RU211233U1 - Cable for signaling and blocking - Google Patents

Abstract

The utility model relates to electrical engineering, namely to the construction of electrical multi-core cables with marked cores. EFFECT: reducing the time spent on identifying cores on any section of the cable and eliminating the color marking of elementary bundles with colored threads or tapes and improving the manufacturability of cable installation. Cable 1 contains a core 2, enclosed in a moisture-proof sheath 3, and includes multi-wire current-carrying copper or tinned copper conductors 4 or groups 5 of conductors 4 with insulation 6. Over the insulation 6, an identification mark is made in the form of an individual number 7 for each conductor 4. Individual number 7 applied along the entire length of the core 4 with a given numbering repetition interval L and is made with the possibility of identifying each core 4 after removing the sheath 7 from the ends 8 of the cable 1 or on any other local area. 2 w.p. f-ly, 3 ill.

Description

The utility model relates to the field of electrical engineering, namely to cable products, in particular to the designs of electrical multi-core cables with marked cores.

A well-known design of an electric multicore cable, in which insulated tinned wires are twisted into pairs to form a core [RU No. 28408 U1, 20.03.2003]. Each conductive core is made of multi-wire, and the insulation of each core is made of plastic and differs from each other in color.

In the design of the installation flexible cable according to the patent [RU No. 48668 U1, 27.10.2005], tinned copper conductors are made with plastic insulation, and each conductive conductor is multi-wire, while the insulated conductive conductors are twisted into pairs. The insulated conductors in pairs differ from each other in color and have a distinctive marking, and the pairs, in turn, are twisted into a core. A water-blocking bandage and a screen located under the shell are successively applied over the core. As the insulation material, a flame retardant polyvinyl chloride compound with low smoke and gas emission, or a halogen-free polymer composition, or a cross-linked polyolefin was used.

The patent [RU No. 106981 U1, 27.07.2011] describes a mounting flexible cable containing a core twisted from elementary bundles of stranded copper conductors, which are covered with plastic insulation. The core and conductors can be shielded and have a water-blocking and heat-resistant coating, the conductors are twisted into elementary bundles either in pairs, or in triples, or in quadruples. The pitch of the twisting of the conductors to increase flexibility does not exceed 90 mm, and the conductors may have a strip or digital marking.

The main disadvantage of these analogs is the marking of current-carrying conductors by means of a different color version of the insulation for each conductor, or their stripe color marking. Such a marking makes it difficult to identify the cores during cable installation and requires additional mandatory “ringing” of each core in order to accurately find its ends. The disadvantage of the used digital marking of cores is that such marking is not made along the entire length of the cable, is not stable, and when removing the sheath, it is not always possible to quickly identify the cores, which makes cable installation difficult.

The closest to the proposed utility model in terms of design is an electric cable with digital marking known from the patent [RU No. 139056 U1, 10.04.2014], which is selected as a prototype. The cable contains a core consisting of at least one insulated single-wire or multi-wire current-carrying copper or tinned copper core, or at least one group of the named cores, twisted into a pair or triple or quadruple. The core is enclosed in a moisture-proof shell, and the insulation of the conductive cores is made of two-layer combined. The first layer, adjacent to the conductive core, is made of extruded silicone rubber, which is ceramized under flame conditions. The second layer is made with at least one mica tape superimposed by winding in a spiral with overlapping mica coating inside, with a tape tension during winding of at least 7N. In order to identify the cores and protect the cable from stripping during rewinding during technological operations, over the winding with a mica tape, each insulated core is additionally superimposed with a spiral winding with overlapping protective polymer tape, over which an individual number is applied with contrasting ink or paint, and a bandage is applied over the core. less than one mica tape wrapped in a spiral with overlapping mica coating inside. Also, to identify the insulated core, the insulation in the mass is additionally individually colored during the extrusion process, providing an individual coloring sufficient to ensure the difference between the named groups in the core, the cores among themselves in the group and in the core twisted from single cores.

The disadvantage of marking the cable cores of the prototype cable is the use of a separate polymer tape with digital marking, since when cutting the cable during its installation, the tapes with numbers are arbitrarily untwisted, which in practice makes it difficult to find the ends of the same core and, thereby, its identification. The disadvantage is the use of colors in the cable core, where cores with the same color are repeatedly repeated, the number of repetitions of which depends on the total number of cores or pairs in the cable core, which makes it difficult to identify the cores during cable installation. The disadvantage is also the technological complexity of the stable application of contrasting ink or paint on a polymer tape due to poor adhesion of the coloring component to the polymer surface, which reduces the quality of the marking and makes it difficult to use in practice. The disadvantage is also the large intervals between the digital designations, which makes it difficult to identify the cores when cutting the cable in the sections between its ends.

The purpose of the utility model is to eliminate the noted shortcomings and improve the manufacturability and subsequent installation of the cable when it is used.

The technical result of the utility model is to reduce the time spent on identifying each core on any section of the cable. The technical result is also the exclusion of the use of additional color marking of elementary beams with colored threads or tapes and an increase in the manufacturability of its installation.

The technical result is achieved by the fact that in a cable for signaling and blocking, containing a core enclosed in a moisture-proof sheath and including multi-wire conductive copper or tinned copper conductors or a group of conductors with insulation, on top of which an identification mark is made in the form of an applied individual number for each conductor, according to utility model, the insulation of the cores is made of polyethylene, which includes an additive for increased resistance to abrasion of an individual number, while the surface of the insulation in the area for applying an individual number is made smooth with a surface finish of ∇ 9÷11 class, and the relative elongation at break of copper wire in polyethylene insulation is 20-25%.

