RU2470688C1 - Dry-chemical extinguishing module - Google Patents

Abstract

FIELD: fire-prevention facilities.SUBSTANCE: invention relates to fire fighting technology, namely, dry-chemical extinguishing modules, which are universal fire-extinguishing means. The dry-chemical extinguishing module comprises a housing 1, a gas generator 3, a nozzle orifice 8, a destructible membrane 9. The housing 1 is equipped with the dry chemical powder. The gas generator 3 is mounted at the upper part of the housing 1 and is equipped at the lower part with the aerator 4. At the upper part the gas generator 3 is connected to the electric triggering element. The nozzle orifice 8 is made in the form of a hollow cylindrical nozzle and placed in the neck 7 of the housing bottom with a gap. The destructible membrane 9 is pressed with the swivel nut 11 to the neck 7 of the bottom of the housing 1. The lateral surface of the aerator 4 is equipped with the holes 5 which are covered with the breaking elements. The end face of the nozzle orifice from the side of the membrane is equipped with a flange 12, and the end face facing the gas generator is equipped with curved holes 15. Each fragment 16 of the end face is in the place of the hole made and bent inside the nozzle orifice. And the connection with the end face is maintained in the part of its perimetre which coincides with the conventional line. A conventional line passes through the center of the end face. The plane of each fragment 16 is placed at an angle of 30-60° to the axis of the nozzle orifice. All the fragments 16 are bent in one direction.EFFECT: module enables to improve the efficiency of firefighting, to increase operational functionality and convenience, the range of applications by creating conditions to enhance fast operation of fire extinguishing and reliable fire extinguishing ability, regardless of its location in space.6 cl, 4 dwg

Description

The invention relates to fire fighting equipment, and in particular to powder fire extinguishing modules, which are universal fire extinguishing agents and can be used both to extinguish local fires and to extinguish in a room by area or volume in automatic, autonomous or manual modes.

Known powder fire extinguishing devices according to patents of the Russian Federation 2082472 (publ. 27.98.1997), 2128071 (publ. Publication 03/27/1998), 2142837 (publ. 12/20/1999), 2147902 (publ. 04/27/2000 ), 2189265 (publ. September 20, 2002), 2283149 (publ. September 10, 2006), which are additionally equipped with autonomous start (self-triggering) functions, while the heat-sensitive element is located inside the housing in all devices except the one known from the last of the listed patents, where the specified element is placed outside the housing.

The prior art device for extinguishing a fire according to the patent of the Russian Federation 2189265 (publ. 09/20/2002), containing a sealed enclosure equipped with a fire extinguishing powder, equipped with a powder jet divider, an exhaust nozzle, a destructible diaphragm and a sealed chamber with a gas generating located in its upper part a charge and an electric start unit equipped with a means for fluidizing the powder. To ensure an autonomous mode of operation (self-operation), the device can be equipped with a heat-sensitive element.

The disadvantages of the prototype include: the design of the jet divider to provide coverage of the entire protected area, which significantly reduces the speed of the powder particles in the combustion zone and can create conditions for their removal by upward flows of combustion products, especially when volumetric fire fighting in areas outside the conical spray angle of the extinguishing powder ; placing the destructible membrane in front of the divider, which can lead to overlapping of the divider opening with particles of the destroyed membrane, subsequent distortion of the cross section of the powder jet and, accordingly, to deterioration of the fire extinguishing ability of the device, which reduces the possibility of achieving a functional result, i.e. fire fighting efficiency. In addition, the powder aeration means, made in the form of holes on the side surface of the chamber with a gas-generating charge, located in the upper third of the device body, fluidizes only the upper part of the powder and may not be sufficient for high-quality aeration, therefore, an additional equipment of the device with a jet cultivator, fluidizing the lower part of the powder, which occupies part of the useful volume of the device, increases the number of assembly units, and mobile, which reduces the reliability of fu ktsionirovaniya device as a whole. Thus, the effectiveness of the preparation of the powder for throwing and, accordingly, the effectiveness of fire fighting is being questioned.

