RU49045U1 - NOISE PROTECTION - Google Patents

Abstract

The claimed soundproofing structure is intended for use in the construction of soundproofing structures to protect personnel from the noise of powerful water injection units located inside industrial premises. The noise-proof box-shaped structure contains upper and side sound-insulating walls made of profiled metal sheets, on which a sound-absorbing coating is applied. A metal sheet profile is a combination of trapezoidal hollows and bulges, the distance between the bases of adjacent bulges is 110-130 mm, the wall inclination is 25-30 °, the profile height is 80-120 mm, and the smallest layer of the absorbing coating is from the base structure closest to the internal volume trapezoid is 70-80 mm. The soundproofing structure is made with the possibility of installation on the foundation so that soundproof walls surround the air-discharge unit. Means for supplying air into the interior of the noise insulation structure is made in the form of a technical duct connected to the process duct and communicating with the interior of the noise insulation structure. The ratio of the diameters of the technological and technical ducts is (8 ... 10): 1, their axes at the junction intersect at an angle of 30-40 °. The means for discharging air from the structure is made in the form of a ventilation duct mounted on the upper wall of the noise-proof structure and having an inlet and an outlet. The length L of the box is equal to the width of the noise insulation structure, its width and height are (0.08-0.1) L. Inside the box, on opposite walls, are mounted opposite each other in a checkerboard pattern and are tilted towards the air flow, partitions at a distance of 0.05-0.1 L from each other. The height of the partitions is equal to the height of the box, and the length is from 0.5 to 0.6 of the transverse size of the box. Partitions and the inner surface of the box have a sound-absorbing coating. The walls can be mounted on a supporting frame, and the frame is equipped with eyebolts for securing rigging cables.

Description

The utility model relates to construction, in particular to sound insulation during operation of installations with increased noise, and is intended for use in the construction of noise protection structures to protect personnel from sources - noise emissions of air injection units (VNA), air ducts, electric motors, gearboxes, bearings and other equipment.

Known silencer fan (US Pat. RF No. 2032363), designed for installation in the channel for the working environment. The noise suppressor comprises a housing with perforated concentrically arranged shells housed in it. Shells are provided with visors located above the openings in the flow and form a channel for the working medium.

The silencer works as follows: air from the atmosphere or the supply duct enters the channel for the working medium, where there is a vacuum of air equal to the depression created by the fan. Through openings in the perforated shells, the vacuum extends into all the annular cavities formed by these shells and the walls of the housing, forming annular vacuum sound-absorbing gaps. Visors increase the degree of vacuum due to air ejection.

Thus, in the muffler, noise absorption occurs by multilayer resonant structures separated by vacuum gaps.

This muffler reduces noise by 20-30%.

The operation of the muffler begins automatically with the inclusion (operation) of the fan. The design of the silencer provides long-term and reliable sound attenuation when working in mine conditions.

Such a silencer can be used to reduce noise in the channel during the passage of the working medium, which can be successfully applied in such structures as long-distance ventilation ducts, for example, in the subway.

For VNA installed, for example, in workshops, such a silencer is not effective enough, because in this case there are several noise sources besides air ducts: fans, gearboxes, etc.

In addition, in workshops, as a rule, several VNAs are installed, and they work in turn, and such a muffler is installed in the duct

moving, for example, if necessary, to provide sound insulation of the currently operating VNA, is very difficult technically.

The problem of VNA noise reduction is caused by the complexity of the frequency spectrum of the noise emitted by the unit, with several maxima, and is compounded by the complexity of the sound wave front due to several noise sources. These circumstances make the calculation of soundproof structures very difficult and, in practice, obtaining effective noise protection from such complex noise sources as VNA is possible only as a result of experiments.

To protect against noise, in addition to silencers installed in air ducts, protective structures (screens or casings) are often used that separate the noise source and noise-proof space. These structures are usually a rigid multilayer structure having sound-absorbing and sound-absorbing layers.

