RU231135U1 - FIRE PROTECTIVE CABLE SHEATH - Google Patents

Abstract

The utility model relates to a protective sheath for a cable capable of protecting the cable from the effects of open fire during a fire. The technical result of the utility model is such a technical solution for cable protection that allows: to ensure more stable operation of the cable line for a long time in the event of a fire; in the event of cable damage due to a fire, to quickly replace it with a regular available cable in order to quickly restore power supply or communication, without changing the level of fire protection.

The specified technical result is achieved due to the fact that a protective sheath for a cable is declared, made with such an internal diameter that the cable passes freely inside it, where the sheath is a tube made of non-flammable plastic, around which a fire-resistant coating is formed that tightly compresses the tube, characterized in that the fire-resistant coating is made in the form of a homogeneous mass, and non-flammable fabric is wrapped over the homogeneous mass.

Description

The utility model relates to a protective sheath for a cable, capable of protecting the cable from exposure to open flame during a fire.

As described in [https://fireman.club/statyi-polzovateley/ognezashhita-kabelya-i-kabelnyih-liniy/ ; as published in the edition: 28.10.2022] the energy saturation of not only industrial but also residential facilities is not decreasing every year, but increasing, so is the number of fires associated with improper design; illiterate placement, installation, operation of electrical equipment, including single cables and electrical lines, cable lines laid on building structures on shelves, in trays, boxes; as well as inside cable structures - pits, basements, tunnels, shafts.

Both internal causes - short circuits, transition resistance, strong heating in places of loose contacts, and pyrolysis, ignition of combustible insulation, protective sheath of electric cables from external influences - strong heating of open flame from the source of fire contribute to the rapid spread of fire; moreover, its extinguishing is greatly complicated by the fact that all lines are under voltage.

Structural fire protection of cables is necessary to limit the spread of fire along cable lines with combustible insulation; and to protect electrical lines passing through premises with a high category of explosion and fire hazard.

Passive fire protection of cables is the coating of the surfaces of flammable insulation of current-carrying lines, boxes/trays in which they are laid, with fire-resistant materials - fire-resistant paints, varnishes, pastes, mastics; installation of fire-resistant couplings, fire-resistant penetrations in places where cable routes are laid through fire barriers.

In order to limit and prevent the spread of fire along cable lines that literally penetrate the entire volume of protected objects, within the premises, fire compartments, sections, fire protection boxes with a standard fire resistance limit are used, as well as fire protection penetrations in places where cable lines are laid through fire partitions, ceilings, and building walls.

To do this, fill the holes and openings in them throughout the entire thickness of the building structure with various non-combustible materials - fire-resistant basalt material, fire-resistant foam, light types of fire-resistant plasters. In addition, in places where single power cables pass, fire-resistant couplings are installed on both sides of the building barrier to fire.

Legislative requirements for fire protection of both individually laid electrical cables and power supply lines of buildings and structures are established by Article 82 of Federal Law 123:

Electric wires, cable lines of automatic fire protection of buildings, including stationary fire extinguishing systems, alarms, SOUE; internal fire water supply; fire lifts must remain operational for the period necessary for the evacuation of people, performance of technical functions. For this, fire protection of electric cables with combustible insulation is required.

Cable lines from transformer substations to input and distribution devices must be laid in separate fire-resistant channels or fire-protective materials must be used for their coating.

Openly laid cables must not spread combustion, for which purpose products with non-flammable insulation are used or fire-retardant coatings and compounds are applied.

Fire protection of cable lines also meets the requirements of the Electrical Installation Code (PUE) in terms of ensuring conditions to prevent the spread of fire along electrical lines.

According to GOST R 53316-2009 on the methodology for testing the maintenance of operability of cable routes during a fire, it is called the ability to continue performing specified functions when exposed to high temperatures and fire exposure during the standard period.

The most effective type of passive fire protection for such electrical products is fire protection paint. According to the requirements of Article 150 of Federal Law 123, to confirm the quality and effectiveness of fire protection paints used to cover cable lines, a fire safety certificate is required for each batch of products, regardless of their volume.

