RU106029U1 - MOUNTING CABLE, PREVIOUSLY EXPLOSIVE AND FIRE-SAFE, INCLUDING FOR EXTREMELY SAFE CHAINS - Google Patents

Abstract

 1. Explosion-proof mounting cable mainly for intrinsically safe circuits, containing a core of at least one stranded copper or copper tinned conductive core with polymer insulation or from at least one group of these conductors, pre-twisted together in a pair, or three, or four, non-hygroscopic polymer aggregate, applied in a concentric layer over the core and providing the cable with a round cylindrical shape, and a moisture-proof sheath, characterized in that The insulation, aggregate, and moisture barrier are extruded from non-flame retardant polymers, and the minimum insulation thickness is selected from the condition that the maximum permissible operating voltage of the alternating current is 50 Hz: for thicknesses from 0.2 to 0.25 mm inclusive, not more than 60 V, or for thicknesses from 0.25 to 0.35 mm, inclusive, not more than 90 V, or for thicknesses from 0.35 to 0.4 mm inclusive, not more than 190 V, or for thicknesses from 0.4 to 0.5 mm inclusive no more than 375 V, or for thicknesses from 0.5 to 0.6 mm inclusive no less than 550 V, or for thicknesses from 0.6 to 0.7 mm inclusive no more than 750 V, or for thicknesses from 0.7 to 0.85 mm inclusive no more than 1000 V, or for thicknesses from 0.85 to 1, 15 mm inclusive no more than 1300 V, or for thicknesses from 1.15 to 1.35 mm inclusive no more than 1575 V.! 2. The cable according to claim 1, characterized in that when the number of the named cores or groups in the core of more than one core or group are twisted together into a core. ! 3. The cable according to claim 1, characterized in that in addition to the said insulation is imposed by winding in a spiral with the overlap of at least one mica tape. ! 4. The cable according to

Description

The utility model relates to cable technology, namely: to the designs of multicore installation cables intended for fixed inter-instrument installation of electrical devices of industrial enterprises, mainly in hazardous areas, including the type "intrinsically safe electrical circuit i" according to GOST R 51330.10-99, GOST R 51330.13-99, GOST R 52350.11-2005, GOST R 52350.14-2006, GOST R IEC 60079.14-2008.

Known mounting cable, mainly explosion-proof, including for intrinsically safe circuits, according to the utility model RU No. 91464, IPC - Н01В 7/04.

It contains a core twisted from stranded conductive copper or copper tinned veins with concentric dielectric insulation, single or pre-twisted into groups - pairs or triples or quadruples, equipped with individual or group screens, respectively, having each, respectively, individual or group belt insulation made of dielectric tapes with overlapping or in the form of an extruded concentric continuous layer, aggregate or moisture barrier. In this case, the filler is laid on top of the core in order to ensure a round cable shape in cross section, and the thickness of an individual or group belt insulation is selected to be minimally sufficient to withstand the test with an alternating voltage of 50 Hz at least 500 V applied between any individual or group screens.

The disadvantage of this cable is that it has distinctive features: the presence of filler on top of the core to ensure the round shape of the cable and the presence of an extruded polymer sheath or waist insulation from polymer tapes on individual and group screens, with a thickness selected from the test condition of 500 V AC current frequency of 50 Hz - characterize, taking into account safety requirements, the possibility of laying in networks with explosion protection of the type "intrinsically safe electrical circuit" i ", but do not provide the possibility of choosing a cable with specific design dimensions to meet the requirements for the transfer of electromagnetic energy or electromagnetic signals.

Such a requirement for choosing a cable design used for explosion protection of the type “intrinsically safe electrical circuit“ i ”may be the dependence of the operating voltage in the intrinsically safe electrical circuit on the thickness of the insulation, guaranteed to prevent the possibility of an electrical spark through a solid dielectric, in this case, cable insulation (electrical breakdown) isolation). Such requirements in general (without regard to cables) for the gap between structural elements that are under electrical voltage, separated by a solid dielectric, are shown in Table 5. Clause 6.1.1. GOST R 52350.11-2005 "Electrical equipment for explosive gas environments. Part 11. Intrinsically safe electrical circuit "i".