Known acoustic building construction (RF patent No. 2222673), made by the type of insulation "array - elastic layer - array", in which each of the two arrays of the system "array - elastic layer - array" contains at least one rigid element and is separated from the other array at least one mineral wool layer (slab) in combination with at least one air gap. In an acoustic building structure, the rigid elements are made in the form of pallets of a U-shaped section and filled inside the U-shaped cavity with at least one layer of mineral wool.

The design has good noise-proofing properties in a wide range of frequencies, however it is mounted directly on the site of operation and involves fixing on a supporting structure, for example, a building frame, and is not intended to be assembled to another place.

To use this design for VNA sound insulation, additional technical studies are required. These studies should also be associated with the provision of the temperature set for the operation of the VNA. As a result, the soundproofing structure using the well-known technical solution described can be difficult, expensive and unsuitable for VNA.

Closest to the technical nature of the claimed invention is a “heat and sound protection cabin” (AS USSR No. 1188282) to protect the operator from noise and dust in an industrial environment, which is a box-shaped structure in the form of a cabin, containing upper, lower and side soundproof walls with a supply hole located in the upper wall of the cab and being

part of the means for supplying air, and one outlet located in the lower wall of the cab. At a certain distance from the upper and lower walls of the cab, grilles are installed, supply and exhaust, forming supply and exhaust chambers with corresponding walls. The supply chamber is part of the means for supplying air and is equipped with a sound-absorbing cladding, increasing in thickness from the supply opening to the opposite wall, and the exhaust chamber is part of the noise suppression means, which is formed by the walls of the exhaust chamber lined with sound-absorbing material.

The upper, lower and lateral heat and sound insulating walls of the cab are made in the form of sandwich panels of constant thickness, the dimensions of which are multiples of the adopted module. Side walls can be made blind or with openings.

In the openings of the side walls with the help of sealing elements and hinges, glazing is strengthened and the door is hung. The walls are interconnected using unified shaped fasteners, allowing you to create soundproof volumes of any length and width that are multiples of the size of the module. Cabin assembly can be carried out directly at the place of use. The outer layers of the panels are made of structural material, such as aluminum alloy. The internal cavity of the panels is filled with heat and sound insulating material, such as polystyrene foam.

Supply and exhaust ventilation chambers are made in the upper and lower walls. An air duct from an external air discharge device is connected to the supply hole in the upper wall. The sound-absorbing lining of the supply chamber is made of variable thickness, gradually increasing from the supply opening to the opposite wall. The supply grille is located horizontally under the upper wall at a certain distance from it parallel to the axis of the supply hole.

The exhaust chamber communicates with the atmosphere by an outlet made in the bottom wall. The exhaust grill, which also serves as the floor of the cabin, is located horizontally at a certain height above the bottom wall. The exhaust chamber is lined with sound-absorbing material.

The lower wall (floor) can be equipped with vertical shelves on which the exhaust grill rests.

In a multi-module cabin, which has large dimensions, it is possible to accommodate, for example, a shift of operators with a remote control of the technological process.

During operation, the operator is placed inside the cab. The conditioned air from the external air blower device is supplied through the air duct through the air inlet to the air inlet chamber. The variable thickness of the lining attenuates noise with a wide spectrum penetrating through the duct from an external air blower; the chamber does not prevent air from escaping through the exhaust openings into the atmosphere. The presence of the lining significantly increases the sound insulation of the cab, weakening the penetration of noise from the workshop through the exhaust openings.

Thus, this design protects the operator inside the cab from noise and provides air conditioning inside the cab.

This design is convenient in cases where it is possible to carry out the working process using the control panel from the inside of the cab. In the event that workers must carry out work operations throughout the workshop, it is necessary to ensure normal working conditions by isolating the noise source itself.

The basis of this utility model is the task of creating such a noise protection structure to reduce the noise of an air blower unit, which would provide satisfactory (from the point of view of sanitary requirements) noise attenuation in the working area of the production room in the frequency range 1-3 kHz, which is most critical when a person is exposed to noise, and at the same time provided heat and air exchange inside the noise insulation structure, with the possibility of VNA maintenance and the possibility of moving the structure tion from a non-working VNA to a working one.

