FR2934894A1 - Noise absorbing device for use during practice of firing of missile from e.g. rifle, has partitions partially moved inside firing channel along firing axis such that partitions are moved along firing axis during firing of missile - Google Patents

Abstract

The device has an inner firing channel (31) divided into chambers (33) defined by inner partitions (34). The partitions are centrally traversed by a hole (36), and are covered on one of their faces (341, 342) with plates (35) made of sound absorption materials i.e. mineral wool based material. The partitions covered with the sound absorption materials are arranged at a distant from each other and are partially moved inside the channel along a firing axis (32) such that the partitions are moved along the firing axis during firing of a missile (39).

Description

FIELD OF THE INVENTION The field of the invention is that of the damping of the noise generated by the firing of a projectile by means of a weapon. fire.

The invention relates more particularly to a sound damping module for damping the noise generated by such a shot in the near environment of the shooter as well as in its vicinity. 2. State of the Prior Art and Drawbacks The firing of a projectile by means of a firearm generates at the exit of the barrel of the weapon a detonation which is accompanied by the propagation of sound waves. that is to say a very rapid and intense variation of the pressure of the ambient environment. It is the existence of these waves and their propagation which confer on the detonation its harmful character on the sound plan and its destructive character. These waves animate the ambient air of a vibratory movement (continuation of overpressures and depressions) which spreads gradually in all directions of space. These waves propagate as well as come to hit the eardrums of the shooter, but also those people in its immediate vicinity and in a more distant neighborhood. The pressures and depressions caused by these waves on the eardrums generate acoustic phenomena measurable by their physical characteristics. These acoustic phenomena are the intensity, measured in decibel (dB) and the frequency, measured in hertz (Hz). The human ear generally only perceives sounds in a certain frequency range between about 20 Hz and about 20 kHz. The minimum audibility threshold varies depending on the frequency between about 5 dB and about 85 dB. The maximum audibility threshold varies according to the frequency between about 85 dB and about 135 dB (Wegel graph). The threshold of hearing pain is around 120-130 dB, however, the ears can be damaged from 85 dB (threshold of hearing danger).

In addition to the loudness and frequency of sound, the duration of exposure to sound is also an important risk factor for hearing. Depending on the duration of the sound, there are: - pulsed sounds, less than 300 milliseconds; - impulsive sounds, less than 1 second; - continuous sounds, greater than 1 second. For continuous sound with a sound level of: - 85 dB, it is not necessary to monitor the exposure time; - 95 dB, the tolerable daily exposure time without protection is 1 hour; - 100 dB, the tolerable daily exposure time without protection is 15 minutes; - 105 dB, the tolerable daily exposure time without protection is 5 minutes; - 121 dB, the tolerable daily exposure time without protection is 7 seconds. The detonation of firearms is an impulse sound whose sound level measured at 1 meter from the muzzle usually reaches an intensity of 132-165 dB. In the absence of an obstacle, when the sound level measured at 1 meter from the mouth of the gun is 165 dB, the level measured at 100 meters from the barrel mouth is 145 dB, the one measured at 300 meters is 135 dB, the one measured at 600 meters is 129 dB and the one measured at 1000 meters is 125 dB. The intensity of the firearm detonation is therefore beyond the threshold of hearing pain to a radius of 1000 meters from the point of fire. As a result, not only the shooter, but also those close to him within a radius of less than 50 meters, are at high risk of serious hearing impairment. This is also the case for people who are in a neighborhood farther from the firing point.

In addition, the tolerable daily exposure time without noise protection accompanying projectile firing with a firearm is only a few seconds. It is therefore recognized that exposure to the detonation of firearms has an impact on hearing. Such exposure may result in temporary hearing loss, making the ear more likely to be damaged in the future due to noise or even more serious injuries resulting in irreversible hearing loss. Thus, the amortization of the detonation appears indispensable in the context of the practice of shooting by firearm. This is to prevent the risk of hearing loss and / or hearing impairment for the shooter, people in the immediate vicinity and people in a more distant neighborhood, and to limit noise pollution. it causes. This damping can be achieved by wearing individual hearing protections. Many individual protections have been developed and particularly adapted according to the type of use and the duration of wearing. In this respect, two types of individual protections can be distinguished: - internal ear plugs, and - external headphones. Classic earplugs are made of memory foam that is compacted with the fingers before inserting them into the ear. Once in the ear, they deform and tend to return to their original shape and completely seal the ear. The effective protection, ie the acoustic damping, provided by these plugs is of the order of 8 dB at 40 dB for a frequency range from 63 Hz to 8000 Hz. However, it has been evidence that prolonged use of earplugs could promote the formation of earwax plugs in the ear as it blocks the normal flow of earwax to the outside.