The most famous brands of fire-retardant paints certified in Russia are:

OGRAKS. Under this brand, the UNIHIMTEK group of companies produces fire-retardant intumescent paints on a water basis - B1, BB; on an organic solvent - M; on a fiberglass backing - L1. This allows you to choose the optimal version of the Ograks paint composition for rooms with humidity up to 85%; outdoors; for partially/fully immersed in water; heavily contaminated, armored and bitumen-mastic-coated cables.

FIRETEX is a one/two-component fire-retardant paint imported from the UK with a fire resistance limit of the resulting coating of up to 150 minutes.

МВПО is a universal intumescent coating/paint. It is intended for fire protection of metal structures, wood and sheet products based on it, any types of connecting electric lines - power, lighting, control and monitoring cables with a flame resistance limit of up to 150 minutes. The features and advantages of this paint/coating, which is close to fire-protective mastics in its properties, are its high elasticity; resistance to precipitation, condensation, moisture; up to flooding in cable tunnels, collectors. This allows you to cover cable lines with MVPO both inside buildings and, if necessary, outside; as well as in rooms protected by water, foam fire extinguishing systems, finely sprayed water fire extinguishing systems.

KL-1 is a paint specially designed for covering cable lines. Like MVPO, it is a product of domestic companies.

GOST R 53311-2009, which regulates the methods for establishing the effectiveness of fire-protective cable coatings - mastics, pastes, paints, varnishes, defines them as layers of fire-resistant materials, mixtures, compositions obtained as a result of application to the surface of combustible cable insulation; possessing standard fire-protective effectiveness.

Fire protection paste, as well as mastic for fire protection of load-bearing metal and wooden building structures, transit air ducts of ventilation systems passing through fire-hazardous premises; cable electrical lines on extended sections in buildings, inside various cable structures appeared much earlier than modern fire protection paints.

However, the invention of innovative intumescent compounds, which such paints mainly are, did not become the final verdict for mastics and pastes.

Although they are much thicker than paints and the process of their application with brushes and rollers is more labor-intensive than spraying intumescent compounds, and their consumption is higher; but they are much cheaper; plastic, which is an advantage during operation, routine repairs, and replacement of sections of cable lines.

Fire-retardant pastes and mastics of most common compositions/formulas are viscous, non-drying mixtures based on artificial rubber, some polymers with various mineral fillers that provide the required fire resistance limit.

Such fire-resistant coatings applied to cable lines or single cables reliably hold the fire at the point of origin of the fire, preventing it from spreading; and also, due to the thickness of the fire-resistant coating, effectively prevent rapid heating, pyrolysis, and ignition of flammable insulation of cable products.

Application of fire-retardant paints, treatment with fire-resistant pastes and mastics is carried out on fully assembled cable lines laid on metal shelves, in trays or boxes.

Painting is most often done by spraying thermally active fire-retardant compounds using industrial construction spray guns, airless spray stations; and application, treatment of the surface of cable insulation laid in bundles, pastes, mastics - manually with brushes or rollers, which takes more time with significant labor costs; but the resulting layer of protection from the effects of flame both outside and inside the array of electrical cables is reliable and durable.

When covering a cable with a fire-retardant composition, designers and customers often have a question: what should be the minimum permissible, optimal thickness of the fire-retardant coating for both intumescent thermally active paints and fire-retardant pastes/mastics.

The general rule for treating/coating cable lines with fire-retardant compounds is the need to cover the entire accessible area of the outer surface of single cables, as well as current-carrying product lines laid in multilayer bundles.

The rules for the application of fire-protective coatings are set out in RD 153-34.0-20.262-2002 for energy facilities, which is entirely justified, since it is there that the maximum concentration of connecting cable products is found, significantly exceeding similar parameters of power supply systems for industrial enterprises, public and residential buildings.

In addition, the classification, fire safety requirements, and fire test methods are set out in several official documents that are valid for any type of cable products and fire protection products – NPB 242-97, NPB 248-97, NPB 238-97; GOST R 53316-2009, GOST R 53311-2009, GOST IEC 60332-1-1-2011.

