RU185807U1 - TRANSPARENT DESIGN - Google Patents

Abstract

The utility model relates to the field of construction, namely to the field of building acoustics. The proposed translucent design is applicable for a wide range of tasks in residential, public and industrial buildings.

Improving the soundproofing properties of translucent structures is one of the priority tasks in modern construction. This is due both to an increase in noise levels from external sources (industrial noise, traffic noise, etc.) and the need for reliable protection of premises of residential and public buildings from them, and to the expansion of the scope and scope of the use of translucent structures as internal fences ( primarily in public buildings).

Description

The utility model relates to the field of construction, namely to the field of building acoustics. The proposed translucent design is applicable for a wide range of tasks in residential, public and industrial buildings.

Improving the soundproofing properties of translucent structures is one of the priority tasks in modern construction. This is due both to an increase in noise levels from external sources (industrial noise, traffic noise, etc.) and the need for reliable protection of premises of residential and public buildings from them, and to the expansion of the scope and scope of the use of translucent structures as internal fences ( primarily in public buildings).

In most cases, the structural measures required to increase the sound insulation of a translucent structure entail an increase in material consumption, an increase in the complexity of manufacturing and a substantial increase in the total cost of the structure. Therefore, when developing effective soundproofing translucent structures, the resulting increase in soundproofing properties should be correlated with material costs and design difficulties that arise when the design of the fence is complicated.

Closest to the proposed translucent structure is the structure described in the article (Bogolepov II On the issue of sound insulation of transparent structures // Sound attenuation: Sat. M: VTsNIIOT VTsSPS. 1976. P. 33-39.). To improve the sound insulation of a double translucent polymethylacrylate structure, it is proposed to use an elastic material deposited from the inside along the perimeter of the glazing and serving to acoustically separate the fencing plates and prevent the occurrence of sound bridges.

The disadvantage of the design proposed in the article is the possibility of increasing sound insulation only for structures made of organic glass (the possibility of using for structures made of silicate glass is the most common material for such structures at present, not studied). Also, the influence of the material used as a damping material was not taken into account and the possibility of using self-adhesive materials with the highest damping properties was not considered.

The objective of the utility model is to create a translucent structure with enhanced sound insulation over a wide frequency range, without significantly increasing the mass of the structure and its cost.

The technical result from the use of this design is to increase the soundproof ability of a translucent fence without a significant increase in the mass of the structure and its cost.

The translucent structure includes a glass plate (1), a strip of opaque self-adhesive vibration damping material (2), a rubber seal (3), a distance frame (4), a sealing mastic (5), a window block body (6).

In the proposed design, a strip of opaque self-adhesive vibration damping material (2) is applied to part of the layers or all layers of the glazing in the structure from one or two sides along the glass perimeter (1), which leads to an increase in sound insulation of the translucent structure. The strip of opaque self-adhesive vibro-damping material can be located either directly on the translucent glazing area (this reduces the translucent area), or it can be hidden in the design of the window unit or other structure used to fasten the translucent part of the enclosure (in this case, part of the glazing must be recessed into a frame or other structure used for fastening to the depth necessary to accommodate vibration damping material.

The proposed translucent design works as follows: due to the strip of opaque self-adhesive vibration damping material (2), additional suppression of vibrations arising due to the impact of the incident sound wave on the glass plate (1) occurs. This is achieved by increasing dissipative losses (loss of vibrational energy when it is converted into the thermal energy of the particles of the material) directly in the material of the plate. With an increase in the amount of absorbed sound energy, the amount of sound energy passing through the fence decreases, and the sound insulation of the structure increases.

The utility model is illustrated by the following drawings: in FIG. 1 shows a schematic diagram of the proposed design:

a - vibration damping material on both sides of the glass,

b - vibration damping material on one side of the glass.

In FIG. 2 - one of the examples of structural solutions for the application of the proposed design in modern translucent fencing.

In FIG. 3 - comparison of the frequency characteristics of sound insulation of single-layer translucent structures of silicate glass 4 mm with varying degrees of edge damping with an opaque self-adhesive vibration damping material "Bimast Bomb": curve 7 - structure without edge damping (R _w = 28 dB, R _A.tran = 27 dBA) ; curve 8 - structure with a strip of BiMast Bomb, an opaque self-adhesive vibro-damping material, with a width of 20 mm along the perimeter on both sides of the glass (R _w = 30 dB, R _A.tran = 27 dB A); curve 9 - design with the application of a strip of non-transparent BiMast Bomb self-adhesive vibro-damping material 40 mm wide along the perimeter on both sides of the glass (R _w = 31 dB, R _A.tran = 28 dBA).

Figure 4 - comparison of the frequency characteristics of the sound insulation of a double translucent fence using the proposed design and without it. Comparison of the frequency characteristics of sound insulation of double translucent fencing (silicate glass pane with a glazing formula of 4 + 24 + 4 mm) with varying degrees of edge damping with the opaque self-adhesive vibration damping material “Bimast Bomb”: curve 10 - double-glazed window without edge damping (R _w = 32 R _A.trans = 27 dBA); curve 11 - a double-glazed window with damping by a strip of opaque self-adhesive vibro-damping material "Bimast Bomb" with a width of 20 mm along the perimeter of both glasses (R _w = 33 dB, R _{A. trans} = 28 dB A); curve 12 - a 4 + 24 + 4 mm double-glazed window, damping with a strip of opaque self-adhesive vibro-damping material “Bimast Bomb” 40 mm wide along the perimeter of both glasses (R _w = 34 dB, R _A.tran = 28 DBA).

Strips of an opaque, self-adhesive vibration damping material should be used so that the area occupied by them is no more than 13% of the total area of the glass plate. This value of the effective area was obtained during the experiment. With a further increase in the area of vibration damping material, a significant increase in the sound insulation of the structure does not occur.

For gluing glass around the perimeter, use opaque self-adhesive vibration damping materials with a loss factor of at least 0.35.

The application of the proposed design does not lead to a significant increase in the mass of the fence. So for a single-layer structure of 4 mm silicate glass, when applying a strip of vibration damping material on both sides of the glass with a total area of 13% of the glazing area, the increase in glazing mass will be about 16%.

Experimental studies of sound insulation of the proposed translucent structures were carried out in the acoustics laboratory of NNGASU according to the standard method in accordance with GOST 27296-2012 "Buildings and Structures. Methods of measuring the sound insulation of building envelopes."

Based on the data presented, we can conclude that the proposed translucent structures can improve the sound insulation of translucent fences in a wide frequency range without a significant increase in the mass of the fence and without a significant increase in its cost.

List of used documents and patents:

1. Bogolepov I.I. To the issue of sound insulation of transparent structures // Sound attenuation: collection. M: VTsNIIOT VTsSPS. 1976, p. 33-39.).

Claims (1)

A translucent structure, including a glass plate, a rubber sealant, a spacer, a sealing mastic, a window block case, characterized in that a strip of opaque self-adhesive vibration-damping material is applied to the glass plate around the perimeter.

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