RU74005U1 - MOUNTING CABLE FOR FIRE SAFETY SYSTEMS - Google Patents

Abstract

The utility model relates to mounting cables for fire alarm systems.

The cable contains a core of insulated copper single-wire or multi-wire conductive conductors twisted in pairs, and a moisture-proof sheath. The insulation and sheathing material is a special polyvinyl chloride plastic compound with reduced smoke emission and an oxygen index of at least 30 or a halogen-free polymer composition with an oxygen index of at least 35.

Shielded, armored designs are provided. As well as designs with a cable for suspension on supports and poles.

The proposed design will provide increased fire hazard requirements for cables used for fire alarm systems.

Description

The utility model relates to cable technology, namely: to the construction of assembly cables intended for indoor installation in fire safety systems and other systems.

Known installation cable for fire safety systems according to utility model No. 49351, class. HB01 11/06. The disadvantages of this cable include low fire safety requirements. So to the shell in paragraph 4. The patent formula stipulates a requirement for non-proliferation of combustion, and no fire safety requirements are generally imposed on insulation. In cable technology, it is generally accepted that if a requirement is simply written for non-proliferation of combustion, then this means the weakest requirement for non-proliferation of combustion with a single installation. A number of documents impose more stringent requirements on the non-proliferation of combustion in the bundle, such as in GOST R IEC 332-3 or GOST 12176-89. Moreover, indirectly, compliance with this requirement is confirmed by the use of materials with a specific oxygen index. And as a rule, additional requirements are imposed on low smoke generation and / or indicators of the corrosion activity of smoke and gas products during combustion.

To meet this requirement, either halogen-free polymer compositions with an oxygen index of more than 35, or special polyvinyl chloride plastic compounds with an oxygen index of more than 30 and low smoke emission are used.

Given that alarm devices, as a rule, are connected in several pieces per one pair of cores, in order to determine the exact location of the fire source, the installation cable for fire safety systems must ensure compliance with the most stringent requirements for the non-distribution of combustion.

The absence of a single-pair design in the given analog can also be considered a drawback, because in some cases a single-pair cable is used to connect fire alarm sensors.

In addition, the lack of pairwise stranding of cores is also a disadvantage. Cables with non-twisted pairs of cores can only be used with relatively short lengths (of the order of ten meters), because the effect of electromagnetic interference of high power can lead to a false response of the receiving system.

Choose a cable according to utility model No. 49351 as a prototype.

The technical task of the proposed utility model is to create an installation cable for fire safety systems that meets the requirements of non-proliferation of combustion and low smoke emission.

The technical problem is solved by the fact that a mounting cable for fire safety systems is proposed, comprising a core comprising at least one pair of copper single-wire or multi-wire conductive cores twisted together in pairs, insulated with polymer, a belt insulation made of polymer tape, and a moisture-proof polymer sheath overlaid insulation, and the polymer for insulation and the shell is either a special polyvinyl chloride plastic compound with low smoke emission and an oxygen index of not less than it is 30, or a polymer halogen-free composition with an oxygen index of at least 35.

For cables laid in short sections of about 10 m in length, it is economically more beneficial that the cores in pairs are not twisted together and differ only in the color of the insulation.

For cables laid in a straight line or with bending without twisting, it is advisable that they have a flat design with all pairs laid in the same plane.

Provided that the cables are laid in pipes passing through interfloor ceilings with numerous twists, it is advisable that the pairs of twisted wires are additionally twisted into the core.

To protect against electromagnetic influences of low and medium power, it is advisable to produce cables with a core enclosed in a screen from a metal-polymer tape, superimposed overlapping with a metal layer inside, under which a contact copper or tinned copper wire is laid.

For objects with several geographically spaced buildings, for laying the cable directly into the ground, it is necessary that the cable additionally contains a layer of water-blocking material superimposed on the moisture-proof sheath, armor made of steel laminated with polyethylene tapes, longitudinally corrugated or wound in a spiral, or from round steel galvanized wires, superimposed in the form of a braid or winding in a spiral and moisture-proof hose made of light-stabilized special polyvinyl chloride plastic that reduced smoke emission and the oxygen index of not less than 30 or light-stabilized halogen-free polymer composition with an oxygen index of not less than 35, or a light-stabilized polyethylene or polyurethane light stabilized.

To suspend a cable with spiral twisting-type clamps on poles and communication supports, it is advisable that the cable additionally contains a cable in the center of the core in polymer insulation.

