SE522703C2 - Sound-insulating construction comprises sound-absorbent material placed or incorporated in air or gas intake, has width or depth between 50 and 200 mm and length or diameter dependent upon rate of flow - Google Patents

Abstract

The sound-insulating construction comprises sound-absorbent material placed or incorporated in an air or gas intake, has a width or depth (B) between 50 and 200 mm and a length (L) or diameter dependent upon the rate of flow. It has a number of holes (3) extending into the material (1) from one side (4) and through the entire width to the other side (5). Each hole is surrounded by the sound-absorbing material with a thickness which is at least equal to the radius of the hole.

Description

2 The constructions that work better are built into a part of the outer wall, but these constructions have several disadvantages, e.g. they are difficult to clean and work reasonably well in the highest frequency range but hardly at lower frequencies.

The need today is to achieve an attenuation of up to 35-40 dB for the more traffic-prone properties.

Brief description of the inventive concept The object of the present invention is to eliminate the above-mentioned inconveniences and disadvantages of air intake in buildings with noise-exposed locations, which is why sound attenuation is required.

According to the idea of the invention, the above-mentioned problems are solved in that the sound-absorbing construction has a considerable width or depth which is greater than the height of the material, preferably between 50-200 mm, has a selectable length depending on the flow rate 1 / s and has a number of holes next to each other. which extend through the material from the outside and along the entire width, the depth to the other side, each hole being surrounded by the sound-absorbing material having a thickness equal to the radius of the hole. Smaller hole diameter and more sound-absorbing material provide sound-absorbing benefits.

According to the concept of the invention, a sound attenuation device is obtained in an air intake which provides a very good sound attenuation for both the lowest and medium frequencies as the highest frequencies when the holes are small and the surrounding sound absorbing material is thick, which is easy to apply, is easy to clean, is easy to manufacture and thus cheap to manufacture, can easily be varied in length and size depending on the dimensions of the air inlet and 522 705 3 is easy to replace with a new one, if needed.

Brief description of the accompanying drawings Figure 1 shows an embodiment of the sound attenuation device according to the invention seen in perspective obliquely from the side.

Figure 2 shows a section of the sound attenuation device according to the embodiment in Figure 1, seen from the long side.

Figure 3 shows plates or discs intended to be placed along the long sides of the invention according to Figures 1 and 2.

Figure 4 shows another embodiment of the invention where the sound attenuation device consists of two parts placed next to each other with the halen.concentric axis located at a distance from each other.

Figure 5 shows a further embodiment similar to that in figure 4 but with the holes of the parts displaced in relation to each other in longitudinal direction.

Figures 6 and 7 show alternative embodiments of the invention where the hollow side of the device has a cylindrical and / or rectangular shape.

Detailed Description of a Preferred Embodiment of the Invention Figures 1 and 2 show the sound attenuation device according to the invention comprising a strip 1 of a porous foam plastic 2 such as those sold under the trade names Fireflex and Lamiflec 301 DX, which plastic has good sound absorbing ability.

The strip 1 has a height of 25 mm and a width B, depth, of 100 C W PO IQ Q 03 4 mm and a length L which can be cut to the desired length depending on the flow rate. On the long side 4 a large number of holes 3 are accommodated, which are located at a distance from each other, which is approximately the same as the diameter 2r of the holes 3 and which holes 3 extend through the entire width B of the strip 1 to the other long side 5 and around these holes 3, the sound-absorbing material 2 has a thickness at least as large as the radius r of the hole 3. The diameter 2r of the holes is between 10 to 25 mm, preferably 12 to 20 mm.

Along the long sides 4,5 of the sound-absorbing material 1,2, plates or sheets 6,7, see figure 3, with corresponding holes and of some rigid material such as sheet metal or the like, are arranged to shoe the mouths of the holes 3 on the long sides 4,5 of the sound absorbing material 2.

The sound-absorbing foam strip is cut to the desired length and placed in the slot accommodated in the building. The sound as well as the air must pass through the holes 3 in the device according to the invention to enter the room of the building.

Figure 4 shows that the sound-absorbing material 2 can be divided in length into at least two parts 8,9 with a total width B1 + B2, which is smaller than the width B and which are oriented parallel and at a distance D from each other and with each of the parts hole 3 placed opposite each other and with an air gap arranged between the parts 8,9 at D.

The sound-absorbing material 2 can be divided in length into at least two parts 8,9 with a total width of B1 + B2, which is smaller than the width B and which are oriented parallel and at a distance D from each other and with the parts 8,9 of each part hole 3 placed offset (TI FO [0 703 5 longitudinally to each other and with an air gap arranged at D between the parts 8,9, which is shown in figure 5).

Figures 6 and 7 show alternative forms of the sound-absorbing material.

The lowest frequencies will primarily be attenuated by a reactive attenuation during the energy transfer into the holes and out of the holes due to. large impedance differences.