The problem is solved in that the noise-proof box-shaped structure containing the upper and side sound insulating walls, means for supplying air into the structure and means for discharging air from the structure, in accordance with the utility model, is configured to be installed on the foundation so that the sound insulating walls surround the VNA are made of profiled metal sheets on which a sound-absorbing coating is applied, while the profile of the metal sheet is a collection of depressions and convexity trapezoidal shape, the distance between the bases of adjacent convexes is 110-130 mm, wall slope of 25-30 °, profile height of 80-120 mm and the minimum thickness of the noise absorbing layer by dip coating to the inner

the volume of the construction of the base of the trapezoid is 70-80. mm, the specified means for supplying air into the noise insulation structure is made in the form of a technical duct connected to the technological duct and communicating with the interior of the noise insulation structure, and the ratio of the diameters of the technological and technical ducts is (8 ... 10): 1, their axis in place the connections intersect at an angle of 30–40 °, and the indicated means for discharging air from the structure is made in the form of a ventilation duct mounted on the upper wall of the noise insulation structure, and at the inlet and outlet, the length L of the box is equal to the width of the noise insulation structure, its width and height are (0.08-0.1) L, and inside the box on its opposite walls are mounted opposite each other in a checkerboard pattern and tilted towards the air flow, partitions at a distance of 0.05-0.1 L from each other, the height of which is equal to the height of the box, and the length is from 0.5 to 0.6 of the transverse size of the box, these partitions and the inner surface of the box have a sound-absorbing coating.

Distinctive features of the prototype of the declared "Noise protection design" are the following:

1. The implementation of the soundproof walls of the surrounding VNA from profiled metal sheets on which a sound-absorbing coating is applied, while the metal sheet profile is a combination of trapezoidal hollows and bulges, the distance between the bases of adjacent bulges is 110-130 mm, the wall inclination is 25-30 °, the height of the profile is 80-120 mm, and the smallest thickness of the noise-absorbing coating layer from the trapezoid base closest to the internal volume of the structure is 70-80 mm.

The experiments showed that the most effective is the use of a two-layer structure “metal-sound-absorbing layer” of variable thickness. The use of a metal profile with the indicated parameters proved to be effective.

With a decrease in the distance between the bulges and a decrease in the angle of inclination of the walls below the specified limits, there is a decrease in noise in the higher-frequency region of the spectrum, but an insufficient decrease in the region of 1-3 kHz, and when these parameters increase above the indicated values, on the contrary, there is a more effective decrease in the noise of the low-frequency component , and also not effective enough - in the range of 1-3 kHz.

When the thickness of the sound-absorbing layer is less than 70 mm, noise absorption to an acceptable level occurs only close to sources distant from the main sources.

noise (gearboxes, fans) of the parts of the structure, and with an increase in this layer above the specified value, the consumption of sound-absorbing material increases without significantly improving the noise-proofing characteristics of the noise-proofing structure.

2. The implementation of the means for supplying air to the inside of the structure in the form of a technical duct connected to the BHA process duct and communicating with the interior of the structure, the BHA process duct diameter being 8-10 diameters of the technical duct, and their axes at the junction intersect at an angle of 30 -40 °.

The ratio of the diameters is determined by the need to ensure both the operation of the VNA and the ventilation and cooling of the internal space of the noise insulation structure. When this ratio decreases to less than eight, the proportion of air supplied for ventilation increases beyond the necessary, which leads to a deterioration in the efficiency of the VNA, while increasing to a large ten values, the air structure supplied for ventilation of the internal space is not enough. Fine adjustment of the air supply to the structure can be carried out, for example, using a gate mounted in the air duct of the structure.

The choice of the specified angle of intersection of the axes is due to the need to ensure minimum air resistance at the junction of the technological and technical ducts. Changing the angle both in the direction of increasing and decreasing leads to an increase in air resistance of this site. As a result, ventilation of the structure is insufficient.

