RU2037022C1 - Device for fire protective stopping of passages of service lines in various structures - Google Patents

Abstract

FIELD: civil engineering. SUBSTANCE: device has outer jacket made of high-temperature-resistant material, for instance, silica cloth, able to withstand, without destruction, temperature of standard fire, i.e. 986 ± 49 C. Inner case made of flexible waterproof material, for instance, polyethylene film, is divided into two or three sections insulated from each other. In both design versions ratio of dimensions of sections in length equal to (0.4 - 1.4): 1 is provided. In case of two-section version, one section is filled up with fire-proofing swelling material, and other section, with high thermal conductivity nonburning material. In case of three-section version, extreme sections are filled up with fireproofing swelling material, and middle section, with high thermal conductivity nonburning material. Used as fireproofing swelling material can be vermiculite concentrate or its mixture with dolomite or organosilicon sodium silicate in form of grains or loose powder. Used as nonburning material featuring high thermal conductivity can be various inorganic materials, for instance, vermiculite ore, dolomite, aluminium production wastes (channel dust), etc. Fire resistance limit of cable line ducts with space sealed by fire protection pads is not less than 1.5 h. EFFECT: increased fire safety of constructions. 6 cl, 4 dwg

Description

 The invention relates to passive fire protection devices and can be used primarily for sealing cable passage places and other communications (pipelines, ducts, etc.) through various building structures, as well as for fire protection belts. The device is also intended for sealing, including temporary, technological openings, holes (in walls, floors, ceilings, etc.) to prevent the spread of fire from one room to another during the construction, installation of equipment, operation.

 Known fireproof pillow brand "PU" for sealing cable passages with a filler of superthin basalt fiber in a case made of rubber-glass fabric [1] The disadvantage of such a pillow, which must additionally be covered with a flame retardant composition, is a relatively low fire resistance (0.75 h), lack of self-sealing when it occurs fire, as well as possible overheating of the conductive part of the cable under load.

The closest in technical essence and the achieved result is a device for sealing cable passages in the form of a flexible cushion, filled with fire-retardant, intumescent under the influence of temperature and due to this sealing material sealing. The pillow filler should contain at least three main components: thermal insulation (at least 90-95 wt. As a rule, in the form of mineral fibers, granules or powder, which includes 1-50 wt. Mainly 3-35 wt. Irreversibly expanding when temperature exposure (unexpanded vermiculite or perlite); a binder (usually organic, thermoplastic plastic such as polyamide, polyethylene, polystyrene, etc.) and a dust collector 0.5-5 wt. mainly 1-3 wt. in the form of mineral or silicone oil. zhno use and thermosetting plastics such as urea formaldehyde, melamine formaldehyde, and others. [2]
A disadvantage of the known device is that the pillow filler is represented mainly by a heat-insulating component, which prevents heat from being drawn inside the cable from the cable, especially from its current-carrying metal parts, and thereby reduces the fire resistance of the cable, the main indicator of which is the normalized temperature in the so-called "cold""the end of the cable (on the output side of the cable, opposite the fire). High heat-insulating properties of the filler throughout the termination volume will contribute to overheating of the cable under current load, which leads to premature aging, damage to the insulation, etc. The known device provides for the destruction of the shell from the fire side, therefore, an obligatory component of the aggregate is a ligament that would turn the contents of the pillow into a monolith, otherwise, if the integrity of the cover is violated, some of the aggregate will precipitate, which will affect the quality of the seal. In addition, the ligament is practically not able to prevent the partial precipitation of mineral components that multiply expand in volume, such as raw vermiculite or perlite, in which only the outer surface of the grains was coated with the ligament. It should also be noted that the plastics offered as ligaments are substances harmful to health, and exposure to high temperatures exacerbates the harmful factor associated with the release of toxic substances; in addition, the content of the organic binder affects the decrease in the fire resistance of the aggregate as a whole.

 The main task to which the invention is directed is to increase the fire safety of objects and structures. The solution to this problem is to use the effect of artificially created thermophysical anisotropy, acquired through the use of materials with both high thermal insulation and heat-conducting properties, while distributing them along the length of the device in a certain sequence by sectioning the inner shell. In this regard, the pillow material is distributed in at least two internal, flexible, waterproof, isolated from each other and located in the direction of one of the horizontal axes of the pillow sections, one of them is filled with fire-retardant, intumescent under the influence of temperature and sealing material seal, and the other filled with a non-combustible substance or a mixture of non-combustible substances with high thermal conductivity. The cushion material can be distributed in three internal flexible, waterproof, isolated from each other sections, the extreme ones are filled with fire-retardant material that swells under the influence of temperature, and the middle one is filled with a non-combustible substance with high thermal conductivity.