In cable technology, there are similar requirements for insulation thicknesses depending on the operating voltage, which uses the cables described in GOST 23286-78 “Cables, wires and cords. Standards for insulation thicknesses, shells and stress testing. " However, the requirements for insulation thickness in GOST 23286-78 also depend on the cross section of the conductive core, as a result of which the thickness standards for some sections of the conductive wires are smaller than the thicknesses specified by GOST R 52350.11-2005.

As a prototype, we select the cable design according to the utility model RU No. 91464.

The essence of the proposed utility model is expressed in the creation of an assembly cable, mainly explosion-proof, including for intrinsically safe circuits, guaranteed to ensure that there is no spark through the solid insulation of conductive conductors during the entire operation period.

The technical result is achieved by the fact that it is proposed a mounting cable, mainly explosion-proof, including for intrinsically safe circuits, containing a core of at least one multi-wire copper or tinned copper core with polymer insulation or from at least one group of these wires pre-twisted together in a pair or three, or four, a non-hygroscopic polymer aggregate applied in a concentric layer over the core and providing the cable with a round cylindrical shape, and lagozaschitnuyu shell. In this case, the insulation, aggregate and moisture-proof sheath are made by extrusion from non-flame retardant polymers, and the minimum insulation thickness is selected from the condition that the maximum permissible operating electric voltage of alternating current with a frequency of 50 Hz corresponds: for thicknesses from 0.2 mm to 0.25 mm inclusive - not more than 60 V or for thicknesses from 0.25 to 0.35 mm inclusive - not more than 90 V, or for thicknesses from 0.35 to 0.4 mm inclusive - not more than 190 V, or for thicknesses from 0.4 mm to 0.5 mm inclusive - not more than 375 V, or for thicknesses from 0.5 to 0.6 mm inclusive total - not more than 550 V, or for thicknesses from 0.6 to 0.7 mm inclusive - not more than 750 V, or for thicknesses from 0.7 to 0.85 mm inclusive - not more than 1000 V, or for thicknesses from 0 , 85 to 1.15 mm inclusive - not more than 1300 V, or for thicknesses from 1.15 to 1.35 mm inclusive - not more than 1575 V.

The use of flame-retardant polymeric materials ensures the fulfillment of explosion and fire safety requirements, preventing the spread of flame from one zone to another and preventing the possibility of an explosion. The application of polymers by extrusion ensures linear uniformity of thicknesses (the absence of “jumps” in thickness), which, for the operation of insulation under electric voltage, contributes to stable long-term operation of the insulation, and for the filler and moisture-proof sheath it corresponds to the constancy of the property of non-distribution of combustion, since the spread of combustion increases with per unit length of the combustible mass, which is possible in the presence of a “jump” in thickness.

The choice of cable for the minimum insulation thickness and its operation at the appropriate voltage guarantees its trouble-free operation (absence of electrical breakdowns of insulation) in the same period of time as the rest of the electrical equipment, since the thickness of the insulating coatings will be the same and meet the requirements of Table 5, clause 6.1.1. GOST R 52350.11-2005.

To ensure compactness of the core with the number of cores or groups of more than one, it is advisable to twist them together into a core.

As a rule, the materials of insulation, aggregate and moisture-proof sheath are chosen the same, being guided, first of all, by fire safety requirements.

Under the condition of a single cable installation, a traditional PVC compound with an oxygen index in the range of 20 to 25 is selected.

Under the condition of group cable laying (bundle), a special PVC compound with an oxygen index of at least 30 is chosen (for a filler in accordance with the peculiarities of its chemical composition due to the large amount of filler, at least 28 is allowed).

With the introduction of GOST R 53315-2009 “Cable products. Fire safety requirements. Test methods ”for cables laid in a bundle within the production, residential and administrative premises began to impose requirements for reduced smoke and gas emission. For the general group of cables laid outside the production, domestic and administrative premises, the “ng” index was assigned, for the group of cables with reduced smoke and gas emission - the “ng-LS” index. According to GOST R 53315-2009, smoke production of cable products with the ng-LS index when tested according to GOST R IEC 61034-2 should not lead to a decrease in light transmission by more than 50%.

