RU62020U1 - VOLUME FIRE EXTINGUISHING DEVICE - Google Patents

Abstract

The utility model relates to fire fighting equipment, namely to aerosol gas generators and is intended for volume extinguishing of class B and subclass A2 fires in sealed and conditionally sealed volumes of small-sized equipment and apparatus: for example, distribution cabinets, safes, televisions, computers, etc.

The technical result when using the proposed device is the operational extinguishing of fires in small confined volumes, providing optimal conditions for the release of aerosol and distribution of aerosol jets in the protected volume, as well as resistance to vibration loads.

The specified technical result is achieved in that the device for volumetric fire extinguishing includes a casing in the form of a glass with a lid and exhaust openings, an aerosol forming charge installed in the casing, an initiation means and a gas cooler, with a gas cooler between the lid and the charge, characterized in that the glass is equipped with a flange, the outlet holes are made in the form of an annular channel formed by the gap between the flange and the housing cover, with the ratio of the depth of the annular channel to its height ranging from 1.0 to 2.5, When this annular passage is blocked by a membrane. 11 C.p.F., 2 ill.

Description

The utility model relates to fire fighting equipment, namely to aerosol gas generators and is intended for volume extinguishing of class B and subclass A2 fires in sealed and conditionally sealed volumes of small-sized equipment and apparatus: for example, distribution cabinets, safes, televisions, computers, etc.

A device for volumetric fire extinguishing and a smoke-generating composition is known (RF patent No. 2046614, Cl. A 62 C 37 \ 00, publ. 1995). This device can be used not only in a fire extinguishing system, but also independently, as an individual fire extinguisher. The device contains extinguishing agents, made in the form of a housing with an outlet, a charge of a smoke-generating composition is placed in the housing. Means for detecting tanning, means for connecting and activating fire extinguishing devices are made in the form of a fire wire. The reasons that impede the use of the known device include the uncontrolled temperature of the produced aerosol jets and their distribution in the protected volume.

A device is known that generates gas-aerosol combustion inhibitors (RF patent No. 2136338, class A 62 C 13/22, publ. 1999). This device contains a housing with a cover, inside the housing there is a start device, a cooling unit and a pyrotechnic bomb generating gas-aerosol combustion inhibitor. The shell of the body is filled with a heat-protective layer made of gypsum. And the outlet

distributed around the periphery of the lid, rigidly connected with the shell. The disadvantages that prevent the use of this device include the large size and complexity of the design, since the device is designed to extinguish fires inside large volumes.

By the set of essential features and the achieved result, the closest to the claimed device is the invention according to the patent of the Russian Federation No. 2136338, which is selected as a prototype.

The task to which the proposed utility model is directed is to provide optimal conditions for extinguishing a fire source within the protected volume of a small-sized object.

The technical result when using the proposed device is the operational extinguishing of fires in small confined volumes, providing optimal conditions for the release of aerosol and distribution of aerosol jets in the protected volume, as well as resistance to vibration loads.

Optimum conditions, characterized by a decrease in the time of aerosol release and the distribution of jets within the protected object of small volume, are provided:

- a housing made in the form of a glass with a flange;

- a gap in the form of an annular channel formed between the surface of the flange and the surface of the cover;

- a certain ratio of the depth (L) of the channel to its height (N).

The presence of a gas cooler in combination with other essential features ensures the efficiency of aerosol cooling without additional structural elements and without increasing the overall dimensions of the devices.

The specified technical result is achieved in that the device for volumetric fire extinguishing, comprising a case in the form of a glass with a cap, exhaust and openings, an aerosol-forming charge installed inside the body, initiating means and a gas cooler, with a gas cooler between the cover and the charge, characterized in that the glass is equipped with a flange , the outlet is made in the form of an annular channel formed by the gap between the flange and the housing cover, with the ratio of the depth of the annular channel to its height ranging from 1.0 to 2.5, while the gas cooler is placed between the cover and the charge.

Improving the reliability of the device after transportation is ensured by the fact that the gas cooler is placed between the gaskets and made granular, and the aerosol-forming charge is preloaded using a Belleville spring.

The implementation of the membrane in the form of a metal mesh or perforated sheet contributes to resistance to vibration.

The execution of the means of initiation in the form of a fire-retardant cord provides an additional possibility of fire detection.

Preferably, the curved placement of the flame-retardant cord inside the housing, which eliminates the possibility of the formation of a direct channel through which an aerosol jet with an increased temperature could break through.

Manufacturability and adaptation to the place of operation is due to the fact that the flame-retardant cord can be led outside the housing through the lid, or through the bottom of the glass, or through an annular gap.

It is preferable to make the output node of the flame-retardant cord in the form of a sleeve.

The flame-retardant cord, brought outside the housing, can be provided with an additional coating, for example, a thermosensitive composition, which contributes to the rapid detection of the source of ignition.

Electric start is carried out through an electroactivator (not shown in the drawing), located directly near the aerosol-forming charge. The combined implementation of the initiation means (flame wire and electric start) increases the reliability of the device

The design of the proposed device is illustrated by drawings:

- figure 1 presents a section of a device for detecting and extinguishing a fire;

- figure 2 presents a top view.

The proposed device is structurally a housing (1) (a flat cylindrical box, for example, with a diameter of 40 mm, a height of 40 mm and a diameter of the lid of 0.5 mm).

