RU15457U1 - FIRE SAFE COMMUNICATION COLLECTOR - Google Patents

Abstract

1. Fireproof communication manifold containing a housing, water supply, cable structures placed on both sides of the housing in the form of racks with shelves, DC power cables with fire-retardant elements and AC power cables with fire-retardant elements located above the water supply, and also located on the opposite from the water supply to the side of the housing are the power cables of the collector’s own needs, the control cables of the collector’s own needs and the communication cables located under them, characterized in that it is it is loaded with cable trays made of flame-retardant material that are integral along the length of continuous sections, in some of which the collector's auxiliary power cables are laid, and in the other, collector's own auxiliary control cables, fireproof devices in which communication cables are laid, and a fireproof partition through which the cables communications are separated from the power and control cables of the collector’s own needs, while each fireproof device is made in the form of continuous trays of interconnected lengths unstable material, in each of which a flexible sheet of fire-resistant material is placed along the entire length, the transverse size of which corresponds to the size necessary to cover the cables with overlapping by the longitudinal edges of the sheet, the fireproof partition is made of two layers, the upper layer of which is made of fire-resistant material, and the lower one made of heat-insulating and fire-resistant material, fire-retardant elements of DC power cables and AC power cables are made in the form of a composite length

Description

Fireproof Communication Manifold

The utility model relates to fire fighting equipment, namely, communication collectors with comprehensive protection of all cables laid in it from the spread of burning when exposed to an ignition source flame (open flame during fire work or during deliberate arson, an electric arc in an arc short circuit in adjacent cables, etc.).

A fireproof cable structure is known that contains many flexible coatings of flame retardant fabric with a heat-insulating lining located around a cable tray with tight coverage of multilayer cables laid on it, as well as an outer casing in the form of a rigid spatial structure, covered over the entire length of the cables with many coatings of the same fire-resistant fabrics with heat-insulating lining. At the same time, around the cable tray, between it and the casing, there is free space (1).

However, this structure is designed to protect mainly power cables, which require the removal of heat generated by them along the entire length. Therefore, flexible coatings, tightly covering the tray with cables, are made in the form of belts placed at a sufficient distance from each other. And between the cables and the casing there is free space for ventilation.

This embodiment of the protective structure in case of fire within it does not prevent the spread of fire between the belts, and also does not protect the cables from the effects of the electric arc of adjacent cables.

2000117345

Object: IPC device: А62СЗ / 16

Known communication manifold closest to the proposed one, which contains a housing, water supply and cable structures with shelves located on both sides of the housing. At the same time, direct current and alternating current power cables are laid over the water supply, along the shelves of cable structures, and on the opposite side of the body from the water supply there are collector auxiliary power cables, collector auxiliary control cables and communication cables placed under them. For fire safety, fireproof partitions are provided between the shelves with power cables (2).

In such a communication collector, fireproof partitions are usually made of asbestos-cement sheets, which are not sufficiently resistant to the electric arc arising in power cables, and often collapse from it partially or completely, depending on the intensity of the electric arc, which leads to damage to the cables. Power cables located on one shelf are not protected from each other in any way when an electric arc arises in any of them. The partition also does not provide effective protection of cables against the spread of combustion, since it is usually located at a certain distance from the cables and limits the space near the cable on one side only.

At the same time, communication cables, which are mainly made with insulation or with insulation and a sheath of combustible polyethylene, are not protected from the effects of the ignition source flame, as well as from the spread of combustion in the event of such exposure, which leads to burnout of communication cables over long distances. In such fires, the power and control cables of the collector’s own needs located above the communication cables are not protected from the flame in any way, which may

lead to the ignition of their shells and, as a result, to the spread of fire to the entire height of the collector.

The present utility model is based on the task of creating such a communication collector in which all cables would be reliably protected from the spread of combustion when exposed to the flame of the ignition source and, therefore, the possibility of the occurrence and spread of fire in the collector would be excluded.

