RU2781614C1 - Method for heat and sound insulation and system for its implementation - Google Patents

Abstract

FIELD: building structures protection.

SUBSTANCE: invention relates to methods for protecting building structures and facilities, namely to methods for isolating, absorbing or reflecting heat, sound or noise to ensure normal thermal and acoustic conditions in rooms. The effect is achieved in that the heat and sound insulation system is characterized by the fact that it contains slats installed around the perimeter of the insulated surface; fasteners fixed on the side surface of the rails by means of a detachable fixed connection with a certain step from each other; guy wires secured between a pair of opposing fasteners, with the crossing of the guy wires forming a network-like structure; damping anchors fixed on the insulated surface opposite the points of intersection of the stretch marks; fabric material placed between the braces and the insulated surface, hermetically fixed along its perimeter to the rails, while the braces are connected at their intersections with each other with damping anchors through the fabric material by means of flexible elements; and the space between the insulated surface and the fabric material is filled with heat and sound insulating bulk material, and the technical result is achieved by the method for heat and sound insulation containing such a system.

EFFECT: increasing the heat and sound insulation of rooms while reducing the total mass of the heat and sound insulating system.

9 cl, 7 dwg

Description

The invention relates to methods for protecting building structures and facilities, namely to methods for isolating, absorbing or reflecting heat, sound or noise to ensure normal thermal and acoustic conditions in rooms.

To date, a large number of different methods and materials have been developed to achieve the required level of sound insulation and acoustic comfort in residential, office and industrial premises. According to the method of attachment to the protected building structures, they can be divided into:

- methods using spraying;

- methods using adhesive bases;

- methods using damped (vibration-proof) rigid frames to hold soundproof materials.

Thus, a multilayer wall covering is known from the prior art according to the patent for the invention RU 2604608 C2 (IPC: E04B 1/88, B32B 17/02, B32B 5/18, publ. 10.12.2016), containing a base layer formed from a foam based on organic polymer having an open porosity which is 0.50-0.995, or non-woven material made of viscose fibers, the surface density of which is from 150 g/m ² to 500 g/m ² , a surface layer formed by glass cloth having a static resistance to air passage, measured in accordance with ISO 9053, which is from 105 N s m ^-4 to 106 N s m ^-4 , a discontinuous sublayer at the boundary surface between the base layer and the surface layer, the surface density of which is from 17 to 60 g/ ^m2 . This multi-layer wall covering is designed to be bonded to one or more interior walls of a room or building.

The well-known wall covering is made in a frameless manner and does not have rigid elements in its composition. However, due to the small thickness of its layer, such a coating will not provide a level of sound wave absorption sufficient for sound insulation, and can be considered mainly as an acoustic material.

In addition, a soundproof screen is known from the prior art according to utility model patent RU 162971 U1 (IPC: E04B 1/82, publ. 10.07.2016). Soundproof screen contains outer layers and two layers of fibrous fabric made of silicon-containing material. At the same time, mineral wool or fiberglass canvas-stitched type PSH-T was used as a fibrous web of a silicon-containing material; around the perimeter of the screen and at least with adjacent layers of fibrous web. However, the design of the well-known soundproof screen does not imply the presence of a vibration-proof attachment system to the bearing planes that are planned to be soundproofed.

The closest analogue of the claimed invention, according to the principle of sound protection, can be attributed to the adhesive fastening of fiberglass cuts (ThermoZvukoizola) to the ceiling or walls (https://www.termozvukoizol.com/articles/termozvukoizol-dlia-zvukoizoliatsii-stena). For soundproofing walls, TermoZvukoIzol is used as one of the components of the insulating system. In the simplest case, the mats are attached to the wall in any way possible and then covered with sheets of drywall or plywood. In more complex versions, a structure is used based on a metal profile, several layers of material and a layer of mineral wool between them.

