RU185081U1 - SOUND INSULATION MATERIAL - Google Patents

Abstract

The proposed utility model relates to construction and can be used mainly as the main sound-insulating layer for any enclosing structures separating rooms that are subject to increased requirements for sound insulation, the technical result is the creation of a relatively thin, from 1.5 to 20 mm, soundproof material having physical and mechanical characteristics that determine its sound insulating qualities, comparable with the above characteristics of lead and n without lead deficiencies - high cost and environmental hazard, the result is achieved by the implementation of soundproofing material containing fillers and binders, with a thickness of 1.5 to 20 mm and a density of 1200 to 12000 kg / m ³ , having a shear rate of 2 to 10 mm at a load of 300 N and from 4 to 25 mm at a load of 500 N; dynamic elastic modulus 0.04-1.3 MPa at a load of 2 kPa and 0.1-3.0 MPa at a load of 5 kPa; relative strain of 0.0-0.07 MPa at a load of 2 kPa and 0.0-0.1 MPa at a load of 5 kPa.

Description

The proposed utility model relates to construction and can be used mainly as the main sound-insulating layer for any enclosing structures separating rooms that are subject to increased sound insulation requirements (residential premises, kindergartens and nurseries, offices, hotel rooms, special rooms, meeting rooms, home theaters, etc.).

The proposed technical solution can be used in the automotive industry, shipbuilding, carriage building, etc. for the same purpose.

It is known that at present in construction, if it is necessary to provide high sound insulation of building envelopes, for example, partitions, interroom walls, ceilings, etc. To fulfill the conditions of their relatively low weight, additional soundproof claddings were widely used.

However, as the results of numerous laboratory and field tests show, the soundproofing effectiveness of such claddings in many cases does not meet modern requirements that impose soundproofing on many types of premises.

Acoustic materials are divided into soundproofing, sound-absorbing, vibration-absorbing and vibration-absorbing. The greatest effect of noise reduction is provided by soundproof materials. They form the basis of additional soundproof cladding.

The requirements for soundproofing materials of such structures are determined by the acoustic properties of a thin solid plate (hereinafter “obstruction”) in the air.

It is known from the prior art that:

1) In the frequency range an octave above the first resonant frequency and an octave below the critical frequency, the soundproofing of an obstacle is determined by the law of mass and is calculated by the formula:

R = 20 log m⋅f - 47.5 (dB)

Where m = ρ⋅s is the surface mass of the barrier in kg / m ² , f is the frequency of sound in Hz, ρ is the density of the material of the barrier in kg / m ³ , s is the thickness of the barrier in m.

As can be seen from the formula, the only property of an obstacle of thickness s and density ρ that provides sound insulation is its surface mass m.

2) At frequencies an octave below the critical frequency and above it, the soundproofing of the obstruction depends on many factors, the main of which are the internal loss coefficient η (dimensionless quantity) and the dynamic modulus of elasticity of the obstruction material E (usually measured in MPa).

Based on the foregoing, soundproofing barrier materials are mainly characterized by four parameters: thickness s, density ρ, dynamic elastic modulus E and internal loss coefficient η.

Moreover, the soundproofing of the barrier is the greater, the greater the density of the material ρ and its thickness s, i.e. the greater the surface mass of the barrier m = ρ⋅s.

Also, the soundproofing of an obstacle is greater, the greater the loss coefficient η.

It is known that even a thin layer, 5-10 mm thick, made of sheet lead, sharply increases the sound-insulating ability of building envelopes. But lead is an expensive and environmentally unsafe material. Therefore, its use as sound insulation is limited to unique and special rooms, mainly for military purposes.

Lead has a combination of the following characteristics:

- density ρ = 11400 (kg / m ³ )

- dynamic modulus of elasticity (at a load of 5 kPa) E = 0.36 MPa;

- loss coefficient η = 0.15

Currently, the applicant does not know materials intended for sound insulation and at the same time possessing properties similar to those of lead.

The technical result of the utility model is the creation of a relatively thin, from 1.5 to 20 mm, soundproofing material having physical and mechanical characteristics that determine its sound insulating qualities, comparable with the above characteristics of lead and without the disadvantages of lead - high cost and environmental hazard.

Soundproofing material is a very heavy, in comparison with commonly used soundproofing materials, visco-elastic polymer membrane with the following physical and mechanical characteristics:

The claimed technical result, namely the creation of a material with the indicated physical and mechanical characteristics that determine its soundproofing properties, is achieved by the fact that the soundproofing material has a very high density with a relatively small thickness, a significant loss coefficient, a relatively low dynamic modulus of elasticity and is a complex polymer composition natural and synthetic rubbers with fillers from heavy minerals of the class of sulfates or carbonates, or mixtures thereof.