This object is achieved in that a fireproof communication manifold comprising a housing, water supply, cable structures placed on both sides of the housing in the form of racks with shelves, DC power cables with flame retardant elements and AC power cables with flame retardant elements located above the water supply, as well as located on the opposite side of the casing from the water supply, the power cables of the collector’s own needs, the control cables of the collector’s own needs and located under them communication aerials are equipped with cable trays of fire-resistant material, composite along the length of continuous sections, in some of which the collector's auxiliary power cables are laid, and in the other collector's own auxiliary control cables, fireproof devices in which the communication cables are laid, and a fireproof partition, by which communication cables are separated from the power and control cables of the collector's own needs, while each fireproof device is made in the form of continuous interconnected lengths x trays of flame-retardant material, each of which contains a flexible sheet of flame-retardant material along its entire length, the transverse dimension of which corresponds to the size necessary to cover the cables with overlapping longitudinal edges of the canvas, the fireproof partition is made of two layers, the top layer of which is made of fireproof material, and the bottom is from

heat-insulating and fire-resistant material, fire-retardant elements of direct current power cables and alternating current power cables are made in the form of an integral individual tray length for each cable made of fire-resistant material, and the cavity height of each of them is not less than the diameter of the cable laid in this tray, cable trays, fireproof devices, individual trays and a fireproof partition are placed on the shelves of cable structures, AC power cables are located They are located under direct current power cables, and control cables for the collector's own needs are under the collector's own power cables.

In the particular case of execution, basalt fabric was used as a flame-retardant material for the canvas, electrotechnical arc-resistant asbestos cement was used as a fire-resistant material for the upper layer of the fireproof partition and individual trays, and pressed basalt fiber was used as heat-insulating and fireproof material for the lower layer of the fireproof partition.

Placing the power and control cables of the collector’s own needs in cable trays made of flame-retardant material that is integral along the length of continuous sections ensures the protection of these cables from the effects of the ignition source flame for a certain time (fire resistance period of the cable tray material), and also significantly reduces the possibility of burning propagation in the case of from ignition (when the effect of the ignition source continues after a certain time), since the cables lie directly on the bordering the surface of the bottom surface of the tray and limited by the side walls of the tray,

The implementation of the fireproof device in the form of solid trays interconnected along the length of fireproof material, each of which is placed along the entire length of the flexible canvas of fireproof

material, for example, basalt fabric, in which communication cables are wrapped with an overlap of its longitudinal edges, allows for a certain time (fire resistance period of the basalt fabric) to reliably protect these cables from exposure to the flame of the ignition source. It also provides non-proliferation of combustion in the event of sunburn after a certain time, since due to the tightly wrapped around them along the entire length of the paintings the volume of air surrounding them is minimized.

For more reliable protection of communication cables, the canvas in each tray from the side facing the cables is made with a lining of heat-insulating and heat-resistant material, for example, basalt fiber.

The thermal insulation of the lining significantly slows down the increase in the temperature of the cables, which allows to maintain the operability of the cables when exposed to the fireproof device of the flame of the ignition source, since it prevents melting of the cable insulation at a already high enough temperature for the canvas. And the heat resistance of the material allows it to not be destroyed.

The implementation of fire-retardant elements of direct current power cables and alternating current power cables in the form of an individual tray lengthwise for each cable made of fire-resistant material, for example, asbestos-cement, electrotechnical arc-resistant and whose walls completely cover the side cable, can reliably protect each of these cables from the effects arc of adjacent cables, as well as from the flame of other ignition sources for a certain time (period of fire resistance and individual tray material). In the case of cable fire after a certain time, the tray-shaped fire retardant element

restricts air access to the cable from below and from the sides and thereby ensures the non-proliferation of cable combustion.

The placement between the communication cables and the power and control cables of the auxiliary needs of the collector of the fireproof partition provides protection of the latter from the flame in case of possible ignition of the communication cables.

Due to the implementation of the upper layer of the fireproof partition from a fireproof material, for example, asbestos cement of an electrotechnical arc resistant, additional protection of communication cables from the electric arc arising in the power cables located above them, as well as protection of the latter from an open flame under the partition, is provided.

And the implementation of the lower layer of the fireproof partition from heat-insulating and fireproof material, for example, pressed basalt fiber in the event of fire of communication cables, protects the upper layer of the fireproof partition from overheating, which can lead to a significant increase in temperature over the fireproof partition, which, in turn, is provoking factor for tanning cables placed here. At the same time, the fire resistance of the material allows it not to collapse under the influence of fire and, therefore, maintain its heat-insulating properties.

For more reliable protection of cables located above the fireproof partition from flame in case of fire of communication cables, the gap between the fireproof partition and the wall of the collector housing is provided.

Overlap of the gap is provided due to the fact that the fireproof partition from the edge facing the racks of cable structures is made along the entire length with a protrusion of the lower layer relative to the upper layer, exceeding the width of the racks in width, and transverse cuts are made in the protrusion along its entire width, whose width corresponds

the width of the racks, while the fireproof partition is placed on the shelves of cable structures with the emphasis of the upper layer on the racks, which are placed in the cutouts of the protrusion of the lower layer.

