RU2230585C1 - Fire-extinguishing installation for extinguishing fire at elevated locations (variants) - Google Patents

Abstract

FIELD: fire-fighting equipment and technology, particularly for extinguishing fires at elevated locations.

SUBSTANCE: installation has two small displacing vessels having volume of 0.1 m³, which are self-filled from main container. Displacing vessels are emptied alternately by pressurizing thereof performed by gunpowder gas generators based on nitroglycerine gunpowder. Gas generators are located in rotary head of turret head type, which provides feeding heated gas into displacing vessels. Main pipeline comprises check valve for medium feeding. Displacing vessels have valves for residual pressure release into main container. Turret includes has gunpowder charge with glazed ends.

EFFECT: possibility of fire-extinguishing substance elevation to high locations (up to 500 m) and, as a result, reduced cost, operational safety due to compensation of vessel damage by means of main container, prevention of reaction effect following accidental charge ignition due to opening of gunpowder charge from both ends thereof.

5 cl, 8 dwg

Description

The invention relates to techniques and technologies used in extinguishing fires to raise extinguishing mixtures to great heights.

A known installation for extinguishing fires containing centrifugal high pressure pumps mounted on fire engines.

However, their service life is insignificant due to the high requirements for cleaning the feed medium and cavitation of the flow, destroying the pump blades, resulting from high rotation speeds. In addition, the cost of such a pump is quite high, and the domestic industry does not produce them due to the high requirements of assembly and operation (data from the Uralpozhtehnika plant, Miass, Chelyabinsk region). Data on the use of a high-pressure fire pump is given as an example of operating a standard PM-40 centrifugal pump.

Known fire pump combined NTs PK-40-100-4-400, which allows you to raise the extinguishing mixture to a height of 400 meters, but it provides a flow rate of only 4 liters per second, which in most cases is very small to extinguish. Its dimensions and weight are very significant and amount to 0.5 m ³ and 90 kg [1].

Known schemes for supplying liquid media to a distance: knapsack fire extinguishers, piston pumps for spraying with pesticides in gardens, etc. Fire extinguishers are also known in which the medium is supplied using chemical gas generators.

However, all these tools use small containers and, as a result, small liquid reserves, since their small size prevents emergency situations leading to their destruction. Small sizes allow avoiding large mechanical stresses arising in the structure from boost pressure.

Known displacing system for supplying liquid media, used in rocket technology and containing installed in the tanks (main tanks) with fuel and oxidizer, powder gas generators for pressurization.

This system has not found wide application due to the high requirements for strength and tightness of large-sized tanks, has a limited service life (single use) and does not provide the supply of liquid medium to the required distance, in particular to a great height. In addition, its use is also limited by large heat losses in the “mirror” of the liquid [2].

The basis of the invention is the creation of such a fire extinguishing installation design, which would ensure the supply of extinguishing liquid to any desired height with the required costs, safety and reliability in operation, reduced requirements for the purity of the supplied liquid, and would also have simplicity of design and low cost.

The problem is solved in that in a fire extinguishing installation for any ignition heights containing a main container with a liquid medium, a powder gas generator, a pressurized container, and a device for discharging a liquid medium (for example, a fire hose), according to the invention, a displacement container connected by a gas duct is located in the main container with a powder gas generator mounted on the body of the main tank and equipped with an inlet valve connecting both tanks, a residual pressure relief valve in the main tank and a reverse a valve for connecting the displacement container to a liquid discharge device (for example, a fire hose), while the vitrified powder charge is located in the cell of the gas generator.

According to another embodiment, in a fire extinguishing installation for any ignition heights containing a main container with a liquid medium, a powder gas generator, a pressurized container, and a device for discharging a liquid medium (for example, a fire hose), according to the invention, there is a displacement container in the main container connected by a gas duct to the powder a gas generator installed on the body of the main tank and equipped with an inlet valve connecting both tanks, a residual pressure relief valve in the main tank and a check valve for connecting the pressure of the displacing tank with a device for discharging a liquid medium (for example, a fire hose), while the vitrified powder charges are located in the cells of the turret located in the gas generator and mounted on the main body body.

