RU2083775C1 - Sound-proofing panel with maximal sound-proofing property - Google Patents

Abstract

FIELD: mechanical engineering. SUBSTANCE: panel has integral hermetic body 1 made of fluoroplastic material in which sealed is reinforcement 2 with internal space 3 having minimal distance between walls d, where medium vacuum is ensured with provision of condition l ≥ d, where l-length of free travel of molecules. Body 1 externally has sound-absorbing interlayers 4 at face side and interlayers 5 at rear side. Installed inside body 1 and bearing constructions 6 of structure on which body is fastened are magnets 7 with parameters such as polarity and magnetic field strength are so selected that there is no direct mechanical contact between body 1 and bearing constructions 6 and interval 8 is formed between them filled with air. Body reinforcement 2 is used as part of contactless fastening unit as winding of electromagnet 7 included in body and that is in certain places of panel body 1, its structural components 2, 7 are combined into one component (matched). EFFECT: high efficiency. 2 cl, 1 dwg

Description

 The invention relates to technical means of controlling noise in the way of its propagation by sound insulation, i.e. to soundproof panels.

 The most effective is the use of such panels as the enclosing structure of the so-called reverberation chambers, where it is necessary to provide as much as possible multiple reflection of sound (i.e., a large reflectance and a low transmittance of sound through the enclosing structure).

 The prototype of the invention is a device having two walls with an elastic gasket placed between them along the perimeter, with the possibility of evacuating the inner space, the walls being made as part of a sphere facing outwardly convex, and vibration-isolating supports in the form of metal rigidly connected to the walls are placed between the walls and the gasket framework. A vacuum is used as a sound insulating medium in this device. The elastic laying of the prototype is equivalent to the soundproofing laying of the proposed device (performs similar functions).

The prototype of the invention has a number of disadvantages, namely: a small soundproofing ability and the impossibility of technical implementation in accordance with the description, because in the prototype materials:
there is no description of the attachment points of such a soundproofing element to the supporting structures of the structure to which it is attached, and if they are performed arbitrarily, favorable conditions are created for the so-called structural sound to propagate through them, which makes it pointless to increase the soundproofing ability of the remaining structural elements of the prototype,
there is no characteristic of vacuum in the internal space, and from an indirect indication that the vacuum does not conduct sound well, which is available in the description of the prototype, it follows that, obviously, the prototype uses a low vacuum with a low sound-insulating ability, the possibility of using an average vacuum is not provided, there is no relationship between the smallest distance between the walls of the internal space and the length l of the mean free path of the molecules,
reducing the pressure in the inner cavity to the pressure range of the average vacuum is impossible, because the prototype body is not integral, but composite (in this case, there will be a loss of tightness with an elastic gasket placed along the perimeter of the walls of the housing),
there is a loss of damping abilities by this elastic gasket due to the occurrence of compression stresses in it (the gasket is excessively compressed due to the large difference in pressure between the external atmosphere and the vacuum in the internal space).

In addition, the scope of the prototype is limited to the portholes in aircraft, control cabins and the casing of the machine (it is limited by the formula of the prototype, namely, the given shape of its body, while this form does not affect the soundproof ability of the prototype, but complicates operation, worsens the design and etc.)
The objective of the invention is to increase the soundproofing ability to the maximum possible value.

 The object is achieved in that the soundproofing panel with the highest possible soundproofing ability according to the invention has a panel body made integrally and sealed, with a sound-absorbing gasket placed on both the front and back sides of the panel, in the body and on the supporting structures of the structure to which a panel is attached, magnets are placed that form contactless attachment points (magnetic suspension), the parameters of these magnets (polarity and field magnets) are selected so once, that between the panel body and the supporting structures of the structure to which the panel is fixed, a gap is formed filled with atmospheric air, and in the internal cavity of the panel there is an average vacuum characterized by the equality or slight excess of the mean free path of molecules l over the smallest distance d between the walls of the internal cavities.

 Also, the task is achieved by the fact that electromagnets are used in the design of contactless attachment points.

 The task is also achieved by the fact that the panel body is made of metal-reinforced fluoroplastic, and the body reinforcement is used as part of a contactless attachment site as a winding of the electromagnet included in its structure.

