RU148023U1 - HIGH FREQUENCY SYMMETRIC FIRE RESISTANT CABLE - Google Patents

Abstract

1. A high-frequency symmetrical fire-resistant cable, comprising a core consisting of at least one shielded pair, symmetrically twisted single-wire copper conductors, each of which is insulated with silicone rubber, the outer sheath of the cable is made of a halogen-free polymer composition, characterized in that the screen has two layers, the first of which is made of laminated aluminum foil, superimposed on the silicone rubber insulation with a metal layer outward, and the second layer is made braiding of tinned copper provolok.2. A high-frequency symmetrical fire-resistant cable according to claim 1, characterized in that the core includes more than one, twisted together, shielded pairs. 3. A high-frequency symmetrical fire-resistant cable according to claim 2, characterized in that a winding of a polyethylene terephthalate film is applied to the core. 4. A high-frequency symmetric fire-resistant cable according to claim 3, characterized in that a filler of a plastic plastic material is applied to the winding of a polyethylene terephthalate film. 5. A high-frequency symmetrical fire-resistant cable according to claim 2, characterized in that the aggregate of a plastic plastic material is superimposed on the core.

Description

The utility model relates to the field of electrical engineering, in particular, to high-frequency symmetric fire-resistant cables for data transmission, ensuring the preservation of the data transmission parameters of the cable (wave resistance and pair attenuation coefficient) under the influence of a fire and after it, and when exposed to sinusoidal vibration and mechanical blows of single action.

From the "prior art" known fire-resistant symmetrical cable containing at least a pair of twisted insulated copper conductive single-wire or multi-wire strands with silicone rubber insulation; individual screen of each pair or a common screen of pairs made of foil composite material with a contact conductor of tinned copper wire; a shell made of polyvinylchloride plastic compound of reduced fire hazard or of a polymer halogen-free material (RU 123209 U1, 20.06.2012). This cable remains operational under open fire conditions.

The disadvantages of the known device are:

- cable design does not provide high-frequency data transmission;

- frequency characteristics of the cable are not standardized - wave impedance of pairs;

- low resistance of the cable to mechanical stresses (sinusoidal vibration and mechanical shock of a single action) in a fire and after exposure.

The closest analogue to the claimed utility model is a flame-retardant symmetrical cable KSBng (A) -FRHF N × 2 × D, containing at least one symmetrical pair N with copper conductive conductors with a diameter D from 0.64 to 1.78 mm with insulation made of flame-retardant silicone rubber, twisted together with a polyimide film, with a common screen of aluminum-lavsan tape and with a contact conductor of tinned copper wire, in a sheath of a halogen-free polymer composition (TU 16.K99-037-2009, LLC SPP Spetskabel) [one]. The silicone rubber insulation, when burned, forms a dense ceramic layer creating a refractory barrier, the cable sheath is halogen-free and does not spread combustion. Thus, the known cable remains operational in open flame conditions. However, the protective layer obtained by sintering silicone rubber is quite fragile and has low mechanical characteristics, for example, resistance to tearing, sinusoidal vibrations or impact. A protective layer of a polyimide film located on top of a twisted pair or a bundle of pairs does not provide additional protection for silicone rubber from mechanical stress. Thus, the known cable is not resistant to mechanical stresses arising in a fire.

The problem to which the claimed utility model is directed is to preserve the frequency characteristics (wave impedance and couple attenuation coefficient) of a digital signal transmitted via a cable under open flame conditions up to 850 ° C and a single multiple mechanical shock for at least 2 hours during cooling to a temperature of 400 ° C for 1.5 hours and after exposure to an open flame for 300 hours.

The technical result consists in increasing the resistance of the cable to the effects of an open flame with a simultaneous increase in mechanical loads (vibration and single impacts).

The achievement of the technical result is ensured by a symmetrical fire-resistant cable, comprising a core consisting of at least one shielded pair, symmetrically twisted single-wire copper conductors, each of which is insulated with silicone rubber, and the outer sheath of the cable is made of a halogen-free polymer composition, while the screen has two layers, the first of which is made of laminated aluminum foil, superimposed on the silicone rubber insulation with a metal layer outward, and in Ora layer is formed as a braid of tinned copper wires.

According to the claimed utility model, the symmetrical fire-resistant cable includes a core containing more than one shielded pair twisted together.

According to the claimed utility model, a winding of a polyethylene terephthalate film is applied to the core.

According to the claimed utility model, a filler of a plastic polymer material is applied to the winding of a polyethylene terephthalate film.

According to one embodiment of the claimed utility model, an aggregate of polymer plastic material is superimposed on the core.

Preservation of the frequency characteristics and resistance of the cable to mechanical stress during and after fire is provided by: reinforcing the brittle ceramic layer formed by the braiding of the screen formed during the burning of combustible substances that are part of the silicone rubber insulation. Converting the insulation of a shielded pair when exposed to an open flame into a protected reinforced ceramic layer allows the cable to remain operational (wave resistance and pair attenuation coefficient at a frequency of up to 250 MHz) under fire conditions and after it under simultaneous mechanical stresses.

