RU73273U1 - INSULATION MATERIAL - Google Patents

Abstract

The utility model relates to multilayer polymeric insulating materials intended for the installation and repair of roofing of residential and industrial buildings and structures operating in various climatic zones, as well as for waterproofing buildings and structures, pipelines, etc. The insulating material contains a base made of woven or non-woven material, or a foil material having increased strength and separation properties that prevent the penetration of hot bitumen-polymer material deposited on one of its sides onto the other side of this base with elastomeric or thermoplastic material applied to it composition. The base material has a surface strength of at least 75 g / cm ² and a mesh size of not more than 0.1 mm without capillary suction. The bitumen-polymer layer is made of a bitumen-polymer composition, including bitumen and divinyl-styrene thermoplastic elastomer or polyolefin with a mass ratio of (70-95) :( 5-30), and also additives such as filler, antiseptic additive are possible. The resulting material has stable insulating properties, water resistance, frost resistance. 1 n.a.s. f-ly, 6 z.p. crystals, 1 ill., 1 tab.

Description

The utility model relates to multilayer polymer insulating materials intended for the installation and repair of roofing, residential, public, industrial and agricultural buildings and structures operated in all climatic regions, as well as for waterproofing these buildings and structures, pipelines, etc.

Known insulation material containing a base and a rubber composition of ethylene-propylene rubber applied to it (Polymer, soft roofing and heat-insulating building materials industry. Issue 2, M., VNIIESM, 1993, p.30).

However, this material has low plastoelastic, technological characteristics and large shrinkage.

Also known is an insulating material containing a fabric or non-woven base and a layer of a polymeric material made of a thermoplastic or elastomeric composition, for example, ethylene-propylene (diene) rubber (Yu.P. Shulzhenko, Polymeric roofing materials.) Materials ”, 1998, No. 11, pp. 8-10).

The disadvantages of this material include the complexity of the technology when installing coatings due to the need to use adhesive mastics on organic solvents, which worsens the production environment and creates the prerequisites for a fire and explosive situation, and in addition, leads to the formation of defects (swelling, unevenness of the adhesive layer) .

A useful model is known for an insulating material containing a fabric or nonwoven fabric base and a layer located on one of its sides made of an elastomeric or thermoplastic composition, and on the other side of the base a layer made of a bitumen-polymer composition including bitumen and divinyl styrene thermoplastic elastomer or polyolefin in a mass ratio (70-95) :( 5-30) (see RF patent for utility model No. 15688, priority 08.06.2000).

This device is taken as a prototype of the claimed device, since it is closest to it in the aggregate of common essential features and the achieved technical result.

A disadvantage of the known technical solution is that because of the need to form a layer of a bitumen-polymer composition from a hot bitumen-polymer mass, there is a chance of penetrating it through the layer of the base onto the side of the base on which the elastomeric or thermoplastic composition is applied, which leads to poor adhesion them to the base and other strength properties of the insulating material as a whole.

The technical task of the utility model is to create an insulating material with improved properties - increasing the adhesive properties of a layer of an elastomeric or thermoplastic composition to the base and the physicomechanical and physicotechnical properties of the insulating material, for example, increasing the resistance of the material to negative temperatures, as well as water and chemical resistance.

According to the claimed utility model, the technical problem is achieved in that the insulating material containing the base and a layer located on one side thereof made of an elastomeric or thermoplastic composition, and on its other side a layer made of a bitumen-polymer composition comprising bitumen and divinyl-styrene thermoplastic elastomer or polyolefin in their mass ratio (70-95) :( 5-30), according to the utility model, contains a base made of

sufficiently strong and crush-resistant material with separation properties that prevents the hot-applied bitumen-polymer composition from penetrating the other side of the base with a layer of an elastomeric or thermoplastic composition previously applied to it, while the base material is a woven material or non-woven material, or foil material with a surface density of at least 75 g / cm2 and a mesh size of not more than 0.1 mm, without capillary suction.

The insulating material, according to this utility model, as a base material contains a metal foil, for example, aluminum or copper, or a polymer foil (polymer foil material) with the above characteristics: surface strength of at least 75 g / cm ² and mesh size of not more than 0 , 1 mm.

A layer of a bitumen-polymer composition applied to one side of the base may additionally include a filler in an amount of 5-30 parts by weight, for example, such as talc-magnesite, and may additionally contain various antiseptic additives, for example, coal tar or coal oil.