If a short circuit occurs in the AC power cable, a sufficiently reliable operation of the protective device that turns off the power is provided, as a result of which the electric arc is short-lived.

And when a short circuit occurs in DC power cables, such a protective shutdown does not work with remote short circuits, as a result of which the electric arc is long-lasting. Therefore, in order to protect the remaining cables from a long arc, DC power cables are placed above the AC power cables, that is, at the very top of the cable structure.

Based on similar considerations, the collector’s auxiliary cables are placed under the collector’s auxiliary cables.

The essence of the utility model is illustrated by drawings.

Figure 1 shows a fireproof communication manifold in cross section;

figure 2 - fireproof partition placed on cable structures, top view.

Fireproof communication manifold includes a housing 1, water supply 2 and cable structures located on both sides of the housing 1, consisting of racks 3 attached to the walls of the housing 1 and shelves 4 fixed to them,

Above the water supply 2, on the uppermost shelves 4, DC power cables 5 are laid, and under them are AC power cables 6. On the opposite side of the housing 1, on the uppermost shelves 5,

the power cables of the auxiliary needs of the collector 7 are placed, under them are the control cables of the auxiliary needs of the collector 8, and even lower - the communication cables 9.

Moreover, each DC power cable 5 and each AC power cable 6 on the shelf 4 is laid in the individual length 10 of the individual tray 10 made of fire-resistant material, which is used as an asbestos cement electrotechnical arc-resistant. The cavity of each individual tray 10 is made of a height not less than the diameter of the cable laid in it.

Communication cables 9 on each shelf 4 are housed in a fireproof device made in the form of continuous trays 11 of fireproof material, for example metal, interconnected along the length of each, along each length of which a flexible fabric 12 of fireproof material is placed, which is used as basalt fabric. Communication cables 9 along the entire length are wrapped in cloths 12, the transverse dimension of each of which corresponds to the size necessary to cover the cables with overlapping longitudinal edges of the cloth 12.

In a more preferred embodiment, the web 12 in each tray 11 from the side facing the communication cables 9 is made with a lining 13 of heat-insulating and heat-resistant material, which is used as basalt fiber.

Communication cables 9 are separated from the power cables of the collector’s own needs 7 and the control cables of the collector’s own needs 8 located above them with a fireproof partition 14 made of two layers. Its upper layer is made of flame-retardant material, asbestos-cement is used as an electrotechnical arc-resistant material, and the lower layer is made of heat-insulating and fire-resistant material, which is made of pressed basalt fiber.

In a more preferred embodiment, the fireproof partition 14 from the edge facing the uprights 3 is made along the entire length with the protrusion 15 of the lower layer relative to the upper layer. The width of the protrusion 15 exceeds the thickness of the uprights 3. In the protrusion 15, over its entire width, transverse cuts 16 are made, the width of which corresponds to the width of the uprights 3. And the fireproof partition 14 is placed on the shelves 4 with an emphasis on the upper layer in the uprights 3, which are placed in notches 16 of the protrusion 15.

The auxiliary power cables of the collector 7 and the auxiliary control cables of the collector 8 on the shelves 4 are placed in cable trays 17 made of flame-retardant material, for example, metal, that are continuous in length from continuous sections.

The fire safety of the communication header is ensured as follows.

Each individual tray 10, due to the arc resistance of its material, protects the DC power cable 5 or AC power cable 6 located in it from an electric arc arising in any adjacent or downstream cable. And due to the fire resistance of the material it protects from the flame of other ignition sources. If the exposure of the ignition source continues after the end of the fire resistance or arc resistance of the material, the individual tray 10 at the point of exposure may collapse, which will lead to cable ignition. However, due to the restriction of the space around the cable by the walls and the bottom of the individual tray 10, the spread of combustion does not occur.

Placed in each tray 11 of flame-retardant material, the web 12, also of flame-retardant material, reliably protects the communication cables 9 wrapped in it from the effects of the flame of the ignition source. In the case of a web 12 with a lining 13 made of heat-insulating and heat-resistant material, communication cables 9 with sufficiently high heating

the blade 12 is protected from melting their insulation and, as a consequence, loss of performance.

With a longer exposure to the ignition source than the fire resistance of the web material 12, the communication cables 9 at the site of exposure may catch fire. However, the spread of combustion of the cables is almost impossible due to the tightly wrapped around them cloth 12.