Fire cushion protection

Such fire-protective products are used for insulating rows of cables between themselves, for filling cable boxes, trays; passages through building fire barriers.

Fire-resistant cushions are covers made of fiberglass fabric with waterproof inserts filled with non-flammable filler. Fiberglass both prevents the development of the combustion process of cable insulation and restrains the release of toxic smoke products.

There are two types of such fire protection agents:

PPU. In them, the covers are filled with fibrous mineral materials, which creates a temperature limit of fire resistance up to 1000 ℃.

PPV – filled with powder mixtures, often similar to fire extinguishing powders, with a sintering/swelling range, resistance to open flame from 150 to 900 ℃.

Thus, in technology today there are solutions related to the manufacture of cable with a sheath that has either non-flammable properties or a fire-extinguishing composition of the braid. Also known are solutions for laying a conventional cable in a protective sleeve or box that has fire-resistant cushions.

For example, Japanese Patent Application JP 2000/106041 describes a flexible non-halogen flame-retardant electric cable. The cable comprises two cores of polyvinyl chloride or polyolefin insulated conductors or a plurality of cores of these insulated conductors with a distance between the twisted cores and foamed non-halogen flame-retardant sheaths, which are formed by mixing in an olefin-based resin at least one flame-retardant agent such as magnesium hydroxide, calcium hydroxide, barium hydroxide, aluminum hydroxide in an amount of 50 to 200 parts by weight per 100 parts by weight of the resin, and an organic foaming agent such as azodicarbonamide, p-toluenesulfonyl hydrazide or 4,4'-oxybis (benzenesulfonyl hydrazide) in an amount of 0.2 to 5 parts by weight per 100 parts by weight. parts of resin, and other processing aids or antioxidants may be added, and the foaming rate obtained is 5% to 20%. The above-mentioned fire-retardant casings are said to have a prescribed breaking load and a prescribed bending load, which improves the breaking performance, handling and processability, and provides standard fire resistance. The process used to manufacture the said foamed fire-retardant casings is not mentioned.
European application EP860465 discloses a method for producing a foamed thermoplastic article comprising heating and mixing, optionally using a static mixer, a thermoplastic elastomer selected from the group comprising styrene-based thermoplastic elastomers and thermoplastic polyolefin elastomers, with an effective amount of a water-containing compound, preferably aluminum trihydrate or magnesium hydroxide, to a temperature at which the compound releases water, which is a temperature higher than the melting point of the elastomer, followed by releasing the resulting heated mixture into atmospheric conditions. It is claimed that the above-mentioned process makes it possible to produce foamed articles with a fine and uniform cellular structure.

A solution is known according to patent US2007262483, published: 2007-11-15, which describes a method for producing a self-extinguishing cable, comprising at least one transmissive element and at least one fire-resistant coating in a position radially external from said at least one transmissive element, in which said at least one coating includes:
(i) obtaining a foamed fire-resistant polymer material containing:

(a) at least one foamable polymer;

(b) at least one expanding agent;

(c) at least one fire-retardant inorganic filler in an amount of from 100 to 250 parts by weight relative to 100 parts by weight of the polymer;

(ii) feeding the flame-retardant polymeric material into an extruder where it is melted and mixed;

(iii) passing the fire-resistant polymeric material obtained in step (ii) through at least one static mixer;

and (iv) applying by extrusion the fire-resistant polymeric material obtained in step (iii) onto said at least one transfer element fed into said extruding device.

Known is patent RU96693U, publication: 2010.08.10, for a fire-resistant installation control and power cable for explosive zones on floating drilling rigs and offshore fixed platforms, consisting of a core including at least one insulated conductive core twisted from several copper wires, or at least one group twisted from several of the named insulated conductive cores, wherein all air cavities in the core, including those within the groups, are filled with a polymer filler of at least one screen and a polymer moisture-proof sheath applied under pressure, characterized in that the insulation of the conductive cores is made combined, consisting of at least two layers, the first layer is made fire-resistant, and the second layer is made concentric, extruded from a polymer material, the screen is made in the form of a braid of copper or tinned copper wires, and the density of the braid is selected such that the mass The braid was no less than 90% of the mass of the copper tube with the same internal diameter and wall thickness equal to the diameter of the braid wire, and the said moisture-proof sheath was made of a polymer that was resistant to oil, petrol, sea water and sea fog and did not support spontaneous combustion.

