RU2721349C1 - Autonomous modular fire extinguishing unit - Google Patents

Abstract

FIELD: fire-fighting equipment.

SUBSTANCE: unit comprises module 1 equipped with shutoff-starting device 2 and fire detectors 3. Module 1 is heat-insulated housing 4. Inside housing 4 there arranged is at least one heating element 9. Besides, tube 10 is arranged inside the case to discharge overheated water 6 connected with shut-off and start-up device 2. Shut-off and starting device 2 is switched on remotely by a signal received from fire detectors 3. Shut-off and start-up device 2 is connected to pipeline 14 equipped with drencher sprayer 15 with hole 16. Upper inner surface of the housing of the module is equipped with ribs, the length of which in the direction of the lower surface is limited by an imaginary plane separating not less than 10 % of the internal volume of the housing of the module.

EFFECT: proposed invention relates to independent fire extinguishing unit.

9 cl, 1 dwg

Description

The invention relates to fire extinguishing techniques, and in particular to fire extinguishing installations used in extinguishing fires at industrial and other enterprises, as well as in commercial, public and other buildings, in passenger vehicles and other objects associated with finding a large number of civilians.

Stationary fire extinguishing systems are known that protect buildings and structures that are fire hazardous and constitute a complex system of tanks with extinguishing liquid, pipelines and pumping stations. Such systems are bulky and require constant monitoring of their condition and maintenance. In addition, in such systems, the power of the pumping stations is often not enough to provide an intensive supply of extinguishing agent to the protected area. The exit time of these systems to the operating mode is long, which prevents the operational extinguishing of the resulting tanning.

It is known that superheated water supplied under pressure, falling into the burning center, effectively extinguishes the fire. This is due to the fact that the interaction of water with the ambient air, having a temperature ^of over 130 C, the slurry forms an air-steam mist in the form of tiny droplets of water (less than 10 microns). This suspension displaces air oxygen from the fire zone. When the oxygen content reaches less than 16%, the combustion processes cease, however, for humans, such an oxygen content is not critical. So, for example, a volume of superheated water equal to 0.2 m ³ (200 liters) is enough to extinguish a fire on an area of about 300 m ² with a ceiling height of about 3 meters.

Practice has shown that with a small amount of superheated water, both burning solid materials and flammable liquids are effectively extinguished.

This effect is embodied in the solution used in RF patent No. 2030194 (prior. 06.10.1992, publ. 10.03.1995), which describes a device for extinguishing a fire with superheated water in which the water passing through the heat exchanger coil through the burner is heated. Water heated to a temperature higher than 120 ^{° C,} and then fed into the barrel to spray water. This device is successfully used in fire fighting, but its drawback is the significant preparation time for entering the operating mode. Another disadvantage is the need for running water to power the coil and the fuel tank for the burner.

The disadvantages are resolved in the patent of the Russian Federation No. 188570 (prior 26.11.2018, publ. 04.16.2019), which describes a fire extinguisher, which contains a thermally insulated casing, forming a container designed to be filled with fire extinguishing liquid. At least one heating element is installed inside the housing. Also inside the body is fixed a pipe for the output of extinguishing fluid, connected to the locking and starting device. At the same time, inside the casing in its upper part there is a level limiter made in the form of a pipe segment. Moreover, the lower section of the pipe segment is located in a plane separating at least 10% of the internal volume of the housing.

The main disadvantage of the described utility model is the insufficient volume to combat a large area fire. Also, the preparatory time that is necessary to bring the fire extinguisher into action, namely the time it takes to get to the fire extinguisher, can be significant. Sometimes a fire extinguisher may be inaccessible due to a fire.

The problem solved by the present invention is the creation of safe for people fast-working stationary fire extinguishing means.

The technical result achieved by the application of the present invention is the ability to use the installation in production, in particular with a large number of working people, in commercial premises, in places of possible large crowds of people along evacuation routes, for example, at sports and cultural events, in any passenger transport means.

The problem is solved, and the technical result is achieved in that the autonomous fire extinguishing installation modular contains at least one module equipped with a locking and starting device, and fire detectors. The module is a thermally insulated casing, forming a tank designed to fill with water no more than 90%. An emergency valve is installed in the wall of the module case. At least one heating element is placed inside the housing. Also, a tube for discharging superheated water is connected inside the housing, connected to a locking-starting device. In this case, the module is installed permanently. The locking and starting device is switched on remotely by a signal received from fire detectors. The locking-starting device is connected to a pipeline equipped with at least one deluge spray with an opening.

In a particular case, the inclusion of a fire extinguishing installation can be done automatically.

In a particular case, the inclusion of a fire extinguishing installation can be done manually.

Preferably, the upper inner surface of the module housing is provided with ridges in the form of ribs, the length of which in the direction of the lower surface is limited by an imaginary plane separating at least 10% of the internal volume of the module housing.