3. Creating a means for removing air from the internal volume of the structure, and providing this with the required temperature regime of the VNA. In addition, due to the implementation of the means for air outlet in accordance with the utility model, it provides a reduction in noise from the VNA emitted through the air outlet.

The selected dimensions of the box (length L, equal to the width of the soundproofing structure, width and height equal to (0.08 ... 0.1) L and the distance between the partitions, which is (0.05 ... 0.1) L, determine the maximum levels of noise reduction, radiated from the outlet of the duct, the minimum consumption of materials and optimal air exchange in a noise-attenuating structure .With a reduction in the size of the duct and the distance between the partitions, the specified

air exchange, and with increasing - increases the level of noise emitted through the outlet of the duct and the consumption of material for the manufacture of ducts.

In the event that the transverse size of the partitions exceeds a value of 0.6 of the transverse size of the duct, the air flow rate is significantly slowed, which leads to a deterioration in the ventilation modes of the device. If this size is less than 0.5 - the partitions do not overlap, part of the sound signal is not absorbed either by the partitions or the walls of the box, which degrades the noise-absorbing characteristics of the device.

4. The implementation of the portable design, for which a supporting frame is used for attaching sound-absorbing walls.

This also provides the possibility of a simpler disassembly of part of the walls, if necessary, maintenance of the VNA.

According to the information available to the authors, the utility model is new, because the set of essential features is not known from the prior art. Their combined use in the claimed utility model allows to obtain the required technical result, namely, to reduce the noise from the operation of the VNA and to improve the conditions for its operation, maintenance and repair.

The essence of the utility model is illustrated by drawings:

Figure 1 shows the noise insulation structure, made in accordance with the utility model, installed in the working position, in cross section;

Figure 2 shows a sound-absorbing wall of a soundproof structure made in accordance with a utility model in cross section;

Figure 3 schematically shows the connection node of the technological duct and technical duct, ventilating the inner space of the noise insulation structure made in accordance with the utility model;

Figure 4 shows the ventilation duct of the noise insulation structure made in accordance with the utility model, in cross section;

Figure 5 shows the spectral characteristics of the VNA sound emission without a soundproofing structure and with soundproofing structures made in accordance with the utility model, in comparison with the permissible noise emission in accordance with sanitary standards.

As shown in FIG. 1, a box-shaped soundproofing structure 1 (hereinafter “construction”) is installed on the foundation 2 so that the air-blowing unit (BHA) 3 is surrounded by walls 4 of structure 1. Design 1 includes

the upper 4a and side 4b soundproof walls fixed to the supporting frame 5. A door 6 is installed in one of the side walls 4b, which can be used for maintenance of the VNA inside structure 1, and a technological hole is made on the other wall for power cables 7, etc.

The walls 4 are made of profiled metal sheets 8, which are applied sound-absorbing coating 9 (Figure 2). The profile of a metal sheet is a combination of hollows and bulges of a trapezoidal shape. The distance between the bulges in the base, indicated in the drawing b ₁ , is 110-130 mm, the profile height (indicated in the drawing h ₁ ) is 80-120 mm, the inclination of the walls β is from 30 to 40 °. The layer thickness h _{2 of the} noise-absorbing coating from the trapezium base closest to the internal volume of the structure 1 is at least 70-80 mm.

At less than 70 mm layer thickness, the absorption of the sound signal is insufficient, and with an increase of more than 80 mm, it leads to an excess consumption of this material without a significant increase in sound absorption.

The sound-absorbing coating can be made of ordinary microfiber materials, for example, sound-absorbing mats based on super-thin basalt fibers, which are fixed to metal walls in any suitable way, for example, using glue, ensuring the profile is completely filled. The sound-absorbing coating can be made different, for example, from microporous material.

The design shown in FIG. 1 involves mounting by attaching the walls 4 to the frame 5. Thanks to the use of the frame, which can be made from a corner, it provides easy installation and dismantling of the walls, which allows operators to access individual nodes and mechanisms of the VNA for their maintenance and repair.

