RU2725417C1 - Device extinguishing burning flammable and combustible liquids with a minimum boiling point over 40 °c - Google Patents

Abstract

FIELD: fire safety.SUBSTANCE: invention relates to fire equipment and can be used for fire extinguishing of flammable and combustible liquids arising in emergencies from various industrial equipment, fuel lines, cistern, tanks, reservoirs. Extinguishing device consists of an assembly of vertical channels with a specified ratio of the height of the vertical channel H, which is not filled with liquid, to its equivalent diameter and is equipped with a grid flame-splitting element. Assembly of vertical channels and mesh element are arranged in steel housing consisting of vertical and pyramidal parts with vertical and inclined walls installed along perimeter of assembly of vertical channels. Height of vertical walls is equal to height of channels. Inclined walls form a receiving reservoir made in the form of a truncated turned pyramid, located under the vertical channels assembly to direct the liquid into the hole of the inlet pipe of the hydraulic lock of the siphon structure placed directly under the bottom of the receiving container.EFFECT: improving quenching efficiency, optimizing metal consumption and improving operating characteristics of devices for quenching liquids with operating temperature T<0_8T, where T≥40 °C is minimum boiling point of liquid.3 cl

Description

The invention relates to fire fighting equipment and can be used to extinguish fires of flammable and combustible liquids in emergencies on various kinds of industrial equipment, fuel lines, tanks, tanks, tanks in which fluids with operating temperature T <0.8 T _bale , where T _bales ≥40 ° С - minimum boiling point of the liquid.

It is known (SU, copyright certificate 787046, publ. 12/25/1980) a device for self-extinguishing burning liquids, containing a container with pipes placed in it, the bases of which are parallel to the side walls of the container and installed along the entire cross section of the container. The height of each pipe "N", not filled with liquid at the maximum spill, and its effective diameter "d _eff " are determined from the ratio H> 12 _eff . In this case, the lower part of the pipes resting on the bottom of the tank is equipped with perforated holes for leveling the liquid level in the tank.

The disadvantages of this device are its high metal consumption and the uncertainty of the level of perforations, since with a low level of filling the tank with liquid between the vertical channels, natural convection and the continuation of the combustion process, which will have a focal character, can occur.

A device for self-extinguishing and preventing the ignition of combustible liquids is known (SU, copyright certificate 1463317, publ. 07.03.1989). The device contains a container in which, to increase the efficiency of extinguishing, pipes are located along its entire cross section, the walls of which are parallel to the walls of the container. At the same time, reflectors are installed along the perimeter of the upper cut of each pipe, the angle of deviation of which from the vertical walls of the pipe is determined from the ratio: d _ECV / N, where d _ECV is the equivalent pipe diameter; H - pipe height not filled with liquid. The length of the surface of the reflectors is l = 0.06N, and the lower pipe cut is located at a distance h≤0.25d _equiv from the bottom of the tank.

The disadvantages of this device is the difficulty of manufacturing and assembling the entire design of the device using reflectors installed in each vertical pipe. It is apparently possible to install such reflectors only in vertical pipes of a sufficiently large diameter. In addition, the presence of reflectors increases the surface of the device, on which, in particular, a burning stream of liquid falls. This in turn leads to the formation of a process of spraying a burning liquid and, consequently, the intensification of the combustion process near the upper part of the device. A significant drawback in the design of this device is also its high metal consumption, since the pipes almost completely fill the entire tank. Most strongly manifested in the lack of large volumes of spilled liquid, since the lower section of the pipe should be placed on h≤0,25d _ECI distance from the tank bottom.

It is known (RU, patent 2252804, publ. May 27, 2005) a device for self-extinguishing and preventing the ignition of flammable liquids. The device contains a metal container - a casing in which two main elements are installed to increase the extinguishing efficiency and improve operational characteristics. This is a horizontal layer of axisymmetric in cross section, vertically arranged channels (pipes) forming a cellular structure, and a flame-cutting layer formed by two layers of metal grids tightly adjacent to the lower part of the cellular structure. The distance between the grids does not exceed 10 mm. In this case, the device can be installed in containers of various sizes, as well as in pits and trays for collecting leaks of flammable liquids. Its vertical size does not depend on the depth of the tank (pit, tray). It was experimentally established that the assembly of vertical channels has the greatest fire extinguishing efficiency when the height H, which is not filled with liquid, corresponds to the condition H≥3d _ECV , where d _ECV is the equivalent diameter of the circular channel.