For the manufacture of the shell, a material is used, which is maintained without breaking the temperature to 986 ± 49 ^о С, i.e. the maximum possible temperature of a standard fire at which fire tests are carried out (in accordance with ST SEV 1000-78). These requirements are met by a number of materials: high-temperature fabrics (based on silica, silica-alumina, aluminosilicate and other fibers), as well as special films, papers, etc. In our opinion, one of the most acceptable materials for the shell, given the technical and economic indicators, production mastery, are silica fabrics.

 Filling the cushion is possible with a minimum of two components providing thermophysical anisotropy of the seal. The 2-component filler also simplifies pillow technology. One component acts as a fire-retardant, intumescent and sealing material, which, increasing in volume during temperature exposure, acquires heat-insulating properties, which prevents heat transfer from the fire zone to the interior of the seal. The second main component is used to ensure the removal of heat from the cable inside the termination (which is especially important from its metal, current-carrying part). The tool also suggests the possibility of using various mixtures to fill the extreme sections of two or more intumescent materials (for example, raw vermiculite and perlite, or raw vermiculite and organic intumescent binder, or raw vermiculite and organosilicon silicate, etc.), or a mixture intumescent (for example, raw vermiculite) and inert material (in order to save the first, or to give additional fire-fighting action). Thus, carbonate-bearing rocks and, in particular, dolomite emit carbon dioxide, which prevents burning, and organosilicon sodium silicate when exposed to high temperature.

 To fill one part of a two-section pillow or the middle part of a three-section pillow it is possible to use various bulk materials with a sufficiently high thermal conductivity (and, accordingly, with a high bulk density): the same dolomite, vermiculite ore, aluminum production wastes, etc. Mixtures of similar materials are also possible.

 The presence of a high-temperature casing of the pillow, which does not lose its integrity during fire, allows not introducing an organic bond into the aggregate, which not only simplifies the technology for producing pillows, but also avoids the source of toxic gas emissions.

 The placement of components in flexible waterproof, insulated sections (usually made of synthetic film materials, for example, polyethylene) ensures their non-wetting, preservation in their original form, eliminates the need for dust-suppressing substances, and ensures the immiscibility of components with different functional purpose, since their mixing will reduce the effectiveness of their action separately. In this case, two main options for a partitioned pillow are possible: either sequential filling of the inner cover, corresponding in size to the outer shell, with the required components with sizing of partitions between the sections, or the preliminary manufacture of individual sections and their arrangement inside the pillow in a given sequence.

 It should be noted that a number of pillow aggregate components specifically recommended for use are represented by relatively inexpensive and industry-produced materials: vermiculite ore and vermiculite concentrate produced by Kovdorslyuda GOK, liquid glass, ethyl silicate, sodium chloride, as well as by-products: dolomite screening crushing dolomite rubble Trust "Apatitstroy" or dust from bus channels, waste from the Kandalaksha aluminum smelter (Murmansk region).

 In FIG. 1 shows a 2-section pillow; in FIG. 2 fragment sealing passages using 2 sectional pillows; in FIG. 3 3-section pillow; in FIG. 4 fragment sealing passages using 3 sectional pillows.

 Each pillow consists of an outer cover 1 made of silica fabric CT of one of the brands: II-C8 / 3, 23Н, 23Н-С5 / 3, II-Э / 0.15. Moreover, the seams on the cushion cover (not shown in Fig.) Can be made either with silica thread of one of the brands of these fabrics, or with a thread of type K11C6-250-BA, or with metal brackets, or a thin wire, for example, of type X27105T.

 The fire cushion also has an internal, flexible, waterproof cover 2, which can be made of plastic film with a thickness of 0.10-0.15 mm. The polyethylene film cover can be divided into either 2 sections or 3 sections.

 One of the sections or two extreme sections is filled with flame retardant, intumescent under the influence of temperature, heat-insulating or acquiring such properties, and the other or the middle is filled with a non-combustible substance with high thermal conductivity.

