RU205795U1 - VACUUM SOUND INSULATING PANEL - Google Patents

Abstract

A vacuum sound-insulating panel is proposed, including bounding walls, between which an evacuated cavity is formed, in the vacuum sound-insulating panel, the bounding walls are made flat with stiffeners fixed to the inner sides of the bounding walls, between the bounding walls along the perimeter there is a frame to which the bounding walls are firmly fixed, forming closed vacuum-tight cavity, which is evacuated to 0.01-0.2 atm.

Description

The utility model relates to noise control means and can be used as a sound-insulating vacuum panel in the construction of buildings and structures, as well as in mechanical engineering. Vacuum sound-insulating panels can be used in the group of means for sound insulation in civil and industrial construction, for sound insulation of premises; as protective screens in areas of airports, railways and highways, in workshops for soundproofing machines and equipment with high noise levels.

It is possible to mount from several claimed vacuum soundproofing panels of chambers of a closed volume around a noise source with a high level.

Known soundproofing and soundreflecting panels, developed as a means of fighting noise. In the variety of such panels, a special place is occupied by evacuated panels. Obviously, the absence of air (in a vacuum) in the building envelope makes the sound insulation (noise insulation) the best; when discharging air in the enclosing structure, sound insulation depends on the degree of taste. However, when flat panels are evacuated, high compressive forces are generated for the cover sheets, which until now has been a limiting factor in producing evacuated panels with an evacuated cavity and high vacuum. In the known designs, vacuum sound-insulating flat panels are made with a shaping, sound-insulating filling of the evacuated space made of porous material. For example, a vacuum sound-insulating structure (RF Patent. No. 2582149. Application: 2014141725/03, 15.10.2014. Published: 20.04.2016 Bull. No. 11).

In the specified source, the vacuum sound-insulating structure contains a restrictive element with the formation of an internal space for its evacuation. The limiting element is made in the form of a sealed shell made of metal foil or metal foil laminated with a polymer film, inside which is placed a shaping, sound-insulating filler made of material with open pores or cells. The hermetically sealed enclosure is covered on the outside with sound-absorbing material, sealant or rubber or rubber-like material.

However, in the construction under consideration, a sound-insulating filler made of material with open pores or cells will be the main carrier of sound energy, and the vacuum effect will be significantly reduced, which will lead to low sound insulation performance of this type of sound-insulating structure. In addition, there are no rigid elements in the structure under consideration, and such a structure cannot be considered as a sound-insulating panel or a sound-insulating screen.

Known vacuum sound-insulating panels with sound-insulating filling of the evacuated space from a porous material, which is used as a support for the cover sheets of the panel. The application for the invention "Electrified vacuum panel" (RU 2004107130 A, IPC G01L 1/00. Application 2004107130/28, 07.02.2003) describes a vacuum panel containing an intermittent or porous filling material, enclosed between at least two protective sheets , mutually connected at the edges, in which one or more reformers are placed, to provide power supply to at least one device, which is installed inside the vacuum panel, while the reformers are installed to ensure gas tightness between the protective sheets.

In such a design of a vacuum panel with rigid protective sheets, an intermittent or porous filling material is located between these sheets, which is also a conductor of sound vibrations and, therefore, the disadvantage of this design is its relatively low sound insulating ability.

Known soundproofing structure, in which soundproofing is provided by evacuating the enclosed cavity. "Sound insulating element"

(AS No. 1270251, class E04B 1/82, 1982). The sound-insulating element contains two walls made in the form of a part of a sphere with a bulge outward; with the placement between them along the perimeter of the elastic gasket with the possibility of evacuating the internal space. Vibration-insulating supports are placed between the walls and the gasket, rigidly connected to the walls of the metal frames. When creating a vacuum in the cavity of the walls, external pressure presses the walls against each other, which increases the tightness of the sound-insulating element. Spherical walls with a bulge outward increase sound insulation in the low frequency range. However, the sound insulating element has several disadvantages. The spherical shape of the parts of the walls with a bulge outward restricts the use of this element due to the unknownness of its attachment to the supporting structure. An integral part of the enclosure will reduce airtightness and sound insulation over time. The sound-insulating element is difficult to manufacture due to the need to form the walls in the form of parts of a sphere of a certain thickness, which requires significant manufacturing costs. In addition, such a design does not have a rigid vacuum-insulated cavity, which will affect during operation and lead to a decrease in the degree of vacuumization of the cavity between the spherical walls.

The closest in technical solution and the achieved result is a vacuum sound-insulating panel (RU 198761 U1 for the useful model "Vacuum sound-insulating panel").

In this vacuum sound-insulating panel, an evacuated cavity is formed between the boundary walls, and along the perimeter the boundary walls are vacuum-tightly connected to each other by a stiffening frame. In this case, the confining walls are made flat with stiffening ribs fixed to the outer sides of the confining walls, and the evacuated cavity between the confining walls is evacuated to 0.01-0.2 atm.