The main disadvantage of the device selected as the closest analogue is the uncertainty of the dependence of the height of the vertical channels not filled with liquid on the operating temperature and the boiling point of the liquid. In addition, mesh layers with cells smaller than 1 mm in size, located under the cellular structure of vertical channels (pipes), will quickly become dirty, which will lead to a decrease in the throughput of the grids and the efficiency of the device as a whole. When the grids are located under the mesh structure, the removal of the entire device is required to clean the grid layers.

The technical problem to be solved using the developed device is to expand the scope and range of extinguishing devices of burning flammable and combustible liquids

The technical result achieved by the implementation of the developed device consists in increasing the extinguishing efficiency, optimizing the metal consumption and improving the operational characteristics of the devices for extinguishing liquids with an operating temperature T <0.8 T _bales , where T _bales ≥40 ° C - the minimum boiling point of the liquid.

To achieve said technical result using the device proposed extinguishing burning flammable and combustible liquids with a minimum boiling point over 40 ° C, consisting of an assembly of vertical channels with a predetermined ratio of the height H of the vertical channel is not filled with liquid to its equivalent diameter H / d _eq ≥6 equipped with a mesh flame-cutting element, and the assembly of vertical channels and the mesh element are placed in a steel casing consisting of vertical and pyramidal parts with vertical and inclined walls installed along the perimeter of the assembly of vertical channels, while the height of the vertical walls is equal to the height of the channels, and the inclined walls, form a receiving tank, made in the form of a truncated inverted pyramid, located under the assembly of vertical channels for directing liquid into the hole of the inlet pipe of the siphon water seal, located directly under the bottom of the receiving tank.

The equivalent diameter of the vertical channel is determined by the density and surface tension of the liquid:

d _equiv ≥6.5 (δ / gρ) ^0.5 ;

d _equiv = 4F / P,

where δ is the coefficient of surface tension of the liquid;

g is the acceleration of gravity;

ρ is the fluid density;

F is the cross-sectional area of a channel of arbitrary shape;

P is the perimeter of the cross section of a channel of arbitrary shape.

The ratio of the height of the vertical channel H, not filled with liquid, to its equivalent diameter H / d _ek ≥6.

The flame-cutting mesh element is attached to the vertical walls of the assembly housing with a snug fit to the upper ends of the channels and a complete overlap of the cross section of the metal container and is a removable cartridge (flat frame) with two horizontal layers of mesh with cells, preferably 0.5-1.0 mm, placed preferably at a distance of 5-8 mm from each other.

The volume of the receiving device and the diameter of the inlet of the hydraulic seal are counted on the reception of the maximum second intake (flow) of liquid. The geometric parameters of the receiving device are determined by the dependencies:

h [S ₁ + (S ₁ S ₂ ) ^0.5 + S ₂ )] = 3q,

S ₂ = q / μ (2gh) ^0.5

where h is the height of the receiving device, m;

S ₁ - the area of the modular assembly of vertical channels, m ² ;

S ₂ - the area of the inlet of the water seal, m ² ;

q - maximum second inflow of a combustible liquid, m ³ / s;

μ = 0.64 - the coefficient of flow through the valve.

It is known that the process of free combustion of combustible and flammable liquids proceeds in the gas phase — the diffusion mode of combustion. In this case, the combustion zone is located at a certain distance from the burning surface of the liquid and the existence of a flame is possible only with naturally convective air flows that supply a sufficient amount of oxidizing agent to the combustion zone, as well as evaporation from the surface of the liquid created by the radiation of the flame and delivering fuel to the zone burning. It is possible to stop the combustion process by reducing the oxygen concentration in the environment to the limit values for the combustion process or by lowering the temperature of the burning surface of the liquid to values at which the evaporation process sharply decreases. In addition, the cessation of the combustion process can be achieved by reducing the intensity of naturally convective air flows that supply the oxidizing agent to the flame zone.

In the developed grid device of the flame-cutting element, due to the developed surface of heat exchange and friction, the temperature in the combustion zone and the rate of entry of the oxidizing agent into the combustion zone are reduced, which provides quenching in the volume of channels, since during the combustion of liquid vapor in vertical channels, the released volume of combustion products blocks the flow of oxidant into the combustion zone. Further cooling of the gas phase, a decrease in the rate of evaporation of the liquid and its cooling takes place in the assembly of the vertical channels and the receiving tank, and a water trap prevents the release of liquid vapor back to the receiving tank, which, in comparison with the known devices, provides effective quenching during jet liquid outflow, in which not all assembly channels are filled with combustion products, and expands the scope and range of devices for extinguishing burning liquids.

