RU136915U1 - CONTROL CABLE (OPTIONS) - Google Patents

Abstract

1. A control cable containing multi-wire conductive conductors coated with polyvinyl chloride plastic insulation twisted together by concentric windings and an outer sheath of polyvinyl chloride plastic compound, characterized in that a non-woven water-blocking tape is additionally applied on top of the twisted insulated conductive wires, and polyethylene terephthalate is applied over the latter. while the outer shell is made of frost-resistant non-combustible polyvinyl chloride plasticate. 2. The control cable according to claim 1, characterized in that the conductive conductors are twisted from copper wires or from copper wires tinned with tin or tin-lead solder. 3. The control cable according to claim 1, characterized in that on top of the multi-wire conductive veins under insulation, a winding of heat-resistant mica-containing tapes with a thickness of at least 0.12 mm is applied. The control cable according to claim 1, characterized in that under the outer sheath it further comprises armor made in the form of a braid of galvanized steel wires with a diameter of at least 0.30 mm and a surface density coefficient of at least 65%, and an inner sheath of non-combustible polyvinyl chloride plastic compound applied under the armor over the polyethylene terephthalate film. 5. A control cable comprising insulated multi-wire conductive conductors twisted in concentric coils, a screen overlaid on these cores and made in the form of a braid made of tinned copper or copper tinned wires, a belt insulation overlaid over the screen, and an outer sheath made of a polymeric material, characterized in that surface density coefficient

Description

The utility model relates to the cable industry, in particular, to the design of flexible cables for transmitting electrical signals of alternating current with voltage up to 500 V and frequency 1 MHz and electric signals of direct current with voltage up to 750 V and can be used for remote control of actuators in various rooms, outdoors, in canals, tunnels and subways.

Known control cable according to the patent for utility model RU No. 311174, IPC H01B 7/04, publ. 07/20/2003. The control cable contains multi-wire conductive conductors coated with insulation made of PVC compound and made of tinned copper wires and twisted in concentric coils at first into a pair, and then in a coiled twist into a common core. A fastening tape of polyethylene terephthalate is spirally applied over the core and the outer coils of conductive wires. On a pair of conductive conductors twisted in pairs, a screen of foil-coated lavsan and a shell of low combustibility polyvinyl chloride plastic compound are sequentially laid. Under the screen, tinned copper wire is longitudinally placed. The cable design protects the electrical circuits from mutual influence and from the influence of external signals, and also has increased resistance to aggressive environmental components. However, the cable according to patent RU No. 311174, having a screen made of foil-coated lavsan, does not have sufficient flexibility and is subject to mechanical damage during repeated bending, which reduces noise immunity from external factors. As a result, the cable does not provide stability of electrical parameters when transmitting control signals.

There are two options for the control cable according to the patent for utility model RU No. 45554, IPC H01B 7/04, publ. 05/10/2005, which have increased stability of transmission of control signals and are more convenient in operation in comparison with the previous analogue.

According to the first embodiment, the control cable according to RU No. 45554 contains multi-wire conductive cores coated with insulation from polyvinyl chloride plastic compound, made of tinned copper wires and twisted into a pair, and then into a cable, in concentric layers. Each pair has its own twisting step, while their twisting steps are mutually agreed. The insulation of the cores in the pair is different in color. In addition, the pairs differ from each other in the color of at least one insulated conductive core. A screen is applied over the pairs of cores, which is made with a surface density coefficient of at least 70% in the form of a braid of tinned copper or copper wires with a diameter of not more than 0.15 mm. A belt insulation made of fluoroplast-4 or of a polyethylene terephthalate film and a shell of low flammability polyvinyl chloride plasticate are sequentially placed on top of the screen.

The second version of the cable according to RU No. 45554 has the same essential features as the cable in the first version, but additionally also contains wire armor in the form of a braid made of galvanized steel wire with a surface density coefficient of not less than 70% and an inner sheath overlaid with belt insulation . The armor enhances the noise immunity and mechanical resistance of the control cable.

