RU2739388C1 - Fire-extinguishing module - Google Patents

Abstract

FIELD: fire-prevention equipment.

SUBSTANCE: invention relates to fire extinguishing devices of volumetric quenching with the use of liquid fire-extinguishing substance, which is in the reservoir under constant pressure. Fire extinguishing module includes housing filled with excess fire extinguishing substance with attachment unit in upper part, shut-off-trigger device located in lower part of housing, made in form of vertically oriented nozzle with taps for safety valve and pressure sensor in housing. According to the invention, it is equipped with two siphon tubes, vertically installed inside the housing, wherein the latter has a spherical shape, fire extinguishing substance is in the body in a liquid state with formation of a gas zone above it, each branch is made in the form of a channel in the wall of the nozzle, inlet section of which is located on the side of the upper end of the nozzle, in the inlet section of each branch pipe there is a siphon tube, wherein the upper end sections of the siphon tubes are located in the gas zone.

EFFECT: as a result, it is possible to use different fire-extinguishing substances in the fire extinguishing module, including liquefied gas and liquid, besides, the fire extinguishing module is characterized by optimum ratio of the weight of the tank and the fire-extinguishing substance contained in it.

8 cl, 2 dwg

Description

The invention relates to fire-fighting equipment, and more specifically to stationary automated devices for volumetric extinguishing by means of a fire-extinguishing agent in a tank under constant pressure, and can be used for volumetric extinguishing of class A, B fires and electrical equipment.

From the prior art, a fire extinguishing module with a finely sprayed extinguishing liquid is known, including a sealed round-shaped body equipped with a liquid extinguishing agent, in the upper part of which there is a bracket for mounting the module over the protected area, and in the lower part it is equipped with a neck with an irrigation means, see, patent for invention , RU, cl. А62С 35/00, No. 2607967, published on January 11, 2017. The disadvantage of the known fire extinguishing module is the weighted thick-walled structure of the body with two pole flanges and a gas-generating device that creates an increased pressure at the time of start-up.

A known fire extinguishing module includes a two-necked cylinder operating under pressure, in each neck of which a shut-off device is installed, the inlets of which are connected respectively to the gas and liquid phases of the two-necked cylinder by means of a siphon tube, see, utility model patent, RU, cl. A62C 35/00, No. 108982, published 10.10.2011, or patent for invention RU, cl. A62C 35/00, No. 2461402, published 20.09.2012, The disadvantage of the known devices is the two-necked design of the cylinder, which makes it impossible to use them in a vertically oriented position with a suspension from the ceiling (vertical and ceiling), even with two siphon tubes.

A known gas fire extinguishing module includes a housing filled with a fire extinguishing agent with a fastener in the upper part, a locking and starting device located in the lower part of the housing containing a pressure sensor in the housing, a destructible glass flask and a safety valve with a bursting diaphragm, while a bypass channel is made in the safety valve for communicating the cavity of the housing with the atmosphere, see, utility model patent RU, cl. A62C 35/02, No. 166375, published on 20.11.2016. This known device is adopted as a prototype, as the closest analogue in technical essence and the achieved result. The fire extinguishing module according to the prototype is characterized by the simplicity of assembly / disassembly of the module at the facility, convenience of its maintenance and operation.

The disadvantage of the prototype is the impossibility of using in it as a fire extinguishing agent liquefied gas, which is in a tank under excess pressure of its own vapor or propellant gas, or liquid (water, water with additives), which is under excess pressure of the propellant gas. The reason for this limitation is the provisions of regulatory documents that do not allow, for safety reasons, the location in the liquid zone of the fire extinguishing agent of the input elements of the membrane safety device and the pressure control device. In addition, the shape of the body of the gas fire extinguishing module according to the prototype is not optimal from the point of view of mass-dimensional characteristics, which reduces the efficiency of the module. The above disadvantages of the prototype cast doubt on the possibility of guaranteed reliable achievement of a functional result when used on a number of objects, which significantly limits the scope of the module.