The technical problem with the above solutions is the need to manufacture a cable with

fire-protective sheath so that it can be placed in a given place of the cable route. The cost of such a cable is significantly higher than a normal one and after a fire the cable still needs to be replaced after damage to the braid.

Despite the fact that such cables do not spread combustion, they often do not solve the main task of fire protection of the cable route - to ensure stable operation of the cable line for a long time in case of fire. With prolonged exposure of the fire-resistant cable to open fire, sooner or later the cable sheath melts and is damaged, which leads to a short circuit of the cable line.

More effective solutions are those that involve laying a regular cable in a protective sleeve or box.

The protective box is the most reliable in terms of cable protection from any type of fire exposure, but has the disadvantage that it takes up a lot of useful space in the room, taking into account the thickness of the insulation protection, and is structurally difficult to install, is very heavy in itself and requires special anchor hangers and fasteners. During a fire, these fasteners are weakened and the anchors fall out of the wall, the box falls or breaks. Open flame penetrates into the place of the box break and damages the cable lines.

In addition, the technical problem of the protective box is the impossibility of its use in rooms where there is little space for its allocation. And more problems arise in situations where cable lines are already installed in places where the protective box cannot be erected around them.

Protective sleeves are smaller in size and easier to place.
Known is patent RU2140309, published: 1999.10.27, for a method of protecting cable routes from fire, in which a substance that forms an insulating layer and foams when heated is applied to the cable and cable fastening elements of the cable route, characterized in that the substance that forms the insulating layer is applied to a substrate that improves the adhesion of the foamed substance, and the material that serves as the substrate is used to wrap or coat the cable at least in the area of the cable fastening.

Known is patent RU2168341, publication: 2001.06.10, which describes a device for fire protection of single-layer or multi-layer laid cables, containing a fire-resistant coating located around the cables with a tight grip along their entire length, characterized in that the fire-resistant coating tightly gripping the cables is made in the form of a plurality of flexible pads wrapped around the cables made of fire-resistant and melt-impermeable polyethylene fabric, the longitudinal edges of each of which are overlapped and fastened together, while the pads are placed on the cables in series and connected to each other, forming a sleeve.

The technical problem with these solutions is the installation of several cables in one protective sleeve or protective box. During a fire, open flames will sooner or later penetrate the sleeve or box, burning through the sheath or damaging it so much that it needs to be replaced. Eventually, due to damage to the sheath, all cables in the sleeve will need to be replaced, even if none of them are damaged.

In addition, if the braiding of one or more cables is damaged by open fire, the entire cable route may short-circuit and be put out of order.

The main purpose of fire protection of cable routes is to ensure stable operation of the cable line for a long time in case of fire. Protective sleeves do not always cope with this task.

Thus, today there are unresolved problems:

- ensure stable operation of the cable line for a long time in case of fire;

- in case of damage to a cable, in order to quickly restore power supply or communication, it is necessary to quickly replace or repair it, and with a regular accessible cable.

From the prior art RU2658650, H01B 7/29, published 22.06.2018, a protective sheath for a cable is known, comprising a coating over which fabric is wrapped; in this case, the sheath is wrapped around the insulation, the sheath is placed around the insulation.

This technical solution does not allow, in the event of cable damage, to quickly replace it temporarily with a regular, accessible cable in order to quickly restore power supply or communications.

In case of cable damage due to fire, it will not be possible to quickly replace the damaged cable with a regular available cable, since in the place where the sheath and cable burn through, the latter will be fused with the sheath itself. In this case, it is impossible to cut off the damaged piece of the sheath together with the cable and insert a "patch" on such a protective sheath.

In addition, the fire-resistant coating formed around the tube does not effectively ensure stable operation of the cable line for a long time in the event of a fire, since the sheath is placed around the insulation and only the fire-resistant coating provides protection from fire, while the cable sheath itself is subject to rapid damage by fire and after the protective coating and insulating fabric are lost by fire, nothing protects the cable from fire.

