RU28621U1 - Powder Extinguishing Module - Google Patents

Description

The utility model relates to fire fighting equipment, namely to automatic powder fire extinguishers, and is designed to extinguish fires in rooms for various purposes.

Known powder fire extinguisher (Pat. RF No. 2082472, IPC A62C35 / 10, publ. 1997), containing a metal body made of two parts, inside the sealed cavity of which is placed a fire extinguishing powder and a gas-generating substance in the form of poropps. A fire extinguisher fires itself from the heat of a fire.

The disadvantages of this fire extinguisher include the fact that when triggered, it does not ensure uniform distribution of the powder extinguishing composition over the protected area.

A device for extinguishing a fire (US Pat. RF No. 2405593, IPC A62C13 / 00, publ. 2001).

The disadvantages of this device include a large inertia in self-operation mode, because the self-firing unit is shaded from the convective column of the products of fire combustion by spraying parts.

In addition, this device has an insignificant horizontal penetration range of the Poropsp cloud.

The closest technical proposal to the claimed module of powder fire extinguishing for the combination of essential features is a device for extinguishing a fire according to patent No. 2405593, which is selected as a prototype.

The task of creating the proposed utility model is to reduce the inertia of the response in the self-operating mode, as well as to increase the penetration range of the powder cloud in the horizontal direction, for example, when fighting fires in warehouses with shelf storage of materials.

The powder fire extinguishing module is aimed at solving this problem. The essence of the proposed utility model is that this device has two response modes. The first mode is the electric start mode at the signal of fire detectors. The second mode is the self-operation mode - thermochemical. The thermochemical sensor is outside the module housing; it has a developed surface due to fins. A decrease in inertia and an increase in the penetration range is provided by the combination of all design features indicated in the utility model formula.

The strengthening of the specified technical result in the horizontal direction is observed in the presence of a hemispherical spray head with holes for raising poropps on the nolosphere.

The specified technical result when using the proposed utility model is achieved in that the powder fire extinguishing module comprising a housing with a fire extinguishing powder and an outlet nozzle with a membrane, an electric activator and a chamber for a gas-generating charge placed in the housing, characterized in that the module is additionally

equipped with a nagging sleeve, partially located in the corne coaxially to the chamber, and the guide sleeve is provided with a cap with the possibility of sealing, while the electroactivator is placed in the upper part of the cavity of the guide sleeve, and in its lower part there is a spring-loaded piston with a hammer and a capsule coaxially inserted into the chamber, with this heat-sensitive element is connected via a flame retardant cord to the upper part of the cavity of the guide sleeve.

The heat-sensitive element can be made in the form of a container with a gas-forming composition, and the flame-retardant cord is placed in the pipeline.

To increase heat transfer, the surface of the container is corrugated.

The output nozzle of the module housing is hermetically connected to the spray gun of a fire extinguishing powder, made in the form of a hemisphere with holes. This allows you to increase the penetration range of the powder cloud in the horizontal direction.

The achievement of the indicated technical result is ensured by using the entire set of essential features given in the formula of the utility model.

The proposed device is not known from available sources of information, and therefore meets the criterion of "novelty under current law.

The proposed utility model is illustrated by drawings.

In figure 1. presents a general view of the module of powder fire extinguishing (section). In figure 2. a sectional view of a powder fire extinguishing module equipped with a spray in the form of a hemisphere with holes.

The powder fire extinguishing module contains a housing 1 with a fire extinguishing powder 2, an electroactivator 3, located in the guide sleeve 4 in the upper part of its cavity 5, while the sleeve 4 is equipped with a sealed cover 6. Inside the housing 1, coaxially to the guide sleeve 4, a chamber 7 for a gas-generating charge is made 8 and a gas cooler 9. In the lower part of the cavity 5 of the guide sleeve 4, a piston 10 with a stripper 11 is placed through a spring 12, and a capsule 13 is filled coaxially with the striker 11 in the chamber 7. th part of the cavity 5 of the guide sleeve 4.

The heat-sensitive element 14 is made in the form of a container 16, with a gas-generating composition 17, and a flame-retardant cord 15 is placed in the pipeline 18.