According to another embodiment, in a fire extinguishing installation for any ignition heights comprising a main container with a liquid medium, a powder gas generator, a pressurized container, and a liquid discharge device (for example, a fire hose) according to the invention, at least two pressure vessels are located in the main container, each of which is connected by a gas duct to a powder gas generator and is equipped with an inlet valve connecting the displacing tank with the main one, a residual pressure relief valve in the main tank and a check valve nom for connecting the displacement container with a device for discharging a liquid medium (for example, a fire hose), while the vitrified powder charges are located in the cells of the turret located in the gas generator and installed on the body of the main container.

According to another embodiment, in a fire extinguishing installation for any ignition heights, mainly stationary for high-altitude objects, containing a main container with a liquid medium, a powder gas generator, a pressurized container, and a device for discharging a liquid medium (for example, a pipeline), according to the invention, at least at least two pressure vessels, each of which is connected by a gas duct to the powder gas generator and is equipped with an inlet valve connecting the pressure vessel to the main one, the relief valve remains pressure in the main tank and a check valve for connecting the displacing tank with a device for discharging a liquid medium (for example, a pipeline), while the vitrified powder charges are located in the cells of the turret located in the gas generator and installed on the body of the main tank, and the device for discharging a liquid medium ( for example, a pipeline) is connected to a trunk pipeline located on the wall of a high-rise object and equipped with bends made at the technological levels of the object.

The difference of the installation is also that a floating body is located in the displacement container, whose thermal conductivity is 10 ... 100 times less than the working fluid.

The location in the main tank of an additional one additional displacement tank connected to the powder gas generator makes it possible to create high excess pressures (up to 50 kg / cm ² ) due to the outflow of high temperature (up to 2200 ° C) gases. At the same time, one excess atmosphere is able to raise the liquid column by 10 m. The safety of the installation is ensured by the use of small containers (0.1 m ³ ) and, therefore, containers unloaded from high voltages that operate alternately on the main fluid supply line and are immersed in the liquid of the main container. The proposed design ensures safety in the event of an emergency rupture of the displacing tank into a liquid or the free volume of the main tank.

Cyclic filling of small containers occurs automatically from the main tank. The liquid filling device of the displacing tank is made in the form of an inlet valve, which is reliably locked on an elastic seal by the pressure of the medium created during the operation of the gas generator. This design does not require special water treatment. The design is simple and reliable, as it does not contain complex components, drives and assemblies.

A design feature is that the powder charges used in gas generators are vitrified on both sides and cannot be destroyed by external pressure. Powder charges are placed in such a way that they are open on both sides, which avoids the reactive effect during unauthorized commissioning of gas generators.

The use of a main pipeline located on the wall of a high-rise object and equipped with bends made at the technological levels of the object allows for the supply of liquid medium to the fire extinguishing site, and fulfilling the operating conditions of the main pipeline with a pre-filled liquid medium ensures more efficient use of the fire extinguishing installation. A feature of the use of the main pipeline as an element of the fire extinguishing installation is that the main pipeline must have the necessary strength in order to withstand the working pressure of the liquid medium created by the fire extinguishing installation.

The invention is illustrated in the drawing, where figure 1 shows the construction of the installation in section; figure 2 is a view of the cell with a charge (section AA of figure 1); figure 3 is a view along BB of figure 2; figure 4 shows the construction of the installation in the context of another embodiment; figure 5 - the location of the charges in the turret (section bb In figure 4, figure 8); figure 6 is a section DD DD figure 5; in Fig.7 is a section GG of Fig.4, Fig.8; on Fig - shows the design of the installation is mainly stationary for high-rise objects.