When laying cables in rooms equipped with computer and microprocessor technology, an additional requirement is made for the emission of corrosive gases and halogen acids in the process of burning and / or smoldering in terms of HCl no more than 5.0 mg / g. For such cables, a halogen-free polymer composition with an oxygen index of at least 35 is chosen.

General fire safety indicators taking into account the requirements of GOST R 53315-2009 are presented in table 1.

Table 1. Name of material Oxygen Index,%, not less than Decrease in light transmission during smoke formation,%, no more Mass fraction of HCl released during combustion,%, no more Conventional PVC compound 20-25 80 40 Special PVC Compound thirty 80 40 Special PVC with low smoke and gas emission thirty fifty fifteen Halogen free polymer composition 35 25 0.5

For insulation, filler, moisture-proof sheath of cables used for mobile installation (for example: portable lamps, power tools, welding machines) choose cable rubber.

In this case, the oxygen index is required no higher than 25.

For cable laying conditions with increased flexibility, a polyolefin or polyurethane thermoplastic elastomer with an oxygen index of at least 29 is chosen. In this case, the polyolefin thermoplastic elastomer is cheaper than polyurethane, but the polyurethane thermoplastic elastomer withstands up to 1 million bends at a temperature of minus 30 ° С.

For the conditions of laying cables with the requirement of increased flexibility and the additional requirement of increased oil and gas resistance, insulation, filler and a moisture-proof sheath made of silicone rubber are chosen. Upon presentation of an additional fire resistance requirement, a ceramicizable silicone rubber is selected.

In the case of ensuring the transmission of high-frequency signals to groups (pairs), in order to reduce the attenuation coefficient, it is advisable to insulate with cross-linked polyethylene that is approved for use in hazardous areas by the technical circular of the Association “Roselectromontage” No. 14/2006 of October 16, 2006 “On the use of cables of cross-linked polyethylene in cable structures, including in hazardous areas ”, approved by the Federal Service for Ecological, Technological and Nuclear Supervision (Rostekhnadzor). In this case, the extruded belt insulation, filler, moisture-proof sheath are made of other materials that meet other requirements. For example: increased fire safety requirements.

If the requirements for fire resistance are presented to the cables, it is advisable to additionally lay on top of the conductive wires at least one mica tape with a spiral winding with overlapping, to form the main fire-resistant barrier.

It is also advisable to lay on top of the core an additional belt insulation of at least one mica tape by spiral winding with the mica layer inside, to form a fire-resistant bandage that preserves the cable structure under conditions of prolonged exposure to an open flame with a temperature of at least 750 ° C for 45-180 min in accordance with the requirements of GOST R IEC 60331-11-2003, GOST R 53315-2009.

In both cases, the mica tape is usually a layered composition of mica paper with a silica content of (36.8-45.1)% by weight and alumina (10.8-17.7)% by weight and an insulating fiberglass, impregnated and glued together with an organosilicon binder.

To ensure the identification of isolated conductive cores in groups and the core, as well as groups among themselves, it is advisable to introduce an individual isolation coloring, which allows you to uniquely identify each core within the group and in the core, as well as groups among themselves.

Based on the requirement of noise immunity, it is advisable to establish coordinated steps for adjacent groups (unequal and non-multiple) when twisting, and also to limit the pitch of the strand twisting into groups as follows: in a group of two wires (in a pair) - not more than 0.1 m, out of three - not more than 0.15 m, of four cores - not more than 0.2 m.

In order to prevent possible melting of the insulation of conductive conductors when filler is applied to the core by extrusion, it is advisable to apply at least one polymer tape with overlap on each group.

It is advisable to apply belt insulation from dielectric tapes on top of the core, and to perform the function of bonding the core and the thermal barrier, which protects the insulation of conductive veins from melting when the filler is applied, the belt insulation must be made of polyethylene terephthalate or polyvinyl chloride, or polyethylene or polyamide tape superimposed with overlap in the form of a winding in a spiral or longitudinally.