As a disadvantage of the known device, it should be noted that the heat-sensitive element (for example, a blowing agent) is located on the module housing from the inside, which increases the inertia of the device’s starting, as a thermosensitive element will only respond to a temperature increase after warming up the case, filled with fire extinguishing powder, which is an additional heat sink, to the required temperature. The temperature-sensitive element will react with the delay stated above to increase the temperature from the ignition center located directly below the device, if the center is located away from it, then the heating of the case will begin only after the flame propagates towards the device, i.e. the fire load may be such that putting out a fire is already pointless. During installation, the device must be installed in a vertical position with the nozzle nozzle exactly down, because when you rotate it relative to the horizontal plane, the thermosensitive element is closed by the body of the device, which complicates its heating. There is no control over the readiness of the device for autonomous start-up after assembly and during operation at the facility. In the event that the heat-sensitive element is torn off from the destructible membrane or the flame-retardant cord is broken, the device as an autonomous fire extinguishing agent is not functional. There is no possibility of transmitting a signal to the central monitoring console in the event of a device being triggered, which is an integral requirement in the design of automatic and autonomous fire extinguishing installations.

The known module of the two-threshold operating mode according to the patent of the Russian Federation No. 2283149 (publ. September 10, 2006), containing a housing filled with fire extinguishing powder with fasteners, a gas generator located inside the housing in its upper part, a heat-sensitive element equipped with its own housing mounted outside the module housing on the element of its fastening, exhaust nozzles with a membrane for the release of fire extinguishing powder, which determines the course of the gas-powder jet.

Due to its design features, the known module has a strictly limited orientation of the release of extinguishing powder - only vertically down. The presence of a heat-sensitive element is an indispensable condition for the functioning of the module, as it is an essential feature, which is given in the main paragraph of the formula, therefore, the known module has limitations on operational capabilities. In preparing the powder for a uniform and stable discharge that affects the extinguishing efficiency, it is important to provide aeration of the powder. In the known module, the means providing this process is practically not described and is not shown in the drawing. Analyzing the location of the gas generator in the module, which involves not only a vertical arrangement in the housing, but also the possibility of installing it at an angle, it can be most likely assumed that holes made on the side surface of the gas generator housing to act on the powder can be used as aeration means in the middle (widest) part of the module housing, but their role in the fluidization of the powder lacks sufficient efficiency, since the powder is located directly under the gas generator and compacted in the storage unit, when it is triggered, narrow stream, without creating the spray, fall under the module, i.e., the required functional result is not achieved - effective volume quenching. A conventional outlet nozzle, covered by a membrane, will not be able to correct the situation, because devoid of any elements affecting the flow of the gas-powder stream.

The prior art describes a powder fire extinguishing module (option 2) according to RF patent No. 2283153 (publ. September 10, 2006), comprising a housing equipped with a fire extinguishing powder, a gas generator fixed with the possibility of replacement in the upper part of the housing, and provided in the lower part with gas dynamics associated with an aerator, and in the upper part of the electric starter element, nozzle nozzles, destructible membrane, tightened with a union nut to the neck of the bottom of the body.

This module is intended only for use in a vertical arrangement, when the outlet cross-section of the tangential openings is horizontal, the nozzle nozzle will not be sufficient for pulsed throwing of the gas-powder mixture during the operation of the module and at the same time achieve a continuous cross-sectional flow with no sections weakened by concentration. The presence of holes on the lateral surface of the nozzle nozzle leads to significant energy losses of the gas-powder mixture entering the nozzles, and their tangential arrangement creates the conditions for circular turbulent motion of the gas-powder jet at the module exit, which together significantly increases the speed loss during its movement. Performing an aerator with a central opening for discharging the generated gases is ineffective when the module orientation is changed in space, since a stagnant zone will be formed under the horizontally placed gas generator, as a result of which the powder compacted during storage will not be aerated and, accordingly, an effective functional result will not be achieved. In addition, the well-known technical solution is not structurally presented and does not even consider the possibility of equipping it with an autonomous start (self-operation) function. The module allows you to protect only 6 m ^{2 of the} area from a height of 2-4 m and 8 m ^{3 of a} volume from a height of 2-3 m due to the fact that the gas-powder mixture inside the nozzle nozzle, due to its design features mentioned above, is turbulized in such a way that at the exit from the module it loses speed very quickly, even with the declared location of the module in space. Thus, the known module has limitations on its operational capabilities and amenities when used as intended.