The protective helmets have the advantage of not having this disadvantage. These helmets consist of a hoop that fits on the top of the skull and a shell at each end of the hoop to cover the ears of the user. The shells are lined with a sound insulator that attenuates the sounds that reach the ear. The effective protection of the headphones that are currently on the market is in the range of 8 dB to 40 dB for a frequency range from 63 Hz to 8000 Hz.

The caps and helmets that have just been described can effectively damp the loudness to which the wearer is exposed. Wearing a hearing protection helmet or caps, alone, however, does not always provide effective damping sounds that have an intensity of around the threshold of hearing pain. It is thus advisable, in such a situation, to wear a double protection, that is to say plugs and a helmet. In addition, hearing protection helmets, like caps, are means of personal protection, providing only the protection of the person wearing them.

In the end, earplugs and hearing protection helmets are insufficient to provide effective protection for shooters and their neighbors. In this context, noise damping devices intended to damp the detonation of a firearm shot in the immediate vicinity of the firing point and in its more distant neighborhood have been developed. The patent application bearing the number FR-A1-2 783 908 discloses such a device. In particular, this document describes a regular firing tunnel having the shape of a rectangular parallelepiped whose inner walls are constituted by a flexible and elastic foam-like cellular material capable of absorbing part of the waves generated by the detonation.

Such a device is advantageously used in shooting stands outdoors and indoors. It partially mitigates the noise resulting from projectile firing by means of a firearm whose barrel has previously been inserted inside the firing channel. However, the level of sound attenuation obtained by the implementation of such a device remains insufficient and needs to be improved. In particular, such a device does not prevent a part of the sound waves generated by the firing of a projectile spreads outside the device on the shooter's side. OBJECTIVES OF THE INVENTION An object of the invention is therefore to provide a noise-absorbing device caused by the firing of a projectile by a firearm, which makes it possible to effectively reduce the intensity of the detonation. In particular, the object of the invention is to propose such a device which has improved damping capacities compared to those of the prior art. Another object of the invention is to provide such a device that significantly protects the noise of both the shooter and the surrounding people. Yet another object of the invention is to provide such a versatile technique, that is, one that can be adapted to several types of firearms. The invention also aims to provide such a technique that is simple and inexpensive to implement. 4. Objectives of the invention These objectives, as well as others which will appear thereafter, are achieved by means of a device for damping the sound of firing a projectile, along a firing axis, by means of a gun having a barrel, said damper device defining a firing tunnel extending along said firing axis and having an inlet for at least partial insertion of said barrel and an exit through which the projectile is ejected .

According to the invention, said firing channel of such a device is divided into a plurality of chambers by partitions, said partitions being traversed at their center by an opening and being covered on at least one of their faces by a material. with sound absorption, said partitions covered with said sound-absorbing material being distant from one another and being at least partially movable within said channel along said firing axis so that said partitions are able to move along said axis of shot during a projectile shot. As already explained, the firing of a projectile by means of a firearm is accompanied by the emission of a detonation. The sound waves generated by this detonation animate the ambient air with a vibratory movement (following overpressures and depressions relative to the ambient pressure) that spreads from one to the next and in all directions from space to space. inside the firing canal.

The implementation of rooms delimited by isolated partitions (that is to say at least partially covered by sound absorption material) distant from each other can trap a portion of these waves so that they remain imprisoned inside the damping device and are absorbed therein.