This design provides rigidity to the confining walls, since the stiffening ribs prevent the deflection of the confining walls after evacuating the cavity between them.

However, this design of the sound insulating panel has disadvantages due to the presence of irregularities on the outer surfaces of the boundary walls in the form of stiffeners. When the sound-insulating panel is attached to a vertical wall or other flat sound-insulating surface, a gap is formed between this surface and the boundary wall of the sound-insulating panel to the height of the stiffeners. This feature reduces the functionality of the vacuum soundproofing panel. On the other side of the considered design of a vacuum sound-insulating panel, stiffening ribs protrude towards the room, which degrades the design of the sound-insulating panel and may require additional finishing, for example plastering, work. It is difficult to carry out finishing work on such a surface. For example, to paste wallpaper, paint, decorative plaster, etc. Thus, the functionality of the vacuum sound-insulating panel is reduced.

The task of the utility model is to eliminate the aforementioned disadvantages, namely, to increase the functionality of the vacuum sound-insulating panel.

The problem is solved by the fact that the vacuum sound-insulating panel, including the limiting walls; a stiffener frame connected to the boundary walls along the perimeter, so that the boundary walls and the stiffening frame form an evacuated cavity; the flat bounding walls are made with stiffening ribs on the inner sides of the flat bounding walls.

The essence of the claimed utility model is illustrated by drawings, where figure 1 shows a diagram of a vacuum sound-insulating panel in two views, front view and section A-A front view.

The vacuum sound-insulating panel consists of two limiting walls 1, a frame 2, stiffeners 3. The elements of the vacuum sound-insulating panel 1,2 form a closed evacuated cavity 4 with the possibility of deep vacuum up to 0.01 ... 0.2 atm., While the elements 1,2 are connected between themselves motionless and vacuum-tight, and the stiffening ribs 3 are fixed along their entire length to the inner surface of the bounding walls 1 permanently.

The limiting walls of the vacuum sound-insulating panel are made mainly of sheet steel with a thickness of 0.3-1.5 mm or of sheet plastic. Stiffeners are also made of sheet steel with a thickness of 1-3 mm or from a square, triangular or rectangular section, it is possible to use standard profiles: corner, channel, T-bar, pipe, etc. The limiting walls of the vacuum sound-insulating panel can be made simultaneously with the stiffeners. For example, by stamping or bending. Bounding walls can be made of plastic and obtained by casting simultaneously with stiffening ribs. The height of the stiffeners and the distance between them are determined by the dimensions of the vacuum soundproofing panel, its purpose, the degree of evacuation and operational requirements. The height of the stiffeners is lower than the distance between the bounding walls. The stiffeners inside the vacuumized cavity do not touch each other.

The stiffening frame can be made from known metal profiles or from durable plastic, or from reinforced elastic rubber or strong elastic plastic. The frame and the bounding walls are connected by well-known methods: adhesive, soldering, welding, riveting, and other methods that provide a vacuum-tight connection. To increase the reliability of a vacuum-tight connection, it is possible to use mastics, putties, sealants, seals, varnishes and other typical sealing materials.

The claimed design works as follows.

After manufacturing the structure, through a special nipple mounted in the frame (not shown), the cavity between the limiting walls is evacuated, with simultaneous control of the degree of evacuation to 0.01 ... 0.2 atm., After which the nipple is closed, fixed in the closed state and the panel ready to install.

The panel is fastened either to the wall or to a special support using known additional fasteners provided on the panel frame, for example, lugs. For these lugs on the wall or on a special support, holes are provided for fixing the panels. After installing the panels, they are ready for use.

The proposed design has a number of advantages over analogues. It has the best soundproofing ability, is relatively easy to attach and operate, and is reliable in operation. Having flat outer surfaces of the enclosing walls, it has increased functionality compared to the prototype.

In the proposed design, in comparison with the prototype, the effectiveness of sound insulation does not deteriorate. Stiffening ribs made on the inner surfaces of the limiting walls will prevent them from bending due to external pressure forces during the evacuation of the cavity between the limiting walls of the vacuum soundproofing panel. In this case, the outer surfaces of the bounding walls will be flat. That will increase their consumer properties and functionality. Such a sound insulating panel can be attached with minimal clearance to a sound insulating surface. The surface of the sound-insulating panel can be processed relatively easily, and finishing work can be done on it faster and with better quality. The flat appearance of the surface of the sound insulating panel provides a more aesthetic appearance for these panels.

No expensive materials are required to manufacture such a panel. The degree of evacuation of the panel can be different, and therefore the sound insulating capacity will be different. The soundproofing characteristics of the inventive panel and its cost depend on the degree of its evacuation.

Claims (1)

Vacuum soundproofing panel, including bounding walls, stiffness frame, along the perimeter connected to bounding walls, which form an evacuated cavity, and the bounding walls are made flat with stiffening ribs, while the evacuated cavity between the bounding walls is evacuated to 0.01-0.2 atm. , characterized in that the stiffeners are made on the inner sides of the flat bounding walls.

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