Two fire options are possible: on one side of the seal and on two sides. If it is sufficient to comply with the requirements of unilateral fire protection, it is possible to carry out the termination of 2 sectional pillows; basically, the termination is carried out by 3 sectional or twin 2-sectional pillows. In this case, the functional sections of the pillows should be correctly oriented in relation to the fire. For example, if a fire occurred in one of the compartments, then the fire bags 4 and 5, having insulating on the side of section 1 (expansion of vermiculite concentrate or sodium silicone silicate) and cooling, diluting or inhibiting the fire action (CO ₂ , H ₂ O, end effect and etc.) prevent the burning of the shell 6 and insulation 7 inside the seal. Since the heat load is mainly transmitted through the conductive metal cores 8, the intensive removal of heat from the cable contribute to the components of the filler section 11 having high thermal conductivity.

 It is effective to use vermiculite concentrate of a fraction of less than 10 mm or its mixture with dolomite particle size less than 5 mm or its mixture with organosilicon sodium silicate in the form of particles less than 5 mm as a protective material that swells under the action of temperature and seals the seal of the pillows; obtained on the basis of water glass, ethyl silicate, higher fatty acids or sodium chloride.

As a non-combustible material with high thermal conductivity for filling sections of 11 pillows, for example, the following can be used: vermiculite ore fractions of less than 10 mm (average bulk density of more than 1400 kg / m ³ ), having an average mineral composition, wt. hydromica 21.31, olivine-forsterite 31.01, diopside 24.39, magnetite 4.47, apatite 3.06, feldspar 6.80, sungulite 3.68, intergrowths of minerals 5.28; or waste from aluminum production dust of tire channels (PSC) with a particle size of up to 1 mm (average bulk density of more than 1500 kg / m ³ ), containing, wt. alumina 70-80, fluorine salts 10-15, graphite 10-5; or dolomite (screening crushing) with a particle size of less than 5 mm (average bulk density of about 2000 kg / m ³ ).

 To enhance the fire-fighting effect of the agent, the possibility of introducing into the section substances that cause a decrease in combustion, for example, crystalline hydrates of salts with a pronounced endothermic character, etc., is not excluded. It is also possible to stitch with materials with high thermal conductivity, such as metal foil, fine chips or powder in combination with substances that absorb heat well, for example, during a phase transition, etc.

 The fire test of the facility by bench tests was carried out at the VNIIPO Ministry of Internal Affairs of the USSR A cable passage 300 mm thick was tested with sealing with three-section fire-retardant vermiculite-containing pillows of two representative batches from among the developed species. Based on the test results, it was concluded that this device for flame retardant sealing of passages provides non-proliferation of combustion for a standardized 1.5 hours

Claims (4)

 1. DEVICE FOR FIREPROOF TERMINATION OF PASSAGES OF COMMUNICATIONS IN VARIOUS DESIGNS, including a flexible shell and a filler, characterized in that the filler is distributed in at least two internal, flexible, waterproof, isolated from one another and located in the direction of one of the horizontal axes of the shell section, and one of them is filled with fire-retardant material that swells under the influence of temperature, and the other is a non-combustible substance with high thermal conductivity, while the shell is made of mother la withstanding without destruction temperature to (986 ± 49) ° C.  2. The device according to p. 1, characterized in that when the filler is distributed in three sections, the extreme ones are filled with fire-retardant material that swells under the influence of temperature, and the middle one is non-combustible with high thermal conductivity.  3. The device according to claim 1, characterized in that the shell is made of silica fabric.  4. The device according to claim 1, characterized in that a vermiculite concentrate of a fraction of less than 10 mm or a mixture of vermiculite concentrate with dolomite with a particle size of less than 5 mm in the following ratio, wt. Vermiculite concentrate 20 85
Dolomite 80 15
or a mixture of vermiculite concentrate obtained on the basis of water glass, ethyl silicate and sodium chloride, organosilicon sodium silicate with a particle size of less than 5 mm in the following ratio, wt. Vermiculite concentrate 10 90
Organosilicon sodium silicate 90 10
5. The device according to paragraphs. 1 and 2, characterized in that as a non-combustible substance with high thermal conductivity used vermiculite ore fraction of less than 10 mm, having an average mineral composition, wt. Hydromica 21.31
Olivine Forsterite 31.01
Diopside 24.39
Magnetite 4.47
Apatite 3.06
Feldspar 6.80
Sungulitis 3.68
Mineral splices 5.28
or waste aluminum production dust of bus ducts with a particle size of up to 1 mm, containing, by weight. Alumina 70 80
Fluoride salts 10 15
Graphite or 10 15
Dolomite with a particle size of less than 5 mm 10 15
6. The device according to paragraphs. 1 and 2, characterized in that the ratio of the lengths of adjacent sections located in the direction of the horizontal axis of the shell is 0.4 1.4: 1.