The closest analogue is (CN103401203 A, H02G 9/02, published 20.11.2013) a protective sheath for a cable, which is a tube made of non-flammable plastic, around which a fire-resistant coating is formed.

This solution allows, in the event of mechanical damage to the cable, to quickly replace it temporarily with a regular, accessible cable.

However, the fire-resistant coating formed around the tube is not effective enough to ensure stable operation of the cable line for a long time in the event of a fire, since only the fire-resistant coating provides protection from fire, and all other elements of the device are subject to rapid damage by fire.

But in case of cable damage due to fire, since only the fire-resistant coating provides protection from fire, and all other elements of the cable's protective sheath are subject to rapid damage by fire, it will not be possible to quickly temporarily replace the damaged cable with a regular available cable, since in the place where the sheath and cable burn through, the latter will be fused with the sheath itself. In this case, it is impossible to cut off the damaged piece of the sheath together with the cable and insert a "patch" on such a protective sheath.

The technical result of the utility model is a technical solution for cable protection that allows:

- ensure more stable operation of the cable line for a long time in case of fire.

The specified technical result is achieved due to the fact that a protective sheath for a cable is declared, made with such an internal diameter that the cable passes freely inside it, where the sheath is a tube made of non-flammable plastic, around which a fire-resistant coating is formed that tightly compresses the tube, characterized in that the fire-resistant coating is made in the form of a homogeneous mass, and non-flammable fabric is wrapped over the homogeneous mass.

It is acceptable that the fire-resistant coating is wrapped around the tube with a plurality of flexible pads made of fire-resistant and melt-impermeable polyethylene fabric, the longitudinal edges of each of which are overlapped and fastened together, while the pads are placed around the tube in series and connected to each other, forming a sleeve. Preferably, the sleeve is clamped with clamps or fasteners.

It is preferable that a corrugated cable pipe is used as a fire protection tube.

It is acceptable that a smooth tube made of non-flammable plastic is used as a fire-protective tube.

It is acceptable to place a layer of foil between the tube and the fire-resistant coating.

Brief description of the drawings

Fig. 1 shows the device of a protective sheath in the form of a sleeve with overlapping connections of the pads for multi-layer laid cables, a side view and a sectional view.

Fig. 2 shows the stages of repair of a damaged section of a protective shell made of a homogeneous mass.

Fig. 3 shows a prototype with a shell in the form of a bare sleeve over a tube without filling with a homogeneous mass.

Fig. 4 shows an example of a cable passed through a prototype tube with a sleeve-shaped sheath.

Fig. 5 shows a prototype with a sheath in the form of a homogeneous mass with a cable passed through a tube before a non-flammable fabric is wrapped over the homogeneous mass.

Fig. 6 shows a close-up of a section of the prototype according to Fig. 5.

Fig. 7 shows four samples prepared for testing - 2 samples according to Fig. 3 and Fig. 5, and 2 control samples, in which the cable was simply wrapped in a sleeve without a tube and filled with a homogeneous mass.

Fig. 8 shows the fire exposure zone before testing.

Fig. 9 (A, B) shows 8 ends of the sections of the routes of all 4 samples brought out from the other side of the wall (before the start of the tests).

Fig. 10 shows the fire test process (view from the control panel).

Fig. 11 shows the contact integrity monitoring lamps at all 8 ends of 4 samples at the beginning of the tests.

Fig. 12 shows the contact integrity control lamps at all 8 ends of 4 samples after testing.

Fig. 13 shows the fire exposure zone after testing.

In the drawings: 1 - cable, 2, - tube, 2.1 - insert of damaged section of tube, 2.2, 2.3 - ends of tube, 3 - foil layer, 4 - clamp, 5, 5.1 - protective sheath in the form of homogeneous mass, 6 - soldering, 7 - non-flammable fabric.

Implementation of a utility model

The device is used for laying single or multilayered cables 1 inside it. The result declared by the utility model is achieved by using a protective sheath for the cable, made with such an internal diameter that the cable inside it passes freely, where the sheath is a tube made of non-flammable plastic, around which a fire-resistant coating is formed tightly squeezing the tube. What is new is that the fire-resistant coating is made in the form of a homogeneous mass, and non-flammable fabric is wrapped over the homogeneous mass.