To suspend a cable with gripping clamps on poles and communication supports, it is advisable that the cable and cable be enclosed in an additional general sheath made of light-stabilized special PVC compound with reduced smoke emission and an oxygen index of at least 30 or a light-stabilized polymer halogen-free composition with an oxygen index of at least 35, or light stabilized polyethylene, or light stabilized polyurethane., and the cable was located parallel to the Central axis of the cable.

In the future, the proposed utility model is illustrated by specific examples of implementation and the accompanying drawings, in which:

Figure 1 - depicts a cross section of a cable flat design with conductors twisted in pairs;

Figure 2 - depicts a cross section of a shielded armored cable;

Figure 3 - depicts a cross section of a cable with a cable embedded in the core;

Figure 4 - depicts a cross-section of a cable with a cable embedded in a protective sheath.

Installation cable for fire safety systems 1 (Fig. 1), containing a core including four copper single-wire conductive conductors 2, insulated with polymer 3, twisted in pairs, and pairs laid parallel to each other in the same plane, with belt insulation 4 of polymer tape, enclosed in a moisture barrier 5 having a flat structure.

Mounting cable for fire safety systems 6 (Figure 2) is armored, containing a core, including several copper single-wire conductive cores 2, insulated with polymer 3, twisted together in pairs 7, which, in turn, are twisted into a core, belt insulation 4 of polymer tape, moisture-proof polymer shell 5, over

which superimposed a layer of water blocking material 8, armor 9 and moisture-proof hose 10.

Mounting cable for fire safety systems 11 (Figure 3), designed for cable suspension with spiral clamps of a curling type on poles and communication supports, contains a core including a cable 12 laid in the center in polymer insulation 13 and pairs 7 twisted around it, consisting of twisted together copper single-wire conductive conductors 2, insulated with polymer 3, a core insulation 4 of polymer tapes and moisture-proof sheath 5 are applied to the core.

Mounting cable for fire safety systems 14 (Figure 4), designed to suspend a cable with gripping clamps on poles and communication supports, contains a core that includes several copper single-wire conductive cores 2, insulated with polymer 3, twisted together in pairs 7, which in turn, twisted into a core, a belt insulation 4 from a polymer tape, a common moisture-proof sheath 15, superimposed simultaneously on the core in a zone insulation 4 and a cable 12, parallel to the central axis of the cable.

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

Conducting cores 2 are made, as a rule, in the form of soft (annealed) copper wire, obtained from copper wire "wire rod" mainly with a diameter of 8 mm by drawing. Depending on the diameter of the finished wire, only the coarse drawing operation or two operations can be used: coarse and medium drawing. Moreover, in modern equipment, the coarse drawing operation (final) can be combined with the annealing operation, and the medium drawing operation is combined with the annealing and isolation operation in the extrusion line.

Insulation 3 is superimposed on the extrusion line.

Twisting of insulated cores in a pair of 7, as a rule, is performed on frame twisting machines.

The twisting of pairs 7 into the core is usually carried out on lantern-type machines, in the same operation, with the help of the built-in tape wrapper, belt insulation 4 is applied.

The belt insulation 4 can be applied longitudinally, while belt insulation 4, a screen (not shown in the drawings) and a moisture barrier 5 can be applied simultaneously on the extrusion line.

The screen for the mounting cables for fire safety systems is mainly made of metal-polymer tape with a polymer to a moisture-proof sheath, and a tinned copper contact wire is laid under the screen.

The water blocking layer 8 is made by applying a spiral winding of a water blocking tape on a winding machine.

Also, a tape of water-blocking material for the manufacture of a water-blocking layer 8 may be allowed to pass longitudinally under the armor 9 for cable reservation operations.

The application of tape armor 9 can be done by winding steel tapes in a spiral fashion on an armor machine or longitudinally in a unit combined with an extrusion line for applying a moisture-proof hose 10 with preliminary corrugation of the tape.

The imposition of round wire armor 9 can be carried out by the method of braiding on a braiding machine or winding in a spiral on a reservation machine.

For the cables of the outer strip with the longitudinal laying of the armor tapes 9 with a polymer underlayer, the polymer underlayer is directed to the moisture-proof hose 10 and it is advisable to select the polymer homogeneous with the polymer of the moisture-proof hose.

The moisture proof hose 10 and the general moisture proof sheath 15 are superimposed on the extrusion line.