For the prototype for all variants of the claimed utility model adopted the first version of the control cable according to RU No. 45554, as the closest. In the control cable adopted for the prototype, the implementation of the screen in the form of a braid from tinned copper or copper tinned wires, the presence of belt insulation, as well as the execution of the twisting steps of pairs of different and mutually agreed upon, increase the flexibility of the cable. The flexibility of the cable protects the conductive conductors from mechanical damage and interference, and thereby ensures the stability of transmission of control signals. The difference in the insulation of the conductors in pairs and pairs from each other in color creates the convenience of cable operation in accordance with RU No. 45554. However, the prototype cable has insufficient reliability during operation in conditions of increased fire hazard. In turn, this fact, as well as the presence of only paired twists of conductive veins narrows the scope of the cable according to the prototype.

The objective of the utility model according to the proposed options is to simultaneously increase the reliability of the cable according to the prototype and increase its reliability and survivability under the conditions of the spread of dangerous fire factors, as well as expand the scope of the cable.

The technical result is to ensure the stability of the transmission of control signals and to increase the fire safety and fire resistance of the cable.

The task and the technical result are achieved as follows.

According to the first embodiment, the control cable, like the prototype, contains multiconductor conductive wires coated with insulation from polyvinyl chloride plastic compound, twisted together by concentric layers, and an outer sheath of polyvinyl chloride plastic compound.

In contrast to the prototype, the control cable according to the first embodiment further comprises a non-woven water-blocking tape superimposed on top of twisted insulated conductive conductors, and a polyethylene terephthalate film on top of the latter. The outer sheath in the control cable according to the first embodiment is made of frost-resistant non-combustible polyvinyl chloride plastic compound.

Conductors can be made of copper wires or copper wires tinned with tin or tin-lead solder. To enhance the fire resistance of the cable over multiwire conductive conductors under insulation, a winding of heat-resistant mica-containing tapes with a thickness of at least 0.12 mm can be applied. In a particular case, for greater operational reliability and protection from external electromechanical influences, armor in the form of a braid made of galvanized steel wires with a diameter of at least 0.30 mm can be made under the outer shell. The coefficient of surface density of the armor braid is at least 65%. In addition, on top of the polyethylene terephthalate film under the armor, an inner shell of non-combustible polyvinyl chloride plasticate is applied.

In a second embodiment, the inventive control cable, as well as the prototype cable, comprises insulated multi-wire conductive conductors twisted in concentric layers, a screen overlaid on conductive wires and made in the form of a braid of tinned copper or copper wires, a belt insulation overlay on the screen, and outer shell made of polymer material.

In contrast to the prototype, the coefficient of surface density of the screen is at least 65%, moreover, it is made of wires with a diameter of not more than 0.30 mm, and the insulation of the conductive wires and the outer sheath of the cable are made of a flame-retardant polymer composition.

The belt insulation can be made of fluoroplast-4 or polyethylene terephthalate film, and a polyethylene terephthalate film or heat-resistant mica tape can be applied under the screen over conductive wires. In the latter case, a polyethylene terephthalate film may also be applied under a thermally stable mica tape.

In particular cases, insulated conductive conductors made of tinned copper or copper wires are twisted first or in pairs, or in triples, or in fours with an agreed step, and then these twists of the conductive conductors are twisted together in a cable, each pair either a triple or a four has its own pitch, and the insulation of the cores in these twists differs in color. In addition, twisted pairs, triples, quadruples of conductive conductors differ from each other in the color of at least one insulated conductive core. To enhance the fire resistance of the cable over multiwire conductive cores, a winding of heat-resistant mica-containing tapes with a thickness of at least 0.12 mm can be applied first, and then insulation is applied to the winding.

As in the first embodiment, the control cable according to the second embodiment may additionally contain armor under the outer sheath, which is made in the form of a braid of galvanized steel wires with a diameter of at least 0.30 mm. The coefficient of surface density of the armor braid is at least 65%. Under the armor over the belt insulation, an inner shell of a flame retardant polymer composition is applied.

According to the third option, the control cable, like the prototype, contains insulated multi-wire conductive conductors twisted in concentric coils, a screen overlaid on these cores and made in the form of a braid of tinned copper or copper wires, a belt insulation overlaid on top of the screen, and an outer sheath of polymer material.