The invention is aimed at achieving a technical result, which is expressed in ensuring the possibility of using various fire extinguishing substances in the fire extinguishing module, including liquefied gas and liquid. In addition, the fire extinguishing module is characterized by an optimal ratio of the mass of the tank and the extinguishing agent contained in it. Ultimately, this technical result makes it possible to significantly expand the scope of the module, to increase the efficiency of its use. In the invention, all the positive properties of the prototype are preserved as much as possible, the most important of which are reliability and ease of use.

The specified technical result is achieved by the fact that the fire extinguishing module, including a body filled with an overpressure fire extinguishing agent with an attachment point in the upper part, a locking and starting device located in the lower part of the body, made in the form of a vertically oriented fitting with taps for a safety valve and The pressure sensor in the housing differs from the prototype in that it is equipped with two siphon tubes vertically installed inside the housing. The body itself has a spherical shape, and the extinguishing agent is in the body in a liquid state with the formation of a gas zone above it. Each branch is made in the form of a channel in the wall of the fitting, the inlet section of which is located on the side of the upper end of the fitting, while a siphon tube is installed in the input section of each branch. The upper ends of the siphon tubes are located in the gas zone. Optimal from the point of view of achieving the specified technical result is the installation of siphon pipes by means of a threaded connection in the inlet section of each branch, from the side of the upper end of the fitting diametrically opposite, and their manufacture is made of copper, with a height of 0.9 ÷ 0.95 of the inner diameter of the body.

It is advisable to make L-shaped bend channels. It is preferable to use freon as a fire extinguishing agent. In all cases of module implementation, nitrogen may be contained in the gas zone.

Autonomous fire extinguishers, in which fire extinguishing agents are under excess pressure of their own vapors or propellant gas, are devices of constant readiness, as well as multiple use, which necessitates constant monitoring of their condition.

The invention is based on the principle of universality of a fire extinguishing module when choosing a protected object and interchangeability when selecting a fire extinguishing agent used in it. Depending on the type of protected object, climatic and other conditions, the choice of fire extinguishing agent is selected by weight, type and type of fire extinguishing agent. The possibility of using a liquid extinguishing agent in a ceiling-mounted fire extinguishing module imposes a number of design restrictions and requirements. It is necessary to ensure the maximum completeness and speed of displacement of the liquid extinguishing agent from the tank, as well as accessibility during the inspection of the module readiness. Both of these tasks are accomplished by locating a shut-off device with a safety valve and a pressure sensor at the lowest point of the housing.

The module body makes up the bulk of its passive weight. Reducing the body weight improves the operational and economic performance of the fire suppression module. The spherical shape of the body has two (unique) remarkable properties: the sphere is uniformly strong under internal pressure loading, and therefore the wall thickness of the spherical body will be the same everywhere and the minimum required; the sphere, in comparison with other forms, is characterized by the minimum ratio of its surface area to the internal volume, which provides the maximum volume of extinguishing agent with a minimum body weight. In addition, the single flange design (there is only one neck in the body) also reduces the passive weight of the body.

The extinguishing agent 2 fills almost the entire volume and is in the housing 1 in the liquid phase under an excess pressure relative to the environment. The pressure level is not constant and depends on many factors, including the room temperature. Pressure drops between liquid and gaseous media are perceived differently by the sensitive elements of the safety valve and pressure sensor, so when the latter are placed in a liquid medium, their unauthorized operation and premature loss of performance are likely, as well as blockage of the access channels by solid particles of sediment. The presence of siphon tubes, the upper end sections of which are located in the gas zone, excludes the contact of the sensitive elements of the safety valve and the pressure sensor with the liquid medium.

