DK142467B - Muffler. - Google Patents

Description

V P Bl / OD PUBLICATION 1 K2kSl VL- / DENMARK (51) lnt'3 ^ ^ ^ 1 ^ 06 // eo4b 1/82 '(21) Application No 2512/75 (22) Filed on 4 Jun. 1975 (24) Race day 4 Jun. 1975 (44) The application presented and the petition published on 5 · nOV · 1 9o0

Dl THE RECTORATE FOR.

PATENT AND TRADE MARKET (30) Priontet requested from it

5. jun. 1974. 7407 ^ 68, SE 17 · Dec. 1974, 7415822, SE

(71) GLASS CONTROL AB, Kamrergatan 19, S-211 56 Malmoe, SE.

(72) Inventor: Bjoern Ingvar Nystroem, Grevie 1, S-245 00 Staffanstorp, SE.

(74) Plenipotentiary in the proceedings:

Hofman-Bang & Boutard Engineering Company__ (54) Silencer.

The invention relates to a sound attenuating device of the kind set forth in claim 1.

Muffler designs of various kinds are known in the past.

Among other things, it is known to design silencers such that the desired silencing is achieved by interference effect. This is so that both gas and sound are passed along two or more roads with different path lengths and then brought together, whereby the difference in path length between a pair of paths is an odd complete multiple of half the wavelength of the sound which must be attenuated. This results in silencing or attenuation of the sound by interference effect.

2 142467

When attenuating low frequency sound, which has a wavelength of approx.

However, from about 1-10 m, the wavelength difference becomes significant, and consequently the sound attenuating device takes up a lot of space and is clumsy.

The invention aims to avoid this disadvantage and to provide a sound attenuating device which is simple in its construction, less in scope than previously known devices of similar kind, and which is suitable for sound attenuation of, for example, vehicles, compressors, building elements and the like. A particular aspect of the invention relates to such a device for sound attenuation of a building element, such as a sound attenuating vent element in residential buildings, which element allows for fresh air to be entrapped in the living space, but excludes noise, and in particular low frequency noise, such as traffic noise.

The object of the invention is achieved by means of a device of the kind mentioned in the preamble, which device is characterized by the characterizing part of claim 1.

Hereby, the transmission characteristics of the maximum attenuation of the partition should be such that the sound intensity of the sound which has passed the first path is substantially equal to the intensity of the sound which has passed the second path before the interference occurs.

According to the invention, the length of one of the different lengths of the road is thus reduced to almost zero by being replaced by the partition. This results in a more compact construction.

It is possible to perform the device according to the invention with multiple input openings, but for convenience, it is preferable to have only one input opening, whose cross-sectional dimension preferably extends to at most 1/4 of the lowest wavelength of the sound to be attenuated. At the frequency range up to 400 Hz this implies a cross-sectional dimension of approx. 2 - 3 dm. In this dimensioning, the function of the sound attenuating device becomes independent of the angle of sound to the device.

In its simplest design, the first path of device 3142467 according to the invention consists of a single channel which, in conjunction with the partitioned second path, only causes attenuation or extinguishment of a single frequency. Therefore, for quenching or attenuation with several different frequencies, it is preferable to design the first path as several independent and preferably parallel channels having different lengths adapted to the respective frequencies. Similar results can generally also be obtained in a simpler way by forming the first path as two sub-columns connected at one end by an oblique, slot-shaped opening, whereby the total path length along one edge of the columns is longer than along the other edge. These differences in the total path length are, as in the first case, adapted so as to cause extinguishing or attenuation of undesirable sound at different frequencies in the context of sound transmitted via the second membrane-supplied path.

Also, to limit the transmission of sound at higher frequencies, it is appropriate to provide the device with sound-absorbing material such as mineral wool, glass wool, foam rubber or the like. The sound-absorbing material is thereby placed on the walls of the first and second paths, whereby it is also convenient to apply sound-absorbing material to the partition itself in order to adapt the sound transmission via the first path to the sound transmission that occurs via the second path.

