RU2715351C1 - Sound-insulated air duct - Google Patents

Abstract

FIELD: ventilation.SUBSTANCE: invention relates to structural components of ventilation and/or conditioning systems, specifically to a device for sound-insulated air ducts. Sound-insulated air duct comprising an outer box made in the form of a metal pipe of rectangular cross-section with wall thickness of 0.4 to 3 mm; wherein it comprises layer of noise-absorbing material with thickness of not more than 50 mm; means of connecting the sound absorbing material layer to the outer box, comprising at least one spring member configured to press the sound absorbing material layer to the outer box from the inside; wherein noise absorbing material layer with its outer surface adjoins at least part of inner surface of outer box.EFFECT: this allows increasing noise insulation properties of domestic air duct while maintaining its compactness, appearance and ease of installation.5 cl, 3 dwg

Description

FIELD OF THE INVENTION

The disclosed technical solution relates to the field of structural elements of ventilation and / or air conditioning systems, namely to the device of soundproof ducts laid inside residential or office premises.

BACKGROUND

The main field of application of the air ducts referred to in the present description is the distribution of air coming from an external supply ventilation unit over adjacent rooms of an apartment or office. In particular, from a forced-air ventilation unit located on the facade of the building. For air distribution, it is necessary to lay the duct through vertical ceilings (walls), as a result of which the sound insulation of the wall is violated, and the duct actually becomes a sound conductor between the rooms.

The design of soundproofed ducts is known (https://www.roomklimat.ru/upload/ballu-vozduxovodu-opisanie.pdf, page open 11/19/2018). The duct contains a metallized film with a spiral frame, an insulation layer and an outer metallized film. The well-known duct is used mainly in technical rooms or in hidden ducts. In case of use in domestic premises, it is necessary to additionally install a decorative box. At the same time, the disadvantage of the known duct is the difficulty of installation in domestic premises, decorative boxes. Such a duct can also be installed over a suspended ceiling, which is extremely difficult in residential premises, the ceiling height in which can be 2.5-2.7 meters. In addition, the placement of a sound-insulating layer on top of the duct provides a low efficiency of damping the sound passing inside the duct, which must be compensated by the large thickness of the layer of sound-absorbing material.

Also known is the design of the plastic duct (Vents catalog, 08.2011, p. 22, http://www.aquamaster.net.ru/catalog/vents/Vents_plastikovie_ventkanali_catalog_08_2011.pdf), which is selected as the closest analogue (prototype) of the disclosed technical solution. The air duct is made in the form of a pipe of round or rectangular cross section made of PVC. Ducts of this design are easier to install and can be used as decorative ducts in domestic premises. However, these ducts do not have sufficient soundproofing properties.

SUMMARY OF THE INVENTION

The challenge facing the developers of the disclosed technical solution was to increase the noise insulation properties of the household duct while maintaining its compactness and ease of installation.

The problem was solved by creating an air duct that contains an external duct made in the form of a metal pipe of rectangular cross-section, with a wall thickness of 0.4 to 3 mm; characterized in that the duct contains a layer of sound-absorbing material with a thickness of not more than 50 mm; moreover, the layer of sound-absorbing material with its outer surface is adjacent to at least part of the inner surface of the outer duct.

The technical result achieved by the disclosed technical solution is to increase the noise insulation properties of the household duct while maintaining its compactness, appearance and ease of installation.

Hereinafter, the disclosed technical solution will be described in more detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Figure 1 is a sectional view of a soundproof duct in an embodiment with a spring element;

Figure 2 is a sectional view of a soundproof duct in an embodiment with a perforated frame;

Figure 3 - local section of a soundproof duct in the embodiment with a perforated frame.

MODES FOR CARRYING OUT THE INVENTION

In accordance with the present disclosed technical solution, the soundproofed duct comprises an external duct 1 made in the form of a pipe with a thickness of 0.4 to 3 mm. Also, the duct contains a layer 2 of sound-absorbing material with a thickness of not more than 50 mm. Moreover, the layer 2 of sound-absorbing material with its outer surface abuts against at least a portion of the inner surface of the outer duct. In preferred embodiments of the present technical solution, the thickness of the layer 2 of the sound-absorbing material does not exceed 30 mm.

The outer box 1 is preferably made of a material capable of reflecting sound. As the material of the outer box 1, a polymeric material (for example, polyvinyl chloride or polypropylene) or a metal (for example, iron, aluminum or others) can be used.

The outer box 1 can be made of a continuous pipe, or of a pipe consisting of individual segments connected to each other. The connection of the segments can be performed using a threaded connection or rivets (shown in figure 3).

External box 1 can be made of pipes of various sections: for example, round or rectangular. In a preferred embodiment of the technical solution, the outer duct 1 is made of a pipe of rectangular cross section. In this embodiment, the space of the room is used more economically, since the duct is most often laid along the walls so that it is adjacent to the flat surface of the wall. In addition, the rectangular shape of the duct is more effective for reducing the power level of sound passing through the duct at frequencies up to 500 Hz, and is much more effective for reducing the power level of sound passing through the duct with frequencies up to 250 Hz than the round shape (Table 17 11 “Decrease in levels sound power in metal ducts of rectangular and circular cross-section ”on page 338 of the designer’s reference book“ INTERNAL SANITARY AND TECHNICAL DEVICES ”, edited by I.G. Staroverov, part II, publ. In 1977, [1]). The rectangular shape increases the number of reflections of the sound wave from the walls of the pipe inward (relative to the pipe of circular cross section), which increases the path that the sound wave passes through the layer of sound-absorbing material.