In order to protect against electromagnetic effects, it is advisable to run a cable with at least one screen. At the same time, to protect against internal electromagnetic influences and to organize grounding circuits according to screens, it is advisable to make screens individual, superimposed on a separate conductive core or group, superimposed on a separate group. To protect against external electromagnetic influences, it is advisable to perform a common screen superimposed on the core.

To protect against electromagnetic effects in the low frequency range, it is advisable to make a screen in the form of a braid or winding from tinned copper or copper wires.

To protect against electromagnetic effects in the high frequency range, it is advisable to fabricate the screen from at least one metal-polymer tape imposed by the metal inside with a spiral winding overlapping or longitudinally with the screen wire laid under the screen.

To protect against electromagnetic effects in a wide range of frequencies, it is advisable to make a screen in the form of a braid or winding from tinned copper or copper tinned wires, additionally laying under the braid or winding with metal upwards overlapping the metal-polymer tape longitudinally or by winding in a spiral.

Advantageously for intrinsically safe cables, it is advisable to extrude a polymer sheath or belt insulation onto each individual or group screen in the form of a spiral winding with overlapping polymer tape, and the thickness of the polymer sheath and zone insulation according to individual and group screens should be selected so that it withstands the voltage test not less than 500 V AC with a frequency of 50 Hz applied between any individual or group or common screens, which corresponds to the requirements of Clause 12.2.2.1 of GOST R 51330.13-99 and Clause 12.2.2.1 of GOST R IEC 60079-14-2008.

The material for the extruded polymer shell, according to individual and group screens, as a rule, is chosen from the same considerations as the material for insulation, aggregate and moisture barrier.

In cables intended for explosion protection of the type “flameproof enclosure d”, it is advisable to partially seal the above groups and the core by introducing filler into the air cavities in order to significantly reduce the spread of explosive gases and liquids along the cable core.

In the absence of significant crushing forces on the cable during operation (for example: for cables suspended along the walls of buildings and fences) in order to reduce the weight of the cable and save materials, it is advisable to make foam filler.

For the purpose of identification during operation, it is advisable to paint the cable sheath for intrinsically safe circuits in blue or overlay a blue strip.

For operation under conditions of impact on the cable crushing forces in order to ensure radial strength, it is advisable to lay armor made of round steel or stainless steel or phosphor bronze wires under a moisture-proof sheath. The choice of a specific wire material: steel, stainless steel, phosphor bronze - is determined by the requirement for magnetic permeability of the material, which decreases in the indicated order. And the magnitude of the magnetic permeability characterizes the degree of loss of the electromagnetic field in the armor and, accordingly, the heating of the cable, worsening its operational properties. Depending on the diameter of the cable, the wires can be applied in the form of a braid or in the form of a winding. As a rule, braiding machines braid the core with a filler with a diameter of not more than 30 mm.

For operation under conditions of tensile forces acting on the cable in order to ensure longitudinal strength, it is advisable to lay armor made of steel tapes under the moisture-proof sheath.

Steel tapes are superimposed on a spiral winding with overlapping, and steel tapes with a polymer sublayer are superimposed longitudinally overlapping, pre-corrugated.

If armored cables are designed for air suspension at the transitions between buildings, along buildings and fences, then the moisture-proof sheath of any material is made light-stabilized.

In the case of operating armored cables in ducts or sewers under conditions of constant or prolonged exposure to water under the armor, it is advisable to lay a water blocking tape that will prevent the longitudinal distribution of water.

In order to improve the technological process for protecting the core from damage during the process of applying the armor, it is advisable to lay an additional intermediate shell under the armor made by extrusion of a material that is homogeneous with the material of the moisture barrier.

In the range of negative temperatures there is a critical temperature at which the properties of ordinary materials change dramatically. This usually occurs at a temperature of minus 60 ° C. In order for the dielectric material not to crack at low temperatures, special additives are introduced into it. For cables operating at temperatures of minus 60 ° С and below, it is advisable to insulate, sheath according to an individual or group screen, and a moisture-proof sheath to be made of cold-resistant polymer materials with a brittle temperature not exceeding minus 60 ° С that does not propagate combustion.

