SU1727856A1 - Fire-fighting method and relevant system - Google Patents

Abstract

Use: in fire protection, mainly for extinguishing inside objects (tanks, holds, etc.). SUMMARY OF THE INVENTION: Powdered dehydrated natural zeolite saturated with low-temperature carbon dioxide is supplied to the fire center. These substances are placed in different containers, which in the upper parts are connected directly, and in the bottom part the tank with zeolite is connected to a transporting tube, one end of which is plugged. 2 sp.f-ly, 1 ill., 2 tab.

Description

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The invention relates to fire protection and can be used to extinguish fires originating on the open surface and inside objects (tanks, holds, railway cars, warehouses, etc.).

A fire extinguishing system is known, which contains a container with fire extinguishing granular substance (powder), inside of which two perforated (mesh) partitions are fixed in its lower part. The partitions are installed end-to-end, and each of them is set at an angle of repose and an extinguishing powder on them. Sub-septum space is connected to the tanks with a gaseous working agent (compressed air). Above the junction of the perforated partitions is the end of the transporting pipeline with the possibility of sucking into it and moving the extinguishing agent from

the subsequent release into the space through the second end of the pipeline in the direction of the source of fire.

When the system is operating, the powder is pushed out of the container by compressed air. The fire is extinguished by mechanically isolating it from the surrounding air. The system is effective only in the initial stage of ignition of objects both on the open surface and inside the object. The advantage of the known installation is its speed and ease of operation.

The disadvantages of the known system are the inefficiency of extinguishing the fire when the process of strong ignition of the object begins: extinguishing is possible, but for some time, after which the object ignites again, and besides, the system is ineffective when extinguishing the fire inside the object, for example, inside the car

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The path of movement of the fire extinguishing powder is met by a mechanical obstacle preventing the powder from penetrating directly into the fire. At the same time, the caking of the fire extinguishing powder often leads to failure of the installation. Melting the fire extinguishing powder always necessitates scraping (cleaning) the molten powder from objects after the fire has been eliminated. Many items cannot be cleaned at all (food, etc.). The incomplete discharge of a container with an extinguishing powder during the operation of the system indirectly reduces the efficiency of extinguishing the source of fire, as it reduces the duration of the supply of fire extinguishing powder to the center of fire. The decrease in the useful volume of the container with fire extinguishing powder due to the presence of sub-septum space free from powder, as well as the complication of the design of the container with fire extinguishing powder due to the presence of perforated partitions and transport pipeline in it are disadvantages of the known system.

The purpose of the invention is to increase the efficiency of fire extinguishing, regardless of the fire force of the object, the location of the source of combustion, the elimination of system failures due to caking of the fire extinguishing substance and simplification of the design.

Both capacities of the system are isothermal and, in contrast to the known, their upper parts are interconnected. One of the tanks is filled with liquid low-temperature carbon dioxide, the gaseous phase of which is used as a working agent. The second tank is filled with highly porous mineral granular material (natural zeolite), and in its bottom part along the straight line holes are made, connected by means of nozzles to a transport pipeline, one end of which is plugged, and the second one is connected with a three-way valve only the porous substance into the space, and to feed it into the second conveying pipeline, one end of which is connected to the bottom of the tank with liquid low-temperature dioxide ohm carbon, and the second is communicated with the space, and the pipeline is equipped with a shut-off valve. In order to intensify the emission of a mixture of zeolite and aerosol of carbon dioxide at the junction of two conveying pipelines, an ejector is installed, which gives the possibility of supplying the fire to the hearth

a mixture of two extinguishing agents: zeolitic powder and carbon dioxide aerosol.

The tank with the zeolite (porous substance) is connected to the tank with liquid low-temperature carbon dioxide, and the pipeline is connected to the gas phase of carbon dioxide. Zeolite is used in a finely divided state. Yavl smiling

0 with a highly porous substance, the zeolite is saturated with carbon dioxide as much as possible, since the temperature in both tanks isolated isothermally is low (35 - 40 ° C). At this temperature, the zeolite saturated with carbon dioxide is in the tank before it is used. Thus, fluctuations in ambient air temperature (winter, summer) do not change the degree of saturation of zeolite with carbon dioxide.

0 Zeolite, entering the combustion zone, releases gaseous carbon dioxide, which forces air out of the fire zone, creates an inert environment, contributing to the extinguishing of fire, including fires with a high degree of ignition. This is the main additional property of zeolite saturated with carbon dioxide. At the same time, the spread of gaseous carbon dioxide emitted in space also contributes to the extinguishing of the fire center located behind a mechanical obstacle if such an obstacle is encountered along the path of the emitted zeolite.

5 One of the tanks of the system is filled with liquid low-temperature carbon dioxide at (-35) - (-40) ° C and a pressure of 8-12 atm, which is a necessary condition for the maximum adsorption of carbon dioxide by the adsorbent (zeolite).

The cooled zeolite, getting into the fire center, causes a significant cooling of the environment, which increases the quenching efficiency.

In the proposed system there are separate distinctive features (zeolite, liquid low-temperature carbon dioxide, isothermal tanks) with previously known functional purposes and properties. However, these separately taken signs do not cause the development of a new property, consisting in the release of gaseous carbon dioxide by the zeolite, when extinguishing the hearth of fire.

The release of carbon dioxide gas is possible only when it is pre-saturated with carbon dioxide at a low temperature, since the degree of saturation at a normal temperature is low. Therefore, liquid low-temperature carbon dioxide is required, and isothermal capacity is required for its storage. The capacity of the zeolite must also be isothermal, since it is associated with the isothermal capacity of liquid low-temperature carbon dioxide. Therefore, both tanks are structurally placed in one isothermal shell. Thus, the release of carbon dioxide gas by a zeolite cannot occur without regard to the listed features.