Unlike the prototype, the control cable according to the third embodiment has a screen with a surface density coefficient of at least 65%, and the screen is made of wires with a diameter of not more than 0.30 mm. The insulation of the conductive conductors and the outer sheath of the cable according to the third embodiment are made of a halogen-free polymer composition.

Belt insulation is made of fluoroplast-4 or polyethylene terephthalate film.

An additional polyethylene terephthalate film or heat-resistant mica tape can be applied under the screen. In the latter case, a polyethylene terephthalate film may be applied under a thermally stable mica tape.

In special cases, insulated conductive conductors made of tinned copper or copper wires are twisted first in pairs, or in triples, or in fours with an agreed step, and then these twists of the conductive conductors are twisted into a cable. Moreover, each pair, or three, or four has its own twist pitch, and the insulation of the cores in these twists differs in color. In addition, twisted pairs, triples, quadruples of conductive conductors differ from each other in the color of at least one insulated conductive core. The control cable may also under the outer sheath contain armor in the form of a braid made of galvanized steel wires with a diameter of at least 0.30 mm and a coefficient of surface density of the braid of at least 65%. Under the armor over the belt insulation, an inner shell of a halogen-free polymer composition is applied. The use of a halogen-free polymer composition reduces smoke and gas emissions during combustion and decay of polymer materials.

For all proposed variants of the utility model, the control cable, like the cable of the prototype, has the flexibility to protect conductive wires from mechanical damage and interference, and thereby increase the stability of transmission of control signals. At the same time, the presence of armor enhances mechanical protection and protection against interference, which ensures the stability of the transmission of electrical signals. In the presence of twists, the insulation of the conductive conductors differs in color, and the twists themselves differ from each other in the color of at least one insulated conductive core. This creates ease of use for the cable. In all variants of the utility model, for insulation and for the outer shell, fire-resistant and reduced combustibility materials are used, which ensures that the control cable meets fire safety requirements and, in comparison with the prototype, increases its fire resistance, fire safety and reliability. Depending on the scope and purpose of the cable, it can be made from single conductive cores, or twisted in pairs, triples, fours, which extends the operational capabilities of the cable. Thus, all three variants of the claimed utility model are united by a single creative concept, since they are aimed at achieving the same technical result, they solve the same problem in the same way.

Next, the utility model is illustrated by drawings.

In FIG. 1 shows a cross section of a cable according to a first embodiment.

In FIG. 2 - cable cross-section according to the first embodiment in the presence of armor (special case).

In FIG. 3 is a cable cross-section according to the second and third embodiment with twisted single conductive cores.

In FIG. 4 is a cable cross-section according to the second and third embodiment with a pair of twisted conductive conductors.

In FIG. 5 is a cable cross-section according to the second and third embodiment with a pair of twisted conductive conductors in the presence of armor.

In FIG. 6 is a cable cross-section according to the second and third embodiment with twisted triples of conductive wires.

In FIG. 7 is a cable cross-section according to the second and third embodiment with twisted fours of conductive conductors.

The control cable according to all options (Fig. 1, 2, 3, 4, 5, 6, 7) contains multi-conductive insulated conductors 1. Conducting conductors 1 are made of copper wires or copper wires tinned with tin or tin-pig solder not lower than PIC -61, and comply with GOST 22483 no lower than class 3 for conductive conductors with a section of 0.5; 0.75; 1.0; 1,2; 1.5; 2.5; 4.0 mm and not lower than class 4 for conductive conductors with a cross section of 0.35 mm ² . Nominal insulation thickness for conductive conductors: section from 0.35 to 0.75 mm ² - 0.5 mm, section from 1.0 to 2.5 mm ² - 0.6 mm, section 4.0 mm ² - 0, 7 mm.