This technical solution for cable protection allows for more stable operation of the cable line for a long time in case of fire, since, for example, unlike the prototype CN103401203 or the analogue RU2658650, the declared device has an additional protective shell. In comparison with the prototype CN103401203, this additional protection is non-flammable fabric, and in comparison with the analogue RU2658650, the tube itself is made of non-flammable plastic.

And in the event of damage to a cable due to a fire, in order to quickly restore power supply or communications, it is possible to quickly replace it with a regular, accessible cable.

This is achieved both due to the fact that the cable or cables 1 inside the tube 2 pass freely without tight coverage, which allows the use of the declared solution in such a way that in the event of damage to the cable for the purpose of promptly restoring power supply or communication, it can be quickly replaced, and with a regular available cable.

To do this, the damaged cable 1 is pulled out of the tube 2 and a new one is inserted.

A fire-resistant coating in the form of a homogeneous mass can be obtained in various ways, for example, as described in the decision on patent RU2237078, publication: 2004.09.27.

For example, a fire-resistant coating in the form of a homogeneous mass according to the present solution can be obtained by mixing the polymer base, the fire-retardant filler, the dehydrating agent and other additives that may be present according to techniques known in the art, for example using an internal mixer of the type containing tangential rotors (Banbury) or braked rotors, or in continuous mixers of the agitator (Buss) type or twin-screw type with co-rotation or counter-rotation.

Preferably, the dehydrating agent is introduced after the first stage of processing the composition, during which, due to the heat generated during the preparation of the mixture, the fire-retardant filler loses a certain amount of absorbed moisture. In this way, premature deterioration of the ability of the dehydrating filler to absorb water is avoided, this filler must be active mainly during the subsequent extrusion stage. The temperature of the composition in this first stage of preparing the mixture is at least 100° C., preferably at least 150° C., and the stage is carried out for at least 5 minutes.

Alternatively, instead of adding the dehydrating agent during the preparation stage of the flame retardant composition, it may be added during the extrusion stage, for example through the extruder chute.

In both cases, the dehydrating agent can be added to the flame retardant composition in a divided form (granules, powder), optionally coated with dispersing and protective agents such as microwaxes, fatty acids. Alternatively, in order to improve their dispersion in the polymer base, the dehydrating agent can be used with preliminary dispersion in the polymer material (e.g. in semi-crystalline ethylene/propylene rubber).

Smooth non-flammable plastic tube or corrugated tube for laying cables is coated with a fire-retardant homogeneous mass during the extrusion stage of the latter.

When two layers are present, the extrusion may take place in two separate stages, with the inner layer extruded onto the tube in a first pass and the second layer extruded onto the inner layer in a second pass. Advantageously, the coating process may take place in a single pass, for example by means of a "tandem" technique using two separate extruders arranged in series, or alternatively by co-extrusion using a single extruder head.

The temperature at which the flame retardant composition is extruded can vary widely and is determined as a function of the extrusion rate that must be obtained. The extrusion rate actually depends on the viscosity of the composition in the molten state and, thus, on its temperature. In turn, the viscosity depends mainly on the type of polymer base and on the type and amount of fire retardant filler. The minimum extrusion temperature for the composition, as a rule, exceeds the plasticization temperature of the polymer base, while the maximum extrusion temperature is set in such a way as to prevent degradation or decomposition of the polymer base and/or the fire retardant filler. Thus, based on the above criteria, in the case of flame retardant compositions based on a mixture of polypropylene and ethylene/α-olefin copolymers as described above, in which magnesium hydroxide is used as a flame retardant filler, the temperature at which the flame retardant composition is extruded is, as a rule, in the range between 160 and 320°C, preferably between 200 and 280°C.

The cable tube (see Fig. 1) includes the tube itself 2 and a layer of homogeneous mass 5, which functions as a protective sheath with fire-retardant properties.