For example, during their propagation inside the firing channel, some waves encounter a first partition. Part of them is then absorbed by the material covering this first partition, while another part is reflected, diffracted or diffused to a second partition. Again, a part of these waves is absorbed while the other is reflected diffracted or diffused to another wall, this phenomenon reproducing an infinity of times. Thus, the presence of these rooms defined by isolated partitions distant from each other is as many obstacles to the propagation of sound waves outside the damping device. Also, the sound intensity propagated outside the damping device will be even lower than the waves generated by a detonation will encounter isolated partitions inside the firing channel. This particular configuration also prevents sound waves propagating outside the firing channel towards the shooter. In addition, the repercussion of these waves against the movable partitions in their guidance, causes at least a partial movement of the partitions from front to back along the axis of fire. By at least partial movement it is understood that the whole of the partition moves back and forth along the firing axis, or that only a portion of the partition moves along this axis, for example the makes of its elasticity. This displacement or this elastic deformation of the partitions contributes to increasing the absorption of a part of the sound intensity. In a preferred embodiment of the invention, said partitions are secured to the inside of said channel by means of connecting and / or guiding elements ensuring locking in translation along said firing axis of at least two of their members. opposite ends.

It is noted that an end may be formed by a longitudinal edge or an angle of a partition. This particular configuration allows to block in translation along the firing axis at least two opposite ends of the partitions while allowing their movement in the other directions. Thus, the ends of the partitions being partially free, the passage of sound waves through the perforating light of an insulated partition generates its deformation along the firing axis in the form of oscillations from front to back because of its elasticity. In a variant, it may be envisaged that each of the angles of the partitions is locked in translation along the firing axis and free in the other directions. In this way, the stress printed on a partition by the propagation of sound waves will be uniformly distributed through it, which then deforms in a regular manner. According to yet another variant, it may be envisaged to implement means for guiding the partitions in translation along the firing axis and return means 30 tending to return them to an equilibrium position. Thus, the passage of sound waves through the light of a partition will generate on it a force able to overcome the force printed on the partition by the return means so that the partition will oscillate back and forth according to the axis of fire. According to an advantageous characteristic of the invention, said partitions have a first face facing said inlet, said first face being covered by a sound-absorbing material. The fact of covering the face turned towards the entrance of the partitions makes it possible to capture a part of the waves propagating in the direction of the exit of the firing channel. These waves are partially absorbed directly by the sound-absorbing material, the others being diffused, diffracted or reflected substantially in the direction of the entry of the firing channel. This makes it possible to limit the number and the intensity of sound waves that can propagate outside the damping device towards the target. According to another advantageous characteristic of the invention, said partitions have a second face facing said outlet, said second face being covered by a sound-absorbing material. The fact of covering the face turned towards the entrance of the partitions makes it possible to capture a part of the waves propagating in the direction of the entry of the firing channel. Part of these waves are identically directly by the sound-absorbing material, the others being diffused, diffracted or reflected substantially towards the exit of the firing channel. This implementation therefore makes it possible to limit the number and the intensity of sound waves that can propagate outside the damping device in the direction of the shooter. Preferably, said firing channel is formed by a box, said box 25 having internal walls covered by a sound-absorbing material. Thus, during their propagation inside the firing channel, the sound waves, or at least most of them, encounter the sound-absorbing material which at least partially covers the inside of the tunnel. This has the effect of absorbing part of the intensity of these waves. It is therefore understood that the use of a technique according to the invention makes it possible to limit the sound intensity of the detonation which is dispersed outside the noise damping device. Preferably, the surface of each of said slots (36) represents between 8 to 40% of the surface of the partition (34) through which it passes.

Such proportions make it possible to obtain the formation of obstacles large enough to make it possible to limit the propagation of sound waves outside the noise-damping device while limiting the risks of deflection of the projectile. According to an advantageous characteristic, said sound absorbing material is a rock wool material. It may especially be a TONGA type white material marketed by Saint Gobain. In this case, said sound-absorbing material advantageously has a thickness of between 25 and 100 millimeters. The use of this type of material has the advantage of being able to absorb effectively, at least in large part, the sound waves propagating inside the firing channel. 5. List of Figures Other features and advantages of the invention will be clear from reading the following description of a preferred embodiment, given by way of a simple illustrative and nonlimiting example, and the accompanying drawings. among which: - Figure 1 shows a perspective view of a noise damping device according to the invention; Figure 2 is a partial perspective view of the device illustrated in Figure 1; - Figure 3 illustrates a longitudinal sectional view of a noise damping device according to the invention; FIG. 4 illustrates the propagation of sound waves inside a noise damping device according to the invention; - Figures 5a and b illustrates a variant in which the box of a device according to the invention is slidably mounted along columns so as to allow its height adjustment. 6. Description of an embodiment of the invention 6.1. BACKGROUND OF THE GENERAL PRINCIPLE OF THE INVENTION The general principle of the invention is based on the use, within a sound-absorbing device for firing projectiles by means of firearms, of remote insulated movable partitions. from each other so as to define rooms.

