RU205425U1 - FIRE RESISTANT ELECTRIC CABLE - Google Patents

Abstract

The utility model relates to a fire-resistant multicore electric cable. The cable contains a core and an inner and outer sheaths, which are respectively located on top of the core and are made of halogen-free polymer compositions. The core is made in the form of twisted current-carrying conductors of an aluminum alloy, on each of which two glass-mica-containing tapes are wound along a helical line, one on top of the other in opposite directions, with insulation located on top. Said glass-mica tapes have a thickness of 0.14-0.25 mm and are wound with an overlap of 45-60%. The angle of winding of the first tape on the conductive core relative to the axis of the conductive core is 45-60 °. The angle of winding of the second tape on the first tape relative to the axis of the conductive core exceeds the value of the said angle of the first tape by 15-20 °. As a result, the fire resistance of the cable is provided for at least 210 minutes at a flame temperature of 750 ° C, the density and rigidity of winding glass-mica-containing tapes is increased and the possibility of their displacement relative to the conductive core is prevented, which eliminates the occurrence of air gaps in the winding during mechanical stress on the cable. 2 ill., 3 ave.

Description

The utility model relates to the field of electrical engineering, namely to fire-resistant electric multicore cables intended for operation in power circuits, control and monitoring circuits, as well as in power supply lines in railway transport.

A fire-resistant electrical cable (RU 157628 U1, 10.12.2015) / 1 / is known from the prior art, selected as the closest analogue of the claimed utility model, which contains a conductive core made of an aluminum alloy, two glass-mica tapes wound along a helical line on a conductive vein one on top of the other in opposite winding directions, insulation located on top of said glass-mica-containing tapes, and inner and outer shells, which are respectively located on top of the insulation and made of halogen-free polymer compositions.

The disadvantage of this cable is that when using it, guaranteed fire resistance is not ensured in case of fire with simultaneous mechanical effects on the cable, because under mechanical stress, the glass-mica-containing tapes are displaced relative to the conductive core, resulting in air gaps in the winding, which leads to a premature approach of the flame to the conductive core.

However, current standards for fire resistance include requirements for the fire resistance of a cable at a specific temperature in combination with mechanical stress on the cable. In particular, it can be noted IEC 60331-31 - testing of cables for rated voltage up to 0.6 / 1.0 kV inclusive by the impact of fire with shock; BS 6387, BS 8434, EN 50200 - standards that determine the performance of electrical cables when exposed to flames, including combinations of fire with water spray and flame with mechanical shock, etc.

The technical objective of the claimed utility model is to create a fire-resistant electric cable with a fire resistance of at least 210 minutes at a flame temperature of 750 ° C, which is achieved in a fire with simultaneous mechanical effects on the cable, for example, when it bends, twisting, stretching, shock, vibration.

The technical result of the claimed utility model is to ensure the fire resistance of the cable for at least 210 minutes at a flame temperature of 750 ° C, increase the density and rigidity of winding glass-mica tapes and prevent the possibility of their displacement relative to the conductive cores on which they are wound, in order to exclude the occurrence of air gaps in the winding with mechanical stress on the cable.

The specified technical result is provided by the fact that the fire-resistant electric cable contains a core and an inner and outer sheaths, which are respectively located on top of the core and are made of polymer compositions that do not contain halogens, while the core is made in the form of twisted conductive conductors of an aluminum alloy, on each of which along a helical line, one on top of the other in opposite directions, two glass-mica tapes are wound, on top of which insulation is located, and the said glass-mica tapes have a thickness of 0.14-0.25 mm and are wound on each conductive core with an overlap of 45-60%, wherein the angle of winding of the first tape on each conductive core relative to the axis of the current-carrying core is 45-60 °, and the angle of winding of the second tape on the said first tape relative to the axis of the current-conducting core exceeds the value of the said angle of the first tape by 15-20 °.