The self-extinguishing sheath of homogeneous mass 5 may consist of a continuous homogeneous mass directly covering the tube without laying other insulating layers. In this way, the fire-protective coating also functions as an electrical insulator if the protective sheath is used to lay only one cable 1, since with such laying, even in the event of a fire and damage to the protective sheath of homogeneous mass 5 and the tube 2 of the cable line, a short circuit with other cable lines will not occur, and the cable line itself will continue to function in a stable mode.

To enhance protection against fire and the temperature effects of an open flame, a layer of foil 3 is placed between tube 2 and the fire-resistant coating made of a homogeneous mass 5. For this purpose, tube 2 is wrapped in foil 3 before extrusion.

Foil layer 3 ensures even more stable operation of the cable line for a long time in the event of a fire, as it shields the heat from the fire and reduces the direct impact of the fire on the cable itself.

Also, for the convenience of fixing the fire-protective pads, a non-flammable fabric 7 can be wrapped in the sleeve over the protective shell of the homogeneous mass 5, which slides better through the openings in the walls and ceilings, and provides protection against abrasion of the protective shell. Clamps 4 or, for example, ordinary wire (see Fig. 4) can be used as a tie for the non-flammable fabric.

If there is damage to tube 2 and the protective sheath after a fire, then the tube with the section of the damaged sheath is cut at the site of damage before laying a new cable (see Fig. 2(A)), removing the damaged section, and the ends of tubes 2.2, 2.3 are joined together through a special insert 2.1, which is the same tube with a protective sheath.

The ends of tubes 2.2, 2.3 and the ends of insert tube 2.1 are freed from part of the shell (see Fig. 2(B)), joined together by soldering 6, and the exposed sections of the shell are sealed with a non-flammable protective compound, which is used in the manufacture of the shell from a homogeneous mass 5 (see Fig. 2(C)).

Fire-protective compositions of homogeneous mass 5 are obtained in a manner similar to that described in the decision on patent RU2237078:

In a closed Banbury mixer (mixing chamber volume: 1200 cm ³ ) filled to a level of 95% by volume. Mixing is carried out in two stages. In the first stage, the components of the compound, except for the dehydrating agent, are mixed together until a temperature of about 200°C is reached in order to ensure good dispersion of the components and to reduce the amount of moisture present in the filler. The dehydrating agent is then added, while maintaining the mixing temperature at about 200°C.

Examples of materials from which a protective shell made of homogeneous mass 5 can be made:

Engage®8003 is a metallocene catalyzed ethylene/1-octene copolymer: ethylene/1-octene mass ratio=82/18 (5.5 mol% 1-octene); d=0.885 g/ ^cm3 ; MFI=1.0 g/10 min; GDI>70%; ΔH2f=55.6 J/g;

Moplen®EP1X35HF is a statistical crystalline copolymer of propylene/ethylene: d=0.900 g/ ^cm3 ; MFI=9.0 g/10 min; T2f=154°C; ΔH2f=90.6 J/g;

Hydrofy®G 1.5 - natural magnesium hydroxide obtained by grinding brucite, without surface treatment (SIMA Company), with a specific surface area of 10.4 ^m2 /g;

Hydrofy®G 1.5S - natural magnesium hydroxide obtained by grinding brucite, surface treated with stearic acid (SIMA Company), with a specific surface area of 10.4 ^m2 /g;

Silquest®A-172 - coupling agent: vinyltris(2-methoxyethoxy)silane (VTMOEO);

Peroximon®DC40 - peroxide initiator: dicumyl peroxide;

Irganox®1010 - antioxidant:

pentaerythryl tetrakis[3-(3,5-di-tert-butyl-4-hydroxyphenyl)propionate] (Ciba-Geigy);

Irganox®MD1024 - metal passivator: 1,2-bis(3, 5-di-tert-butyl-4-hydroxyhydrocinnamoyl)hydrazine (Ciba-Geigy);

Kezadol®GR is calcium oxide pre-dispersed in semi-crystalline EPR rubber (80 wt.% CaO) in the form of granules with an average diameter of 6-7 µm (Kettlitz Company).

The device is used as follows.