This particular implementation makes it possible in particular: to imprison in the interior of the damping device a large proportion of the sound waves generated by the detonation resulting from the firing of a projectile so that they are absorbed therein; - prevent their spread outside the device on the shooter's side; 15 - optimize their absorption by moving the partitions from front to back along the axis of fire this setting in motion resulting from the firing of a projectile. The implementation of the invention therefore makes it possible to significantly dampen, at least in comparison with the techniques of the prior art, the dispersion of the noise generated by a firearm shot both in a close environment only in an environment further away from the shooter. In other words, the implementation of the invention allows both to preserve the health of the gunman, but also those of the surrounding people, and more generally to reduce the nuisance caused by the firing of projectiles by means of weapon fire. 6.2. EXAMPLE OF AN EMBODIMENT OF THE INVENTION In connection with FIG. 1, an embodiment of a device for damping the sound of firing a projectile by means of a firearm according to FIG. 'invention. As shown in this FIG. 1, such a damping device 10 comprises a box 11. This box 11, which has a substantially parallelepipedal shape, is formed by the assembly of four boards 21, 22, 23, 24 on four spars 25, as shown more clearly in Figure 2. The boards 21, 22, 23, 24 respectively constitute an upper wall, a bottom wall, a right side wall and a left side wall of the box 11. These boards are preferably carried out by means of plywood plates having a thickness of about 10 millimeters. In this embodiment, the top 21 and bottom 22 walls measure 1,800 by 720 millimeters, and the right 23 and left 24 side walls measure 1,800 by 720 millimeters. The spars 25 are constituted by wooden battens having a section of 60 by 40 millimeters, and a length of 1,800 millimeters. The ends of this box 11 are closed by means of boards 12, 13. They are also made from plywood plates approximately 10 millimeters thick. These boards 12, 13 are each traversed by a slot 14, 15. The slots 14, 15 have a substantially rectangular outline. They may of course have a different shape contour, for example of oblong, oval, or other shape, in variants of this embodiment.

The light 14 constitutes an input intended for the at least partial introduction of the barrel 381 of a firearm 38, as shown in FIG. 3. The light 15 constitutes an exit allowing the ejection of a projectile 39 shot with this firearm 38.

Such a damping device 10 may for example rest on the ground by means of tripods or trestles 16 to any other equivalent means. It is intended to be placed in the axis of a target 17. In a variant illustrated in FIGS. 5a and 5b, the box 11 can be slidably mounted at each of its ends on columns 51 in such a way that its height can be adjusted for example according to the size of the shooter.

