RU217815U1 - AUTONOMOUS GAS EXTINGUISHING DEVICE - Google Patents

Abstract

The utility model relates to fire-fighting equipment, in particular to stationary devices for localizing and extinguishing fires and fires, including the burning of solid and liquid substances, as well as fires and fires in energized electrical equipment. The technical result of the proposed stand-alone gas extinguishing device is to increase the stability of the operation of the device, the technical result is achieved due to the new design of the device, which makes it possible to program the location of the destruction of the body according to the precisely specified temperature and response time. To do this, the body of an autonomous gas fire extinguishing device, made of a polymer material and filled with a chemical reagent, is made in the form of a different-walled closed profile, which prevents premature weakening of the body in one of its parts (for example, at the point of contact with a gas bubble) and reduces the destruction time in another, programming the temperature, time and direction of the spread of the chemical reagent to the fire source. In addition, the body has at least one groove that forms a weakened zone to create a stress concentrator, which, firstly, serves as a zone of programmed destruction that occurs at a precisely specified temperature and response time with minimal deviations, and secondly, sets the direction of the release of chemical reagent when the device is triggered.

Description

The utility model relates to fire-fighting equipment, in particular to stationary devices for localizing and extinguishing fires and fires, including the burning of solid and liquid substances, as well as fires and fires in energized electrical equipment.

It should also be noted that the claimed technical solution relates to thermally activated self-contained gas fire extinguishing devices and for the operation of such a device there is no need for starting devices, such as, for example, a pressure indicator, a punch or a nipple, and the like.

The following autonomous gas fire extinguishing devices are known from the prior art:

A fire extinguishing device is known (Application US 201113218739 A dated 26.08.2011, Publication No. US 2012048577 A1, IPC: A62C 2/00; A62C 3/00, Applicant Ball Gregory Keaton (US), published: 03/01/2012).

The invention is a device for suppressing or extinguishing fires. In some embodiments, the implementation of the fire extinguishing device includes a fire extinguishing agent, a housing made of material to hold the extinguishing agent, and attachment means for attaching the fire extinguisher to the surface. The fire extinguishing device is activated when the first material loses its integrity when exposed to a predetermined high temperature or exposure to an open flame, which results in the release of extinguishing agent to the target area. The target area is a location where a fire can start, such as a location near any device that generates heat or is combustible and therefore considered a fire hazard. The fire extinguishing device is placed so that the extinguishing agent is thrown onto the target area.

The disadvantage of the known fire extinguishing device in relation to the claimed technical solution is the instability of operation due to the lack of the possibility of destruction of the housing at a precisely specified temperature and response time.

The closest to the claimed technical solution is an autonomous fire extinguishing installation - a prototype (Patent RU 210431 U1, IPC: A62C 3/00, Applicant Limited Liability Company "PiroKhimika" (RU), published: 04/15/2022), which is a body made of polymer material in the form of a polymer tube hermetically sealed from both ends, filled with a chemical reagent, while the tube is additionally covered on the outside with a thin polymer protective film, the ends of the polymer tube are flat-sealed.

The disadvantage of the prototype in relation to the claimed technical solution is also the instability of operation due to the lack of the possibility of destruction of the housing at a precisely specified temperature, time and direction of operation. Including due to the fact that a gas bubble remains in the equal-walled design of the tube during filling, and the place of contact of the bubble with the tube wall is not cooled by a chemical reagent, which, if heating is localized in this area, will lead to premature operation and a problem with the release of fire extinguishing agent in the right direction .

The proposed technical solution is free from these shortcomings.

The technical result of the proposed stand-alone gas fire extinguishing device is to increase the stability of the operation of the device.

To do this, an autonomous gas fire extinguishing device, which is a housing made of a polymer material filled with a chemical reagent, in accordance with the claimed technical solution, the housing is made in the form of a closed profile with different walls and has at least one groove forming a weakened zone.

In addition, the different-walled closed profile in its upper part may have an increased thickness. In addition, a different-walled closed profile in its lower part can be provided with stiffeners. In addition, the groove forming the weakened zone can be made of variable depth. In addition, the chemical reagent can be located in the housing under an overpressure of 0.1-8 bar. In addition, the housing can be filled with a chemical reagent - fluoroketone. In addition, the different-walled closed profile can be provided with end caps. In addition, the body can be provided with fastening elements.

In FIG. 1 shows the claimed self-contained gas fire extinguishing device in longitudinal section.