The objective of the present invention is to provide a powder fire extinguishing module, which allows to increase fire extinguishing efficiency, expand operational capabilities and amenities, and a range of applications in accordance with the existing need by creating conditions to increase fire extinguishing performance and reliable fire extinguishing ability, even in unheated rooms in winter, due to the formation of a uniform concentration of the gas-powder mixture in the cross section of the torch spray it as well as a longer preservation of the speed of its movement outside the module case, regardless of its location in space, while at the same time, if necessary, ensuring the possibility of an autonomous launch enriching the consumer properties of the module.

The problem is solved by the proposed design of the powder fire extinguishing module, comprising a casing equipped with a fire extinguishing powder, a gas generator fixed with the possibility of replacement in the upper part of the casing, provided with a gas-dynamically connected aerator in the lower part, and a nozzle nozzle in the form of a hollow nozzle in the upper part a cylindrical nozzle, a destructible membrane, tightened with a union nut to the neck of the bottom of the body. The peculiarity lies in the fact that the side surface of the aerator is equipped with holes blocked by opening elements, the nozzle nozzles are placed in the neck of the bottom of the housing with a gap, while its end face on the membrane side is provided with a flange, and the end face of the nozzle facing the gas generator is provided with figured holes, each the end fragment located at the place of the hole formed is bent inward of the nozzle nozzle while maintaining communication with the end along the part of its perimeter that coincides with the conditional line passing through the center of the torus a, the plane of each fragment is placed at an angle of 30-60 ° to the axis of the nozzle nozzle, and all fragments are bent in one direction, while the ratio of the length of the side surface of the nozzle nozzle to its inner diameter is 0.8-3.0, the ratio of the total area of the holes at the end of the nozzle nozzle to its passage area is 0.4 or more, and the opening pressure of the destructible membrane is 2.4-3.5 MPa.

In particular, the ratio of the length of the housing to its diameter is 1.0-2.5.

In particular, each of the figured holes has two sides located at right angles, and a third side in the form of a circular arc connecting them.

In particular, the module housing on the side of the gas generator is equipped with a flange made with the possibility of mounting to the bracket.

In particular, the module is equipped with a remote starting temperature device containing a housing with an electronic system for starting and monitoring the necessary parameters, equipped with a hollow tube with holes on the side surface with a thermal relay located inside it, and an element that provides an airtight input into the housing of the electric cable connecting the starting a temperature device with a gas generator, and configured to connect to a fire alarm loop.

In particular, the housing of the remote starting temperature device is heat-resistant, dustproof and protected from continuous splashing and is fixed by means of its own bracket to the flange of the module housing.

A comparative analysis shows that the claimed module for powder fire extinguishing differs from the closest analogue in the design of the nozzle nozzle (with a different arrangement of holes, their different shape, equipping the internal volume of the nozzle nozzle with structural elements), which forms a high-speed turbulent powder jet under high pressure, which maintains its speed at a greater distance from the module and, accordingly, gives the module increased fire extinguishing ability; another organization of the gas entry into the internal volume of the body through the holes in the side surface of the aerator (in the prototype through the central hole of the aerator); placing the nozzle nozzle in the neck of the bottom of the housing with a gap (in the prototype - without a gap); the possibility of equipping a structurally designed remote start-up temperature device with high speed fire detection with the functions of supplying a signal to the fire alarm loop, checking the battery, breaking the start-up circuit and short circuit (in the prototype, there is no possibility of providing these functions with space without loss of achieving an effective functional result (in the prototype, the orientation of the module with the nozzle nozzle is only vertical flax down).