The location of the inlet sections of the outlets from the side of the upper end of the nozzle, and the L-shaped channels in the wall of the nozzle (outside the drain neck) reduces the hydraulic resistance when the extinguishing agent flows out from the body and increases the module's response time. The installation of copper siphon pipes in the inlet sections of the bends by means of a threaded connection is diametrically opposite, i.e. at the maximum distance from each other greatly simplifies the installation of the pipes themselves, as well as access to the safety valve and pressure sensor when carrying out inspections and recharging the module. The execution of the height of the siphon tubes in the range of 0.9 ÷ 0.95 of the inner diameter of the body is guaranteed to ensure that the upper end sections of the siphon tubes are always located in the gas zone, which prevents liquid refrigerant from getting into the safety valve and pressure sensor when the module is tilted or moved.

The structural diagram of the fire extinguishing module according to the invention maximizes the scope of its application in conditions of repeated and prolonged use. Thus, all the distinguishing features of the fire extinguishing module from the prototype are aimed at obtaining and are sufficient to achieve the technical result, namely, the use of liquefied gas or liquid as a fire extinguishing agent in the module, while ensuring optimal mass-dimensional characteristics. A fire extinguishing module, characterized by the described set of essential features, is new, industrially applicable and has an inventive step.

The technical solution is illustrated with drawings.

FIG. 1 shows a general view of the fire extinguishing module; fig. 2 - locking and starting device with a safety valve and a pressure sensor.

The fire extinguishing module contains a housing 1 in the form of a regular sphere (in figure 1, the inner diameter of the housing is indicated by the symbol,), filled with a fire extinguishing agent 2, which is under pressure in excess of the environment. The extinguishing agent 2 is in the housing 1 in the liquid phase and fills almost the entire volume. Freon 125 (HFC-125) or freon 227 (HFC-227ea, FM-200) was used as a fire extinguishing agent. In the upper part of the housing 1, not filled with a fire extinguishing agent in the liquid phase, a gas zone 3 is formed, filled with saturated vapors of the extinguishing agent and a propellant gas, which is used as nitrogen.

In the lower part of the housing 1 there is a pole hole formed by a flange, in which, by means of a threaded connection, a locking and starting device 4 is mounted, made in the form of a vertically oriented fitting, the longitudinal axis of which is aligned with the vertical axis of the sphere. In the wall of the nozzle, bends 5 and 6 are made, each of which is an L-shaped bypass channel. The outlet section (short leg of the L-shaped channels) of the branch 5 is in communication with the safety valve 7, and the outlet section of the branch 6 is in communication with the pressure sensor 8. The inlet sections (the long leg of the L-shaped channels) of the branches 5 and 6 are located on the side of the upper end 9 of the fitting ...

In the housing 1, two identical in shape, vertically oriented copper siphon tubes 10 and 11 are installed. The siphon tubes 10 and 11 are arranged in such a way that their lower end sections are installed by means of a threaded connection in the inlet sections of the branches 5 and 6, and the upper end sections of the siphon tubes 10 and 11 are made open and located in the gas zone 3. The siphon tube 10 is installed in the inlet section of the branch 5, and the siphon tube 11 is installed in the inlet section of the branch 6. Thus, the siphon tube 10 communicates the gas zone 3 with the safety valve 7, and the siphon the tube 11 communicates the gas zone 3 with the pressure sensor 8. In this case, the siphon tubes 10 and 11 are oriented diametrically opposite to the center of the upper end 9 of the fitting, i.e. removed from each other at the maximum possible distance. The height of each siphon tube 10.11 from the upper end 9 of the nozzle to the upper end section in the gas zone 3 is 0.9 ÷ 0.95 of the inner diameter (∅) of the housing 1.

The shut-off-starting device 4 of the fire extinguishing module is equipped with a shut-off poppet valve 12 resting on a destructible glass flask 13, a spray gun 14, a pyro pusher 15. In the safety valve 7, which communicates the inner cavity of the housing 1 with the atmosphere, a bursting disc 16 is installed, made of aluminum foil and hermetically overlapping the flow area of the safety valve 7. The pressure sensor 8 is intended for continuous measurement of the pressure level in the housing 1 and is a dial gauge or electronic signaling manometer equipped with an electrical contact connector for transmitting readings via wired or wireless to a remote control point.