The housing 1 is equipped with an outlet nozzle 19 and a membrane 20 for exiting the extinguishing powder 2, and the chamber 7 can be equipped with an aerator 24.

The output nozzles 19 of the housing 1 are hermetically connected to the atomizer 21 of the extinguishing powder 2, while the atomizer 21 is made in the form of a hemisphere 22 with holes 23.

The proposed device operates both in electric start mode and in self-operation mode.

The operation of the device in the electric start mode.

When an electrical impulse is applied to the electric activator 3, it also shuts off under the action of the generated gases, the piston 10 with the striker 11 moves downward compressing the spring 12 and punctures the capsule 13 located in the chamber 7. Under the influence of the high temperature of the gases, the capsule 13 occurs

ignition of the gas-generating composition 8, forming sensible gases passing through the cooler 9 are cooled to the required level and through the aerator 24 enter the module housing 1. Gases aerate the extinguishing powder 2 and inside the module housing 1 a gas-powder mixture of a certain density is created. When the gas pressure inside the housing 1 of the module rises to a certain level, the membrane 20 is destroyed and under the influence of excessive pressure the gas-powder mixture is ejected through the nozzles 19 into the protected volume.

The device operates in self-operating mode.

In the event of a fire in the room, the convective column of heated combustion products spreads upward and spreads over the ceiling of the room.

When the fire temperature acts on the container 16 with the gas-forming composition 17 due to heat transfer, the temperature is transferred from the container 16 to the gas-forming composition 17. When a certain temperature level is reached (for example, 70-90 0), chemical reaction of the gas-generating powder 17c by incineration occurs at any point of the container 16 elevated temperature (about 250-400 ° C) and gases. Under the influence of high temperature, the fire-resistant cord 15 is ignited, accompanied by the release of high () temperature and gases. Gases heated to high temperature through a flame-retardant cord 15, placed in the pipe 18, enter the upper part of the cavity 5 of the sleeve 4, ignite the electric activator 3 and, under the action of the generated gas pressure, the piston 10 with the striker 11 compresses the spring 12 and moves in the direction of the capsule 13 and punctures it. The capsule 13 is triggered and ignites the gas generating charge 8 in the chamber 7.

Further, the module operates as well as in the electric start mode.

The outlet nozzles 19 are hermetically connected to the atomizer 21 of the fire extinguishing powder 2, and the atomizer 21 is preferably filled in the form of a hemisphere 22 with holes 23, and the powder is ejected in a hemisphere, i.e. a cloud of clouds spread vertically and horizontally. This module design is recommended for wall mounting with placement of spray holes inside the volume of the protected room. In this case, the powder cloud spreads over a considerable distance in the horizontal direction, which is especially important for extinguishing fires during shelf storage of materials, as well as the presence of shading surfaces for vertical jets of powder.

Tests have shown that the proposed powder fire extinguishing module secures the solution of the task and at the same time meets the criterion of “industrial applicability but current legislation.

Claims (4)

1. A powder fire extinguishing module, comprising a housing with a fire extinguishing powder and an outlet nozzle with a membrane, an electric activator and a chamber for a gas-generating charge placed in the housing, characterized in that the module is additionally equipped with a guide sleeve, partially placed in the housing coaxially with the camera, and a guide sleeve with a cover with the possibility of sealing, while the electroactivator is located in the upper part of the cavity of the guide sleeve, and in its lower part there is a spring-loaded piston with a striker and aligned with it in the chamber A capsule is made, wherein the heat-sensitive element is connected by means of a fire-retardant cord to the upper part of the cavity of the guide sleeve. 2. The device according to claim 1, characterized in that the heat-sensitive element is made in the form of a container with a gas-forming composition, and the flame-retardant cord is placed in the pipeline. 3. The device according to claim 2, characterized in that the surface of the container is corrugated. 4. The device according to claim 1, characterized in that the output nozzles of the module housing are hermetically connected to the spray gun of a fire extinguishing powder, made in the form of a hemisphere with holes.