RU2344489C1 - Sound-proof acoustic protection - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: sound-proof acoustic protection contains profiled and perforated walls with a layer of sound-proof material arranged there between, one of the walls being made smooth and the said sound-proof material being arranged in two layers. Note that one of the said layers, more rigid, is solid and profiled, while the other one, a soft layer, is discontinuous and arranged above the first layer surfaces. The production area sound-absorbing elements comprise a skeleton, window openings and doorways, apertures to accommodate lighting fixtures and acoustic screens representing rigid and perforated walls with sound-absorbing material arranged there between. Note that more rigid layer is a continuous and complicated-profile one made up of inclined faces directed downward and jointed to horizontal faces, while the soft layer is a discontinuous one arranged above the rigid layer sound reflecting surfaces, the aforesaid sound absorbing element rigid layer being made from a sound-proof material with sound reflection factor exceeding that of sound absorption and the discontinuous layer elements representing a taper, multi-face pyramid or a figure of rotation formed by the n^th-order curve.

EFFECT: increased efficiency of sound absorption.

4 cl, 2 dwg

Description

The invention relates to industrial acoustics, in particular to broadband sound attenuation, and can be used in all sectors of the economy for sound attenuation of production equipment by sound absorption.

The closest technical solution to the technical nature and the achieved result is a sound-absorbing panel in accordance with a.s. USSR N 348755, class F01N 1/04, 1970 [1], containing a perforated wall and a sound-absorbing layer in which pyramidal cells with vertices facing the inside of the layer are made from the side of the wall.

The disadvantage of the prototype is the relatively low efficiency of sound attenuation due to the partial reflection of sound waves from the sound absorber, as well as the relatively narrow (exceptionally high frequencies) range of sound attenuation.

The technical result is an increase in the efficiency of sound absorption due to the expansion of the frequency range and the secondary absorption of sound waves reflected from the sound absorber.

This is achieved by the fact that in an acoustic enclosure containing profiled and perforated walls, between which a layer of sound-absorbing material is placed, one of the walls being made smooth, and the sound-absorbing material located in two layers, one of which is more rigid, is made solid and shaped, and another, soft, made intermittently and located under the surfaces of the first layer, the sound-absorbing elements of the room contain a frame, window, doorways, openings for luminaires and acoustic ogres expectations made in the form of rigid and perforated walls, between which is a sound-absorbing material located in two layers, one of which is more rigid, made solid and profiled with a complex profile consisting of inclined faces directed downward and connected to horizontal faces, and the other - soft, made intermittently and located under the sound-reflecting surfaces of the first layer, and a continuous profiled layer of sound-absorbing material is made of a material with a reflection coefficient sound more than absorption coefficient, and the discontinuous layer elements are formed as cone or rotating polyhedral pyramid shapes formed by n-th order curve.

Figure 1 shows the layout of the room, figure 2 - the design of the acoustic fencing of the room.

The acoustic enclosure of the premises contains a workshop framework (not shown in the drawing), window 2 and 8, door 9 openings, openings 5 for accommodating lamps and acoustic fences 1, 3, 4, 10, 12 (Fig. 1). Acoustic fencing (figure 2) is made in the form of rigid 13 and perforated walls 14, between which there is a sound-absorbing material located in two layers, one of which, more rigid 20, is solid and profiled with a complex profile consisting of inclined faces 15 and 17 directed downward and connected to horizontal faces 18 (or in the form of conical surfaces). Between the faces 15, 17, 18 and the layer 20 on one side and the rigid wall 13 is a sound-absorbing material 19 having a higher sound absorption coefficient compared to the layer 16, which is made intermittent, for example in the form of a cone, which is located under the sound-reflecting surfaces of the first layer 20 The continuous profiled layer 20 of sound-absorbing material is made of a material in which the reflection coefficient of sound is greater than the coefficient of sound absorption.

Equipment 11 is installed on vibration-isolating supports (not shown in the drawing), window openings 2 and 8 contain vacuum soundproofing double-glazed windows, and metal ceramics with a degree of porosity that is in the range of optimal values: 30 ... 45% are used as sound-absorbing material of the acoustic enclosures of the room and sound absorbers. , or an element is used in the form of a layered and cross winding of porous threads wound on an acoustically transparent frame, for example a wire frame (not shown o), or an element made of a rigid porous sound-absorbing material, for example, metal foam or a shell rock (not shown in the drawing). The proposed acoustic fence provides optimal noise reduction with the following parameters:

a = H / W = 0.2 ... 0.4; b = D / W = 3.0 ... 5.0, where H is the height, W is the width, D is the length of the room;

a / H ₁ = 0.004 ... 0.005; b / H ₂ = 0.1 ... 0.15, where H ₁ is the thickness of the acoustic fence, H ₂ is the distance from the smooth wall of the room to the first composite layer of sound-absorbing material;