The outer and inner protective sheaths of the cable, made of polymer compositions that do not contain halogens, as well as the insulation, protect the cable from mechanical damage and impact and are the initial fire-resistant barrier when it burns. The execution of the conductive cores of the aluminum alloy core increases the fire resistance of the cable at a flame temperature of 750 ° C. Winding two glass-mica tapes along a helical line on each conductive core, one on top of the other in opposite winding directions, prevents the strips from separating from their conductive core. The execution of tapes of glass-mica-containing material, having a thickness of 0.14-0.25 mm, provides a cable fire resistance of at least 210 minutes at a flame temperature of 750 ° C. In this case, with a tape thickness of less than 0.14 mm, the mentioned fire resistance is not achieved, and with a tape thickness of more than 0.25 mm, the probability of air gaps in the winding increases at the above angles of tape winding and the range of their overlap. The angle of winding of the first tape on each conductive core relative to its axis, equal to 45-60 °, and the angle of winding of the second tape on the first tape relative to the axis of the conductive core, exceeding the value of the said angle of the first tape by 15-20 °, are interconnected with the overlap area within 45- 60% and provide an increase in the density and rigidity of winding glass-mica tapes, preventing the possibility of their displacement relative to the conductive core and eliminating the possibility of air gaps in the winding under mechanical stress on the cable. The functional purpose of the second tape is to create an additional fire-resistant barrier and rigid attachment and fixation of the first tape wrapped around its conductive core. At the same time, it was empirically determined that at the angles of the second tape relative to the axis of the conductive core that are not included in the above range of values, the density and stiffness of winding glass-mica-containing tapes significantly decreases and the displacement of the tapes relative to the axis of their conductive core is possible under mechanical influences on the cable during combustion. , which leads to the creation of air gaps in the winding. When the angle of winding of the first tape on the conductive core relative to its axis, which is less than 45 ° and more than 60 °, under mechanical influences on the cable during combustion, the said tape is shifted relative to its conductive core, which leads to the creation of air gaps in the winding. With a percentage overlap of less than 45 and more than 60% at the above-considered winding angles of the first and second tape, the density and rigidity of winding glass-mica tapes decreases, and therefore air gaps in the winding are possible.

The utility model is illustrated by drawings, where:

in fig. 1 is a general view of a cable with a core with three current-carrying conductors;

in fig. 2 is a general view of a cable with a core with four conductive conductors.

The fire-resistant electrical cable 1 contains a core made in the form of several stranded conductive conductors 2 of an aluminum alloy, for example, grade 8030 or 8176. The drawings show, as an example, embodiments of the core with three and four conductive conductors. However, for a specialist it is obvious that the core can contain two, five or more conductive cores. Two glass-mica tapes 3a and 3b are wound along a helical line on each conductive core 2 one on top of the other in opposite directions. Glass-mica tapes contain phlogopite mica or muscovite mica and a fiberglass tape backing. These types of mica retain their inherent layered structure up to melting temperatures in the range from 1200 ° C to 1300 ° C, which provides high fire resistance. The difference between the two types of mica is determined by their chemical composition. When ignited, they release small amounts of water. In muscovite, this process takes place at temperatures above 600 ° C, and in phlogopite, above 800 ° C. These tapes are halogen-free and do not emit hazardous vapors. When exposed to a flame, glass-mica-containing tapes are sintered with each other and with their conductive core, forming on its surface a dense layer of electrical insulation that is resistant to mechanical stress, which is responsible for the cable's performance during a fire. Each glass-mica tape 3a and 3b has a thickness of 0.14-0.25 mm. The tapes 3a and 3b are wound with an overlap area of 45-60%. The angle of winding of the first tape 3a on each conductive core 2 relative to the axis of this conductive core 2 is 45-60 °. The angle of winding of the second tape 3b on the first tape 3a relative to the axis of the said conductive core 2 exceeds the value of the said angle of the first tape by 15-20 °.

On top of said glass-mica strips 3a and 3b, there is an insulation 4, for example oil-impregnated paper or plastic. Insulation paper is made of sulphate cellulose and impregnated with a liquid dielectric - oil-roasted oil composition. Plastic insulation can be in the form of a mixture of PVC resin with plasticizers and stabilizers, or cross-linked polyethylene. On top of the core in the form of twisted conductive conductors 2, each of which is wrapped with tapes 3a and 3b and covered with insulation 4, there is an inner sheath 5. Above the inner sheath 5 is an outer sheath 6. The inner 5 and outer 6 shells are made of polymer compositions that do not contain halogens ...