The cable 12 is usually bought ready-made, twisted from metal wires, glass fibers or strong synthetic threads. Polymer insulation 13 of the cable is made of any polymer material by extrusion.

To confirm the technical result, six samples of single-pair cables and ten-pair cables were made, of which three samples of each design had insulation and a sheath made of special polyvinyl chloride plastic compound with reduced smoke emission and an oxygen index for insulation not lower than 30, for the sheath not lower than 35, and three samples of each design had insulation and a shell of a halogen-free polymer composition with an oxygen index of at least 37. For comparison, three samples of one-pair and ten-pair samples were made cable with insulation and sheath made of ordinary plastic.

Cable samples were tested for non-propagation of combustion in a beam according to GOST 12176-86 sec. 3 (category A) and the optical density of smoke according to IEC 61034-1-99 and IEC 61034-2-99. The test results are summarized in table.

Table Number of pairs Insulation and sheathing material Name of the controlled parameter norm The test result for sample No. one 2 3 one Special PVC Compound The length of the charred part, m No more than 2.5 1.28 1,11 1.17 Decrease in light transmission,% No more than 60 53 43 44 Halogen Free Polymer Composition The length of the charred part, m No more than 2.5 0.96 1,03 1.19 Decrease in light transmission,% No more than 60 43 40 45 10 Special PVC Compound The length of the charred part, m No more than 2.5 1,07 1.15 1.24 Decrease in light transmission,% No more than 60 49 56 51 Halogen Free Polymer Composition The length of the charred part, m No more than 2.5 0.85 0.78 0.93 Decrease in light transmission,% No more than 60 31 42 36 one Plain PVC Compound The length of the charred part, m No more than 2.5 More than 2.5 More than 2.5 More than 2.5 Decrease in light transmission,% No more than 60 87 94 94 10 The length of the charred part, m No more than 2.5 More than 2.5 More than 2.5 More than 2.5 Decrease in light transmission,% No more than 60 96 91 90

Claims (10)

1. Installation cable for fire safety systems, containing a core comprising at least one pair of copper single-wire or multi-wire conductive conductors insulated with polymer, twisted together in pairs, and a moisture-proof polymer sheath applied over the core, characterized in that the insulation and sheath are polymer a special polyvinyl chloride plastic compound with a low smoke emission and an oxygen index of at least 30 was selected or a polymer halogen-free composition with an oxygen index of at least e 35. 2. The cable according to claim 1, characterized in that the cores in pairs are not twisted together and differ from each other only in the color of insulation. 3. The cable according to any one of claims 1 and 2, characterized in that when the number of pairs is more than one pair are laid in the same plane parallel to each other, providing the cable with a flat design. 4. The cable according to claim 3, characterized in that on top of the pairs around the entire perimeter of the sheath there is a screen made of metal-polymer tape with a metal layer overlapping inside, under which contact copper or tinned copper wire is allowed. 5. The cable according to claim 1, characterized in that when the number of pairs is more than one pair are twisted together in a core, and a belt insulation of polymer tape is applied over the core. 6. Cable according to any one of paragraphs.1 and 5, characterized in that under the moisture-proof sheath around the entire perimeter of the sheath is laid a screen made of metal-polymer tape with a metal layer overlapping inside, under which a contact copper or tinned copper wire is allowed. 7. The cable according to claim 6, characterized in that it further comprises a layer of water-blocking material superimposed on the moisture barrier, armor made of metal wires or steel tapes laminated with a polyethylene composition, and a moisture barrier made of light-stabilized special PVC compound with reduced smoke emission and an oxygen index of at least 30 or light-stabilized polymer halogen-free composition with an oxygen index of at least 35, or light-stabilized polyethylene, or light stability lysed polyurethane. 8. The cable according to claim 6, characterized in that it contains more than one pair and further comprises a cable located in the middle of the core along the central axis of the cable, around which the pairs are twisted, and the sheath material is made light stabilized. 9. The cable according to claim 6, characterized in that it is enclosed in an additional sheath of light-stabilized special polyvinyl chloride plastic compound with reduced smoke emission and an oxygen index of at least 30 or a light-stabilized polymer halogen-free composition with an oxygen index of at least 35, or light-stabilized polyethylene, or light-stabilized polyurethane and additionally contains a cable placed in the said additional sheath parallel to the central axis of the cable. 10. The cable according to claim 9, characterized in that the moisture-proof sheath and the additional sheath are a single unit.