The fire extinguishing installation contains a main tank 1 with a liquid medium 2 and a displacement tank 3 located in the main tank and connected to it by an inlet valve 4. A powder generator 5 is connected to the body of the main tank 1, connected to the displacement tank 3 by a gas duct 6 for supplying hot gases to the displacement capacity. The displacing tank 3 is equipped with a residual pressure relief valve 7 in the main tank and a check valve 8 for connecting to a liquid discharge device (for example, a fire hose) 9. A floating body 10 is located in the displacing tank, whose thermal conductivity is less than 10 compared to the working fluid. ..100 times. In the cell 11 of the gas generator placed a powder charge 12, vitrified 13 on both sides.

Installation works as follows.

The gas generator is triggered by an external command, and the powder gases through the gas duct 6 enter the displacement tank 3. The pressure of the inlet valve 4 is pressed along the perimeter to the seal, and the liquid begins to be displaced through the check valve 8 into the device for discharging a liquid medium (for example, a fire hose) 9. After what triggers the residual pressure relief valve 7, bleeding gas into the liquid of the main tank 1. The previously displaced liquid is held in the device for discharging the liquid medium 9 by the check valve 8. The equalized pressure allows opening inlet valve 4 and run a new portion of liquid into the displacement container 3. After loading the powder charge 12 into the cell 11 of the gas generator 5, the installation is again ready for operation. A gas generator with a powder charge based on nitroglycerin powders having a high calorific value (about 800-900 kcal / kg) is used to pressurize the displacement tank. In order to reduce heat loss in the “mirror” of the liquid, the surface of the working fluid and the hot gas stream separates the floating body 10 from a material with relatively low (compared to the working fluid) thermal conductivity, for example, from steel.

According to another embodiment, the fire extinguishing installation comprises a main container 1 with a liquid medium 2 and a displacement container 3 located in the main container and connected to it by an inlet valve 4. A powder gas generator 5 is fixed to the main container body 1 and connected to the displacement container 3 by a gas duct 6 for supplying hot gases into the displacement tank. The displacing tank 3 is equipped with a residual pressure relief valve 7 in the main tank and a check valve 8 for connecting to a liquid discharge device (for example, a fire hose) 9. A floating body 10 is located in the displacing tank, whose thermal conductivity is less than 10 compared to the working fluid. ..100 times. A turret 15 is mounted on the axis 14 in the gas generator, in each of the cells 16 of which a powder charge 12 is placed, vitrified 13 on both sides.

According to another embodiment, at least two or more displacement containers 3 are located in the main tank 1 of the fire extinguishing system, each of which is connected by a gas duct 6 to a gas generator 5. Each of the powder charges 12 is vitrified 13 on both sides and placed in the cell 16 of the turret 15 installed on the axis 14 in the gas generator 5.

According to another embodiment, the fire extinguishing installation, mainly stationary for high-rise buildings, contains a main tank 1 with a liquid medium 2 and a displacement tank 3 located in the main tank and connected to it by an inlet valve 4. A powder gas generator 5 is fixed to the main tank 1 body and connected to the displacement tank 3 gas duct 6 for supplying hot gases to the displacement container. The displacing tank 3 is equipped with a residual pressure relief valve 7 in the main tank and a check valve 8 for connecting to a liquid discharge device (for example, a pipeline) 9 and a main pipe 17 located on the wall of a high-rise building 18 and equipped with taps made at the technological levels of the building 18 A floating body 10 is located in the displacement container, the thermal conductivity of which is 10 ... 100 times less than that of the working fluid.

Installation works as follows.

One of the cells of the turret 15 coincides with the channel of the gas duct 6, communicating with the displacement container 3. In this case, the opening of the cell open on the other side is muffled. The gas generator is triggered, and the powder gases enter the displacement container 3. By pressure, the inlet valve 4 is pressed around the perimeter to the seal, and the liquid begins to be displaced through the check valve 8 into the liquid discharge device 9. When the cycle is repeated, the turret 15 rotates by one cell. The previously displaced liquid is held in the device for discharging the liquid medium 9 by a check valve 8. The residual pressure relief valve 7 is activated, bleeding gas into the liquid of the main tank 1. The equalized pressure allows the inlet valve 4 to open and a new portion of liquid to be launched into the displacement tank 3. After which the cycle repeats. A gas generator with a powder charge based on nitroglycerin powders having a high calorific value (about 800-900 kcal / kg) is used to pressurize the displacement tank. In order to reduce heat loss in the “mirror” of the liquid, the surface of the working fluid and the hot gas stream separates the floating body 10 from a material with relatively low (compared to the working fluid) thermal conductivity, for example, from steel.