In FIG. 2 shows the claimed self-contained gas fire extinguishing device in cross section.

In FIG. 3 shows the body of an autonomous gas fire extinguishing device in accordance with the claimed technical solution.

In FIG. 4 shows the case of an autonomous gas fire extinguishing device in a longitudinal section.

In FIG. 5 shows the claimed self-contained gas fire extinguishing device in assembled form and in accordance with the claimed technical solution.

The technical result of the proposed autonomous gas fire extinguishing device is to increase the stability of the operation of the device, which is achieved due to the new design of the device, which makes it possible to program the location of the destruction of the housing 1 according to the precisely specified temperature and response time.

To do this, the claimed autonomous gas fire extinguishing device (as shown in Fig. 1, 2) is a housing 1 made of polymer material filled with a chemical reagent 2. In this case, the housing can be made both in one layer and in several layers.

In order to achieve a technical result, which consists in increasing the stability of the operation of the device, and in accordance with the claimed technical solution:

The polymer can be either thermoplastic or thermoset. The thermoplastic or thermosetting polymers proposed for example have one destruction temperature of +100°C, thus a threshold value is set - the device response temperature of +100°C.

Chemical reagent 2 or fire extinguishing agent (OTV) - a substance with physical and chemical properties that make it possible to create conditions for stopping combustion.

Fluoroketone can be used as a chemical reagent. Fluoroketone is the latest generation of gas fire extinguishing compositions for fire extinguishing systems, the main advantages of which are that it is harmless to humans and the environment.

However, to determine the parameters on the basis of which it would be possible to program the places of destruction of the body according to the precisely specified temperature and response time, knowing the temperature of the destruction of body 1 and the properties of the chemical reagent 2 is not enough, this only indicates at what threshold temperature the body 1 will destroyed and extinguishing will begin. To solve the problem, it is necessary to fully program the device for a source of fire (or increased heat), including taking into account the volume of the protected object for the spread of fire extinguishing agent when the device is triggered.

To do this, the housing is made in the form of a closed profile with different walls 3. Under the different-walled profile 3 can be understood both variable geometry (walls of different areas) and walls of different (variable) thicknesses. Making the profile 3 closed with different walls allows (including due to the thickening of the walls of the housing as shown in Fig. 2-4) by changing the geometry of the walls of the housing 1 to cut off the gas bubble 4 from the exit zone of the chemical reagent 2, that is, to slow down the destruction of the housing 1 in one of its part and reduce the time of destruction in another by programming the temperature, time and direction of the spread of chemical reagent 2 to the source of fire.

In a particular case, the different-walled closed profile 3 in its upper part may have an increased thickness (as shown in Fig. 2). Prevention of premature weakening of the housing at the points of contact of its walls with the gas bubble 4 (a place not cooled by a chemical reagent) can be done differently.

In order to set the destruction zone that will work first and release the reagent in the right direction to the ignition source, the different-walled closed profile 3 has at least one groove 5, which forms a weakened zone to create a stress concentrator. If necessary, there may be several such zones.

The stress concentrator, firstly, serves as a zone of programmed destruction that occurs at a precisely specified temperature and response time with minimal deviations, and secondly, it sets the direction of the release of a chemical reagent when the device is triggered.

Thus, the set of essential features indicated in the formula will allow the new gas fire extinguishing device to increase the stability of its operation due to the possibility of programming the location of the body destruction according to the precisely specified temperature and response time.

Under the operation of the device, one should understand not the time of destruction of one or another part of the body, but the performance of the main function - extinguishing a fire.

The new device, in accordance with the claimed technical solution, allows you to set both the temperature and the response time of the device, and the direction of the release of the chemical reagent 2.

Different-walled closed profile 3 in its lower part can be provided with stiffeners 6 to impart overall rigidity to the structure of the device in places with weakened zones.

Groove 5, which forms a weakened zone and creates a stress concentrator, can be made of variable depth. As well as the variable geometry of housing 1, the variable depth of the voltage concentrator allows you to vary the values of temperature and response time, as well as set the direction of the release of chemical reagent 2.

The chemical reagent 2 can be placed in the housing under pressure from 0.1 to 8 bar or more, which, in turn, also has a positive effect on the programmable response speed of the device.

Housing 1 can be filled with a chemical agent - fluoroketone. As already mentioned, fluoroketone is the latest generation of gas fire extinguishing compositions for fire extinguishing systems, the main advantages of which are that it is harmless to humans and the environment. In addition, due to the filling factor, the use of fluoroketone allows you to increase the protection zone (the volume of the protected object) with the same dimensions of the device.