So, using in the claimed insulation material, the base, in addition to other properties (reinforcement), must have additional properties:

1. The most important of them is the resistance to punching the base, ie nonwoven fabric or foil fabric.

2. Another important property is that the base is a separation layer. It should not allow direct contact of the layers located on its sides during the manufacturing process.

The top layer, made of elastomeric (rubber) or thermoplastic composition, is applied to the base first. Another layer applied to the other side of the base, from the bitumen-polymer composition (mass), is applied in a hot state. It should not be allowed that when applying the second layer on the other side of the base, the previously applied top layer made of an elastomeric (rubber) or thermoplastic composition would soften.

As noted earlier, this top layer is of two types: elastomeric (rubber) composition and thermoplastic composition.

The elastomeric layer (rubber) is destroyed at high temperature: thermal decomposition of rubber from the rubber mixture occurs. Long-term contact of a layer of an elastomeric composition (rubber layer) with a substance with a high temperature (above 120 ° C) leads to a general deterioration in physical and technical properties (thermal conductivity, waterproofing properties) and physical and mechanical properties (strength characteristics - strength, magnitude of elongation under load).

When using a thermoplastic composition to form one of the layers of insulating material, heating is also not allowed to exceed 140-150 ° С, because its thermoplastics, such as, for example, polyvinyl chloride, polyolefins (for example, polyethylene) or their mixtures at a higher temperature, first pass into a fluid state in which they lose their mechanical properties, and after lowering the temperature they return to their original state. But at the same time, their physicochemical and physicomechanical properties are also deteriorating.

Thus, regardless of what is used to form one of the layers of insulating material — an elastomeric composition or a thermoplastic composition — to preserve their physicomechanical and physicochemical properties, heating them at temperatures above 120-150 ° C is undesirable.

To form a bitumen-polymer layer on the other side of the base, a bitumen-polymer mass is applied at 165-175 ° C. After applying to the other side of the base, the bitumen-polymer mass is immediately cooled, which is carried out on large metal drums inside which cold water passes (cold water from the wells inside at a temperature of 15-18 ° C) (usually the material passes between two, four or eight pairs of such drums). Upon contact with the drums, the bitumen-polymer mass cools, giving off heat to the metal. As a result, the temperature of the bitumen-polymer layer decreases to a temperature of 35-40 ° C.

During the application process, it is impossible to allow the bitumen-polymer mass to pass through the base and come into contact with a layer made of an elastomeric (rubber) or thermoplastic composition for the above reasons because of the possibility of the following processes.

When bitumen-polymer layer is heated, fractions of bitumen and its oil can migrate through the base to the upper layer. Rubber from contact with them will swell both from intense temperature transfer and from chemical interaction. As a result, its spatial structure will be destroyed and it will turn into a degraded structure and lose its physical, technical and physical-mechanical properties.

Similarly, the thermoplastic composition begins to change from heating.

The penetration process is activated as a result of the fact that during the application of the bitumen-polymer mass pressure is applied to it in the direction of the base, which leads to the fact that it can begin to squeeze through the cells of the base, which, in addition, begins to squeeze, which contributes to the stretching of the cells .

The heated fractions of bitumen, acquiring mobility, will tend to penetrate through the cells on the other side of the base, making contact with a layer made of an elastomeric (rubber) or thermoplastic composition, heating it and acting chemically, which leads to the above negative consequences.

This penetration process is further enhanced by capillary suction.

Another drawback of penetration is that the hot fractions of the bitumen-polymer composition penetrated on the other side of the base sharply worsen the adhesion (“sticking” value) to the base of a layer previously made in another plant made of an elastomeric (rubber) or thermoplastic composition.

Thus, the base must have separation properties - the wall must be impermeable and have sufficient density, the cell of the material does not have capillary suction and the openings of the cells must be such that the hot bitumen-polymer mass cannot come close to the rubber (does not come into contact with the top rubber or thermoplastic layer.)

In other words, the cell size must be such that the bitumen-polymer mass does not penetrate the other side of the base and there is no capillary suction (as noted above, bitumen contains a lot of liquid fractions such as oils, from the effect of which the rubber swells. In addition Moreover, oil is a release agent and impairs adhesion (adhesion) of the rubber layer at the base). The decrease in adhesion to the base of a layer made of an elastomeric or thermoplastic composition is the second disadvantage if the bitumen-polymer composition comes into contact with it through the base.

Therefore, the objective of the technical solution is to increase the physicotechnical and physicomechanical properties of the whole coating and to prevent the adhesion of the layer made of an elastomeric or thermoplastic composition from decreasing to the base.