Data on the operation of the standard PM-40 high-pressure pump (according to the fire department of the city of Chelyabinsk).

1. Pumps allow a maximum life of five years.

2. The average service life is 1 year 7 months for the PM-40 pumps.

3. Pumps require 30-40 repairs per year.

4. The cost of spare parts alone is 3,000 rubles for one repair.

5. Provide water supply to a height of not more than 20 meters.

6. Fire hoses withstand pressure up to 250 kg / cm ² .

Industrial applicability

The proposed displacement scheme for supplying liquid media can have a wide range of applications for extinguishing fires at various heights (up to 500 m). Simple enough to be implemented constructively.

It is also suitable for industrial use in extinguishing forest fires from clearings and forest roads, since due to high pressures it makes it possible to supply a liquid medium at an angle over considerable distances (up to 200 m) and due to the fine atomization of liquid particles at such distances to increase their heat-absorbing ability.

A similar installation is applicable for pollination of farmland from roads adjacent to them and at the same time is safe during operation.

Sources of information

1. 621.01 D446 Dynamics of machines and structures. Thematic collection of scientific papers. - Chelyabinsk, 1988, p. 32. Zaykov M.S., Osipov U.N., Tarasov S.I., Chernobrivets M.G. A method of reducing pressure in pneumatic actuators pressurized by a gas generator with quick-burning fuel.

2. V.A. Makhin. Liquid rocket engines. - M.: House of Technology, 1961, p. 525.

Claims (5)

1. Fire extinguishing installation for any ignition heights, comprising a main container with a liquid medium, a powder gas generator, a pressurized container and a device for discharging a liquid medium (for example, a fire hose), characterized in that a displacement container is connected in the main container, connected by a gas duct to the powder gas generator, mounted on the body of the main tank, and equipped with an inlet valve connecting both tanks, a residual pressure relief valve in the main tank and a check valve for connecting the pressure th container with a device for the release of liquid medium (for example, a fire hose), while the vitrified powder charge is located in the cell of the gas generator. 2. Installation according to claim 1, characterized in that the vitrified powder charges are located in the cells of the turret located in the gas generator and mounted on the main body. 3. A fire extinguishing installation for any ignition heights, comprising a main container with a liquid medium, a powder gas generator, a pressurized container and a device for discharging a liquid medium (for example, a fire hose), characterized in that at least two displacement containers are located in the main container, each of which is connected by a gas duct to a powder gas generator and is equipped with an inlet valve connecting the displacement container to the main one, a residual pressure relief valve into the main tank, and a check valve for connecting a displacement container with a device for discharging a liquid medium (for example, a fire hose), while vitrified powder charges are located in the cells of the turret located in the gas generator and mounted on the body of the main tank. 4. Fire extinguishing installation for any ignition heights, mainly stationary for high-altitude objects, containing a main tank with a liquid medium, a powder gas generator, a pressurized tank and a device for discharging a liquid medium (for example, a pipeline), characterized in that at least , two pressure vessels, each of which is connected by a gas duct to the powder gas generator and is equipped with an inlet valve connecting the pressure vessel to the main, residual pressure relief valve in the main oval tank and a check valve for connecting the displacing tank with a device for discharging a liquid medium (for example, a pipeline), while the vitrified powder charges are located in the cells of the turret located in the gas generator and installed on the body of the main container, and a device for supplying a liquid medium (for example, a pipeline ) is connected to the main pipeline located on the wall of a high-rise object and equipped with bends made at the technological levels of the object. 5. Installation according to claim 1, or 3, or 4, characterized in that a floating body is located in the displacement container, whose thermal conductivity is 10–100 times less than that of the working fluid.

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