Example 1. A fire-resistant electrical cable contains a core with three conductive conductors made of 8030 aluminum alloy. Two glass-mica tapes are wound along a helical line on each of the three conductive conductors one on top of the other in opposite directions, each of which has a thickness of 0.18 mm. Insulation is located on top of said glass-mica tapes. An inner sheath is located on top of the core with three conductors wrapped in tapes and covered with insulation. On top of the inner shell is the outer shell. The inner and outer shells are made of halogen-free polymer compositions. Glass-mica tapes are wound with an overlap area of 50%. The angle of winding of the first tape on each conductive core, relative to the axis of the conductive core, is 50 °. The angle of winding of the second tape on the first tape, relative to the axis of the conductive core, is 68 °. As a result of tests, the electric cable showed a fire resistance of at least 210 min (230 min) at a flame temperature of 750 ° C. In this case, the cable was subjected to mechanical effects in the form of twisting and stretching of the cable, however, no shifts of the glass-mica-containing tapes relative to their current-carrying conductors and the occurrence of air gaps in the winding were found.

Example 2. A fire-resistant electrical cable contains a core with four conductive conductors made of 8176 aluminum alloy. Two glass-mica tapes are wound along a helical line on each of the four conductive conductors one on top of the other in opposite directions, each of which has a thickness of 0.23 mm. Insulation is located on top of said glass-mica tapes. An inner sheath is located on top of the core with four conductors wrapped in tapes and covered with insulation. On top of the inner shell is the outer shell. The inner and outer shells are made of halogen-free polymer compositions. Glass-mica tapes are wound with an overlap area of 55%. The angle of winding of the first tape on each conductive core relative to the axis of the conductive core is 56 °. The angle of winding of the second tape on the first tape relative to the axis of the conductive core is 72 °. As a result of tests, the electric cable showed a fire resistance of at least 210 minutes (248 minutes) at a flame temperature of 750 ° C. In this case, the cable was subjected to mechanical influences in the form of shocks and vibration of the cable, however, no shifts of the glass-mica-containing tapes relative to their current-carrying conductors and the occurrence of air gaps in the winding were found.

Example 3. Tests were carried out on cables not characterized by a set of essential features of the claimed utility model. The electric cable contains a core with four conductive conductors made of 8176 aluminum alloy. Along a helical line on each of the four conductive conductors, one on top of the other in opposite directions, two glass-mica tapes are wound, each of which has a thickness of 0.30 mm. Insulation is located on top of said glass-mica tapes. An inner sheath is located on top of the core of four stranded conductors wrapped in tapes and covered with insulation. On top of the inner shell is the outer shell. The inner and outer shells are made of halogen-free polymer compositions. Glass-mica tapes are wound with an overlap area of 40%. The angle of winding of the first tape on each conductive core, relative to the axis of the conductive core, is 20 °. The angle of winding of the second tape on the first tape, relative to the axis of the conductive core, is 30 °. As a result of tests, the electric cable showed a fire resistance of less than 210 minutes (130 minutes) at a flame temperature of 750 ° C. At the same time, mechanical influences were carried out on the cable during the first tests in the form of twisting and stretching of the cable, as in example 1, and during the second tests in the form of shocks and vibration of the cable, as in example 2. In both cases, shifts of glass-mica-containing tapes relative to their conductors, in connection with which air gaps in the winding were detected, which led to the premature approach of the flame to the conductive core and damage to the cable.

Thus, the proposed utility model, characterized by a set of essential features, ensures the fire resistance of the cable for at least 210 minutes at a flame temperature of 750 ° C, while the density and rigidity of winding glass-mica tapes increases and the possibility of their displacement relative to their conductive cores is prevented, which excludes the occurrence of air gaps in the winding under mechanical stress on the cable.

Claims (1)

A fire-resistant electrical cable containing a core and an inner and outer sheaths, which are respectively located on top of the core and are made of polymer compositions that do not contain halogens, while the core is made in the form of twisted conductive conductors of aluminum alloy, on each of which, along a helical line, one on top of the other two glass-mica-containing tapes are wound in opposite directions, on top of which insulation is located, characterized in that the said glass-mica tapes have a thickness of 0.14-0.25 mm and are wound on each conductive core with an overlap of 45-60%, while the angle the winding of the first tape on each conductive core relative to the axis of the current-conducting core is 45-60 °, and the angle of winding the second tape on the said first tape relative to the axis of the current-conducting core exceeds the value of the said angle of the first tape by 15-20 °.

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