Preferably, the partition or diaphragm is impermeable to gas, but very good sound attenuation can be obtained even in the case where the diaphragm not only allows passage of sound but also allows some passage of gas. Thus, the membrane or partition may have some gas permeability, e.g. in the form of perforations, so as to achieve some improvement in the gas flow, without causing any significant detrimental effect on the sound attenuated properties.

It will be appreciated that the permeability of the partition must, of course, not be so great as to adversely affect the sound attenuating ability of the device, and according to the above, the permeability of sound transmitted over the first and second paths respectively in the main proceedings must be alike. In this context it should be noted that the permeability of the partition depends not only on the size and number of perforations of the partition, but also on the possible insulation material with which the partition is lined. In general, it can be said that the total effect of insulating material and perforations on the gas permeability of the partition must be such that the amount of gas passing through the second path is at most half, preferably at most 1/10 of the amount of gas passing through the first path. .

The sound transmission through the partition is adjusted by appropriate choice of material and thickness. Preferably, the partition is made of a rubber or plastic membrane, but other materials such as metal are also included in the invention.

The hole of claim 11 in the wall containing the exit opening supports the effect of claim 1, because this hole results in an improved gas circulation along the first flow path.

The invention will now be described in more detail with reference to the drawing, in which fig. 1 shows a vertical end section of the device according to the invention, which section is taken along A-A in FIG. 2 and B-B respectively in FIG. 3, FIG. 2 is a side elevational view of the device of FIG. 1, FIG. 3 is a side elevational view of another embodiment of the device of FIG. 1, in which embodiment the first path is provided with an inclined, slot-shaped opening, and fig. 4 shows a vertical end section of an alternative embodiment of the device according to the invention, in which the first path is divided into several channels.

The FIG. 1 and 2, the preliminary embodiment of the device according to the invention is in the form of a box 1, which is provided with an inlet opening 2 for gas and sound and an outlet opening 3 for gas and attenuated sound. The box 1 is provided with an intermediate wall 4 which has an opening 5 at one end thereof. Hereby, the first path is extended which thus extends from the entrance opening 2 up to the opening 5, where the flow of gas and sound is turned 180 ° and then flow down to the exit opening 3. As shown in FIG. 2, the aperture 5 according to one embodiment of the invention may be formed as a horizontal, straight gap. This only achieves silencing or attenuation of one wavelength or frequency sound. In order to obtain attenuation of several different wavelengths or frequencies, the slit-shaped aperture 5 can be inclined as shown in FIG. 3, whereby the total wavelength of the first path 2-5-3 becomes longer along one side (the right in FIG. 3) than along the other (the left in FIG.

3).

gum shown in FIG. 1, the intermediate wall 4 is also provided with an opening 6 at its other end, i. the end opposite to the end provided with the opening 5. The opening 6 is provided with a membrane 7 which completely covers the opening. Thereby, the second path 2-7-3 is formed which is blocked by the membrane 7 which is substantially impervious to gas, i.e. it may either be completely impermeable to gas or may exhibit some permeability to gas, e.g. because it is perforated, as shown in FIG. 1 and 4, By dimensioning the first path 2-5-3 and the second path 2-7-3 such that they have a difference in path length which constitutes an odd integer multiple of half the wavelength of the sound desired attenuated, is achieved at the output of the output port 3 extinguishing or attenuating the sound.

The construction described above is primarily arranged for attenuation of low frequency sound at a frequency of up to 400 Hz, such as traffic noise, which sound is difficult to attenuate otherwise, e.g. with sound-absorbing material. However, in order to also limit the device's transmission of higher frequency sound, it is convenient to coat the box 1 with sound-absorbing material 8, such as mineral wool or glass wool.