In the experiments performed, the temperature of the liquid at the outlet of the water seal did not exceed 30 ° C.

In one embodiment of the developed device for extinguishing liquids with an operating temperature T <0.8 T _bales , where T _bales ≥200 ° C is the minimum boiling point of the liquid, a horizontal tray can be used in the device, which acts as a water seal, adjacent to the lower cut channels. To ensure easy removal of the bulk of accidental spillage into the receptacle on the lower slice channel continuous perforation is formed in the form of semi-circular holes with a diameter d _{of holes.} Horizontal pallet, serving as a water seal, is a container bounded by the perimeter rim, whose height H ≥1,5d _{board holes.} This ensures the retention of the minimum amount of flammable or flammable liquid necessary to flood the vertical channels and achieve the effect of extinguishing the flame. In this embodiment, the ratio of the length of the vertical channel to its equivalent diameter should satisfy the ratio (H-H _side ) / d _ek ≥3.8.

The developed device in various implementations can be recommended for use at enterprises of the chemical and petrochemical industries, at sea, river, railway and air transport, nuclear and thermal power plants, in warehouses of fuels and lubricants, storage facilities for liquid fuels, that is, at facilities with a constant handling of flammable and flammable liquids.

The system for extinguishing combustible and flammable liquids can consist of several devices and can be installed in containers of various sizes placed directly under the equipment, or, when organizing directed discharge of liquids along sloping floors, in containers (pits, trays) at a certain distance from the equipment, and also in open tanks or reservoirs under a layer of liquid. When organizing the inclined surface of the floors, providing a directed drain of liquid in the direction of this tank, the area occupied by the extinguishing devices can be significantly reduced.

So, for example, a fire extinguishing system can be installed:

1. In the premises of oil refining industry enterprises under the equipment for processing or storage of fuels and lubricants; at overflow and refueling complexes in the areas of fueling and storage of fuels under appropriate equipment;

2. At power plants and transformer substations under oil transformers;

3. In open tanks or reservoirs under a layer of liquid, in which, if it ignites, the liquid is drained from the lower part of the tank to the reserve tank and, when the upper burning layer passes through the system of extinguishing devices, an effective suppression of the combustion process is achieved.

Claims (13)

1. Extinguishing device for burning flammable and combustible liquids with a minimum boiling point of more than 40 ° C, consisting of an assembly of vertical channels with a predetermined ratio of the height of the vertical channel H not filled with liquid, to its equivalent diameter, equipped with a mesh flame-cutting element, characterized in that the assembly vertical channels and the grid element are placed in a steel casing consisting of vertical and pyramidal parts with vertical and inclined walls installed along the perimeter of the assembly of vertical channels, the height of the vertical walls being equal to the height of the channels, and the inclined walls form a receiving tank made in the form of a truncated inverted pyramid located under the assembly of vertical channels for directing fluid into the opening of the inlet pipe of the siphon water trap, located directly under the bottom of the receiving tank, while the equivalent diameter of the vertical channel is set by the density and surface tension of the liquid according to the dependencies: d _equiv ≥6.5 (δ / gρ) ^0.5 ; d _equiv = 4F / P, where δ is the coefficient of surface tension of the liquid; g is the acceleration of gravity; ρ is the fluid density; F is the cross-sectional area of a channel of arbitrary shape; P is the perimeter of the cross section of a channel of arbitrary shape; the mesh element is attached to the vertical walls of the assembly body with a snug fit to the upper ends of the channels and a complete overlap of the cross section of the metal container. 2. The device according to claim 1, characterized in that the geometric dimensions of the device in the plan are set by the expected maximum fluid intake S = V / H, where V is the expected maximum fluid intake, m ³ / s; N is the height of the vertical channel, which is not filled with liquid, m, and the volume of the receiving device and the diameter of the inlet of the hydraulic lock are designed to receive the maximum second flow of liquid, the geometric parameters of the receiving device are given by the dependencies: h [S ₁ + (S ₁ S ₂ ) ^0.5 + S ₂ )] = 3q, S ₂ = q / μ (2gh) ^0.5 , where h is the height of the receiving device, m; S ₁ - the area of the modular assembly of vertical channels, m ² ; S ₂ - the area of the inlet of the water seal, m ² ; q - maximum second inflow of a combustible liquid, m ³ / s; μ = 0.64 - the coefficient of flow through the valve. 3. The device according to claim 1, characterized in that the grid element is a removable flat frame with two horizontal layers of grids with cells of 0.5-1.0 mm, placed at a distance of 5-8 mm from each other.