The smoothness of the insulation in the zone is characterized by the absence of bubbles and cracks, for which the zone is additionally processed in a plasma jet, and as an additive, the polyethylene insulation includes the Dynamar processing additive.

The individual number is applied on the entire length of the core with an interval L of no more than 50 mm with the possibility of identifying each core at a given relative elongation at break of copper wire in polyethylene insulation.

The essence of the utility model is illustrated by the drawings in Fig. 1-3.

In FIG. 1 is a schematic cross-sectional view of a cable.

In FIG. 2 is a schematic diagram of digital marking of conductive copper or tinned copper conductors in the cable core.

In FIG. 3 - view of the end of the cable after removing the sheath during cutting.

Cable 1 contains a waterproof sheath 3 with a core 2, including stranded conductive copper or tinned copper wires 4 or a group 5 of wires 4 with insulation 6; identification marks in the form of an individual number 7 for each core 4 applied to the insulation 6 along the entire length of the core 4 with a given numbering repetition interval L to identify each core 4 after removing the sheath 7 from the ends 8 or on any other local section of the cable 1; the interval L of repetition of numbering with an individual number 7 over the entire length of the core 4 is not more than 50 mm; insulation 6 is made of polyethylene and in zone 9 for applying individual number 7 has a surface cleanliness of ∇ 9÷11 class.

Implementation of the utility model.

Cable 1 is made in accordance with the specifications developed according to the requirements in accordance with GOST 34679-2020 “Cables for signaling and blocking. General technical conditions". At the same time, insulation 6 made of polyethylene is applied to the stranded conductive copper or tinned copper conductors 4, which contains various special additives, for example, the Dynamar processing additive, which, on the one hand, exclude the deterioration of its electrical and mechanical parameters and, at the same time, ensure its increased durability. to abrasion. Insulation 6 in zones 9 for applying an identification mark with an individual number 7 in the process of applying to the conductors 4 is performed with a surface cleanliness of ∇ 9÷11 class to give the necessary smoothness, which further ensures the durability of the marking. In this case, immediately before marking, it is possible to additionally treat the surface of the insulation 6 in zone 9 for applying an identification mark with high temperature in the plasma jet. Marking is carried out using a specially designed device (not shown in the drawing), which ensures the exact location of the core 4 with insulation 6 at a speed of up to 1500 m/min, while at the point where section 9 is currently located, the device excludes vibration of the core 4 , which guarantees the receipt of a high-quality, well-read marking text with the maximum possible dimensions of the individual number 7, while the insulation 6 is obtained without bubbles and cracks (see Fig. 2). The relative elongation at break of copper wire in polyethylene insulation 6 is set in the range of 20-25%.

Further, from stranded conductive copper or tinned copper conductors 4 or group 5 of the said conductors with insulation 6, a core 2 is twisted, the interior of which can be filled with a hydrophobic filler or water-blocking material (not shown in the drawing). Then, other necessary insulation elements are placed on the core 2 (aluminum-polyethylene screen, belt insulation, etc. - not shown in the drawing) and, using a well-known technology, enclose it in a moisture-proof shell 3 made of a polymer material, which is made of low-density polyethylene or polyvinyl chloride plastic compound, or PVC compound with reduced fire hazard, or from a polymer composition that does not contain halogens (see Fig. 1).

The interval L of repetition of the numbering of the individual number 7 over the entire length of the cores 4 is not more than 50 mm and is selected based on the practice of using cables during their installation during commissioning. This choice of the numbering repetition interval L makes it possible to reliably identify each core 4 in the cable 1 when cutting its ends (see Fig. 3) or finding the core 4 in any section along the entire length of the cable 1 during installation.

The developed design of the cable 1, according to the utility model, can significantly reduce the time spent on identifying each core 4 in any section of the length of the cable 1, and also eliminates the need for additional color marking of cores 4 and elementary bundles from groups 5 of these cores with colored threads or tapes, which improves the manufacturability of its installation.

Claims (3)

1. Cable (1) for signaling and interlocking, containing a core (2) enclosed in a moisture-proof sheath (3) and including stranded conductive copper or tinned copper conductors (4) or a group (5) of conductors (4) with insulation (6) , on top of which an identification mark is made in the form of an applied individual number (7) for each core (4), characterized in that the insulation (6) of the cores (4) is made of polyethylene, which includes an additive for increased abrasion resistance of the individual number (7) , while the surface of the insulation (6) in the zone (9) for applying an individual number (7) is made smooth with a surface finish of ∇ 9÷11 class, and the relative elongation at break of copper wire in polyethylene insulation (6) is 20-25%. 2. The cable according to claim 1, characterized in that the smoothness of the insulation (6) in the zone (9) is characterized by the absence of bubbles and cracks, for which the zone (9) is additionally processed in a plasma jet, and as an additive, the insulation (6) is made of polyethylene includes processing additive Dynamar. 3. The cable according to claim 1, characterized in that the individual number (7) is applied over the entire length of the core (4) with an interval L of not more than 50 mm with the possibility of identifying each core (4) at a given relative elongation at break of copper wire in polyethylene insulation (6).

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