RU2767755C1 - Device for volumetric aerosol fire extinguishing - Google Patents

Abstract

FIELD: fire-fighting equipment.

SUBSTANCE: invention relates to fire-fighting equipment, namely to devices for volumetric aerosol fire extinguishing, which suppresses fire due to the impact on the source of the aerosol medium formed during the combustion of a solid charge of an aerosol-forming composition (AFC). The device for volumetric aerosol fire extinguishing contains a body equipped with a bottom and a nozzle cover, an aerosol-forming charge made in the form of a channelless checker and fixed inside the body with a protective and fastening layer from the side surface, an afterburner formed inside the body, a launch unit installed in the cover, and an ejector nozzle connected to the body. At the same time, in the central part of the end surface of the charge, a cavity is made from the bottom side, filled with a flame retardant composition. The nozzle cover is equipped with nozzles with a critical section and thermal protection on the inside. Moreover, the nozzles are made in such a way that they pass through the cover with thermal protection and protrude outward from the outer surface of the cover.

EFFECT: expanding the possibilities of its use, in particular, for fire protection in rooms with various, including large, volumes.

4 cl, 1 dwg, 2 ex

Description

SUBSTANCE: invention relates to fire-fighting equipment, namely to devices for volumetric aerosol fire extinguishing, which suppresses fire due to the impact on the source of the aerosol medium formed during the combustion of a solid charge of an aerosol-forming composition (AOC).

A device for extinguishing fires is known (patent RU 2116090 C1, publ. 27.07.1998), which contains a thermally protected housing, a means of initiation and axially sequential pyrotechnic charge, a combustion chamber, a cooling cylinder inside the combustion chamber, filled with a gas-permeable ablation layer and closed with a lid in the form a truncated cone with outlet holes distributed on its lateral surface to form a jet outflow of an aerosol flow.

The disadvantage of the known device is that when passing through the cooler layer, part of the active condensed aerosol particles settle on the surface of the cooler layer and, accordingly, do not enter the protected volume, which leads to a decrease in the fire extinguishing capacity of the generator.

It is also known a fire extinguishing device with a highly effective fire extinguishing aerosol (CN 107519602 A, 12/29/2017), which includes: a shell divided into upper and lower parts, a heat-insulating insert, a launch unit, an aerosol-forming charge, a block with a composite material containing ceramic fiber and a cooling agent, a mesh screen, an insert with jet channels, sealing films, one of which is glued to the insert and the other is glued to the bottom surface of the top cover, a block with a cooling ultrafine powder, and a top cover with Laval nozzles.

The known device has the same significant drawback as the device according to patent RU 2116090 C1, and it contains two blocks with a cooler, the presence of which leads to a decrease in the fire extinguishing ability of the device, one block includes a composite material containing ceramic fiber and a cooling agent to reduce the temperature of the jets aerosol, and the other is a cooling ultrafine powder.

The closest analogue of the proposed device is the solution according to the patent RU 2683363 C1, publ. 03/28/2019, in which a device for volumetric aerosol fire extinguishing is disclosed, containing a thermally protected housing, an electric start unit, an aerosol-forming charge made in the form of a channelless checker and fixed in the housing, a combustion chamber is formed inside the housing, the housing is equipped with a bottom and a nozzle cover made in the form truncated cone with flanging and with nozzle holes distributed along the side surface of the cover. The launch unit is made in the nozzle cover, the nozzle cover in the form of a truncated cone is made with a side surface inclination angle of 10 to 15 degrees. In the central part of the end surface of the charge, from the bottom side, a cavity is made in the form of a disk filled with a substance that decomposes with heat absorption and the formation of products that do not support combustion, the cavity is insulated on the open side with a non-combustible material. The charge is made of a composition with a negative oxygen balance, the charge is fixed in the body from the side surface and from the bottom side with a protective and fastening layer, and the combustion chamber is formed from the side of the cover, the device is additionally equipped with an ejector nozzle fixed to the body from the side of the nozzle cover. The known device provides a high fire extinguishing capacity while maintaining an acceptable temperature level of the aerosol jet.