Preferably, at least one temperature sensor of the heated water is installed in the module case. Such a sensor may be, for example, a temperature sensor, a pressure sensor, or both sensors simultaneously. It is desirable that the sensor be equipped with an indicator displayed on the outer surface of the module housing.

The outlet openings provided with the deluge nozzles may have a different shape, for example a slotted or circular, formed by a washer with a sharp edge. Sprayers can be equipped with a hole made in the form of a Laval nozzle.

The implementation of a modular fire extinguishing installation allows you to arrange modules of various capacities and shapes in the most convenient places for fire protection. In this case, the module capacities are calculated based on the areas and volumes of the premises served. Modules can be piped together. Modules can be located in places difficult to access for people, which eliminates the possibility of vandal exposure to humans.

The module, which is a thermally insulated housing, having the shape most suitable for placement in the served room, forms a container designed to be filled with water. Moreover, to ensure guaranteed safety, the tank should be filled with water no more than 90%.

This is facilitated by the implementation of the upper inner surface of the module casing with protrusions in the form of ribs, the length of which in the direction of the lower surface is limited by an imaginary plane separating at least 10% of the internal volume of the module casing. The proposed solution to the implementation of the inner surface of the module housing allows you to guarantee the formation of air bubbles, the total volume of which will be about 10% of the internal volume of the module housing.

The safety valve installed in the wall of the module housing also contributes to increased safety.

The stationary installation of the module allows you to place a heating element inside the housing that is connected to a supplied power source.

At the same time, the autonomy of the installation lies in the ability to be in a ready state for at least six hours, after reaching the maximum temperature of the heated water, in the event of a power outage.

Also, autonomy lies in the ability to automatically turn on a fire extinguishing installation by a signal received from fire detectors.

However, it is possible to turn on the fire extinguishing installation manually, for example, from a button installed in the driver's cab of the vehicle.

The readiness of the fire extinguishing installation for operation can be determined by the sensor of the state of the heated water. Such a sensor can be, for example, a temperature sensor, a pressure sensor, or both sensors simultaneously equipped with an indicator displayed on the external surface of the module case. This allows you to control the installation, increasing the safety of its operation.

The fact that the locking and starting device, switched on remotely by a signal received from fire detectors, is connected to a pipeline equipped with at least one deluge spray gun with a hole, it makes it possible to bring the fire extinguishing installation into operation almost immediately after a situation that could lead to the fire.

Moreover, the presence of deluge sprayers with outlet openings of various shapes and purposes allows you to set various methods of exposure to fire. So, for example, sprayers equipped with a slit hole are able to install a steam-water vertical curtain, cutting off the fire and, thus, allowing people who enter the combustion zone to leave it.

 Spray guns equipped with a hole formed by a sharp-edged washer make it possible to create a steam-water cloud covering the fire source, displacing oxygen from the combustion zone and, thereby, stopping the fire.

Sprayers equipped with an opening made in the form of a Laval nozzle are capable of delivering a steam-water mixture over relatively long distances, which allows them to be used to extinguish fires located relatively far from the installed pipeline.

In the following, the claimed invention is illustrated by a detailed description of a specific but not limiting present solution, an example of its implementation and the attached drawing, which schematically shows an autonomous modular fire extinguishing installation.

The autonomous modular fire extinguishing installation contains at least one module 1, equipped with a locking and starting device 2, and fire detectors 3. Module 1 is a heat-insulated housing 4, forming a tank 5, designed to fill water 6 by no more than 90%. An emergency valve 8 is installed in the wall 7 of the housing 4 of module 1. Inside the housing 4, at least one heating element 9 is placed. Also, a tube 10 for discharging superheated water 6 is connected inside the housing and connected to the locking-starting device 2.

The upper inner surface of the housing 4 of the module 1 in the specific example is provided with protrusions 11 in the form of ribs, the length of which in the direction of the lower surface is limited by an imaginary plane 12 (shown conditionally), separating at least 10% of the internal volume of the tank 5 of the housing 4 of the module 1.

The locking and starting device 2 is switched on remotely by the signal received from the fire detectors 3. In the autonomous modular fire extinguishing installation, the possibility of manual remote activation is provided, for which there is a manual activation button 13.

The locking-starting device 2 is connected to a pipe 14 provided with at least one deluge atomizer 15 with an opening 16. The holes 16 that are provided with the deluge sprayers 15 may have a different shape. For example, the atomizer 15 may be provided with a slotted hole, a round, formed by a washer with a sharp edge. Sprayers can be equipped with a hole made in the form of a Laval nozzle.

A sensor 17 for the state of heated water 6 is installed in the housing 4 of module 1. In a specific example, this is a temperature sensor, however, both a pressure sensor and both sensors can be used simultaneously. The sensor 17 is equipped with an indicator 18, displayed on the outer surface of the housing 4 of the module 1.