H ₁ / H ₂ = 1.2 ... 1.35; d / H ₂ = 0.6 ... 1.25; t / d = 2.5 ... 4.5; where H ₁ is the thickness of the acoustic fence, H ₂ is the distance from the smooth wall of the room to the first composite layer of sound-absorbing material, d is the maximum diameter of the rotation bodies of the intermittent sound absorber located at the focus of the composite first layer, t is the step of the location of the rotation bodies.

Fencing acoustic room works as follows.

Sound waves propagating in the production room interact as follows. Sound energy from the equipment 11 located in the room, passing through the perforated wall 14 of the acoustic fences 1, 3, 4, 10, 12, enters the layers of soft sound-absorbing material 16 (for example, made of basalt or glass fiber), which is intermittent and located under the sound-reflecting surfaces of the first layer 20. The transition of sound energy into thermal energy (dissipation, energy dissipation) occurs in the pores of the sound absorber, which are a model of Helmholtz resonators, where energy losses occur due to friction, which fluctuates with the excitation frequency, the mass of air in the mouth of the resonator against the walls of the mouth itself, which has the form of a branched network of pores of a sound absorber. The perforation coefficient of the perforated wall is taken to be equal to or more than 0.25. To prevent the eruption of a soft sound absorber, a fiberglass fabric, for example, type EZ-100, is located between the sound absorber and the perforated wall. Part of the sound energy is reflected from the more rigid profiled surface 20 and falls, focusing, onto the layers of soft sound-absorbing material 16 made intermittently, the elements of which are made in the form of a cone, a multifaceted pyramid, or a rotation figure formed by an nth-order curve.

An advantage of the invention is its versatility of application for various production facilities having a wide variety of noise characteristics. In this case, it should be noted the relative ease of tuning the acoustic panel to the required frequency range of noise reduction and its economically feasible efficiency (meaning reducing noise to sanitary standards). In addition, coating the body parts with foil prevents the deposition of dust on acoustic fencing, and the implementation of a sound absorber from non-combustible materials makes it fireproof.

The design of sound-absorbing elements of the room proposed by the authors is an effective way to combat industrial noise.

Claims (4)

1. An acoustic enclosure containing profiled and perforated walls, between which a layer of sound-absorbing material is placed, one of the walls being smooth and sound-absorbing material located in two layers, one of which is more rigid, made solid and shaped, and the other is soft, made intermittent and located under the surfaces of the first layer, characterized in that the sound-absorbing elements of the room contain a frame, window, doorways, openings for luminaires and acoustic fencing made in the form of rigid and perforated walls, between which there is a sound-absorbing material located in two layers, one of which is more rigid, made solid and profiled with a complex profile consisting of inclined faces directed downward and connected to horizontal faces, and the other - soft, made intermittently and located under the sound-reflecting surfaces of the first layer, and a continuous profiled layer of sound-absorbing material is made of a material for which the reflection coefficient is AUC greater than the absorption coefficient, and the discontinuous layer elements are formed as cone or rotating polyhedral pyramid shapes formed by n-th order curve. 2. The acoustic enclosure according to claim 1, characterized in that the production room where the sound-absorbing acoustic enclosure is installed has parameters that are in the following optimal ranges of values: a = H / W = 0.2 ... 0.4; b = D / W = 3.0 ... 5.0, where H is the height, W is the width, D is the length of the room. 3. The acoustic fence according to claim 1, characterized in that the ratio of room parameters to the dimensions of the sound-absorbing acoustic fence is in the following optimal ranges of values: a / H ₁ = 0.004 ... 0.005; b / H ₂ = 0.1 ... 0.15, where H is the thickness of the acoustic fence, H ₂ is the distance from the smooth wall of the room to the first composite layer of sound-absorbing material. 4. The acoustic fence according to claim 1, characterized in that the ratio of the parameters of the sound-absorbing acoustic fence is in the following optimal ranges of values: H ₁ / H ₂ = 1.2 ... 1.35; d / H ₂ = 0.6 ... 1.25; t / d = 2.5 ... 4.5; where H ₁ is the thickness of the acoustic fence, H ₂ is the distance from the smooth wall of the room to the first composite layer of sound-absorbing material, d is the maximum diameter of the rotation bodies of the intermittent sound absorber located at the focus of the composite first layer, t is the step of the location of the rotation bodies.

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