These columns 51 are connected transversely by sleepers 52. The height adjustment may for example be obtained by operating a lever acting on a gear cooperating with a worm formed on the columns 51. Figure 3 is a longitudinal sectional view of the damping device 10 illustrated in Figure 1. As shown in this Figure 3, all the inner walls of the box 11 are lined with plates 35 of sound-absorbing material. These plates 35 are held there by gluing, screwing or any other suitable fastening means. The inner walls of the box 11 then constitute isolated walls. The damping device 10 defines an interior firing channel 31. This firing channel 31 extends along a firing axis 32 and is divided into a plurality of chambers 33. In the present embodiment, the housing comprises six 33. Chambers 33 are here delimited by five internal partitions 34. These partitions 34 are preferably made of plywood plate having a thickness of the order of 10 millimeters. They are covered, on at least one of their face, by a plate of sound-absorbing material 35 so that they constitute isolated partitions. These insulated partitions 34 have a height substantially equal to the distance separating the upper insulated walls 21 and lower 22, and a width slightly smaller than the distance separating the insulated right 23 and left 24 lateral walls of the caisson i 1. The partitions 34 have an first face 341 turned towards the inlet 14 and a second face 342 turned towards the exit 15. In this embodiment, all the faces 341 facing the inlet 14 are covered with a sound absorbing material plate 35. while only the faces 342 facing the outlet 15 of the first two walls 34 are covered with a plate 35 of sound-absorbing material. In variants, it may be provided that only the faces 341 facing the inlet 14 are covered with sound-absorbing material. It may also be provided that only the faces 342 facing the outlet 15 are covered with sound-absorbing material. It may further be provided that all the faces 341 and 342 are covered with such a material. The insulated partitions 34 are separated in pairs so as to allow the creation of the chambers 33 inside the damping device 10. The distance 5 separating these isolated partitions 34 may be regular or not. Each of the insulated partitions 34 is traversed at its center by a slot 36. These slots 36 extend in the extension of the slots 14 and 15 respectively constituting the inlet and the outlet of the box 11. They also have a contour identical to those -this. In this embodiment, these lights have a height equal to about 40 centimeters and a width equal to about 30 centimeters. More generally, the shape and dimensions of these lights are chosen in such a way that a shooter can have in sight the target he wishes to aim at while the barrel of his firearm is engaged inside the device. In addition, the area of a light in this embodiment is of the order of 30% of the area of the partition through which it passes. This proportion may however be in a range of 8% to 40% depending on the use case. It is noted that values in this range give a device according to the invention a high level of performance in terms of sound absorption. The insulated partitions 34 are held inside the box II by means of connecting elements 37. These connecting elements are constituted by wooden battens having a section of 60 by 40 millimeters. These cleats 37 are attached to the upper 21 and lower 22 walls by gluing, screwing or any other suitable fastening means. They extend parallel to the boards 12, 13 and each join two consecutive longitudinal members 25, as shown in FIG. 2. These cleats 37 are separated in pairs by a distance approximately corresponding to the thickness of a wall 34. isolated. These cleats protrude inside the firing channel 31 over a distance d of the order of 20 millimeters. They thereby ensure a locking in translation along the firing axis 32 of two opposite ends of each of the isolated partitions 34. They do not provide any blocking of these ends along an axis perpendicular to the firing axis 32. The lower and upper ends of each of the isolated partitions 34 are free to move along a vertical axis perpendicular to the axis of shot 32.

The dimensions and materials used indicated above have been communicated for information only. Other materials and other dimensions can of course be implemented. 6.3. Operation of a noise-damping device according to the invention The operating principle of a sound-absorbing device for firing a projectile according to the invention will now be explained. As shown, a damping device 10 according to the invention is intended to rest on the ground so that the firing axis 32 is located in the axis of the target 17 (see Figure 1).

Before firing a projectile by means of a firearm, a shooter at least partially introduces the barrel 381 of his weapon 38 into the firing channel 31 by introducing the barrel 381 through the barrel. 14. The firing of a projectile 39 is accompanied by the emission of a detonation. The sound waves generated by this detonation animate the ambient air with a vibratory movement (following overpressures and depressions relative to the ambient pressure) that spreads from one to the next and in all directions from space to space. This phenomenon is illustrated in FIG. 4, which schematically represents the propagation of sound waves inside the damping device 10 according to the invention.

A relatively weak part A of the waves emitted by the detonation propagates directly outside the damping device by the exit towards the target 17. The other part of these waves collide, during their propagation inside the device, the insulated interior walls of the box 11 and / or the insulated partitions 34.

The waves striking the insulated interior walls of the box 11 are partially absorbed, scattered, diffracted and reflected, the non-directly absorbed portion propagating again inside the firing channel 31 meeting in their path other isolated partitions or the insulated inner walls of the box 11. This phenomenon is repeated an infinity of times. The waves striking the insulated partitions 34 are also partially absorbed, scattered, diffracted and reflected, the non-directly absorbed part propagating again inside the firing channel 31 also meeting in their path other isolated partitions or the walls insulated interior of the box 11. This phenomenon is repeated an infinity of times. It is therefore clear that the creation of chambers 33 inside the box 11 by means of isolated partitions 34 spaced apart from each other is particularly interesting. In particular, these chambers can trap a portion of these waves so that they remain trapped inside the damping device and are absorbed. The presence of these chambers 33 defined by these isolated partitions 34 spaced from each other constitutes obstacles to the propagation of sound waves outside the damping device 10. Finally, the sound intensity propagated outside the damping device will be even weaker as the waves generated by a detonation will meet with isolated partitions inside the firing channel. In addition, the implementation of these chambers and these isolated partitions also makes it possible to constitute obstacles to the propagation of waves in a direction opposite to that of projectile fire. In other words, the technique according to the invention not only limits the propagation of sound waves towards the target 17, but also towards the shooter. Moreover, the propagation of the sound waves inside the firing channel 32 engenders an elastic compression of the isolated partitions 34, and is consequently accompanied by a displacement of these insulated partitions 34 from front to back along the axis shooting 32.