In the range of positive temperatures there is also a critical temperature at which the properties of ordinary materials change dramatically. For a number of widely used polymeric materials, this temperature is plus 80 ° C. At the same time, there are emergency conditions in which the cable must remain operational for some time at elevated temperatures (for example: plus 100 ° C). In order for the cables to meet this requirement, special additives are introduced into the polymers. At the same time, polyolefin and polyurethane thermoplastic elastomers withstand temperatures plus 125-150 ° C in the usual version, and silicone rubber plus (180-200) ° C in the usual version.

For cables operating in conditions in which emergencies with an ambient temperature of at least 100 ° C are possible, it is advisable to insulate, sheath according to an individual or group screen, and make a moisture-proof sheath from heat-resistant polymeric materials with a melting temperature not lower than 105 ° С that do not extend combustion.

In addition to electrical breakdown between electrodes with different signs of potential through solid insulation, an external breakdown to earth is possible due to the electromagnetic field energy accumulated by the cable due to reactive parameters such as electric capacitance and inductance. To prevent the discharge of accumulated energy in the cable, it is advisable to select the cross section of the conductive core and the insulation thickness such that an electric capacitance of less than 200 nF is provided for a length of 1 km, an inductance of less than 1 mH for a length of 1 km, the ratio of inductance to electrical resistance of the conductive core to direct current is less than 30 μH / Ohm.

The proposed utility model is illustrated by a specific example of implementation, represented by a drawing of a cross section of a cable with conductors twisted into groups (pairs).

The cable shown consists of stranded conductive copper or tinned copper conductors 1, insulated with PVC compound 2 with an oxygen index of 20 to 25, the minimum insulation thickness is selected from the condition that the maximum permissible operating electrical voltage of alternating current with a frequency of 50 Hz matches: for thicknesses from 0.2 mm up to 0.25 mm inclusive - not more than 60 V or for thicknesses from 0.25 to 0.35 mm inclusive - not more than 90 V, or for thicknesses from 0.35 to 0.4 mm inclusive - not more than 190 V, or for thicknesses from 0.4 mm to 0.5 mm inclusive - n more than 375 V, or for thicknesses from 0.5 to 0.6 mm inclusive - not more than 550 V, or for thicknesses from 0.6 to 0.7 mm inclusive - not more than 750 V, or for thicknesses from 0.7 to 0.85 mm inclusive - not more than 1000 V, or for thicknesses from 0.85 to 1.15 mm inclusive - not more than 1300 V, or for thicknesses from 1.15 to 1.35 mm inclusive - not more than 1575 V, twisted each other in three pairs, and the pairs, in turn, are twisted into a core superimposed on top of the core of filler 3, and on top of it armor in the form of a braid of round steel wires 4 and a moisture barrier 5.

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

Copper wires for conductive conductors 1 are made of copper wire "wire rod", usually with a diameter of 8 mm by drawing method. Depending on the diameter of the finished wire, the following operations can be used: coarse and medium drawing or coarse, medium and fine drawing.

To ensure softness, the wire is annealed in special annealing furnaces or in a passage for drawing operations. Annealing is not required to obtain tinned wires. Tinning is done hot, making the wire soft.

Conductors 1 are twisted from the required number of wires on twisting machines of cigar, frame or lantern type.

Insulation 2 of polyvinyl chloride plastic compound or special polyvinyl chloride plastic compound, or a halogen-free polymer composition, or thermoplastic elastomer is applied by extrusion on extrusion lines and continuous vulcanization lines - using rubber or silicone rubber, the minimum insulation thickness is selected from the condition that the maximum permissible operating voltage current frequency of 50 Hz: for thicknesses from 0.2 mm to 0.25 mm inclusive - not more than 60 V or for thicknesses from 0.25 to 0.35 mm inclusive - not more than 90 V, or for thicknesses from 0.35 to 0.4 mm inclusive - not more than 190 V, or for thicknesses from 0.4 mm to 0.5 mm inclusive - not more than 375 V, or for thicknesses from 0.5 to 0.6 mm inclusive - not more than 550 V, or for thicknesses from 0.6 to 0.7 mm inclusive - not more than 750 V, or for thicknesses from 0.7 to 0.85 mm inclusive - not more than 1000 V, or for thicknesses from 0.85 to 1.15 mm inclusive - not more than 1300 V, or for thicknesses from 1.15 to 1.35 mm inclusive - not more than 1575 V.

