.29;

- the noise absorption element is performed in a laminated thickness of 51.8 mm;

- the noise absorption element is placed in a polyethylene shell with a thickness of 0.15 mm;

- the wall area of the perforated panel is from 486,000 mm ² .

The perforated panel 1 shown in FIG. 1 contains slot traps in which the reflectors 6 and 7 in the cross section are straight and arranged at different angles to the perforated panel surface 22, the difference in angles being 30 °. The experiments showed that it is advisable to choose the difference in the angles of inclination of the reflectors from a range of values from 0.1 ° to 35 °. In this case, the angles of inclination of the reflectors to the surface of the perforated panel is selected from the range from 10 ° to 70 °. In the experimental batch, the tilt angles were 20 ° and 50 °.

The indicated panel design is used to absorb radiation in the frequency range from 40 Hz to 1015 Hz. Noise absorption experiments were carried out with panels in which the reflectors 6 and 7 in the cross section were rounded with a rounding radius of 10 mm (it is advisable that the rounding radius be made from 5 mm to 15 mm). The waves reflected from which reflector diverge at different angles, which contributes to wave interference.

The sound-absorbing panel operates as follows.

The panel is oriented towards the radiation source so that the radiation falls on the perforated panel. By reflectors tilted under various

angles to the surface of the perforated panel, sound waves and waves of other radiation passing through the perforation into the panel are sent to the noise absorption element at different angles, which causes intense interference of sound waves and waves of other radiation inside the noise absorption element with attenuation of the amplitudes of the radiation waves. The waves are directed into the absorption element, as shown in figure 2 (not across, but mainly along the noise absorption element). The wave amplitudes of various radiation are also attenuated due to the deformation of the noise absorption element and the polyethylene sheath. Thus, the sound absorption mechanism in the claimed device consists in the deformation of the noise absorption element and the polyethylene sheath, the dissipation of wave energy on them, and also in the mutual cancellation of the waves due to the interference of the waves deflected by the reflectors.

Providing the panel with noise absorption in its upper and lower parts with covers 4 and 5 made of polyethylene, it is possible to dampen acoustic vibrations of the structure caused by the action of the sound front of the sound source, and thereby eliminate the possibility of turning the panel noise-absorbing into a source of unwanted acoustic vibrations. With the elimination of acoustic vibrations, the reliability of the noise protection screen is increased (mechanical loads on the screen are reduced), which consists of noise-absorbing panels.

In addition, the polyethylene covers 4 and 5, which fix the perforated and blank panels, play an important role as a damper that dampens the vibration of the panel by noise absorption caused by wind load and impedes their transfer to the racks. This is especially important when installing screens on bridges and overpasses. If the panel is made of aluminum, the covers also carry the function of insulating the panel from the steel profile, thereby preventing electrochemical corrosion. Thus, additional corrosion resistance of the structure is achieved.

The number of slot traps (perforation holes) is selected from the range from 100 to 250 pcs. In practice, slotted traps with various areas of slots (areas of perforation holes) are performed according to the invention. The area of the slits and, accordingly, the area of the reflectors is selected from a range of values from 500 mm ² from 1000 mm ² . For example, a small gap is chosen with an area of 700 mm ² , a large gap is chosen with an area of 750 mm ² .

Thus, the task and the technical result of the invention are achieved.

Claims (4)

1. The sound-absorbing panel, comprising a perforated panel, a blank panel, a noise absorption element located between the perforated and blank panels, lids for connecting the perforated and blank panels, the perforated panel having holes in the form of slotted traps with reflectors turned towards the noise-absorbing element, characterized the fact that the perforated panel contains at least two slotted traps, in which the reflectors are located at different angles to the plane of the perforated panel. 2. The sound-absorbing panel according to claim 1, characterized in that the ratio of the total perforation area to the wall area of the perforated panel is from 0.2 to 0.4. 3. The noise absorption panel according to claim 1, characterized in that the noise absorption element is made with a thickness of 30 to 100 mm and is placed in a polyethylene shell with a thickness of 0.1 to 3 mm. 4. The sound-absorbing panel according to claim 1, characterized in that the wall area of the perforated panel is from 100,000 to 1,000,000 mm ² .