The disadvantages of this method include the following:

- the possibility of fastening by means of glue only one thin layer (14-20 millimeters) of fiberglass, which provides a small level of sound protection;

- the presence of a risk of detachment of the glued fiberglass from the insulated surface, which often requires the use of rigidly fixed fasteners that form vibration transmission bridges, which worsens the overall sound insulation result.

The task to be solved by the claimed invention is to create a method and system for heat and sound insulation of rooms in which loose heat and sound insulating materials are used, distributing their mass on tensile-thread structures, which makes it possible to abandon damped (vibration-protected) rigid frames.

The technical result of the claimed invention is to increase the heat and sound insulation of the premises while reducing the total mass of the heat and sound insulating system.

The specified technical result is achieved by the fact that the claimed system of heat and sound insulation contains rails installed along the perimeter of the insulated surface, fasteners fixed on the side surface of the rails by means of a detachable fixed connection with a certain pitch from each other, extensions fixed between a pair of opposite fasteners, and the intersection of the braces forms a network-like structure, damping anchors fixed on the insulated surface opposite the intersections of the braces, a fabric material placed between the braces and the insulated surface, hermetically fixed along its perimeter to the rails. At the same time, the stretch marks are connected at the points of their intersection with each other with damping anchors through the fabric material by means of flexible elements, and the space between the insulated surface and the fabric material is filled with heat-sound insulating bulk material.

In an additional embodiment of the claimed system, the slats are made of a non-combustible material and/or a waterproof material.

In an additional embodiment of the claimed system, the fasteners, between which the braces are stretched, are screws with a half ring, screw hooks or fastening angles.

In an additional embodiment of the claimed system, the stretch marks are strong non-combustible threads.

In an additional embodiment of the claimed system, the flexible elements are plastic clamps or stretch marks.

In an additional embodiment of the claimed system, the fabric material is a non-combustible fabric or a polypropylene fabric.

In an additional embodiment of the claimed system, the heat and sound insulating bulk material is a composition containing crushed cellulose fiber, a fire retardant and an antiseptic.

In addition, this technical result is achieved by the fact that in the claimed method of heat and sound insulation along the perimeter of the insulated surface, rails with a thickness of more than 10 mm are installed, on the side surface of which, by means of a detachable fixed connection, fasteners are fixed with a step from each other. Then, braces are stretched between pairs of opposite fasteners, forming a network-like structure, and damping anchors are fixed on the insulated surface opposite the intersections of the braces. After that, a fabric material is placed between the stretch marks and the surface to be insulated, which is then hermetically fixed along its perimeter to the rails, and connected by means of flexible stretch elements at their intersections with each other with damping anchors, passing the flexible elements through the fabric material. After that, the space between the insulated surface and the fabric material is filled with heat-sound insulating bulk material.

In an additional embodiment of the claimed method, the heat-sound insulating bulk material is directed into the space between the insulated surface and the fabric material by means of pneumatic supply.

The essence of the claimed invention is illustrated by drawings (figure 1-figure 7), which shows the stages of the method of heat and sound insulation, providing the installation of a heat and sound insulation system, which includes interconnected structural elements, indicated by the following positions:

1 - rail;

2 - insulated surface;

3 - fasteners;

4 - stretch marks;

5 - damping anchors;

6 - fabric material;

7 - flexible elements.

Thus, a fundamentally new method of fastening loose heat and sound insulating materials has been developed. This method allows for frameless protection of building structures and structures with bulk heat-sound insulating materials, which does not have bridges for transmitting vibration from the insulated surface and is made with the possibility of forming any thickness of the protective layer. The developed method makes it possible to reliably distribute the mass of loose heat and sound insulating material on the fabric material, which, in turn, rests on an extension network attached parallel to the insulated surface.

The main difference between the proposed system of heat and sound insulation from the existing ones is the absence of rigid elements (fixing or frame) in the soundproofing layer, which makes it possible to exclude the presence of vibration transmission bridges in the structure, and, as a result, improves the result of sound insulation. The use of light heat and sound insulating bulk material in the system further reduces the total mass of the heat and sound insulation system.