The implementation of the upper layer of the fireproof partition 14 of the fire-resistant material is an additional protection of the communication cables 9 from the electric arc of the power cables located above them, as well as protection of the latter from fire in the event of fire of the communication cables 9. The thermal insulation of the lower layer allows the upper layer to not heat up if there is an open flame under fire retardant partition 14. And this, in turn, protects the collector's auxiliary power cables located above 7 and the collector's auxiliary control cables 8 from overheating, which may cause them to catch fire.

The protrusion 15 on the fireproof partition 14 provides an overlap of the gap between the fireproof partition 14 and the wall of the housing 1 formed by the uprights 3. And due to the width of the protrusion 15 exceeding the thickness of the uprights 3, the pressed basalt fiber is superimposed on the wall of the housing 1, which ensures a more reliable overlap of the gap , as well as the ability to compensate for wall irregularities using transverse cuts on the edge of the protrusion 15.

Cable trays 17 made of flame-retardant material also protect the auxiliary power cables of the collector 7 and the auxiliary control cables of the collector 8 from the effects of the flame of the ignition source. In the case of cable fire in the place of flame exposure at the end of the fire resistance period of the tray material, the latter limits the spread of burning of the cables placed in it due to the presence of air obstruction on three sides of the cables.

And the placement of DC power cables 5 over AC power cables 6 provides protection for the latter from the effects of an electric arc of long duration.

Thus, all cables of the communication collector are protected from the spread of combustion when exposed to various ignition sources. And this, in turn, provides reliable protection of the collector from the occurrence of a fire in it.

Sources of information:

1.U.S. Patent No. 4585070, MKI H02G 3/04, CLUS 169 / 48.19886.

2. Technical regulations for the design, construction and commissioning of urban collectors for utilities in Moscow. MOSINZHPROEKT Institute, Moscow, 1990, p. 4.5, fig. 2; p. 14, clause 3.2; p. 25, clause 3.18 (prototype).

Appendix: copy of the prototype on 5 sheets.

Authors: CV / // Feskov EM

Herman V.I. UtflU Dmitrieva T.Yu.

Claims (7)

1. Fireproof communication manifold containing a housing, water supply, cable structures placed on both sides of the housing in the form of racks with shelves, DC power cables with fire-retardant elements and AC power cables with fire-retardant elements located above the water supply, and also located on the opposite from the water supply to the side of the housing are the power cables of the collector’s own needs, the control cables of the collector’s own needs and the communication cables located under them, characterized in that it is it is loaded with cable trays made of flame-retardant material that are integral along the length of continuous sections, in some of which the collector's auxiliary power cables are laid, and in the other, collector's own auxiliary control cables, fireproof devices in which communication cables are laid, and a fireproof partition through which the cables communications are separated from the power and control cables of the collector’s own needs, while each fireproof device is made in the form of continuous trays of interconnected lengths unstable material, in each of which a flexible sheet of fire-resistant material is placed along the entire length, the transverse size of which corresponds to the size necessary to cover the cables with overlapping by the longitudinal edges of the sheet, the fireproof partition is made of two layers, the upper layer of which is made of fire-resistant material, and the lower one made of heat-insulating and fire-resistant material, fire-retardant elements of DC power cables and AC power cables are made in the form of a composite length e individual tray for each cable made of fireproof material, and the cavity height of each of them is not less than the diameter of the cable laid in this tray, while cable trays, fireproof devices, individual trays and a fireproof partition are placed on the shelves of cable structures, variable power cables current are located under the DC power cables, and control cables of the collector's own needs are located under the collector's own power cables.  2. The collector according to claim 1, characterized in that basalt fabric is used as the flame retardant material for the web.  3. The collector according to claim 1, characterized in that the canvas in each tray of the fireproof device from the side facing the cables is lined with heat-insulating and heat-resistant material.  4. The collector according to claim 3, characterized in that basalt fiber is used as a heat-insulating and heat-resistant material.  5. The collector according to claim 1, characterized in that asbestos-cement is electrotechnical arc-resistant as a fire-resistant material for individual trays.  6. The collector according to claim 1, characterized in that the fireproof partition from the edge facing the racks of cable structures is made along the entire length with a protrusion of the lower layer relative to the upper layer, the width exceeding the thickness of the racks, and in the protrusion, over its entire width, transverse cuts are made, the width of which corresponds to the width of the racks, while the fireproof partition is placed on the shelves of cable structures with the emphasis of the upper layer on the racks, which are placed in the cutouts of the protrusion of the lower layer. 7. The collector according to paragraphs. 1 and 6, characterized in that as a flame-retardant material for the upper layer of the fireproof partition, asbestos cement is electrotechnical arc-resistant, and as a heat-insulating and fireproof material for the lower layer of the fireproof partition, pressed basalt fiber is used.