After laying the cable or cables 1 inside the tube 2 along its entire length, where the tube 2 has a homogeneous fire-protective mass 5, the cable route is fixed in the required place in the room. And in places where the cable passes through the walls, holes of the required diameter are made in advance, through which the cable route is passed. After laying the cable route and fixing it to the supports, the places of passage through the walls are sealed with a fire-protective composition. After which the cable route is ready for work.

In case of fire, the cable line may be exposed to open flame, but due to the fact that the cables themselves are laid inside the non-combustible tube 2, even if the fire-protective sheath is damaged, the non-combustible tube will first take the fire's impact, which will only melt, but will not damage the cable sheath. If the flame affects the damaged area for a long time, then the declared solution will still ensure more stable operation of the cable line for a long time in case of fire than in the prototype, since in the prototype, after damage to the protective sleeve, the fire will immediately begin to affect the fire-resistant filler, whereas in the declared solution, the non-combustible fabric 7 will first be affected.

The utility model was tested in practice. Experimental samples (see Fig. 7) of a protective sheath for a cable were manufactured, which were obtained both by making a sheath around a tube 2 in the form of a sleeve of pads 3 (Fig. 5 as a working alternative for comparison), and by making a sheath from a homogeneous mass 5, by extruding the latter (Fig. 5) and then winding it with a sleeve. Two control samples were also manufactured, in which the cable was simply wrapped in a sleeve without a tube and filled with a homogeneous mass.

In the test samples (Fig. 3, Fig. 5) the cables were successfully and easily passed through and then secured to the supports (see Fig. 8). In places where they passed through the wall separating the control zone from the test zone, holes of the required diameter were made in advance, through which the ends of the cable routes of all 4 samples were passed (see Fig. 9).

After laying the cable routes and fixing them to the supports, the places where they passed through the walls were sealed with a fire-retardant compound. After that, the cable routes of the prototypes were ready for testing.

The prototypes according to the stated solution were tested for 1 hour with an open fire using a gas burner (see Fig. 10). The control lamps (see Fig. 11) were observed through the control panel behind the wall, which showed the activity of the contacts for all 8 ends of all 4 prototypes.

Tests showed that in the samples of Fig. 3 and Fig. 5, the protective sheath around tube 2 was practically not subject to melting under the protection of the outer sheath of pads and homogeneous mass 5. At the same time, cable 1, laid inside tubes 2 of both experimental samples, functioned stably throughout the entire period of exposure to fire (see Fig. 12).

In this case, both cables in the control samples melted under fire exposure without tube 2 (see Fig. 12 - two extinguished control lamps).

Thus, the tests showed a significant effect on increasing the protection of the cable under fire exposure in the presence of a non-flammable tube, around which a tightly compressing fire-resistant coating is formed, which can be made as a fire-resistant shell from a homogeneous mass 5, or covered with pads (with the same effect).

Even despite the damage to two supports due to fire exposure (see Fig. 13), where a section of the prototype route sagged, the cable itself remained in working condition after testing.

Claims (6)

1. A protective sheath for a cable, made with such an internal diameter that the cable passes freely inside it, where the sheath is a tube made of non-combustible plastic, around which a fire-resistant coating is formed that tightly compresses the tube, characterized in that the fire-resistant coating is made in the form of a homogeneous mass, and non-combustible fabric is wrapped over the homogeneous mass. 2. A protective sheath for a cable according to claim 1, characterized in that the fire-resistant coating is wrapped around the tube with a plurality of flexible pads made of fire-resistant and melt-impermeable polyethylene fabric, the longitudinal edges of each of which are overlapped and fastened together, while the pads are placed around the tube in series and connected to each other, forming a sleeve. 3. A protective sheath for a cable according to item 2, characterized in that the sleeve is compressed with clamps or fasteners. 4. A protective sheath for a cable according to item 1, characterized in that a corrugated pipe for a cable is used in the form of a fire-protective tube. 5. A protective sheath for a cable according to item 1, characterized in that a smooth tube made of non-flammable plastic is used in the form of a fire-protective tube. 6. A protective sheath for a cable according to item 1, characterized in that a layer of foil is placed between the tube and the fire-resistant coating.