The technical essence of the group of utility models is illustrated by the following illustrations:

FIG. 1 is a cross-sectional view of a cable with four pairs of conductive wires;

FIG. 2 is a longitudinal sectional view of a cable with four pairs of conductive wires.

The cable includes the following structural elements:

1 - conductive core of round copper wire;

2 - isolation from silicone rubber;

3 - a screen made of laminated aluminum foil;

4 - a screen in the form of a braid from round tinned copper wires;

5 - winding with a tape of polyethylene terephthalate film with the number of shielded pairs 2, 4, 14;

6 - filler of plastic plastic material with the number of shielded pairs 2, 4;

7 is an outer shell of a halogen-free polymer composition.

The structural elements that make up the cables have the characteristics shown in Table 1.

The cable manufacturing technology according to the claimed utility model includes the following operations.

Single-wire conductors 1 are made of round copper wire. An insulation 2 of silicone rubber is applied to each conductive core 1 (for example, UNISIL Profff RS 20-8465 silicone rubber mixture). Insulation 2 is applied by extrusion combined with the vulcanization process on continuous vulcanization cable lines. Twisting of insulated cores 2 is performed on a twisting machine. On top of the twisted pair impose a two-layer screen 3, 4 made of laminated aluminum foil, overlaid on top of the insulation 2 with a layer of metal outward and braided with tinned copper wires. According to one embodiment of the invention, the core is made of two or more shielded twisted pairs (up to 14 pairs). On top of the core, for cables with a number of pairs 2, 4, 14, a winding is applied with a tape of polyethylene terephthalate film 5 (for example, PET-E polyethylene terephthalate film 50 × 40). On cables with a number of pairs 2, 4 on the extrusion line, an inner sheath (filler) 6 is applied (for example, halogen-free and fire-resistant filler WK-40 / HFFR). An outer shell 7 of a halogen-free and flame-retardant polymeric material (e.g., ConGuard S-6645 halogen-free polymer composition) is applied to the extrusion line.

The proposed design ensures the preservation of cable operability and the transmission of digital and analog signals at a frequency of up to 250 MHz for the entire time (120 minutes) when exposed to an open flame with a temperature of 800 ± 50 ° C simultaneously with a mechanical shock of a single action (1 time in 5 minutes), and after a fire, to the effects of sinusoidal vibration with parameters: acceleration of 3.3 × 10 ^-2 g and a frequency of 6.4 Hz for 300 hours.

According to the implementation options of the claimed utility model, it is possible to carry out three types of cables with a wave impedance of 75 Ohm, 100 Ohm and 120 Ohm.

Tests carried out to assess the preservation of the frequency characteristics of the cable under conditions of flame exposure (temperature 860 ± 20 ° C), mechanical shock (1 time in 5 minutes) and vibration (with acceleration 3.3 × 10 ^-2 g and a frequency of 6.4 Hz) showed that the cable remains operational for 300 hours. After exposure to an open flame, the wave impedance of the pairs decreases by no more than 1.23%, and the attenuation coefficient of the pairs, calculated on the length of 100 m of the cable, increases by 11.84% at a frequency of 100 MHz, and increases by 6 at a frequency of 250 MHz, 04%, which allows the cable to pass high-frequency signals for a long time even in a fire. The results of the cable performance assessment are given:

- Protocol No. 003-13PB of January 28, 2013: tests of the prototype cable for fire resistance with mechanical shock;

- Protocol for research tests of cable No. 038-12 VP of 12/27/2012: assessment of the preservation of frequency characteristics under the influence of flame, mechanical shock and vibration.

The developed high-frequency symmetric fire-resistant cable provides the ability to transmit high-frequency signals in communication systems, in structures and at weapons and military equipment during external and internal group installation in a fire and after its elimination.

Literature

[1] TU 16.K99-037-2009. Symmetrical cables for security systems, fire resistant. Specifications, KSBsg (A) -FRHF N × 2 × D, LLC NLP “Spetskabel”, Moscow, 2009, 39 l.

Claims (5)

1. A high-frequency symmetrical fire-resistant cable, comprising a core consisting of at least one shielded pair, symmetrically twisted single-wire copper conductors, each of which is insulated with silicone rubber, the outer sheath of the cable is made of a halogen-free polymer composition, characterized in that the screen has two layers, the first of which is made of laminated aluminum foil, superimposed on the silicone rubber insulation with a metal layer outward, and the second layer is made braiding of tinned copper wires. 2. High-frequency symmetrical fire-resistant cable according to claim 1, characterized in that the core includes more than one, twisted together, shielded pairs. 3. A high-frequency symmetric fire-resistant cable according to claim 2, characterized in that a winding of a polyethylene terephthalate film is applied to the core. 4. A high-frequency symmetrical fire-resistant cable according to claim 3, characterized in that a filler of a plastic polymer material is applied to the winding of a polyethylene terephthalate film. 5. A high-frequency symmetrical fire-resistant cable according to claim 2, characterized in that the filler of a plastic plastic material is superimposed on the core.

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