It is a combination of features that are distinctive from the prototype with the other essential features of the proposed solution that made it possible to achieve the above technical result, which cannot be achieved by the known module, and to solve the problem.

The proposed powder fire extinguishing module is illustrated by the drawings:

Figure 1 is a longitudinal section of a powder fire extinguishing module;

Figure 2 is a longitudinal section of a nozzle nozzle;

Figure 3 is a top view of the nozzle nozzle;

Figure 4 - external view of the module in stand-alone execution.

The powder fire extinguishing module (FIG. 1) contains a housing 1, in which a fire extinguishing powder 2 is placed, a gas generator 3, gas-dynamically connected to an aerator 4, equipped with holes 5 with opening elements (not shown conditionally and can be made, for example, of adhesive film, or rubber, or paper). To start, the gas generator 3 is equipped with an electric start element (not shown) with conductive leads 6. A nozzle 8 is installed in the neck 7 of the bottom of the housing 1, the neck 7 is covered by a destructible membrane 9, which is pressed by the nut 11 through the washer 10. The housing 1 of the module from the gas generator 3 is provided a flange 12, made with the possibility of connection with the bracket 13 for mounting the module to the bearing surface.

The nozzle nozzle 8 (FIG. 2, FIG. 3) is a hollow thin-walled cylinder with a flange 14 for installation in the neck 7. At the end of the nozzle nozzle 8, figured holes 15 are made on the side of the aerator 4 (FIG. 3). Each fragment 16 of the end face, located at the place of the formed hole, is bent inward of the nozzle nozzle 8 while maintaining communication with its end face along the part of its perimeter, which coincides with a conditional line passing through the center of the end face. The plane of each fragment 16 (Figure 2, Figure 3) is placed at an angle of 30-60 ° to the axis of the nozzle nozzle 8. The holes 15 together with the bent fragments 16 of the end face of the nozzle nozzle 8 form a high-speed turbulent jet.

To implement the module autonomous start (self-operation) on the flange 12 of the housing 1 of the module mounted bracket 17 remote starting temperature device.

The remote temperature start-up device contains its own housing 18 with an electronic start-up system and control of the necessary parameters located in it. The housing 18 is equipped with a hollow protective tube 19 with holes 20 on the side surface with a thermal relay (not shown) located inside it and an element 21 that provides a sealed entry into the housing 18 of the electric cable 22 connecting the starting temperature device to the gas generator 3 and made with the possibility of connection with a loop fire alarm (not shown).

The proposed powder fire extinguishing module can operate in three modes: in the automatic operation mode from the automatic fire alarm system, forced operation from the manual start button and in the autonomous start (self-operation) mode.

When applying an electrical impulse (automatic mode) to the conductor terminals 6 of the electric start element, the gas generator 3 is triggered, followed by gas generation. The opening elements of the holes 5 of the aerator 4 are destroyed and the gas enters the internal volume of the housing 1 of the module. Passing through the powder 2, the gas fluidizes it, preparing to be released into the protected space. When the gas pressure corresponding to the opening level is reached, the membrane 9 is destroyed, the extinguishing powder 2, entering through the shaped holes 15 in the nozzle nozzles 8 under high pressure, is formed using fragments 16 of the end face of the nozzle nozzle 8 into a high-speed turbulent jet, which enters the combustion zone, where spreads with great speed in the protected area and volume.

In stand-alone startup mode (Figure 4), the module operates as follows. In the event of a fire and reaching a predetermined (threshold) level of temperature, the thermal relays located in the hollow protective tube 19 are activated, their contacts are closed and, according to the given scheme, the remote starting temperature device transmits an electrical impulse through cable 22 to the electric start gas generator element 3, and a fire alarm loop closes in parallel to issue a signal about the operation of the module to the central monitoring console. Further operation of the autonomous launch module is carried out according to the scheme of the powder fire extinguishing module.