As shown in FIG. 1 and 2, the device according to the invention, preferably for residential purposes, is provided with a hole 16 just above the opening 5 in the wall containing the outlet opening 3. This hole is to prevent the circulation of air along the first path 2. -5-3 is stopped by stagnant hot room air, which tends to accumulate in the upper part of the slit 2-5-3 at the opening 5, and instead by chimney effect ensure that the air circulates in the desired manner. The hole 16 need not have any extensive dimensions to achieve the desired effect, but a diameter of the order of 2 cm is sufficient. Obstructed air circulation due to a stagnant plug of hot air has previously posed a significant problem, which by the measure described above has now found its solution. It can be added that the hole 16 has no noticeable effect on the sound attenuating properties of the device.

In FIG. 4 shows a further preferred embodiment of the device according to the invention. For reasons of clarity, the device of this figure does not show any sound-absorbing material, but it will be appreciated that it is of course possible to provide this device with such as in the device of FIG. First

With the same reference numerals as in the previous figures for corresponding parts, the device of FIG. 4, thus, of a box 1 with an inlet opening 2, an outlet opening 3, an intermediate wall 4 and a diaphragm 7. However, to extinguish or attenuate sound at several different frequencies, the first path of the device according to FIG. 4 is divided into two pieces of channels 9 »10 and 11, 12 by a further intermediate wall 13 being arranged between the intermediate wall 4 and the outer walls of the box 1. The aperture 5 of FIG. 1 is hereby divided into two openings 14 and 15, i.e. one for each of channels 9> 10 and 11, 12, respectively.

It will be appreciated that it is possible, and in many cases even convenient, by introducing additional partitions to divide the first path into more than two channels. For simplicity, however, only a division into two channels is shown in FIG. 4th

In order to further illustrate the invention, some examples are given below.

EXAMPLE 1

A device similar to the device of FIG. 1 and 3 were prepared. Hereby, the 1 walls of the box were constructed of 22 mm chipboard, which was cut to a depth of 16 mm in 0.5 dm surfaces for lowering the co-incidence frequency. The width and height of the box 1 were 400 mm and 800 mm respectively. The thickness was 2 dm and the entrance and exit apertures each had a size of approx. 2x3 dm. The intermediate wall 4 consisted of 22 mm chipboard. In aperture 6, a nitrile rubber membrane of 0.5 mm thickness was mounted. The cracks of the device thus produced were sealed with sealant and sound-absorbing material (glass wool) of 20-25 mm thickness applied to the inner walls to limit transmission of high frequency sound. A layer of 50-55 mm thick, sound-absorbing material (glass wool) was applied to the membrane.

The sound attenuating device described above was built into a wall in a sound laboratory so that the entrance opening 2 and the exit opening 3 were located on either side of the wall and the sound-absorbing properties were measured. In the measurements, a mean reduction (Rjjj) for the device of 33 dB and a reduction (Rl 100-500 Hz) of 26 dB were obtained. Also, the wall in which the device was built had an RL value of 26 dB.

EXAMPLE 2

In this example, a sound attenuating device similar to that of FIG. 1 and 3 showed a gas-permeable 0.5 mm thick nitrile rubber membrane measuring 20 cm x 10 cm. This made the one outer wall of the box made of 0.9 mm thick galvanized plate, which was provided with insulation mat of Dempison type of leopal, Malmb. The other walls of the box consisted of 19 mm chipboard. The inner walls of the box were lined with 30 mm thick glass wool insulation of the type Gullfiber Akutex (density approximately 55 kg / rn ^). The membrane was only insulated (about 75 mm thick) on the "room side". The area of the gap forming the first path was 40 cm and the cross-sectional width was 40 mm. The device had a total height of 1.2 m and a total width of 0.3 m. The entrance opening 2 and the exit opening 3 2 each had an area of approx. 200 cm. The device was provided with a limb in front of the exit opening (room side) which could be opened and closed.

The above-described sound attenuating device was built into a wall in a sound laboratory such that the entrance opening 2 and the exit opening 3 were located on either side of the wall and the sound attenuating properties were measured, partly by open limb and partly by closed clay.