At the same time, household air ducts are mainly intended for the distribution of air from the supply ventilation unit throughout the rooms in an apartment, house or office. Due to the fact that domestic air handling units themselves are low-noise and provide sound insulation of the duct relative to external noise, the sound gets into the duct mainly from the room. And the insulation of the air duct is necessary, first of all, so that the air ducts passing through the vertical ceilings do not pass sound through themselves from one room to another.

Mostly, the sound in residential and office premises is made up of the sounds of a human voice. Their frequency does not exceed 500 Hz, and more often is in the range up to 255 Hz. In this case, the cross-sectional size of the duct laid along the wall is less than 400 mm (mainly less than 200 mm). Thus, in accordance with the data of [1], the rectangular shape of the duct in residential and office premises is most effective for sound insulation.

In a preferred embodiment of the disclosed technical solution, the outer box is made in the form of a metal pipe with a thickness of 0.4 to 3 mm. The metal has a high acoustic reflectance and acoustic rigidity. The execution of the external duct of metal leads to the fact that the main part of the sound wave passing through the duct is repeatedly reflected from the walls of the duct, resulting in a multiply increase in the path that the sound wave passes through the layer of sound-absorbing material, which increases the efficiency of sound insulation with small overall dimensions of the duct .

Thus, the placement of a layer of sound-absorbing material inside the outer box on the one hand retains the decorative function (the duct has a flat surface and the ability to decorate), on the other hand, it provides better sound-insulating properties compared to analogs while maintaining the compactness of the duct.

Layer 2 of sound-absorbing material can be made of any sound-absorbing material, for example, mineral wool, acoustic foam, etc. In a preferred embodiment of the disclosed technical solution, the sound absorption coefficient of the layer of sound-absorbing material should be at least 0.2 in octave bands with a geometric mean frequency of 250 Hz .

Layer 2 of sound-absorbing material with its outer surface abuts against at least a portion of the inner surface of outer duct 1. In a preferred embodiment of the present technical solution, layer 2 of sound-absorbing material with its outer surface abuts against substantially the entire inner surface of the outer duct. However, in embodiments where the layer 2 of sound-absorbing material covers part of the inner surface of the outer duct 1, this technical result is also achieved. Due to the adherence of layer 2 of the sound-absorbing material to the inner surface of the outer duct 1, the volume of the duct is most optimally used: all the free space inside the outer duct 1 is a channel for air passage.

The adhesion of the layer of sound-absorbing material to the inner surface can be ensured due to the fact that the layer 2 of sound-absorbing material with the shape and size of its outer surface corresponds to the shape and dimensions of the inner surface of the outer duct 1. Thus, for example, in the embodiment of the technical solution, in which the outer duct 1 is made in the form of a pipe of rectangular cross-section, the layer 2 of sound-absorbing material can be made so that in the installed state, the layer 2 of sound-absorbing material in the transverse the cross section also has a rectangular shape and such dimensions that the shape of the outer surface of the layer 2 of the noise-absorbing material corresponds to the shape of the inner surface of the outer duct 1.

The duct may contain a means of connection. The adherence of the layer 2 of the sound-absorbing material to the inner surface of the outer duct 1 can be carried out using the connection means.

As such a means of connection, the duct may include at least one spring element 3, made with the possibility of pressing the layer 2 of sound-absorbing material to the outer duct 1 from the inside. In other embodiments of the technical solution, the connecting means may be in the form of a reinforcing mesh or other reinforcing structure connected to the layer 2 of the noise-absorbing material, giving the layer 2 of the noise-absorbing material a shape corresponding to the shape of the inner surface of the outer duct 1.

In some embodiments, the duct includes a perforated frame 4 having a shape corresponding to the shape of the outer box 1, having such dimensions and located inside the outer box 1 so that the layer 2 of sound-absorbing material is located in the space between the outer box 1 and the perforated frame 4. Perforation may be made with round holes. The presence of a perforated frame on the one hand ensures that layer 2 of the sound-absorbing material retains its shape, on the other hand, it additionally improves the soundproofing properties of the duct. Part of the sound wave passes through the holes of the perforated frame 4, is reflected from the outer box 1, and then partially reflected from the perforated frame 4. This increases the path that the wave passes through the sound-absorbing material. The perforated frame 4 can be made in the form of a whole pipe, or composite of individual pipe segments, as shown in Fig.3. Pipe segments can be connected using threaded connections or rivets.

This technical solution has been described in detail with reference to individual options for its implementation, however, it is obvious that it can be implemented in various forms, without going beyond the stated scope of legal protection defined by the claims.

Claims (8)

1. Soundproofed duct containing an external duct, made in the form of a metal pipe of rectangular cross-section with a wall thickness of from 0.4 to 3 mm, characterized in that the duct contains a layer of sound-absorbing material with a thickness of not more than 50 mm; means for connecting a layer of sound-absorbing material with an external duct, comprising at least one spring element configured to press a layer of sound-absorbing material to the outer duct from the inside; moreover, the layer of sound-absorbing material with its outer surface is adjacent to at least part of the inner surface of the outer duct. 2. The duct according to claim 1, characterized in that the layer of sound-absorbing material is adjacent to the inner surface of the outer duct due to the fact that the layer of sound-absorbing material in shape and size of its outer surface corresponds to the shape and size of the inner surface of the outer duct. 3. The duct according to claim 1, characterized in that the connecting means is made in the form of a reinforcing structure, giving the layer of sound-absorbing material a shape corresponding to the shape of the inner surface of the outer duct. 4. The duct according to claim 1, characterized in that the duct contains a perforated frame having a shape corresponding to the shape of the outer duct, having such dimensions and located inside the outer duct so that the layer of sound-absorbing material is located in the space between the outer duct and the perforated framework. 5. The duct according to claim 1, characterized in that the thickness of the layer of sound-absorbing material is not more than 30 mm

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