Twisting of isolated conductors into groups - a pair, a three or a four is usually performed on frame-type machines.

An electric shield in the form of a braid or winding is superimposed on braiding or winding machines. Pre-possible cane (combining) of wires in bundles on reed machines.

An electric screen made of metal-plastic tape is applied by spiral winding with overlapping on winding machines or longitudinally with overlapping operations for applying a moisture-proof sheath. The screen is superimposed with metal inward, and a longitudinally tinned copper tinned drainage core is allowed under it. It is possible to longitudinally overlay a screen from a metal-plastic tape with metal inward with a tinned copper drainage conductor while simultaneously applying an extruded belt insulation layer of polyvinyl chloride plastic compound or special polyvinyl chloride plastic compound, or a halogen-free polymer composition, or a thermoplastic elastomer on an extrusion line or rubber rubber silicone rubber .

In the manufacture of a combined electric screen, a metal-plastic tape is allowed to run longitudinally with a metal layer overlapping upwards under a braid or winding on a braid or wrapping machine, respectively.

The belt insulation of dielectric tapes is made by spiral winding with overlapping on winding machines or longitudinally overlapping using an additional thread wrapper or tape wrapper for fastening with a bundle of threads or a narrow plastic tape in a spiral.

Shells on top of an individual or group screen are applied from polyvinyl chloride plastic compound or special polyvinyl chloride plastic compound, or a halogen-free polymer composition, or a thermoplastic elastomer on extrusion lines or from rubber or silicone rubber on continuous vulcanization lines.

Aggregate 3 made of polyvinyl chloride plastic compound or special polyvinyl chloride plastic compound, or a halogen-free polymer composition, or thermoplastic elastomer is extruded onto extrusion lines and continuous vulcanization lines using rubber or silicone rubber.

Foaming of the aggregate material is carried out chemically or physically. In the first case, granular, blowing agent is added to the granules of the main material in the hopper of the extrusion line, in the second case, inactive gas (for example: nitrogen) is introduced into the forming aggregate using a physical foaming unit.

The intermediate shell and the moisture barrier 5 are extruded on the extrusion lines using a polyvinyl chloride plastic compound or a special polyvinyl chloride plastic compound, or a halogen-free polymer composition, or a thermoplastic elastomer, and on continuous vulcanization lines using rubber or silicone rubber.

The water blocking layer is superimposed by a water blocking tape in a spiral winding on a winding machine.

Armor 4 made of round galvanized steel, stainless steel or phosphor bronze wires is applied in the form of a braid or winding on braiding or armoring machines, from steel tapes - according to the spiral winding method with overlapping on tape wrapping armoring machines. When using laminated steel tapes, the armor is imposed longitudinally using a special corrugating and coagulation unit together with the application of a moisture-proof sheath.

Nine groups of cable samples were made, in each group three samples. Each sample has the following design: two conductive conductors twisted from seven soft copper wires each, insulated with PVC compound with an oxygen index of 20 to 25 different colors, twisted together in steps of 0.1 m or less, filler made of material based on polyvinyl chloride plastic compound with an oxygen index of 20 to 25, providing a round cylindrical cable, and a moisture-proof sheath of polyvinyl chloride plastic compound with an oxygen index of 20 to 25. For each group of thickness and the insulation is selected in the middle or closer to the lower boundary of one of the ranges listed in the independent clause (0.2 mm for the thickness range from 0.2 mm to 0.25 mm, inclusive, 0.3 mm for the thickness range from 0, 25 mm to 0.35 mm, inclusive, 0.35 mm for the thickness range from 0.35 mm to 0.4 mm, inclusive, 0.45 mm for the thickness range from 0.4 mm to 0.5 mm, inclusively, 0.55 mm for the thickness range from 0.5 mm to 0.6 mm, inclusive, 0.65 mm for the thickness range from 0.6 mm to 0.7 mm, inclusive, 0.75 mm for thickness range from 0.7 mm to 0.85 mm, inclusive, 0.9 mm - for the thickness range in from 0.85 mm to 1.15 mm, inclusive, of 1.2 mm - for the thickness range of 1.15 mm to 1.35 mm inclusive)

A voltage test was conducted according to GOST 2990-78. Typically, the norm of the test voltage is assumed to be 3-4 times higher than the operating voltage. In this case, a test voltage of 4 times the maximum permissible operating voltage for a specific thickness range was used.