The housing 4 of the module 1 has a filler hole 19, provided with a flange 20, on which the cap 21 of the filler hole 19 is mounted and fastened.

The heating elements 9 through an electrical switch 22 are connected to the power supply. Both 220 volt power and 380 volt power can be used.

Installation fire extinguishing autonomous modular works as follows. Module 1 is installed in a pre-selected location. The capacity 5 of the housing 4 of the module 1 through the filling hole 19 is filled with water 6. It is taken into account that the volume of the filled water 6 should not exceed 90% of the capacity 5. In the case of using module 1 with the protrusions 11 in the form of ribs, this condition is satisfied automatically, so how to fill in more than 90% is impossible due to the air bubble forming.

Then, on the flange 20 of the filler hole 19, a cover 21 is installed with a locking and starting device 2 installed in it, connected to a tube 10 for outputting superheated water 6, and an electric switch 22 connected to the heating elements 9 and connectors for connecting external power.

The locking-starting device 2 is connected either directly to the deluge atomizer 15, or to a pipe 14, on which the deluge atomizer 15 can be placed with holes 16 of various shapes depending on the intended use. For control, the locking-starting device 2 is connected via a signal network to fire detectors 3. It is also possible to install a manual start button 13 in the signal network.

After placing all the elements of the fire extinguishing installation, external power is supplied to the electric switch 22, and after turning it on, power is supplied to the heating elements 9. Water heating 6 is controlled according to the data on indicator 18 received from the heated water state sensor 17. It is also possible to connect the sensor 17 to the electric switch 22 and upon reaching a predetermined parameter, such as temperature, stop supplying power to the heating elements 9.

In order to increase the safety of the fire extinguishing installation, an emergency valve 8 is installed on the wall 7 of the housing 4 of module 1.

The fire extinguishing installation is triggered when the fire detectors 3 respond to a situation that could lead to a fire, such as smoke, a rise in temperature, and send a signal to the locking and starting device 2, which opens the outlet of the superheated water 6 to the deluge sprayer 15, or to the pipeline 14. When superheated water exits from the deluge of the spray gun 15 with the hole 16, it is possible to obtain a different cloud shape depending on the shape of the hole 16. The holes 16 with which the deluge spray guns 15 are provided can have a different shape. For example, when using a sprayer 15 with a slit hole 16, it is possible to obtain a steam-water curtain that cuts people off from the fire. The hole 16, formed by a washer with a sharp edge, creates a dense circular vapor cloud, quickly knocking down the flame from the fire. Sprayers 15 may also be provided with a hole 16 made in the form of a Laval nozzle.

The proposed invention can be widely used not only for extinguishing fires at industrial and other enterprises, but also in commercial, public and other buildings.

Due to the possibility of performing an autonomous modular fire extinguishing installation of relatively small sizes, the invention can be applied in passenger vehicles and other facilities associated with finding a large number of civilians.

Claims (9)

1. The fire extinguishing installation is an autonomous modular, containing at least one module equipped with a locking and starting device, and fire detectors, while the module is a heat-insulated casing, forming a tank designed to fill water no more than 90%, in the wall of the module casing an emergency valve is installed, at least one heating element is placed inside the housing, and a tube for discharging superheated water is connected, connected to the locking and starting device, characterized in that the module is installed stationary, and the locking and starting device is switched on remotely by the signal received from fire detectors, and the locking and starting device is connected to a pipeline equipped with a deluge spray with a hole, while the upper inner surface of the module casing is provided with ribs whose length in the direction of the lower surface is limited by an imaginary plane separating at least 10% of the internal volume of the module casing. 2. Fire extinguishing installation autonomous modular according to claim 1, characterized in that the remote inclusion is automatic. 3. The fire extinguishing installation is autonomous modular according to claim 1, characterized in that the remote activation is manual. 4. The fire extinguishing installation autonomous modular according to claim 1, characterized in that at least one sensor of the state of the heated water is installed in the module casing. 5. The self-contained modular fire extinguishing installation according to claim 4, characterized in that a temperature sensor is installed in the module casing, equipped with an indicator displayed on the outer surface of the module casing. 6. The self-contained modular fire extinguishing installation according to claim 5, characterized in that a pressure sensor is installed in the module housing, equipped with an indicator displayed on the outer surface of the module housing. 7. Fire extinguishing installation autonomous modular according to claim 1, characterized in that the deluge sprayers are equipped with a slotted hole. 8. The autonomous fire extinguishing installation modular according to claim 1, characterized in that the deluge sprayers are provided with an opening formed by a washer with a sharp edge. 9. The self-contained modular fire extinguishing installation according to claim 1, characterized in that the deluge sprayers are provided with an opening made in the form of a Laval nozzle.

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