The proposed system provides for the elimination of bulkheads in the container, while at the same time the design of the container is changed and simplified.

The drawing shows the basic design of the system and section A-A.

The system contains an isothermal shell 1, inside of which is located a tank 2 with a zeolite and a tank 3 with liquid low-temperature carbon dioxide. The tops of the containers are interconnected by means of a pipe 4 having shut off valves 5 and 6. The gaseous phase of the tank 2 is used as a working agent to saturate and displace the extinguishing agent (zeolite).

In vessel 2, a highly porous mineral granular substance (zeolite) is used as an extinguishing agent, which is constantly in a saturated state of carbon dioxide. In the bottom of the tank 2, along the straight line, there are holes connected by means of nozzles 7 to a transporting pipeline 8, one end of which is plugged, and the second is connected to a three-way valve 9 with the possibility of switching it to direct ejection of only one extinguishing agent into the space 10 and to feed the zeolite through an ejector 11, one end of which is connected to a second conveying pipeline 12 having a shut-off valve 13, and the other is connected to the space through a flexible hose 14, a valve 15 VALUE for filling low-temperature liquid tank 3 ((-35) - (-40) ° C) carbon dioxide. The pipe 16 is designed to fill the tank 2 with a zeolite.

Comparative tests were carried out to extinguish fires with the use of standard fire extinguishing powder P-1A, PF and PSB-3 and powdered zeolite without saturation with carbon dioxide and saturated with carbon dioxide. Comparative tests were carried out in accordance with the standard. Tests were carried out

using powder fire extinguisher OP-100. Carbon dioxide contained in a cylinder connected to a container filled with powder through a reducing device was used as an ejector gas.

Experiments were carried out to determine the rate of fire extinguishing ability, the determination of the mass of powder required to extinguish a unit area of the open surface of a class A model center (solid glowing substances).

The model center of fire is made of softwood lumber. The tests are carried out in accordance with known conditions.

The fire-extinguishing capacity of powders (including zeolites), in kilograms per square meter, is calculated by the formula:

tch - GP2 6.7

EA

where mi is the mass of the loaded fire extinguisher before stewing, kg;

GP2 is the mass of the extinguished fire extinguisher after extinguishing, kg;

6.7 - the maximum possible total surface area of the burning of the model source, m2.

Burn time 8 min. The results of comparative tests are given in table.1.

Experiments were carried out to determine the fire extinguisher capacity during extinguishing class B fires (flammable liquids), determine the mass of powder required to extinguish a unit of burning area of a model fire source of class B.

The tests are carried out in accordance with

standard, using a protvine with a diameter of 1500 mm, into which 55 liters of gasoline are poured, which is set on fire, maintaining a free-burning time of 60 s. The hearth is considered extinguished if there is no flame.

The fire extinguishing ability of the powder and zeolite powder (EV) in kilograms per square meter is calculated by the formula

 mi - ma

Ev

1.76

where mi is the mass of the loaded fire extinguisher before stewing, kg;

GP2 is the mass of the extinguished fire extinguisher after extinguishing, kg;

1.76 - the maximum possible surface area of the burning model center, m.

The results of comparative tests are given in table 2.

The system works as follows.

When a zeolite is directly emitted into the fire zone, regardless of the strength of the fire and the place of its occurrence using the three-way valve 9 from the Closed position, the tank 2 is switched to the direct supply of zeolite saturated with carbon dioxide to the fire center through the nozzle 10 and the flexible hose 14. At the same time The zeolite, which is under pressure of 8–12 atm in the tank 2 in the zones of the outlet openings connected to the nozzles 7, is in the fluidized state, i.e. acquires the property of high mobility of particles, like in a liquid, as a result of pressure drop is rapidly ejected into the protected space.

In an extreme situation, when more intensive extinguishing is required in order to increase the concentration of carbon dioxide in the fire, for example, in order to prevent the threat of fire being transferred to other objects, the valve 13 is opened, and the three-way valve 9 is switched to the supply of zeolite to the ejector 11 As a result, through the hose 14, a mixture of zeolite saturated with carbon dioxide and its aerosol is emitted into the protected space, since liquid low-temperature carbon dioxide at the exit of the tank 1 turns into aerosol of PICs.

Fire extinguishing powder

P-1A160

Fire extinguishing powder PF 160

Natural zeolite powder without saturation С02165

Natural zeolite powder without saturation С0г165

Zeolite powder, saturated C02168

Natural zeolite powder, saturated C0g168

Claims (2)

1. Fire extinguishing method, which consists in supplying a fire extinguishing agent under pressure, characterized in that, in order to increase the extinguishing efficiency by eliminating the possibility of caking extinguishing agent, powdered dehydrated is used as an extinguishing agent in the fire site. natural zeolite saturated with low temperature carbon dioxide. 2. A fire extinguishing system containing containers with various fire extinguishing substances, characterized in that, in order to increase the effectiveness of fire extinguishing, the tanks are covered with a heat-insulating sheath and their cavities are connected by means of pipes in the upper part, with holes in the bottom part of one of the tanks. connected by means of nozzles with a transport pipeline installed under it, one end of which is plugged, and a three-way valve is installed at its other end, the other transporting pipeline is It is installed under another container, one end of which is connected to its bottom part, and the other is connected via an ejector to one of the outlets of a three-way valve, the other outlet of which is connected to the fire-extinguishing substance supply pipe to the fire center. 35 Table 1 0.9 0.50 0.39 0.37 0.30 0.30 Re-fire No re-fire Fire extinguishing substance Sleep mass - Snare mass - - Total consumption of fire - Fuel consumption-1 Availability of