The body is made in the form of a glass with a flange - 2. An aerosol-forming charge is placed in the glass - 4, a cover - 3, installed through a gap covered by a membrane - 7, with the formation of an annular channel for the release of aerosol. When the ratio of the depth (L) of the channel to its height (N) in the range from 1.0 to 2.5.

The gas cooler - 5, is laid in the housing 1 through the gaskets 8. The flame-retardant cord 6 is fixed on the charge 4 and is discharged through the annular channel closed by the membrane 7 and through the sleeve 9. The part of the cord 6 brought out of the housing 1 has an additional coating 10, for example heat sensitive paste.

Materials used in the manufacture of the device:

- aerosol-forming element of the brand SEPT, manufactured according to TU 4854-019-04973366-01;

- a fire-resistant cord made in accordance with TU 7275-001-51953776-00;

- thermosensitive composition 4 × 3-21 according to TU 6-03-408-80.

For each type of test, 3 devices were manufactured in accordance with each example. All samples were triggered autonomously when an ambient temperature of approximately 180 ° C was reached or when a flame hit directly on the igniter. The results are presented in the table.

The device with the housing (1) by means of the cover (3) is mounted inside the protected volume. A heat pulse is transmitted through a fire-resistant cord (6) to an aerosol-forming charge (4) after ignition of its working surfaces, a fire-extinguishing aerosol is released that enters the protected volume through the membrane (7) of the annular channel of a certain ratio of the channel depth to its height.

The fire extinguishing ability of the devices was determined in a special model cabinet. Cabinet dimensions: width - 600, height - 500, depth - 400 mm, volume - 120 l., A rectangular hole 280 × 600 mm in size was cut out on the front side of the cabinet. A fire extinguisher with openings in the housing facing the protected volume was secured by a lid on the upper surface inside the cabinet. A tissue flap measuring 30 × 30 cm soaked in A-76 gasoline in an amount of 27 ml was placed at the bottom of the cabinet.

The vaporized gasoline was set on fire, the heat pulse was transmitted to the fire-resistant cord, from which

device triggering. The positive result of the test was the fact of the complete extinguishing of the model fire site.

Determination of the stability of the proposed device to transport vibroloads was carried out according to mode 4 in accordance with GOST V25147-82 and OST 84-1855-80. The duration of the vibration loads was 0.5 ... 1.0 hour with a vibration frequency of 7.5 Hz.

The test results showed that the proposed device with parameters corresponding to examples No. 1, 2 and 3, withstood the specified loads without damage, and when tested to determine the fire extinguishing ability, it provided complete extinction of the model fire center (+). When tested under similar conditions, the device according to the prototype of quenching was not observed in 2 cases out of 3 experiments.

The tests carried out confirmed that the proposed device is aimed at solving the problem, and when it is used, optimal conditions for the release of aerosol and the distribution of aerosol jets in the protected volume are provided, while operability remains after exposure to vibration loads.

Thus, the proposed device meets all eligibility criteria under applicable law.

Table PARAMETER RELATIONSHIP AND TEST RESULTS Options Examples of specific performance of the device one 2 3 four 5 Prototype The ratio of the depth of the channel to its height L: H 1,0 1,5 2.5 0.5 3.0 Cooler mass, kg 0.02 0.02 0.02 0.02 0.02 Fire extinguishing ability before vibroloads +++ +++ +++ + - - + - - + Fire extinguishing ability after vibroloads +++ +++ +++ ** * ** - + - + + - "+" - complete extinguishing of the fire
“- *” - no extinguishing due to the low intensity of the extinguishing aerosol
“- **” - there is no extinguishing due to the high intensity of the extinguishing aerosol supply (the source breaks up and spreads in volume).

Claims (12)

1. A device for volumetric fire extinguishing, comprising a housing in the form of a glass with a cover and exhaust openings, an aerosol-forming charge installed inside the housing, initiating means and a gas cooler, with a gas cooler between the cover and the charge, characterized in that the glass is equipped with a flange, the exhaust openings are made in in the form of an annular channel formed by the gap between the flange and the housing cover, with a ratio of the depth of the annular channel to its height ranging from 1.0 to 2.5, while the annular channel is covered by a membrane. 2. The device according to claim 1, characterized in that the gas cooler is placed between the gaskets. 3. The device according to claim 1, characterized in that the gas cooler is made granular. 4. The device according to claim 1, characterized in that the aerosol-forming charge is preloaded using a Belleville spring. 5. The device according to claim 1, characterized in that the membrane is made in the form of a metal mesh or perforated sheet. 6. The device according to claim 1, characterized in that the means of initiation is made in the form of a flame-retardant cord. 7. The device according to claim 6, characterized in that the flame-retardant cord is placed curvilinearly inside the housing. 8. The device according to claim 6, characterized in that the flame-retardant cord is removed outside the housing through the lid, or through the bottom of the glass, or through an annular gap. 9. The device according to claim 6, characterized in that the output node of the flame-retardant cord is made in the form of a sleeve. 10. The device according to claim 6, characterized in that the flame-retardant cord brought outside the housing is provided with an additional coating. 11. The device according to claim 1, characterized in that the means of initiation is made in the form of an electric trigger. 12. The device according to claim 1, characterized in that the means of initiation is made in the form of a flame-retardant cord and an electric trigger.