An increase in sound-insulating ability is understood primarily as a decrease in the transmittance of sound, which is the ratio of the flow of sound energy that has passed through sound insulation to the common (incoming) flow of sound energy. According to (noise reduction at industrial enterprises, Leningrad State Design Institute, M. Stroyizdat, 1972, p. 58), the sound-proofing qualities of any airborne sound barriers are determined by τ, and any barriers is characterized by the value of sound-insulating ability
R = 10 log1 / τ dB (1)
The technical result of the invention is the complete minimization of the transmittance of sound through the internal cavity τ 0, which leads to the provision of the maximum possible sound insulating ability R ∞ dB. In addition, due to the stipulated design of the contactless attachment points, the transmission of structural sound to the supporting structures of the structure to which the panel is attached is prevented. The average vacuum in the inner cavity makes it impossible to transmit sound through it. According to (Polytechnical Dictionary. Edited by Artabolevsky II Sov. Encycl. 1977, p. 67 68), vacuum is a state of a gas enclosed in a vessel with a pressure significantly lower than atmospheric, and the behavior of this gas is determined by the ratio between the mean free path l molecules or atoms, i.e. the average distance traveled by a particle between its two successive collisions with other particles, and the size d characteristic of a given device or process. The concept of average vacuum is defined there as characterized by the fulfillment of the condition: l ≈ d
Sound waves belong to the so-called elastic waves, where sound energy is transmitted due to elastic vibrations of the medium (due to collisions of neighboring particles). When the pressure of the gaseous medium of the propagation of sound waves decreases compared to atmospheric (low vacuum), the transmission of sound energy decreases, but does not stop completely (prototype). When an average vacuum is created in the medium of sound propagation, it loses the elasticity property, and the transmission of sound through it ceases completely. This is confirmed by the work (Kompaneyets A. Laws of statistical physics. Shock waves. Superdense substance, M. Nauka, 1976, p. 84) under the condition l≥d the transferred momentum is proportional to the number of molecules capable of carrying it and vanishes at full vacuum . If d is the smallest distance between the walls of the internal cavity, under this condition, a particle that transfers sound energy all the way from one wall of the cavity to another simply does not meet another molecule to which it can transfer the energy of sound vibrations transferred to it.

 The one-piece and hermetic enclosure of the proposed panel ensures the maintenance of an average vacuum in its internal cavity for the entire estimated period of its operation.

 Because part of the sound energy can be distributed throughout the body in the form of the so-called structural sound and through the fastening nodes go to the supporting structures of the structure to which the panel is attached, non-contact fastening nodes are provided with an air gap between the panel body and the supporting structures, which prevents the spread of structural sound.

 An additional noise reduction is provided by a sound-absorbing pad placed both on the front (where the sound wave initially gets) and on the back (opposite) sides of the panel (where it prevents the transfer of sound energy into the gap between the building and the supporting structures of the structure).

 Permanent magnets and electromagnets can be used in the design of contactless attachment points (which is more technologically advanced and convenient), but their parameters must be selected in such a way as to ensure that there is no direct mechanical contact between the panel body and the supporting structures of the structure (for the above reasons ) The panel body is made of a material with a high sound absorption coefficient (which increases the efficiency of the panel), namely fluoroplastic, which is also an ideal material for vacuum vessels (traditionally used for their manufacture due to low gas permeability, etc.), in which to ensure greater strength walled reinforcement. This armature can be used as a winding of an electromagnet, which is part of a contactless mount.

 The drawing shows a soundproofing panel with the maximum possible soundproofing ability, cut.

 The soundproofing panel with the highest possible soundproofing ability includes a one-piece and sealed housing 1 made of fluoroplastic, in which a reinforcement 2 of metal is wired, with an internal cavity (characterized by the smallest distance d between its walls), in which the presence of an average vacuum is ensured subject to the conditions l≥d 3, having (case 1) sound-absorbing gaskets on the front 4 and back 5 sides, while magnets are installed in case 1 and the supporting structures of the structure to which it is attached 6 (electric romagnity) 7, their polarity and intensity of the magnetic field are selected in such a way that there was no direct mechanical contact between housing 1 and the supporting structure 6 and between the gap 8 has been formed, filled with air.

 The device operates as follows.

Total incoming stream of sound energy F _Rin incident on the front side of the chassis, according to the law of conservation of energy is partly reflected back to the environment F _Neg partially absorbed by the body substance 1 bar and specifically mounted thereon acoustic gasket 4 F _abs partially passed through the panel P _prop .

_{Neg Rin} F F F + F + _{abs -prop}
The objective of the invention is to reduce the F _prop , due to the fact that the main part of the F _prop attenuates when it enters the internal evacuated cavity 3 due to the absence of elastic medium elements, i.e. sound propagation conditions.

However, part of the _prop in the form of structural sound is distributed along other elements of the panel, i.e., through the housing 1. Since the housing 1 is made of fluoroplastic, i.e., a material with a high sound absorption coefficient, this part of the _prop goes into the _ph . In addition, on the back of the panel there is a sound-absorbing pad 5, which prevents the spread of sound from the back.