Rigging ropes mounted on the frame allow, if necessary, to transfer the structure from a non-working VNA to a working one, providing a reasonable organization of operation of the VNA and a rational number of necessary structures. The result is the convenience and rational organization of the operation of maintenance and repair of VNA.

Installation of the structure can be carried out in another way, for example, by connecting the walls directly to each other using conventional detachable connections.

To supply air to the VNA, use the technological duct 10 (Figure 1), to remove air from the VNA - the technological duct 11. The latter is outside

structure 1 is connected, for example by welding and flanges 12, with a technical duct 13 (Figure 3). The final part of the duct 13 with the outlet openings is located inside the structure 1. The ratio of the diameter d _{1 of the} duct 11 and the diameter d _{2 of the} duct 13 is d ₁ : d ₂ = (8 ... 10): 1. To reduce noise, air ducts 10, 11 and 13 are coated with a layer of sound-absorbing material.

To configure and adjust the air flow in the technical duct 11 installed gate 14.

The longitudinal axis of the ducts 11 and 13 at the junction (along the air flow) intersect at an angle α = 30-40 °.

Means for discharging air from the structure is made in the form of a ventilation duct 15 (Fig. 4) mounted on the upper wall 4a of the structure. The internal space of the box 15 communicates with the internal space of the device 1 through the hole 16, and with the external environment through the outlet 17.

Inside the box 15 on its opposite walls are mounted opposite each other in a checkerboard pattern of the partition 18, which are inclined in the direction of movement of the air flow. The height of these partitions 18 is equal to the height of the box 15, and the length is from 0.5 to 0.6 of the transverse size of the box 15. These partitions 18 and the inner surface of the box 15 have a sound-absorbing coating.

Soundproof design works as follows.

Before starting the work of the VNA, the structure 1, having slid the cable behind the eyebrows 19, installed at the corners of the frame 5 (Fig. 1), for example, using a crane, is mounted on a place prepared on the foundation 2, usually through vibration isolators 20 (Fig. 1) so that VNA 3 is surrounded by the walls of structure 1, and connect the VNA to the power source.

During operation, air through the duct 10 enters the BHA 3 and then is discharged through the process duct 11. At the same time, part of the air enters the technical duct 13, enters the structure and serves to cool and ventilate the internal space of the structure. Due to the indicated ratio of the diameters of the ducts 11 and 13, a sufficient amount of air for efficient ventilation is provided inside the structure 1, and at the same time, a sufficient amount of air through the duct 11 enters the enterprise’s technological system. With an increase in the ratio of the diameter of the duct 11 to the diameter of the duct 13 more than 11, the amount of air entering the structure 1 is insufficient for efficient ventilation and cooling of the VNA units, which worsens the temperature regime, shortens the life

VNA systems and components, leads to an increase in downtime, etc. Otherwise, with a decrease in this ratio, the amount of air entering the device is redundant, and the operation of the process duct is less efficient. More precise control of the amount of air entering the structure is carried out using the gate 14.

Due to the fact that the axes of the air ducts 11 and 13 intersect at an angle of 30–40 ° at the junction of these air ducts, efficient filling of the air duct 13 and, therefore, effective ventilation of the device 1 is provided. Experiments have shown that under commonly used modes (pressure, air speed flow) when the specified angle is reduced to values less than 30 °, the air flow is decelerated, the operating mode of the process duct 13 deteriorates. In addition, at such small angles there are difficulties in manufacturing the evil connection of ducts and their maintenance. In that case, if the angle is more than 40 °, the air flow is disrupted, the air duct 13 is not filled with air, and accordingly, the ventilation modes deteriorate.

When using the air duct 13 in accordance with the utility model, efficient heat and air exchange is provided inside the noise insulation structure, which increases the reliability of the operation of the VNA units and assemblies. This is achieved by the fact that part of the air taken from the VNA technological system is used for ventilation of the structure. The advantage of such a ventilation system is that it eliminates the cost of buying, installing and operating a special fan, and also does not require a place to place it.

Excess air entering the device is discharged through openings 16, 17 of the ventilation duct 15.

