RU2711076C1 - Fire-retardant intumescent coil coating - Google Patents

Abstract

FIELD: manufacturing technology.SUBSTANCE: invention relates to fire-retardant materials and is intended for fire protection of building structures. Fire-proof intumescent coil consists of an elastic polymer composition based on synthetic rubber and oxidized graphite applied on a reinforcing net consisting of a combination of glass fiber, basalt and silica fibers and carbon fiber reinforced plastic, with optimum ratio of components.EFFECT: invention ensures preservation of operational properties of metal structures at fire exposure on them for more than one hour with formation on protected surface of not cracking foam coke with provision of absence of harmful effect on person.1 cl, 1 dwg

Description

The invention relates to flame retardant materials and is intended to protect against fire of building structures of buildings and structures.

A number of structural roll-on fire protection systems are known that have these or those unique properties: dry installation, high installation performance, lower installation losses, since the structure is “wrapped” or “wrapped” rather than covered with plates, etc. Thus, in the classification of fire protection means, a new type of fire protection is highlighted - bendable (roll) intumescent fire protection, which is applied in a "dry" way and at the same time swells when exposed to fire.

Known fire retardant intumescent laminate (patent of the Russian Federation for PM No. 140812, 2014), comprising a flexible base and a flame retardant polymer layer, characterized in that as a flexible base it contains paper with a double-sided release coating, located between the flexible base and the flame retardant polymer layer acrylic dispersion layer, the opposite side of the flame retardant polymer layer is closed with a waterproofing material, and the flame retardant polymer layer is made of a composition containing the following components in the following co ratio, wt. %:

Chlorosulfonated Polyethylene 8.0-12.0 Pentaerythritol 12.0-20.0 Sucrose 5.0-8.0 Ammophos 18.0-28.0 Dicyandiamide 10.0-15.0 Urea 5.0-8.0 Sodium tetraborate water 5.0-8.0 Silica powder 2.0-5.0 Ether glycerin taly rosin 0.6-1.0 High pressure polyethylene film 1.0-2.0 Trichloropropyl phosphate 1.5-3.0 Chloroparaffin-470 4.0-6.0 High molecular weight polyisobutylene-200 2.0-4.0 Ethyl Silicate 32 0.3-0.8

The disadvantage of this rolled fire-retardant laminate is that basalt fiber, polymer layers based on acrylic dispersion, paper, as well as a polymer layer containing soluble components: sucrose, ammophos, aqueous sodium tetraborate, ammophos, glycerol ether, and also “sweating” coating components: trichloropropyl phosphate cannot be used in atmospheric conditions. In addition, MBOR does not swell when exposed to fire, i.e. It is not an intumescent fire retardant. The installation of this material refers to “wet” processes, chlorine-containing and hazardous substances (chlorosulfonated polyethylene, trichloropropyl phosphate; chloroparaffin-4 and dicyandiamide) in the composition of the material, which is also intended for indoor use only, have a harmful effect on the human body and the environment . In case of fire, the release of extremely dangerous and toxic substances should be expected.

An intumescent mesh is known (Canadian Patent No. 2938283, 2018) with many strands that form a series of holes in a flexible mesh having an intumescent coating applied to it. The intumescent coating is made of expandable graphite and a polymer based carrier as ingredients. Moreover, the mesh has such a size that the intumescent coating passes the air flow through the flexible mesh until the intumescent coating is exposed to temperatures equal to or higher than the activation temperature, after which the intumescent coating swells, sealing the holes and preventing air from passing through the flexible mesh. The flexible mesh may comprise wire fabric that may have a 1/4 inch mesh size, while the mesh and intumescent coating may be sized such that the available airflow area is approximately 40-70% of the flexible mesh area.

However, the proposed design of the fire-retardant roll coating does not condense or displace air from the surface of the structure, but forms a dense foam coke around the structure with closed cells containing air, which leads to low thermal conductivity.

The closest analogue is the known fire-retardant intumescent material for the protection of metallic and non-metallic products (RF patent for IZ No. 2260029, 1995), made of fiberglass coated with a polyvinyl chloride intumescent composition containing polyvinyl chloride, dioctyl phthalate, pentaerythritol and diammonium phosphate. The material is mounted as sheets or rolls on the surface of the protected product, where the fiberglass layer of fiberglass is in contact with the protected product, and the layer of intumescent material when heated is an outer layer. When heated, intumescent material increases in volume, prevents the penetration of the heat flux to the protected product.

However, the material intumescent upon heating crack, which leads to an increase in the thermal conductivity of the protective layer, burnouts of this layer and the demolition of the foam-coke layer protecting the product. In addition, the composition of the flame retardant material decomposes when heated with the release of gases harmful to living organisms through an open cracked layer of intumescent material. The disadvantage of the material is the insufficient maximum permissible temperature of thermal exposure, the impossibility of applying flame retardant material to products of complex shape and the release of a large number of strongly fuming and harmful chlorine-containing thermal degradation products that affect the human body. In this case, the fibrous layer and the layer intumescent during emergency heating are made of stretchable material made of a multifilament yarn consisting of an inorganic filament twisted together under conditions of heating with a melting point of more than 1150 ° C and a filament that breaks when exposed to heat at temperatures in the range from temperatures exceeding the maximum permissible operating temperature of the protected product, and up to a temperature of 1050 ° C.