 The disadvantage of the prototype distribution of structural sound through the attachment points is fixed due to the presence of contactless attachment points (in the form of magnetic suspension). Because the parameters of the magnets are selected in such a way that between the back side of the housing 1 and the supporting structures of the structure 6 a gap 8 is formed, filled with air, there are no conditions favorable for the propagation of sound in it. Oscillations of the panel relative to the motionless supporting structures 6 are quenched by magnets 7. Thus, a complete minimization of the sound transmittance τ 0 and the maximum possible sound insulating ability h ∞ dB are ensured. In addition, it is possible to install sound-absorbing gaskets not only on the front and back sides, but also on the sides of the panel.

 Soundproof panel with the maximum possible soundproof ability is possible in technical implementation.

 Magnetic suspension (non-contact attachment points) are known for rail vehicles (Polytechnical Dictionary. Ed. Artabolevsky I.I. Sov. Encycl. 1977, p. 267).

 Similar knots of fastening objects with respect to the structure are also known, but not for the purpose of combating noise (Mezentsev V. Miracles. Popular Encyclopedia. Alma-Ata: Main Edition of the Kazakh Soviet Encyclopedia, 1990, p. 8 10, v. 2) the Muslim world enjoys the legend of the soaring tomb of the prophet. The founder of Islam, the prophet Muhammad, was buried in an iron tomb. In the tomb of the prophet there is supposedly a special stone, which holds the iron coffin in a soaring state. More clearly, the force of magnetic attraction should be such that it would be enough to raise the coffin above the floor, and not enough to pull the iron box with the ashes to the ceiling, in which the magnet is hidden.

где l средняя длина свободного пробега молекул, м;
K 1,38•10^-23 Дж/К постоянная Больцмана;
P искомое давление газа, Па;
D диаметр молекулы, м;
T абсолютная температура, К,
при этом

Зная реальную величину для условия l≥d согласно (3) рассчитывают необходимое давление во внутренней полости для газа (в основном воздуха), подставляя в формулу (3) известную величину диаметра молекулы, и температуры газа, характерной для условий эксплуатации. Как правило, требуемое давление лежит в диапазоне 10²>P>10^-1 Па. В конструкции использованы любые виды звукопоглощающих материалов из известных. Звукоизолирующая панель с максимально возможной звукоизолирующей способностью является наиболее эффективным средством звукоизоляции из возможных средств.The housing 1 of the proposed panel is made in compliance with the requirements for vacuum equipment devices, i.e. provides tightness of the internal cavity (reinforced with metal for strength). The required pressure in its inner cavity 3 can be calculated as follows (to ensure the condition l≥d). According to (Kuhling H. Handbook of Physics. M. Mir, 1985, p. 204): it is known that the mean free path of molecules according to the kinetic theory of gases is

where l is the mean free path of the molecules, m;
K 1.38 • 10 ^-23 J / K Boltzmann constant;
P is the desired gas pressure, Pa;
D is the diameter of the molecule, m;
T absolute temperature, K,
wherein

Knowing the actual value for the condition l≥d according to (3), the necessary pressure in the internal cavity for the gas (mainly air) is calculated, substituting the known value of the diameter of the molecule and the gas temperature typical of the operating conditions into formula (3). As a rule, the required pressure lies in the range 10 ² >P> 10 ^-1 Pa. The design used any kind of sound-absorbing materials from known. A soundproofing panel with the highest possible soundproofing ability is the most effective soundproofing method possible.

Claims (3)

 1. Soundproofing panel with the highest possible soundproofing ability, having a body with a sound-absorbing pad, with the possibility of providing a vacuum in the internal cavity, characterized in that the panel body is solid and sealed, with a sound-absorbing pad, which is placed both on the front and on the back panels, and in the case and on the supporting structures of the structure to which the panel is fixed, magnets are placed that form contactless attachment points, a magnetic suspension, the parameters of these polarity and magnetic field strength are selected in such a way that between the panel body and the supporting structures of the structure to which the panel is fixed, a gap is formed filled with atmospheric air, and an average vacuum is ensured in the internal cavity of the panel, characterized by the equality or excess of the mean free path of molecules over the smallest distance between the walls of the internal cavity.  2. The panel according to claim 1, characterized in that electromagnets are used in the design of the contactless attachment points.  3. The panel according to claim 1, characterized in that its casing is made of ferroplast reinforced with metal, and the casing reinforcement is used as part of a contactless attachment site as a winding of an electromagnet included in its composition.