The claimed technical result regarding environmental safety is achieved through the use of environmentally friendly components in the material.

Soundproofing material consists, in the most general description, of fillers, mainly providing the basic soundproofing properties and binders, also playing the role of soundproofing. The composition may also include softeners, giving the material plastic properties, and coloring pigments.

The binder component used is mainly a polymer composition of natural or synthetic rubbers, or mixtures thereof. In particular, but not limited to, various modifications of butyl rubbers such as BBK, butadiene rubbers such as SKD, SKI-3 isoprene rubber or mixtures thereof can be used.

As heavy mineral fillers, heavy minerals from the sulfate group can be used, in particular, but not limited to barite with a hardness of 3-3.5 and a density of 4-4.7, chalk of organic origin, kaolinite, heavy minerals from the carbonate group, in particular, but, not limited to calcite, or mixtures thereof.

As softeners, various modifications of petroleum plasticizer oils can be used, in particular, but not limited to, PN-6, various modifications of industrial petroleum alloyed oils, the basis for the production of which are sulfur and low sulfur grades of oil, in particular, but not limited to , I-40.

As the most important components of the polymer compositions, various modifications of low molecular weight polyethylene (NMPE) can be used, in particular, but not limited to, NMPE-2, various modifications of liquid chloroparaffin, in particular, but not limited to CP, various modifications of liquid or viscous-liquid polymers ethylene glycol, in particular, but not limited to, macrogol (polyethylene glycol PEG).

To give color to the soundproofing material, special coloring pigments, including those of organic origin, in particular, but not limited to, Zh-83, are added to the mixture.

The composition of the components of the soundproofing material in particular, but not limited to, may be as follows:

In the embodiment, the soundproofing material can be supplemented with glue, non-woven material, foamed polyethylene, felt, aluminum foil, etc.

The production of soundproofing material is as follows.

All components of the material are mixed on rubber-processing rollers designed for processing rubber compounds based on natural and synthetic rubbers in rooms with artificially controlled climatic conditions.

The mixture of components processed on the rollers by friction forces is pulled into the gap between the rollers rotating towards each other. Due to the difference in the circular velocities of the working surfaces of the rolls, the mixture of components in the gap undergoes shear deformations, as a result of which it is processed: mixing, softening, plasticization, heating.

The distance between the rolls is adjustable, as a result of which it is possible to change the thickness of the material from 1.5 mm to 20 mm.

After mixing the components, a sheet of material is pulled onto a technical table adjacent to the rollers, where it is cut and cut according to a template of a given size.

In an embodiment, for additional strength and / or sound-absorbing properties, the material is subjected to additional processing: on the one hand, an adhesive layer of 300 g per 3 m ² is applied to it, a layer of non-woven material of the Spanbond type is applied (either foamed polyethylene, or felt, or aluminum foil, etc.) and rolled by special technology.

Sound insulation material is placed in the drying chamber for a certain time.

Then, the soundproofing material is placed on the technical table, and, to prevent the material from sticking (sticking together), cover with silicone paper / film.

Finished material is packaged in accordance with the specifications of the manufacturer.

Claims (8)

1. Soundproofing material containing fillers and binders, a thickness of 1.5 to 20 mm and a density of 1200 to 12000 kg / m ³ , having a shear rate of 2 to 10 mm at a load of 300 N and from 4 to 25 mm at a load 500 N; dynamic elastic modulus 0.04-1.3 MPa at a load of 2 kPa and 0.1-3.0 MPa at a load of 5 kPa; relative strain of 0.0-0.07 MPa at a load of 2 kPa and 0.0-0.1 MPa at a load of 5 kPa. 2. Soundproofing material according to claim 1, characterized in that it further comprises softeners. 3. Soundproofing material according to claim 1, characterized in that it further comprises coloring materials. 4. Soundproofing material according to claim 1, characterized in that natural rubber is used as a filler. 5. Soundproofing material according to claim 1, characterized in that artificial rubber is used as a binder component. 6. Soundproofing material according to claim 1, characterized in that a mixture of natural and artificial rubber is used as a binder component. 7. Soundproofing material according to claim 1, characterized in that heavy minerals from the sulfate group are used as filler, in particular, but not limited to, barite, or mixtures thereof. 8. Soundproofing material according to claim 1, characterized in that heavy minerals from the group of carbonates are used as filler, in particular, but not limited to, calcite, or mixtures thereof.