It is achieved by the fact that the base is made of a bursting resistant fabric, non-woven material or foil material having a separation property characterized by a mesh size, ensuring the penetration of a bitumen-polymer mass through it when applying and pressing a layer, and also characterized by the absence of capillary suction. This happens if the mesh size is not more than 100 microns or 0.1 mm.

As a basis, the claimed insulation material contains fabric, for example fiberglass, kapron, dacron, basalt, as well as non-woven materials made from natural and chemical fibers without weaving (knitting, piercing, needle-punched, heat-bonded, adhesive), as well as foil material with a surface strength not less than 75 g / cm, for example, with a surface strength of 75 g / cm ² ; 80 g / cm ² , the mesh size of the base is 0.07 mm; 0.1 mm

The proposed material may also contain a protective release film deposited on the bitumen-polymer composition, preventing the adhesion of the material during its formation in the form of a roll and during storage.

The drawing shows a General view of the material in section.

The insulating material includes a base 1 of fabric or non-woven material or foil material, on one side of which is layer 2 (upper or outer layer) made of an elastomeric or thermoplastic composition, and on the other - layer 3 (lower layer) made of bitumen polymer composition.

The following is information confirming the feasibility of implementing a utility model.

The composition of layer 2 is prepared using standard mixing equipment (rollers, rubber mixers) using commercially available thermoplastic elastomers and synthetic rubbers, in particular, copolymerization products of ethylene with propylene (double copolymers of the type SKEP) or ethylene with propylene and a small amount of the third comonomer - diene with isolated double bonds of type SKEPT, chlorosulfopolyethylene (HSPE) based on low density polyethylene (grade HSPE - 20) or high density polyethylene (grade HSPE - 40).

These compositions may include conventional target and special additives, such as curing agents, fillers, stabilizers, plasticizers, dyes, inhibitors.

The composition of layer 3 is made from components also commercially available. Can be applied, in particular, brands of bitumen BNK 40/180 and divinyl-styrene thermoplastic elastomer DST-30, KR-30.

These compositions may also include up to 30 parts by weight. filler, for example, talc-magnesite (5-30 wt.h) and an antiseptic additive, for example, coal tar or oil.

The insulating material is formed in the form of a web (roll) on traditional roll equipment. First, for example, in one plant, layer 2 is applied.

The composition of layer 3 is applied, for example, already at another plant to the other side of the base 1 in the form of its melt from a special bath using, for example, a doctor blade, rolls.

Comparative tests of the proposed insulating material and the known. The characteristics obtained are shown in the table.

Thus, the proposed material is characterized by high manufacturability and a high level of physicotechnical and physicomechanical indicators in the absence of defects, improved ecology of its production and use, as well as stable characteristics during its formation and operation in a wide temperature range.

Table
Insulation Properties The name of indicators Suggested material Known material According to PM No. 15688 Tensile strength, MPa 9.0 7.0 Relative extension, % 300 300 Water absorption in 24 hours,% 0.2 0.3 Frost resistance, ° С -60 -fifty The presence of defects after 1 year of operation 0 0

Claims (7)

1. An insulating material containing a base and a layer located on one side thereof made of an elastomeric or thermoplastic composition, and on the other side a layer made of a bitumen-polymer composition comprising bitumen and divinyl styrene thermoplastic elastomer or polyolefin in a weight ratio of 70 to 95 ) :( 5-30), characterized in that the base is made of a sufficiently strong and break-resistant material with release properties, such as a woven material or non-woven material, or foil material with a surface with a host density of at least 75 g / cm ² and a mesh size of not more than 0.1 mm, without capillary suction, and preventing the penetration of the bitumen-polymer composition applied to the substrate in the hot state onto the other side of the substrate with a layer of elastomeric or thermoplastic composition. 2. The insulating material according to claim 1, characterized in that it contains metal foil as the base material. 3. The insulating material according to one of claims 1 and 2, characterized in that it contains aluminum foil as the base material. 4. The insulating material according to one of claims 1 and 2, characterized in that it contains copper foil as the base material. 5. The insulating material according to claim 1, characterized in that as the base material it contains a polymer foil. 6. The insulating material according to claim 1, characterized in that it contains a layer made of a filled bitumen-polymer composition, comprising 5-30 parts by weight filler. 7. The insulating material according to claim 1, characterized in that it contains a layer made of a bitumen-polymer composition comprising an antiseptic additive in the form of coal tar or coal oil.