The objective of the invention is to ensure the preservation of the operational properties of metal structures when exposed to fire for more than one hour with the formation on the protected surface not subject to cracking foam coke while ensuring the absence of harmful effects on humans.

The problem is solved by a fire retardant intumescent roll coating, consisting of an elastic polymer composition based on synthetic rubber and oxidized graphite, deposited on a reinforcing mesh consisting of fiberglass, basalt and silica fibers and carbon fiber, characterized in that the composition contains components in the following ratio, wt. %:

Nitrile butadiene rubber (SKN-40) 25-45

Ethyl acetate 5-10

Butyl acetate 3-7

Melamine Treated Ammonium Polyphosphate 7-10

Pentaerythritol 7-10

Titanium White 3-5

Oxidized Intercalated Graphite 5-15

Ground fiberglass 2-5

Technical Magnesium Oxide 3-10

Alumina 4-15

Polymethylsiloxane Liquid 0.5-3

Pigments 0.5-1.5.

The surface density of the fire retardant mesh is set and controlled in the factory and is typically 1.0, 1.5 and 2.0 kg / m ² in a typical embodiment.

As pigments are used: titanium dioxide, red pigment 5C m. A, green phthalocyanine pigment G7, carbon black, red iron oxide.

When exposed to fire, the surface of the fire retardant mesh wrapped around the steel element of the building structure swells to form a foam coke on the surface of the mesh from its lower and upper sides.

The temperature of the formation of foam coke fire retardant mesh is 130 ° -160 ° C. After expansion, due to its own reinforcement, a mechanically strong, dense and sufficiently elastic thermal insulation layer of foam coke is formed, which is not mechanically connected to the surface to be protected and ranges from 50 to 200% of the initial mesh thickness.

Fire protection is carried out by wrapping (mounting) a fire retardant mesh on all heated sides of the steel structure, followed by fixing the joints with metal brackets with a pitch of not more than 20-30 mm and an overlap between the layers of 50 mm. The appearance of the installation of the fire retardant mesh of a typical building structure is shown in FIG. 1.

During the installation and operation of most fire-retardant materials, when protecting all types of structures, they imply a rigid mechanical bond (adhesion) to the surface to be protected: fire-resistant plasters, intumescent paints, foiled basalt mats and rolled basalt materials with fire-retardant adhesive. This condition imposes a number of stringent requirements on the condition and preparation of the surface to be protected, application conditions (temperature and humidity), interlayer drying, the availability of application and installation mechanisms and devices, and careful control over the quality and consumption of materials.

When applying the proposed fire retardant coating, time is reached (up to 90 minutes), at which the structures retain their strength characteristics during fire exposure. The fire-retardant mesh retains its operational properties in macroclimatic regions with a temperate and cold climate, including macroclimatic regions with a moderately cold and tropical marine climate (U, HL, UHL, T, OM), category 1 according to GOST 15150- 69 (open areas in these macroclimatic areas) for at least 25 years.

The positive effects of fire retardant mesh are as follows:

- ease of calculation of material costs in order to increase the fire resistance of structures,

- the possibility of designing fire protection of light steel thin-walled structures (LSTK) due to the low weight and volume occupied,

- compatibility with all previously applied flame retardant or anti-corrosion coatings on steel structures,

- lack of requirements for special preparation of the protected surface (priming, dust removal and degreasing) before installation,

- installation in conditions of increased requirements for dustiness of the surrounding space, for example, in the conditions of working complex equipment indoors or in crowded places,

- repair and replacement of the damaged area of the fire retardant coating by the own personnel of the operation service,

- the simplicity of periodic or control inspection of critical nodes of steel structures, followed by the restoration of fire retardant coating,

- A wide range of designs in rich colors to solve architectural and aesthetic problems.

The test results showed the following: fire retardant coating efficiency on steel structures is 15-90 min, depending on the reduced metal thickness; fire resistance of air ducts and wooden structures, maintaining the operability of cable lines using a coating - at least 90 minutes.

Claims (13)

Fire retardant intumescent roll coating, consisting of an elastic polymer composition based on synthetic rubber and oxidized graphite, deposited on a reinforcing mesh consisting of fiberglass, basalt and silica fibers and carbon fiber, characterized in that the composition contains components in the following ratio, wt. %: Nitrile butadiene rubber (SKN-40) 25-45 Ethyl acetate 5-10 Butyl acetate 3-7 Melamine Treated Ammonium Polyphosphate 7-10 Pentaerythritol 7-10 Titanium White 3-5 Oxidized Intercalated Graphite 5-15 Ground fiberglass 2-5 Technical Magnesium Oxide 3-10 Alumina 4-15 Polymethylsiloxane Liquid 0.5-3 Pigments 0.5-1.5.

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