Conducting cores 1 of the control cable according to the first embodiment (Fig. 1) are coated with PVC compound 2 insulation and twisted together by concentric coils. The number of conductive conductors depending on the purpose and field of application can be from 1 to 61 (in Fig. 1 shows a cross section of a cable with 7 conductive conductors). Under insulation over windings of multi-conductor conductors, a winding of thermally resistant mica-containing tapes with a thickness of at least 0.12 mm can be applied. A non-woven water-blocking tape 3 is applied on top of twisted insulated conductive wires, and a polyethylene terephthalate film 4 is placed on top of it. The outer sheath 5 of the control cable according to the first embodiment is made of frost-resistant non-combustible polyvinyl chloride plastic compound. Under the outer sheath 5 in the control cable according to the first embodiment (Fig. 2), armor 6 can be made in the form of a braid of galvanized steel wires with a diameter of at least 0.30 mm. The coefficient of surface density of the braid of the armor 6 should be at least 65%. Armor 6 enhances the mechanical protection of the cable and its protection from external electromechanical influences, increasing reliability. On top of the polyethylene terephthalate film 4 under the armor 6, an inner shell 7 is imposed, which is made of non-combustible polyvinyl chloride plastic compound.

In the control cable according to the second embodiment, the conductive conductors 1 (Figs. 3, 4, 5, 6, 7) are coated with insulation 2 from a flame-retardant polymer composition. A winding of thermally stable mica-containing tapes with a thickness of at least 0.12 mm can be applied over multi-wire conductive conductors. The number of insulated conductive single cores 1 can be from 1 to 61 (Fig. 3 shows 7). Insulated conductive conductors 1 can also be twisted first in pairs 8 (Fig. 4, 5), or in triples 9 (Fig. 6), or in fours 10 (Fig. 7) with an agreed step. Twists 8, 9, 10 of conductive conductors 1 are twisted together in a cable. Each pair 8, or three 9, or four 10 has its own pitch, and the insulation of the cores in these twists differs in color. In this case, the steps of twisting pairs of 8, or triples 9, or quadruples 10 are mutually agreed. In addition, twisted pairs of 8, triples 9 and quadruples 10 of conductive conductors 1 differ from each other in the color of at least one insulated conductive core. Depending on the technical purpose of the cable, the number of pairs of conductive conductors can be from 1 to 27 (Fig. 4, 5 shows an example for 7 pairs of conductive conductors), triples - from 1 to 19 (Fig. 6 shows an example for 7 triplicate conductive conductors ), fours - from 1 to 4 (Fig. 7 shows an example for 4 fours of conductive wires). Nominal cross section of fours, mm ² : 0.35; 0.5; 0.75; 1,0. A screen 11 is superimposed on top of the general twist of pairs 8, triples 9, fours 10. Screen 11 is made in the form of a braid of tinned copper or copper wires with a diameter of not more than 0.30 mm and a surface density coefficient of at least 65%. A belt insulation 12 is applied over the screen 11. The belt insulation 12 is made of fluoroplast-4 or a polyethylene terephthalate film. In a particular case, a polyethylene terephthalate film or a heat-resistant mica-containing tape can be applied under the screen 13. It is possible to apply a polyethylene terephthalate film and then a thermally-resistant mica-containing tape under the screen over the general twist of the conductive wires.

The cable according to the second embodiment is coated with a sheath 5 of a flame retardant polymer composition. Under the outer sheath 5, an additional armor 14 can be made (Fig. 5), made in the form of a braid of steel galvanized wires with a diameter of at least 0.30 mm with a surface density coefficient of at least 65%, and under the armor 14 over the belt insulation 12 is internal shell 15 made of a flame retardant polymer composition. The design of the cable with armor 14 is shown on the example of a cable with a pair of twisted conductive conductors 1 (Fig. 5). The location of the armor 14 and the inner shell 15 in the cable with a twist of conductive wires in the form of a triple 9 and a quadruple 10 is carried out similarly.