The different-walled closed profile 3 can be provided with end caps 7 to ensure the tightness of the housing 1. The housing 1 can also be equipped with elements for attaching the device to the surface in the protection zone (not shown in the figures).

Autonomous gas fire extinguishing device is designed to localize and extinguish fires and fires of classes A, B, as well as fires and fires in electrical equipment under voltage (class E). The device is designed to protect objects with a volume of 0.05 to 1 m ³ . Operating ambient temperature range from minus -40°С to plus +60°С. The device is recommended for use to protect such objects as electrical and distribution cabinets under voltage, small-sized storage facilities, automation cabinets, distribution cabinets and switchboards with high-voltage equipment with a rated voltage of up to 10 kV. The device can be used both as a stand-alone device and as an actuating device as part of a fire alarm and fire extinguishing system (when used in conjunction with a forced and automatic start system that is not included in the device delivery set).

An autonomous gas fire extinguishing device works as follows:

To begin with, based on the temperature of the destruction of the polymer (taken as +100 ° C), the values \u200b\u200bof the destruction of the housing 1 are laid down according to the characteristics of the protected object, the exact dimensions of the different-walled closed profile 3 are determined:

1. With a protected volume of 0.05 m ³ , choose the thickness of the body 1, made of polymer in the form of a different-walled closed profile 3 with a size of 21 mm, with a total length of the product of 110 mm and a mass of chemical reagent 2 of at least 14 g.

2. With a protected volume of 1.5 m ³ , the thickness of the body 1 is selected, made of polymer in the form of a different-walled closed profile 3 with a size of 20 mm, with a total length of the product of 510 mm and a chemical reagent mass of at least 1500.

In accordance with the type of protected object, the position of the grooves 5 on the body 1, their number and direction with respect to the protection zone are selected.

By means of fastening elements, an autonomous gas fire extinguishing device is placed in the protected object, placing it in such a way that the voltage concentrators (grooves 5) are directed to potentially dangerous fire places, and the gas bubble 4, protected by a part of a different-walled closed profile 3, having an increased thickness, is maximally away from a potential source of ignition.

In this way, the temperature, time and direction of gas propagation to the fire source are programmed.

When exposed to a flame and the temperature rises above the nominal response temperature, due to excess pressure, the walls of the housing 1 begin to collapse at the locations of the stress concentrators (grooves 5) and the device is triggered - a directed release of a fire extinguishing agent into the protected area. The fire extinguishing agent (OTV) in the gaseous state spreads throughout the volume of the protected object. There is a slowdown (inhibition) of the combustion reaction, cooling and extinguishing of the source of ignition.

The tests carried out by the applicant showed:

In a test box with a leakage of 0.1 m-1 and a volume of 99 liters, AUGP 100/100-60 extinguishes:

- a class B model hearth container with AI-95 gasoline with a diameter of 100 mm and a height of 30 mm in 59 s.

- model hearth class A2 polypropylene sheet according to GOST 26996 size 200×200×10 for 62 s.

AUGP 100/100-60 parameters:

Product case thickness, mm 21 Total length of the product, mm 210 Mass of fire extinguishing agent, g not less than 22 Product weight, no more than, g 55

Claims (8)

1. Self-contained gas fire extinguishing device, which is a housing made of polymeric material filled with a chemical reagent, characterized in that the housing is made in the form of a different-walled closed profile and has at least one groove forming a weakened zone. 2. Autonomous gas fire extinguishing device according to claim 1, characterized in that the different-walled closed profile in its upper part has an increased thickness. 3. Autonomous gas fire extinguishing device according to claim 1, characterized in that the different-walled closed profile in its lower part is equipped with stiffeners. 4. Autonomous gas fire extinguishing device according to claim 1, characterized in that the groove forming the weakened zone is made of variable depth. 5. Self-contained gas fire extinguishing device according to claim 1, characterized in that the chemical reagent is in the housing under an overpressure of 0.1-8 bar. 6. Autonomous gas fire extinguishing device according to claim 1, characterized in that the housing is filled with a chemical reagent - fluoroketone. 7. Self-contained gas fire extinguishing device according to claim 1, characterized in that the different-walled closed profile is provided with end caps. 8. Autonomous gas fire extinguishing device according to claim 1. characterized in that the body is provided with elements for fastening.

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