To protect rooms with large volumes, it is necessary to increase the dimensions of the aerosol fire extinguishing device used, which in known designs can lead to a negative phenomenon - the burning of gases flowing from the nozzles of the device at the final stage of its operation.

The problem to which the present invention is directed is to eliminate the above disadvantages and create a new volumetric aerosol fire extinguishing device with high fire extinguishing capacity.

The technical result of the invention is to expand the possibilities of its use, in particular, for fire protection in rooms with different, including large volumes.

To solve the problem and achieve a technical result, a device for volumetric aerosol fire extinguishing is proposed, which contains a body equipped with a bottom and a nozzle cover, an aerosol-forming charge made in the form of a channelless checker and fixed inside the body with a protective and fastening layer from the side surface, an afterburner chamber formed inside body, a launch unit installed in the cover, and an ejector nozzle connected to the body. At the same time, in the central part of the end surface of the charge, a cavity is made from the bottom side, filled with a flame retardant composition. The nozzle cover is equipped with nozzles with a critical section and thermal protection on the inside. Moreover, the nozzles are made in such a way that they pass through the cover with thermal protection and protrude outward from the outer surface of the cover.

As a protective and fixing layer, a mixture of an organosilicon compound with a cold curing catalyst and a mineral filler is used.

The checker is made of a composition with a negative oxygen balance, and acidic potassium carbonate or azo compounds, or sulfonylhydrazines, or nitroazo compounds, or acid azides, or other endothermic compounds that emit water vapor and other non-combustible gases during decomposition are used as a flame retardant composition.

The cavity in the charge from the bottom side is made cylindrical or conical.

In the proposed design, a jet aerosol outflow is provided, in which individual jets do not merge with each other and do not intersect with the inner surface of the ejector nozzle, which ensures that there is no loss of aerosol on the structural elements of the device, as well as maintaining the temperature at the outlet of the generator at an acceptable level.

The design features of the proposed device are illustrated in the drawing.

The figure shows a general view of the device in section.

The device comprises a housing 1, equipped with a bottom 2 and a nozzle cover 3, an aerosol-forming charge 4, made in the form of a channelless checker and fixed inside the housing with a protective and fastening layer 5 from the side surface (this layer keeps the charge in the housing and ensures the combustion of the charge from only one end - from the side of the nozzle cover), the afterburner 6 formed inside the body 1, the launcher 7 installed in the cover 3, and the ejector nozzle 8 connected to the body. The afterburner 6 is formed between the cover 3 and the charge 4. At the same time, in the central part of the end On the surface of the charge 4 from the side of the bottom 2 there is a cavity 9 filled with a flame retardant composition, i.e. a substance that decomposes with the absorption of heat and the formation of products that do not support combustion. The cavity 9 may be insulated with a non-combustible material. Nozzle cover 3 on the inside is equipped with thermal protection 10 and nozzles 11 with a critical section. The nozzles 11 are made in such a way that they pass through the cover 3 with thermal protection 10 and protrude outward from the outer surface of the cover 3 in order to remove high-temperature areas of the aerosol flow from the cover 3 and reduce its heating level. Each nozzle 11 has a channel with a critical (smallest) section, made, for example, in the outlet part of the nozzle. The length of the section of the nozzle with the smallest section may be equal to approximately 0.5d, where d is the diameter of the critical section. The diameter of the critical section of the nozzle determines the length of the initial high-temperature region of the aerosol jet and its largest size should not exceed 10...15 mm. The number of nozzles is determined depending on the total area of critical sections necessary to ensure the operation of the device and design and technological considerations when assembling the generator. The cover 3 is fastened to the body by a threaded connection, or by bendable elements, or by the use of expandable retaining rings or rivets.

The thermal protection 10 of the cover 3 can be made of any non-combustible and resistant to temperatures of the order of 1000 ° C, a heat-insulating material, for example, from a pelletized cooler (based on basic magnesium carbonate), which can be held by a steel sheet cap 12 connected to the cover, or any in another known way.

Installation and fastening of the device can be carried out using the bracket 13. The metal ring 14 additionally provides thermal protection of the housing wall in the area of the afterburner.