In the measurements, a mean reduction number (Rm) of 35.5 dB was obtained

at open limb, as well as 37.5 dB at closed limb. Furthermore, an air sound insulation index (I & lab) of 37 dB was obtained at both open and closed limbs. The specific measurement results are shown in Table 1.

9 142467

Table 1 Reduction (dB)

Frequency Open limb Closed limb - (Hz) _ _ 100 9.7 10.3 125 17.0 19.0 160 24.9 26.0 200 25.7 27.8 250 26.8 31.7 315 30.8 38.6 400 35.7 41.7 500 39.8 45.5 630 42.5 44.9 800 45.8 47.8 1000 45.0 46.6 1250 45.3 46.0 1600 43.9 44 , 1 2000 44.9 44.7 2500 42.1 42.0 3150 44.5 44.2 Example 3

In this example, a device similar to that of Ex.

2, with the difference that the diaphragm was perforated with five 10 mm diameter holes, which provided an "open area" of the diaphragm of approx. 2 percent. When measured in sound laboratory, a mean reduction number (R 1) of 35.6 dB at open limb and 37.1 dB at closed limb were obtained. The air sound insulation index (I & lab) went up to 38 dB and 36 dB at open and closed limbs, respectively. The specific measurement results are shown in Table 2, 10 142467

Table 2

Reduction (db)

Frequency Open limb Closed limb (Hz) ___ _ 100 10.6 8.9 125 17.6 18.1 160 25.3 26.7 200 25.7 30.1 250 26.6 31.7 315 29.9 38 , 3 400 34.5 41.3 500 37 42.9 630 43.1 44.8 800 43.7 46.1 1000 44.2 46.1 1250 43.7 44.9 1600 42.1 43.3 2000 43.9 44.4 2500 42.1 41.7 3150 44.3 44.2

The test results show that the device provided very good noise reduction even in the case where the membrane was perforated.

Also, if the partition in the example above is made of a rubber membrane, it will be appreciated that the partition can be made of various other materials, such as plastic, plate, etc., with the same or similar sound-permeable properties.

It is evident that the device according to the invention has a very good attenuating ability, and, e.g. By incorporating into residential properties, such as a vent element, fresh air is allowed to enter the living space without raising the sound level therein compared to that which exists without the vent element and with a closed window.

That this implies a great advantage is readily realized with regard to the considerable noise problem now found in the big cities.

Claims (7)

11 142467 A sound attenuating device, in particular for low frequency sound attenuation, which allows gas to flow at the same time as sound attenuation occurs by interference effect, by conducting two different paths, the difference in wavelength between the first and second path being a odd complete multiple of half wavelengths of the attenuated sound, characterized in that the device has an inlet opening (2) for introducing gas and sound, an outlet opening (3) for closing out gas and attenuated sound, and in between the first path (2- 5-3, 2-9-10-3, 2-11-12-3) which allow passage of gas and sound, and the second path (2-7-3) which is blocked by a sound-permeable and preferably substantially gas impervious partition (7). Device according to claim 1, characterized in that the cross-sectional dimension of the input opening (2) is at most 1/4 of the smallest wavelength of the sound to be steamed. Device according to claim 1 or 2, characterized in that the first path (2-9-10-3, 2-11-12-3) is divided into several independent channels (9, 10 and 11, 12, respectively). ) of different lengths, thereby providing attenuation of multiple frequencies. Device according to claim 1 or 2, characterized in that the first path (2-5-3) consists of two pieces of sub-columns, which are connected by means of an inclined, slot-shaped opening (5) such that the total path length along one edge of the slits is longer than along the other edge. Device according to any one of claims 1-4, characterized in that the walls of the first path (2-5-3, 2-9-10-3, 2-11-12-12) are provided with sound-absorbing material (8 ). Device according to any one of claims 1-5, characterized in that the walls of the second path (2-7-3) are provided with sound-absorbing material (8). Device according to any one of claims 1-6, characterized