This deformation phenomenon, which is favored because of the particular structure of the guiding means 37 of the insulated partitions 34, greatly contributes to improving the absorption of the sound waves by reducing their intensity in both directions when they cross the partitions. 6.4. Advantages The implementation of the technique according to the invention therefore makes it possible in particular: to reduce the quantity of sound waves propagating towards the target outside the damping device; to reduce the amount of sound waves propagating towards the shooter outside the device; to reduce the intensity of the sound waves propagating outside the damping device. The technique according to the invention thus makes it possible to limit the exposure of the shooter and of the neighboring persons to the sound waves emitted during a shooting of a projectile at the firearm, and consequently to reduce the harmful effect that they can exercise both their health and their well-being. The technique according to the invention also has the advantage of being particularly versatile in that the modification of its dimensional characteristics makes it possible to use it for projectile firing using a wide range of firearms. A device according to the invention can thus be implemented for all firearms, from the smallest caliber (22 LR) to the largest calibres used in open shooting stands outside. It can be used for all types of handguns (pistols, revolvers) and long guns (rifles, carbines) with smooth or striped barrel. Tests have been conducted to demonstrate the effectiveness of a noise damping device according to the invention. Table 1 indicates the noise damping values at the output of a noise damping module according to the invention used for firing with different weapons. Such a device makes it possible to reduce the noise emitted directly at the output of the device from 15 to nearly 30 dB.

Calibres Weapon type used Noise reduction at the output of the noise absorber 8 * 64S Mauser 98K -15 dB (c) 7/08 GIS / Mas36 -18.6 dB (c) 45 Smith and Wesson ACP -26 dB ( c) Table 1: noise damping at the output of a noise damping module according to the invention Table 2 shows the sound damping measured outside the sound absorber at different distances from the firing point. As shown in this table 2, the implementation of a device according to the invention reduces by nearly 40 dB (c) and nearly 70 dB (c) the noise emitted at 30 meters and at 200 meters from the firing point. Caliber Weapon Measurement Distance to Sounding Damping Point 7/08 SIG / MAS36 30 meters -36 dB (c) 7/08 SIG / MAS36 200 meters -61.5 to -66.4 Db (c) Table 2: sound damping measured at different distances from the firing point

Claims (8)

REVENDICATIONS1. A device (10) for firing a projectile firing sound, along a firing axis (32), by means of a firearm (38) having a barrel (381), said damper device (10) defining a channel (31) firing along said firing axis (32) and having an inlet (14) for the at least partial introduction of said barrel (381) and an outlet (15) for ejecting said projectile (39). ), characterized in that said channel (31) is divided into a plurality of chambers (33) by partitions (34), said partitions (34) being traversed at their center not a light (36) and being covered over at least one of their faces by a sound-absorbing material (35), said partitions (34) covered with said sound-absorbing material (35) being spaced from each other and being at least partially movable within said channel (31); ) along said firing axis (32) so that said partitions (34) are able to move along the said firing axis (32) during a projectile firing (39). 2. Device according to claim 1, characterized in that said partitions (34) are secured within said channel (31) by means of connecting elements and / or guide (37) ensuring the locking in translation according to said firing axis (32) of at least two of their opposite ends. 3. Device according to any one of claims 1 and 2, characterized in that said partitions (34) have a first face (341) facing said inlet, said first face (341) being covered by a sound-absorbing material ( 35). 4. Device according to any one of claims 1 to 3, characterized in that said partitions (34) have a second face (342) facing said outlet, said second face (342) being covered by a sound-absorbing material ( 35). 5. Device according to any one of claims 1 to 4, characterized in that the surface of each of said slots (36) is between 8 to 40% of the surface of the partition (34) it passes through. 6. Device according to any one of claims 1 to 5, characterized in that said firing channel (31) is formed by a box (11), said box (11) having internal walls covered by a sound-absorbing material (35). 7. Device according to any one of claims 1 to 6, characterized in that said sound-absorbing material (35) is a rock wool material. 8. Device according to claim 7, characterized in that said sound-absorbing material (35) has a thickness of between 25 and 100 mm.