The control cable according to the third embodiment, like the cable according to the second embodiment, contains conductive conductors 1 (Fig. 3), paired twists 8 (Fig. 4), triples 9 conductive conductors 1 (Fig. 6), four 10 conductive conductors 1 (Fig. . 7). The insulation of the conductive conductors in the cable according to the third embodiment is made of a halogen-free polymer composition. Each pair 8, or three 9, or four 10 has its own pitch, and the insulation of the cores in these twists differs in color. In addition, twisted pairs of 8, triples 9 and quadruples 10 of conductive conductors 1 differ from each other in the color of at least one insulated conductive core. Depending on the technical purpose of the cable, the number of pairs 8 (Fig. 4, 5) can be from 1 to 27, triples 9 (Fig. 6) - from 1 to 19, fours 10 (Fig. 7) - from 1 to 4. Nominal cross section of fours 10, mm: 0.35; 0.5; 0.75; 1,0. A screen 11 is superimposed on top of the general twist of pairs 8, triples 9, fours 10. Screen 11 is made in the form of a braid of tinned copper or copper wires with a diameter of not more than 0.30 mm and a surface density coefficient of at least 65%. A belt insulation 12 is applied over the screen 11. The belt insulation 12 is made of fluoroplast-4 or a polyethylene terephthalate film. In a particular case, a polyethylene terephthalate film or a heat-resistant mica tape can be applied under the screen 13. It is possible to apply a polyethylene terephthalate film and then a heat-resistant mica tape under the screen over the general twist of the conductive wires.

The outer sheath 5 of the cable according to the third embodiment is made of a halogen-free polymer composition. As in the cable according to the second embodiment, under the outer sheath 5 can be additionally made armor 14 (Fig. 5). The armor 14 is made in the form of a braid of galvanized steel wires with a diameter of at least 0.30 mm with a surface density coefficient of at least 65%, and under the armor 14 over the belt insulation 12 an inner shell 15 is made, made of a halogen-free polymer composition.

The manufacturing technology of the inventive cable for each of the three options is simple, does not cause difficulties for specialists in the cable industry and does not require sophisticated special equipment. The cable production begins with the manufacture of conductive conductors from wires 1. Then, the conductive conductors are coated with insulating material and twisted into a common twist. Or first, they conduct the twisting of the conductive conductors 1 in pairs 8, or in triples 9, or in fours, and then perform their general twisting. All other elements of the cable are applied to the general twist (depending on the particular design) and, at the last stage, sheath 5 is applied to the cable. For the manufacture of the cable, domestic and foreign materials known to the cable industry specialists are used. The twisting of structural elements of the cable is carried out on ordinary twisting machines, the imposition of insulation on extrusion equipment. For overlaying the screen, armor use braiding machines, for overlaying films - wrapping equipment.

Cable samples were tested for compliance with the requirements of GOST R 53315-2009 “Cable products. Fire Safety Requirements. " Received positive results. The control cables for all options comply with fire safety requirements.

Claims (25)