Tests have shown that the inventive module, equipped with 2.6 kg of fire extinguishing powder ISTO-1, allows you to reliably extinguish fires:

- for Class A fires in a volume of 65 m ³ and on an area of 25 m ² ;

- for class B fires in a volume of 17 m ³ and on an area of 14 m ² .

In parallel, tests were carried out on the prototype design equipped with 1.9 kg of ISTO-1 fire extinguishing powder, which showed that from a height of 2-4 m the fire source would be extinguished in a volume of 12 m ³ and an area of 10 m ² .

The prototype allows you to put out fires for Class B fires in a volume of 8 m ³ and on an area of 6 m ² .

The inventive module has a higher fire extinguishing ability compared to the prototype. The reliability of the tests of the device according to the prototype is undeniable, since the developer and manufacturer of the well-known and claimed modules is ZAO Source Plus.

Additionally, firing tests of the module in stand-alone execution were carried out. The tests were carried out in winter in unheated rooms when extinguishing model fires of a class B fire. The air temperature in the tests was minus 26 ° С. The thermal relays were set to a trip temperature of 72 ° C. When extinguishing model fires in a protected area of 14 m ^2, the module was launched, followed by extinguishing model fires in 1 min 26 s after they were ignited, in a protected volume of 17 m ³ after 54 s. The test results confirmed the high reliability and speed of fire extinguishing even at low ambient temperatures.

Thus, the proposed module of powder fire extinguishing is practically implemented in different operating modes, which allows satisfying a long-standing need for solving the problem.

Claims (6)

1. A powder fire extinguishing module, comprising a housing equipped with a fire extinguishing powder, a gas generator fixed with the possibility of replacement in the upper part of the housing, provided with an aerator in the lower part of the gasdynamically connected with it, and a nozzle nozzle in the form of a hollow cylindrical nozzle in the upper part, destructible membrane, tightened with a union nut to the neck of the bottom of the casing, characterized in that the side surface of the aerator is equipped with holes blocked by opening elements, the nozzle us the dock is placed in the neck of the bottom of the body with a gap, while its end face on the membrane side is provided with a flange, and the end face facing the gas generator is provided with figured holes, each end fragment located at the place of the hole is bent into the nozzle nozzle while maintaining communication with the end face along part of its perimeter, coinciding with a conditional line passing through the center of the end face, the plane of each fragment is placed at an angle of 30-60 ° to the axis of the nozzle nozzle, and all fragments are bent in the same direction, with the side length ratio the new surface of the nozzle nozzle to its inner diameter is 0.8-3.0, the ratio of the total area of the holes in the end of the nozzle nozzle to its passage area is 0.4 or more, and the opening pressure of the destructible membrane is 2.4-3.5 MPa 2. The module according to claim 1, characterized in that the ratio of the length of the housing to its diameter is 1.0-2.5. 3. The module according to claim 1, characterized in that each of the figured holes has two sides located at right angles, and a third side in the form of a circular arc connecting them. 4. The module according to claim 1, characterized in that the module housing on the side of the gas generator is equipped with a flange made with the possibility of attachment to the bracket. 5. The module according to claim 1, characterized in that it is equipped with a remote starting temperature device, comprising a housing with an electronic system for starting and monitoring the necessary parameters, equipped with a hollow tube with holes on the side surface with a thermal relay located inside it, and an element that provides hermetic entry into the body of the electric cable connecting the starting temperature device to the gas generator, and made with the possibility of connection with a fire alarm loop. 6. The module according to claim 5, characterized in that the housing of the remote starting temperature device is heat-resistant, dustproof and protected from continuous splashing and is fixed by means of its own bracket to the flange of the module housing.

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