In the upper part of the housing 1, on its outer surface, there is a fastening unit 17 intended for hanging the fire extinguishing module from the ceiling surface of the protected object.

The fire extinguishing module functions as follows.

The equipped module is permanently mounted by means of the attachment point 17 on the object to be protected, mainly on the ceiling, above the place where a fire is most likely to occur. The electrical connector of the pyro pusher 15 is connected to the electric start circuit, after which the fire extinguishing module is put into operation.

The extinguishing agent 2 fills almost the entire volume and is in the housing 1 in the liquid phase under a pressure of 1.6 MPa. The pressure level is not constant and depends on many factors, including the room temperature. During the entire process of being on the object to be protected, the pressure sensor 8, through the siphon tube 11 and the outlet 6, measures the pressure level in the gas zone 3 of the body 1. When the pressure in the gas zone 3 of the body 1 rises above the permissible value determined by the safety and operation requirements of the product , the rupture disc 16 of the safety valve 7 breaks down and the gas escapes through the siphon tube 10 and outlet 5 into the atmosphere, thereby releasing the critical pressure and preventing rupture of the housing 1.

When primary signs of a fire center appear, the gas fire extinguishing module is launched. An electrical impulse with a current of 0.1 to 1A is supplied to the pyro pusher 15 through an electrical contact connector from the operator's control panel or from the automatic system. When triggered, the pyro pusher 16 acts on the destructible glass flask 13, which, when it breaks, releases the shut-off poppet valve 12 of the shut-off device 4. The glass flask 13 is filled with a temperature-sensitive liquid with a large linear expansion coefficient and self-destructs under the influence of a certain temperature, launching the module in an autonomous mode ... After the destruction of the flask 13, the poppet valve 12 moves under the action of excess pressure inside the housing 1 and frees the passage of liquid through the sprayer 14, the extinguishing agent 2 flows out to the fire site.

The equipment / reloading of the module is carried out more than 10 times according to special regulations with strict observance of the norms and the mode of filling the housing 1 with fire extinguishing agent 2. The fire extinguishing agent freon is safe and non-conductive, does not have a harmful corrosive and chemical effect on metals, plastics and electrical equipment, and also does not represent danger to people.

The advantage of the fire extinguishing module according to the invention is its reliability and efficiency. The operation of such a module is economically and technically not associated with significant costs. The module is recommended for use in any premises, its performance is confirmed by tests.

The examples of the implementation of the fire extinguishing module reflected in the description and drawings are not exhaustive, they are given in order to confirm its industrial applicability.

Claims (8)

1. A fire extinguishing module, including a body filled with an overpressure fire extinguishing agent with an attachment point in the upper part, a locking and starting device located in the lower part of the body, made in the form of a vertically oriented fitting with taps for a safety valve and a pressure sensor in the body, characterized by that it is equipped with two siphon tubes, vertically installed inside the body, the latter has a spherical shape, the extinguishing agent is in the body in a liquid state with the formation of a gas zone above it, each outlet is made in the form of a channel in the wall of the fitting, the inlet section of which is located on the side of the upper end of the fitting, a siphon tube is installed in the inlet section of each branch, while the upper end sections of the siphon tubes are located in the gas zone. 2. The module according to claim 1, characterized in that the siphon tube is installed in the inlet portion of each branch by means of a threaded connection. 3. The module of claim. 2, characterized in that the siphon tubes are installed in the inlet sections of the branches from the side of the upper end of the fitting diametrically opposite. 4. The module according to claim 3, characterized in that the siphon tubes are made of copper. 5. The module according to claim 4, characterized in that the height of the siphon tube is 0.9 ÷ 0.95 of the inner diameter of the body. 6. The module according to claim 5, characterized in that the outlet channels are L-shaped. 7. The module according to claim 6, characterized in that the extinguishing agent contains freon. 8. Module according to PP. 1-7, characterized in that the gas zone contains nitrogen.

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