The claimed heat and sound insulation system in the main embodiment contains rails 1 installed along the perimeter of the insulated surface 2. To ensure the reliability of the developed design, the thickness of the rails 1 must be at least 10 mm. In this case, the rails 1 can be made of any material suitable for the purposes of the invention, for example, wood, plywood, plastic, metal. Additionally, the rails 1 can be made of a non-combustible material and/or a waterproof material, such as moisture-resistant and/or fire-resistant plywood.

Fasteners 3, fixed on the side surface of the rails 1 with a certain distance from each other by means of a detachable fixed connection, have holes, protrusions, rings or half rings for fixing stretch marks 4 on them. In particular, screws with half ring, screw hooks, mounting angles.

Between a pair of opposite fasteners 3, stretch marks 4 are fixed with tension, which form a network-like structure by their intersections. Strong non-combustible threads, for example, made of Kevlar or polyamide, or metal cables of small diameter can be used as these extensions 4.

Damping anchors 5 are fixed on the insulated surface 2 opposite the intersections of the braces 4, and are designed to fasten the developed structure to the insulated surface 2. To provide additional vibration isolation of the structure, plastic anchors are used, and in the case of an exclusively heat-insulating direction of work, it is economically rational to use metal anchors with an eye.

Between the stretch marks 4 and the insulated surface 2, a fabric material 6 is placed, which is hermetically fixed along its perimeter to the rails 1. In the preferred embodiment, a polypropylene fabric is used as a fabric material 6, for example, produced by JSC KZPO Samara (https://kzpo. promportal.su/goods/3980350/polotno-polipropilenovoe), or non-combustible fabric, for example, non-combustible building fabric (membrane) "Economy NG", manufacturer LLC "NPP Insulating Materials", Moscow (http://www.ekonom- ng.ru/gidroizolyaciya), or any other fabric material suitable for the purposes of the invention. At the same time, the intersections of the braces 4 are connected to damping anchors 5, fixed on the insulated surface 2, by means of flexible elements 7 passing through the fabric material 6. As flexible elements 7, for example, plastic clamps or braces, which are strong non-combustible threads, can be used. , for example, made of Kevlar or polyamide, or metal cables of small diameter. The flexible elements 7 used in the claimed invention provide reliable fastening of the fabric material 6 parallel to the insulated surface 2, the absence of sagging of the structure, and at the same time do not create vibration transmission bridges from the insulated surface 2.

The space between the insulated surface 2 and the fabric material 6 is filled with heat and sound insulating bulk material (not shown in the drawings). This bulk material is selected from materials with a low specific gravity, in order to additionally ensure a reduction in the total mass of the heat and sound insulation system. As such a material, a composition containing crushed cellulose fiber, a flame retardant agent and an antiseptic agent can be used. In particular, various types of ecowool can be used for these purposes, for example, Ecowool Extra, manufacturer Ecowool Extra LLC, Tyumen (https://extrawool.ru/ekovata/). The standard composition of the mixture of bulk material used for the purposes of the present invention, in the preferred embodiment, contains: 80% cellulose base, 7-10% flame retardant (eg sodium tetrabonate) and 8-12% antiseptic agent (eg boric acid).

The claimed method of heat and sound insulation is carried out as follows.

Along the perimeter of the insulated surface 2 of the room - wall, ceiling, any part of these surfaces - rails 1 are installed. Fasteners 3 are fixed on their side surface by means of a detachable fixed connection with a certain step from each other. This step is selected during thermal insulation work, depending on the estimated mass of the required thermal insulation layer. In the case of soundproofing and acoustic works - depending on the amplitude-frequency characteristics (AFC) of the soundproofing layer, which must be achieved as part of the work. Accordingly, the greater the calculated mass of the heat-insulating layer, the smaller the fasteners placement step 3 is chosen. In the case of acoustic and soundproofing work, the fasteners placement step 3 is selected based on the length of the sound wave that is planned to be effectively dissipated.