The medium-high frequencies will be attenuated partly reactively as the low frequencies, albeit smaller ones, but will also be attenuated by a resistive attenuation when the sound energy is to penetrate the material. The material will then partly act as a porous absorbent but more porous because the holes give the sound energy a greater opportunity to penetrate into the material. However, the wavelength at these medium-high frequencies is large in relation to the hole diameter, which is why the material as a whole contributes to attenuating the sound energy as there is nowhere possible for adapting the sound wave in the holes through the material. In known constructions with a larger hole or a longer slot, the sound wave can adapt its propagation to these conditions and the transmission becomes much larger through the material.

Thus, since all the lead-through holes are limited in extent in planes, the sound energy at medium frequencies will never be able to propagate as unhindered as in a slit or a larger hole. The highest frequencies are attenuated by the sound-absorbing material around the holes.

The attenuation thus becomes more effective in this frequency range and the lowest and medium frequencies will be attenuated by the dimension of the holes and the sound absorption of the material. The advantage of a number of holes at a certain distance from each other is that the mouth attenuation increases. The geometric relationship between the size of the hole and the wavelength of the sound provides an attenuation according to known principles. The smaller the hole, the greater the attenuation and the better the attenuation at lower frequencies. This orifice attenuation, which is a reactive attenuation due to adjustment losses in the transition l between the sound field in front of the hole orifice and the sound field in the hole, provides an attenuation which decreases with increasing frequency. The reactive attenuation can be enhanced if the holes are terminated at both ends with a board material with sound-insulating ability, e.g. plate.

A slot transmits more sound energy than a hole as the sound wave is easier to adapt to a long slot with the same cross-sectional area than to a hole, so it is more advantageous to use holes instead of using slots.

In addition, it is advantageous to use many holes at mutual distances and surrounded by a lot of sound-absorbing material in order to attenuate the medium-high frequencies when the sound waves meet a larger total area of sound-absorbing material while increasing the amount of sound-absorbing material in contact with the sound. . Lower frequencies will not sense the individual holes but instead react to the sound-absorbing material as a whole.

It will then be perceived as more porous and sound-penetrating than if it were homogeneous. The porosity provides better attenuation for lower frequencies than if the same absorbent surface were placed on opposite sides of an air gap.

The muffler lumï is advantageously used as a muffler in ventilation ducts, as a muffler in exhaust sound traps, in compressed air systems and in all other contexts where pressure variations in a gas are to be reduced in connection between two volumes.

It should be emphasized that the invention can of course be modified within the scope of the invention as expressed in the claims.

Claims (1)

CLAIMS l. Sound-absorbing construction comprising a sound-absorbing material intended to be placed in or included in an air or gas intake, characterized in that the sound-absorbing construction has a width (B) or depth which is substantially between 50-200 mm, has a selectable length (L) or diameter depending on the flow rate l / s, and has a number of holes (3), which extend into the material (1) from one side (4) and through the entire width (B), the depth, to a second side (5), each hole (3) being surrounded by the sound-absorbing material (2) having a thickness (s) which is at least equal to the radius (r) of the hole (3) and that along the long sides of the sound-absorbing material (2) (4,5) are plates or plates (6,7) with corresponding holes and of some rigid material such as sheet metal or the like, arranged to shoe the mouths of the holes (3) on the inside and outside of the sound-absorbing material. let (2). 2. A sound-absorbing structure comprising a sound-absorbing material intended to be placed in or included in an air or gas intake according to claim 1, characterized in that the sound-absorbing material (2) has an elongate shape in the form of at least one strip (1) with the holes (3) are taken up perpendicular to the long sides (4,5) of the material (1). 3. Sound-absorbing construction comprising a sound-absorbing material intended to be placed in or included in a sound-absorbing material according to any one of claims 1-2, characterized in that the sound-absorbing material (2) is divided in length into at least two parts (8,9 ) with a total width (B1 + B2) which is less than the width (B) and which are oriented parallel and at a distance (D) from each other and with the holes (3) of each part placed opposite each other and with a air gap arranged in the space (D) between the parts (8,9). Sound-absorbing construction comprising a sound-absorbing material intended to be placed in or included in a sound-absorbing material according to any one of claims 1-2, characterized in that the sound-absorbing material (2) is divided in length into at least two parts (8 , 9) with a total width (B1 + B2) which is less than the width (B) and which are oriented parallel and at a distance (D) from each other and with the holes (3) of each part (8,9) placed offset in longitudinal to each other and with an air gap arranged in the space between the parts (8,9) - 5. Sound-absorbing construction comprising a sound-absorbing material intended to be placed in or included in a sound-absorbing material according to any one of the claims 1. -4, characterized in that the intake is arranged at a window and in its window frame. 6. Sound-absorbing construction comprising a sound-absorbing material intended to be placed in or included in a sound-absorbing material according to any one of claims 1-5, characterized in that the inlet is arranged at a window and in its window frame.