1. A control cable containing multi-wire conductive conductors coated with polyvinyl chloride plastic insulation twisted together by concentric windings and an outer sheath of polyvinyl chloride plastic compound, characterized in that a non-woven water-blocking tape is additionally applied on top of the twisted insulated conductive wires, and polyethylene terephthalate is applied over the latter. the outer shell is made of frost-resistant non-combustible polyvinyl chloride plastic compound. 2. The control cable according to claim 1, characterized in that the conductive conductors are twisted from copper wires or from copper wires tinned with tin or tin-lead solder. 3. The control cable according to claim 1, characterized in that on top of the multi-wire conductive conductors under insulation, a winding of heat-resistant mica-containing tapes with a thickness of at least 0.12 mm is applied. 4. The control cable according to claim 1, characterized in that under the outer sheath it further comprises armor made in the form of a braid of steel galvanized wires with a diameter of at least 0.30 mm with a surface density coefficient of at least 65%, and an inner sheath of non-combustible PVC compound, placed under the armor over the polyethylene terephthalate film. 5. A control cable comprising insulated multi-wire conductive conductors twisted in concentric coils, a screen overlaid on these cores and made in the form of a braid of tinned copper or copper wires, a belt insulation overlaid over the screen, and an outer sheath of polymer material, characterized in that the coefficient of surface density of the screen is at least 65%, moreover, it is made of wires with a diameter of not more than 0.30 mm, and the insulation of the conductive wires and the outer sheath of the cable are made of fire resistant polymer composition. 6. The control cable according to claim 5, characterized in that the belt insulation is made of fluoroplast-4. 7. The control cable according to claim 5, characterized in that the belt insulation is made of polyethylene terephthalate film. 8. The control cable according to claim 5, characterized in that an additional polyethylene terephthalate film is applied under the screen. 9. The control cable according to claim 5, characterized in that an additional thermally stable mica tape is applied under the screen. 10. The control cable according to claim 9, characterized in that a polyethylene terephthalate film is applied under a thermally stable mica tape. 11. The control cable according to claim 5, characterized in that the insulated conductive conductors are made of tinned copper or copper wires and are twisted first in pairs with an agreed pitch, and then the pairs are twisted into a cable, each pair having its own twisting pitch, and the insulation cores in a pair differ in color, in addition, twisted pairs of conductive conductors differ from each other in the color of at least one insulated conductive core. 12. The control cable according to claim 5, characterized in that the insulated conductive conductors are made of tinned copper or copper wires and are twisted first into triples with an agreed pitch, and then the triples are twisted into a cable, each three having its own twisting step, and the insulation the cores in the three are different in color, in addition, the three of the conductive conductors differ from each other in the color of at least one insulated conductive core. 13. The control cable according to claim 5, characterized in that the insulated conductive wires are made of tinned copper or copper wires and are twisted first into fours with an agreed pitch, and then fours are twisted into a cable, each four having its own twisting step, and the insulation the cores in the four are different in color, in addition, the fours of the conductive conductors differ from each other in the color of at least one insulated conductive core. 14. The control cable according to claim 5, characterized in that under the outer sheath it additionally contains armor made in the form of a braid of galvanized steel wires with a diameter of at least 0.30 mm with a surface density coefficient of at least 65%, and an inner shell made of fire-resistant a polymer composition applied under the armor over the belt insulation. 15. The control cable according to claims 5.11, 12 and 13, characterized in that a winding of heat-resistant mica-containing tapes with a thickness of at least 0.12 mm is applied over the multi-wire conductive veins under insulation. 16. A control cable comprising insulated multi-wire conductive conductors twisted in concentric coils, a screen overlaid on these cores and made in the form of a braid of tinned copper or copper wires, a belt insulation overlaid on top of the screen, and an outer sheath made of a polymeric material, characterized in that the coefficient of the surface density of the screen is at least 65%, moreover, it is made of wires with a diameter of not more than 0.30 mm, and the insulation of the conductive wires and the outer sheath of the cable are made of plastic molecular composition containing no halogen. 17. The control cable according to clause 16, wherein the belt insulation is made of fluoroplast-4. 18. The control cable according to clause 16, wherein the belt insulation is made of polyethylene terephthalate film. 19. The control cable according to clause 16, characterized in that an additional polyethylene terephthalate film is applied under the screen. 20. The control cable according to clause 16, characterized in that an additional thermally stable mica tape is applied under the screen. 21. The control cable according to claim 20, characterized in that a polyethylene terephthalate film is applied under a thermally stable mica tape. 22. The control cable according to clause 16, characterized in that the insulated conductive conductors are made of tinned copper or copper wires and are twisted first in pairs with an agreed pitch, and then the pairs are twisted into a cable, each pair having its own twisting step, and the insulation cores in a pair differ in color, in addition, twisted pairs of conductive conductors differ from each other in the color of at least one insulated conductive core. 23. The control cable according to clause 16, characterized in that the insulated conductive conductors are made of tinned copper or copper wires and are twisted first into triples with an agreed pitch, and then the triples are twisted into a cable, with each triple having its own twisting step, and the insulation the cores in the three are different in color, in addition, the three of the conductive conductors differ from each other in the color of at least one insulated conductive core. 24. The control cable according to clause 16, characterized in that the insulated conductive wires are made of tinned copper or copper wires and are twisted first into fours with an agreed pitch, and then fours are twisted into a cable, each four having its own twisting step, and the insulation the cores in the four are different in color, in addition, the fours of the conductive conductors differ from each other in the color of at least one insulated conductive core. 25. The control cable according to clause 16, characterized in that under the outer sheath it further comprises armor made in the form of a braid of galvanized steel wires with a diameter of at least 0.30 mm with a surface density coefficient of at least 65%, and an inner shell made of polymer a halogen-free composition overlaid on a belt insulation.

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