Between pairs of opposite fasteners 3, braces 4 are stretched, forming a network-like structure. Damping anchors 5 are fixed on the insulated surface 2 opposite the intersections of the braces 4. After that, a fabric material 6 is placed between the braces 4 and the insulated surface 2, which is then hermetically fixed along its perimeter to the rails 1, for example, with a plastic or metal glazing bead.

At the last stage of the implementation of the claimed method, flexible elements 7 connect the intersections of the stretch marks 4 with damping anchors 5, passing the flexible elements 7 through the fabric material 6 and fixing it at a given distance determined by the desired thickness of the heat-sound insulating layer, parallel to the insulated surface 2. After that, the space between the insulated surface 2 and the fabric material 6 is filled with heat-sound insulating bulk material. In a preferred embodiment of the claimed method, a heat-sound insulating bulk material is placed in the indicated space between the insulated surface 2 and the fabric material 6 by means of its pneumatic supply under pressure by a standard pumping unit, for example, an MN 800 blowing unit, manufactured by Technoleader LLC, Ryazan (http ://technoleader.alloy.ru/product/prochaya-stroitelnaya-tehnika/vyduvnye-ustanovki-mn800m-dlya-montazha-ekovaty-14963094/) through cuts in the fabric material 6, which are subsequently hermetically sealed.

Thus, the implementation of the claimed group of inventions makes it possible to increase the heat and sound insulation of rooms while reducing the total mass of the heat and sound insulating system.

Claims (21)

1. The system of heat and sound insulation, characterized in that it contains: - rails installed along the perimeter of the insulated surface; - fasteners fixed on the side surface of the rails by means of a detachable fixed connection with a certain step from each other; - guys attached between a pair of opposite fasteners, and the intersection of the guy wires formed a network-like structure; - damping anchors fixed on the surface to be insulated opposite the places where the guy wires cross; - fabric material placed between the stretch marks and the insulated surface, hermetically fixed along its perimeter to the rails, - at the same time, the stretch marks are connected at the places of their intersection with each other with damping anchors through the fabric material by means of flexible elements; - and the space between the insulated surface and the fabric material is filled with heat and sound insulating bulk material. 2. The system according to claim 1, characterized in that the slats are made of a non-combustible material and/or a water-resistant material. 3. The system according to claim 1, characterized in that the fasteners, between which the braces are stretched, are screws with a half ring, screw hooks or fastening angles. 4. The system according to claim 1, characterized in that the extensions are durable non-combustible threads. 5. The system according to claim 1, characterized in that the flexible elements are plastic clamps or extensions. 6. The system according to claim 1, characterized in that the fabric material is a non-combustible fabric or polypropylene fabric. 7. The system according to claim 1, characterized in that the heat and sound insulating bulk material is a composition containing crushed cellulose fiber, a fire retardant and an antiseptic. 8. The method of heat and sound insulation, which consists in the fact that - along the perimeter of the insulated surface, rails with a thickness of more than 10 mm are installed, on the side surface of which, by means of a detachable fixed connection, fasteners are fixed with a certain step from each other; - between pairs of opposite fasteners, stretch marks are pulled, forming a network-like structure, and damping anchors are fixed on the insulated surface opposite the points of intersection of the stretch marks; - a fabric material is placed between the stretch marks and the surface to be insulated, which is then hermetically fixed along its perimeter to the rails; - connected by means of flexible stretching elements at the points of their intersection with each other with damping anchors, passing the flexible elements through the fabric material; - after that, the space between the insulated surface and the fabric material is filled with heat-sound insulating bulk material. 9. The method according to claim 8, characterized in that the heat-sound insulating bulk material is directed into the space between the surface to be insulated and the fabric material by means of pneumatic supply.

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