The test results presented in table 2.

Table 2. Sample Number Test results of cable samples (voltage / minimum thickness. V / mm) 240 / 0.2 360 / 0.3 760 / 0.35 1500 / 0.45 2200 / 0.55 3000 / 0.65 4000 / 0.75 5200 / 0.9 6300 / 1,2 one issue issue issue issue issue issue issue issue issue 2 issue issue issue issue issue issue issue issue issue 3 issue issue issue issue issue issue issue issue issue Note: “outlet” means that the cable passed the test.

As can be seen from table 2, all the cables passed the test, which is a confirmation of the technical result.

Claims (26)

1. Explosion-proof mounting cable mainly for intrinsically safe circuits, containing a core of at least one stranded copper or copper tinned conductive core with polymer insulation or from at least one group of these conductors, pre-twisted together in a pair, or three, or four, non-hygroscopic polymer aggregate, applied in a concentric layer over the core and providing the cable with a round cylindrical shape, and a moisture-proof sheath, characterized in that The insulation, aggregate, and moisture barrier are extruded from non-flame retardant polymers, and the minimum insulation thickness is selected from the condition that the maximum permissible operating voltage of the alternating current is 50 Hz: for thicknesses from 0.2 to 0.25 mm inclusive, not more than 60 V, or for thicknesses from 0.25 to 0.35 mm, inclusive, not more than 90 V, or for thicknesses from 0.35 to 0.4 mm inclusive, not more than 190 V, or for thicknesses from 0.4 to 0.5 mm inclusive no more than 375 V, or for thicknesses from 0.5 to 0.6 mm inclusive no less than 550 V, or for thicknesses from 0.6 to 0.7 mm inclusive no more than 750 V, or for thicknesses from 0.7 to 0.85 mm inclusive no more than 1000 V, or for thicknesses from 0.85 to 1, 15 mm inclusive no more than 1300 V, or for thicknesses from 1.15 to 1.35 mm inclusive no more than 1575 V. 2. The cable according to claim 1, characterized in that when the number of the named cores or groups in the core of more than one core or group are twisted together into a core. 3. The cable according to claim 1, characterized in that in addition to the said insulation is imposed by winding in a spiral with the overlap of at least one mica tape. 4. The cable according to claim 1, characterized in that the said insulation is made of polyvinyl chloride plastic compound with an oxygen index of from 20 to 25 or special polyvinyl chloride plastic compound with an oxygen index of at least 30, including with reduced smoke and gas emission, or crosslinked polyethylene, or a halogen-free polymer composition with an oxygen index of at least 35, or a thermoplastic polyolefin elastomer with an oxygen index of at least 29, or a thermoplastic polyurethane elastomer with an oxygen index of at least 29, or insulation hydrochloric cable rubber, or silicone rubber including keramiziruyuscheysya under fire conditions. 5. The cable according to claim 1, characterized in that the said insulation of the conductive conductors has an individual color, and the coloring is made by the number of uniform colors sufficient to ensure that the named groups in the core differ from each other by the combination of colors of the named insulation of the conductive conductors and to distinguish these conductors among themselves according to the color of the named insulation inside each group and in the core twisted from separate isolated conductive cores. 6. The cable according to any one of claims 1 or 2, characterized in that the adjacent groups have coordinated twisting steps, the twisting step into a group of two named conductive wires does not exceed 0.1 m, of the three named conductive wires does not exceed 0.15 m, of the four named conductive conductors does not exceed 0.2 m. 7. The cable according to claim 1, characterized in that each named group is additionally superimposed with a winding of at least one polymer tape With overlapping. 8. The cable according to claim 1, characterized in that on top of the core an additional belt insulation is applied from at least one dielectric tape with a spiral winding overlapping or longitudinally. 9. The cable according to claim 8, characterized in that the core insulation on the core is made of polyethylene terephthalate, or polyvinyl chloride, or polyethylene, or polyamide tape. 10. The cable according to claim 8, characterized in that the belt insulation along the core is made of mica tape with a mica layer inside. 11. The cable according to claim 1, characterized in that it further comprises at least one electric screen. 