The sound signal (noise) from the operating VNA extends in all directions, and falls on the inner surface of the sound-absorbing structure. Part of the sound signal is absorbed by sound-absorbing material, part falls at a certain angle on the metal sheet, is reflected from the walls and again partially absorbed by sound-absorbing material. Reflection and absorption of an audio signal occurs many times, and due to the presence of a profile, reflection and absorption of a signal occurs differently at different points, which smooths out the maximum spectral characteristics of noise. As a result, noise outside the device is significantly reduced.

As a result of the experiments, it was found that the optimal results of noise absorption are provided at the indicated geometric dimensions of the metal profile. First of all, increased rigidity of the profiled sheet is ensured, which leads to an increase in the resonant frequency and, accordingly, soundproofing properties of the structure. In the event that the height of the trapezoid is greater than indicated, the consumption of sound-absorbing material increases without a significant improvement in soundproofing properties, and when this height is reduced, rigidity, resonance frequency and, therefore, sound-absorbing properties of the structure are reduced. As the distance between the bulges increases, the sound-absorbing properties also decrease.

The sound signal that goes beyond the structure through the openings of the ventilation duct is also attenuated. The attenuation is facilitated by the sound-absorbing layer on the inner surface of the ventilation duct and partitions. The selected dimensions of the partitions with a sound-absorbing coating can significantly attenuate the sound signal. In the event that the transverse size of the partitions exceeds 0.6 of the transverse size of the duct, the air flow rate is significantly slowed, which leads to a deterioration in the ventilation modes of the device. If this size is less than 0.5 - the partitions do not overlap, part of the sound signal is not absorbed either by the partitions or the walls of the box, which degrades the noise-absorbing characteristics of the device.

As the experiments showed, the use of a structure of a profiled sheet with a sound-absorbing layer, and a ventilation duct of the described design, can reduce noise outside the device to acceptable values.

Figure 5 shows the noise levels from the VNA in the absence of a noise protection device (curve 1), in the presence of a device (curve 2) and the noise level that meets the requirements of sanitary standards (curve 3). From the graphs it can be seen that the proposed design reduces the sound signal from the working VNA below the limits required by the sanitary norm.

The proposed design can be made of standard materials on conventional equipment.

Claims (2)

1. Noise-proof box-shaped structure comprising upper and side soundproofing walls, means for supplying air into the structure and means for discharging air from the structure, characterized in that said noise-proofing structure further comprises a supporting frame for attaching soundproofing walls to it and is configured to be installed on the foundation so that sound insulating walls surround the air discharge unit, said sound insulating walls being made of profiled meta of sheet metal on which a sound-absorbing coating is applied, while the profile of the metal sheet is a combination of hollows and bulges of a trapezoidal shape, the distance between the bases of adjacent bulges is 110-130 mm, the wall inclination is 25-30 °, the profile height is 80-120 mm, and the smallest the thickness of the layer of the noise-absorbing coating from the trapezoid base closest to the internal volume of the structure is 70-80 mm, the indicated means for supplying air into the noise insulation structure is made in the form of a technical duct connected to the technological duct and communicating with the internal space of the noise insulation structure, and the ratio of the diameters of the technological and technical ducts is (8 ... 10): 1, their axes at the junction intersect at an angle of 30-40 °, and the indicated means for air discharge of the structure is made in the form of a ventilation duct installed on the upper wall of the noise insulation structure and having an inlet and outlet, the length L of the duct is equal to the width of the noise insulation structure, its width and height are yayut (0.08-0.1) L, and inside the box on its opposite walls are mounted opposite each other in a checkerboard pattern and tilted in the direction of movement of the air flow, partitions at a distance of 0.05-0.1 L from each other, height which is equal to the height of the box, and the length is from 0.5 to 0.6 of the transverse size of the box, these partitions and the inner surface of the box have a sound-absorbing coating. 2. The sound-absorbing structure according to claim 1, characterized in that the supporting frame is equipped with eyebrows for securing rigging cables.