The proposed device works as follows. Starting unit 7 is activated automatically by the fire protection system or is activated manually. The charge 4 is ignited, placed in the housing 1. The end combustion of the charge 4 passes in the direction from the cover 3 to the bottom 2. At the end of the generator operation, the cavity 9 is opened, and a substance enters into the reaction, which decomposes with the absorption of heat and forms products that do not support combustion, due to which the process of afterburning of incompletely oxidized products formed when using AOS formulations with a negative oxygen balance is excluded after the end of the GOA operation. The flow of combustion products occurs in the direction from the burning end of the charge 4 through the afterburner 6 to the nozzles 11. The products formed during the combustion of the charge 4 flow through the nozzles 11 into the protected volume. With the proposed design of the nozzles, the aerosol jets do not intersect each other, each of them retains its characteristics, including the short length of the high-temperature initial section. The distance of the outlet sections of the nozzles from the surface of the cover in conjunction with the thermal protection 10 prevents its heating and deformation.

The aerosol jets, passing through the cylindrical ejector nozzle 8, are cooled, mixed with the air entering from outside and enter the protected volume, suppressing the fire.

To test the performance and achieve the specified technical result, samples of the proposed device were tested. The results are shown in the examples.

Example 1

In the tested device, an aerosol-forming charge was used from a composition with a negative oxygen balance (CEP composition) containing (% wt.): potassium nitrate 70.4, dicyandiamide - 16.5, epoxy resin 5.2, iditol - 6.5, processing aids - 1.4. As a flame retardant composition located in a cavity made in the central part of the end surface of the charge from the bottom side, acidic potassium carbonate was used, which decomposes with heat absorption and the formation of products that do not support combustion. The protective and fixing layer was made from a mixture of an organic silicon compound with a cold curing catalyst and a mineral filler with a dispersion of ≤ 0.6 mm. The protective-fixing layer was poured directly into the case with the installed charge. Tested according to ISO 15779, the model fire is a 500×500 mm square steel pan filled with n-heptane. Tested device according to the invention to protect conditionally sealed room with a volume of 125 m ³ . The mass of its fuel charge was 5 kg, the hull diameter was 173 mm. Operating time 130±4 s. The model fire was successfully extinguished. There is no afterburning of gases when the device is stopped.

Example 2

In the test device, an aerosol-forming charge and a protective-fastening layer were used as in example 1. The test was carried out according to ISO 15779, model fires were 5 cylindrical thick-walled containers with an internal diameter of 80 mm, filled with n-heptane and installed in a room. A device according to the invention was tested to protect a conditionally sealed room with a volume of 10 m ³ , the mass of the fuel charge was 0.4 kg, the diameter of the generator case was 101 mm. Working time 46±4s. Model fires were successfully extinguished. There is no afterburning of gases when the device is stopped.

As the test results show, the proposed design ensures stable operation of the device in protected rooms of various, including large, volumes without afterburning of gases flowing from the nozzles of the device at the final stage of its operation.

Claims (4)

1. A device for volumetric aerosol fire extinguishing, containing a body equipped with a bottom and a nozzle cover, an aerosol-forming charge made in the form of a channelless checker and fixed inside the body with a protective and fastening layer from the side surface, an afterburner chamber formed inside the body, a launch unit installed in cover, and an ejector nozzle connected to the body, while in the central part of the end surface of the charge from the bottom side there is a cavity filled with a flame retardant composition, characterized in that the nozzle cover is equipped with nozzles with a critical section and thermal protection on the inside, the nozzles are made in such a way that that pass through the heat shield lid and protrude outward from the outer surface of the lid. 2. The device according to claim 1, characterized in that a mixture of an organosilicon compound with a cold curing catalyst and a mineral filler is used as a protective and fixing layer. 3. The device according to claim 1, characterized in that the checker is made of a composition with a negative oxygen balance, and acidic potassium carbonate or azo compounds, or sulfonylhydrazines, or nitroazo compounds, or acid azides, or other endothermic compounds that emit during decomposition of water vapor and other non-combustible gases. 4. The device according to claim 1, characterized in that the cavity in the central part of the end surface of the charge from the bottom side is made cylindrical or conical.

Images