12. The cable according to claim 11, characterized in that the screen is made individual, superimposed on the named core, or group, superimposed on the named group, or common, superimposed on top of the core, and over each individual or group screen is extruded a polymer sheath or waist isolation in the form of a winding in a spiral with overlapping polymer tape, and the thickness of the aforementioned polymer shell and belt insulation is selected so that they withstand a test of 500 V AC at a frequency of 50 Hz, app nnym between any individual or group, or common screens. 13. The cable according to claim 11, characterized in that the said screen is made of not less than one metal-polymer tape, superimposed by the metal inside with overlapping by a spiral winding or longitudinally with a shield wire laid under them 14. The cable according to claim 11, characterized in that the screen is made in the form of a braid or winding of tinned copper or copper wires. 15. The cable according to 14, characterized in that under the braid or winding is additionally superimposed at least one metal-polymer tape with the metal upward, overlapping the winding in a spiral or longitudinally. 16. The cable according to claim 1, characterized in that the said filler is additionally inserted into all voids in the core, including within the groups. 17. A cable according to any one of claims 1 or 16, characterized in that said aggregate is made on the basis of polyvinyl chloride plastic compound with an oxygen index of 20 to 25 or a special polyvinyl chloride plastic compound with an oxygen index of at least 28, including with reduced smoke and gas emission, or halogen-free a polymer composition with an oxygen index of at least 30, or a thermoplastic polyolefin elastomer with an oxygen index of at least 28, or a thermoplastic polyurethane elastomer with an oxygen index of at least 28, or an insulator ionic rubber, or silicone rubber, including ceramicizing under the influence of a flame. 18. Cable according to any one of claims 1 or 16, characterized in that the filler is made of foam material. 19. A cable according to any one of claims 1 or 12, characterized in that the said sheath and moisture barrier are made of polyvinyl chloride plastic compound with an oxygen index of 20 to 25 or a special polyvinyl chloride plastic compound with an oxygen index of at least 30, including with reduced smoke and gas emission, or a halogen-free polymer composition with an oxygen index of at least 35, or a thermoplastic polyolefin elastomer with an oxygen index of at least 29, or a thermoplastic polyurethane elastomer with an oxygen index of at least it 29, or hose rubber, or silicone rubber, including ceramiziruyemy under conditions of flame exposure. 20. The cable according to claim 1, characterized in that under the said moisture-proof sheath the armor is additionally laid in the form of a braid or winding from round galvanized steel or stainless steel, or from phosphor bronze wires or steel tapes by spiral winding with overlapping, or longitudinally with overlapping of metal-polymer corrugated tape. 21. The cable according to claim 20, characterized in that the intermediate shell of a polymer material homogeneous with the material of the said moisture-proof sheath or winding with at least one polymer tape is additionally laid under the armor by extrusion. 22. The cable according to claim 20, characterized in that a layer of water-blocking swelling material is additionally applied under the armor. 23. A cable according to any one of claims 1 or 19, characterized in that the said insulation, sheath, and moisture-proof sheath are made of cold-resistant polymer materials with a brittle temperature of not higher than minus 60 ° C that do not spread combustion. 24. The cable according to any one of claims 1 or 19, characterized in that the said insulation, sheath, and moisture-proof sheath are made of heat-resistant polymer materials with a melting point of at least 105 ° C, which do not propagate combustion. 25. The cable according to claim 1, characterized in that the cross section of the named conductive core and the thickness of the named insulation are additionally selected so as to provide an electric capacitance of less than 200 nF for a length of 1 km, an inductance of less than 1 mH for a length of 1 km and the ratio of inductance to electrical resistance a conductive core with a direct current of less than 30 μH / Ohm. 26. The cable according to claim 1, characterized in that the moisture barrier is made of blue or with a blue stripe.