RU2553956C1 - Fire fighting system in vertical tanks - Google Patents

Abstract

FIELD: fire safety.SUBSTANCE: on telescopic hoist outside the tank a foam generator is fixedly installed and the hose is brought, which is connected to the supply pipeline and the tanks with the foaming agent and water. In the lower part the telescopic hoist mounted on the support is connected to the piston, which is in the cylinder. On the foundation the movement limiting device of the telescopic hoist is mounted. In the upper part of the links of the telescopic hoist there are seals and stoppers. To the cylinder with the piston and the telescopic hoist the air duct is brought for air supply, which is connected to the cylinders filled with compressed air. Outside the vertical steel tanks below the level of soil freezing two horizontal tanks of suitable capacity are mounted, one of which is filled with water and the other - with the foaming agent. The tanks are sealed and interconnected by the air-duct. At that the pipeline connecting the tank with the foaming agent with the supply pipeline has a metering device. The cylinder with compressed air is connected to the air duct and the tank for water and the foaming agent. The cylinder with compressed air is equipped with a pressure regulator and a crane-squib. In the upper part of the vertical steel tanks the sensors of pressure and temperature are mounted which are connected to the crane-squib and have an autonomous power supply system (e.g., batteries).EFFECT: increase in reliability of fire fighting of oil products in vertical steel tanks with any type of roof without human involvement.5 dwg

Description

The invention relates to fire-fighting equipment for automatic extinguishing of petroleum products in vertical steel tanks (PBC) with any type of roof.

A device is known for extinguishing a fire in an internal combustion engine, consisting of a housing with a mounting flange, a mesh, a spray gun, a pipe for supplying a foaming agent solution, a protective umbrella, a tight shutter cover, a traction with a tensioning device, a cover position lock, a latch restrictor cable and a manual backup cable drive (SU 978878, class А62С 3/00, publ. 07.12.1982).

This design is installed directly on the roof or wall of the tank. If the vapor-air mixture of petroleum products explodes, the device may be destroyed. In addition, the use of the device for extinguishing a fire requires the participation of a fire brigade, which is associated with a great risk to human life, and also significantly increases the start time of a fire extinguishing from the moment of fire, which leads to heating of the upper layer of oil products and significantly complicates the fire extinguishing.

The closest analogue (prototype) of the proposed fire extinguishing system is a device for supplying extinguishing foam into tanks with burning oil products according to the patent of the Russian Federation No. 2359723. The device is made with a telescoping telescoping tube, which is carried out using a chain transmission. A hook-shaped foam is attached to the upper part of the inner pipe, through which fire extinguishing foam is drained onto a burning surface.

This design when extinguishing a fire in a tank requires not only the direct participation of the fire brigade in extinguishing a fire, but its use poses a direct danger to the lives of people deploying the device near a burning tank with petroleum products. In addition, the area near the reservoir may be cluttered with reservoir structural elements flying up as a result of the explosion of the vapor-air mixture, or near the reservoir there may be a burning oil product spilled as a result of the destruction of the reservoir structural elements, which will make it impossible to deploy the device.

EFFECT: increased reliability of extinguishing a fire of oil products in vertical steel tanks with any type of roof without human intervention.

This is achieved by the fact that a foam generator is fixedly mounted on the telescopic elevator outside the tank and a sleeve is connected, which is connected to the supply pipe and reservoirs with a foaming agent and water. In the lower part, a telescopic elevator mounted on a support is connected to a piston, which is located in the cylinder. A telescopic boom limiter is installed on the foundation. In the upper part of the links of the telescopic lift there are seals and stoppers. An air pipe is connected to a cylinder with a piston and a telescopic elevator for supplying air, which is connected to cylinders filled with compressed air. Outside the RVS below the level of soil freezing, two horizontal reservoirs of appropriate capacity are installed, one of which is filled with water, and the other with a foaming agent. The tanks are sealed and interconnected by air. Moreover, the pipeline connecting the reservoir with the foaming agent to the inlet pipe has a dispenser. A can of compressed air is connected to the air duct and the water tank and the foaming agent. The compressed air cylinder is equipped with a pressure regulator and a pyrocartridge. In the upper part of the RVS, pressure and temperature sensors are installed, which are connected to the pyrocartridge crane and have an autonomous power supply system (for example, batteries).

Figure 1 shows a fire extinguishing system in standby mode; 2 - deployment fire extinguishing system, in FIG. 3 - fire extinguishing system in operation, FIG. 4 is a diagram of a foam generator, FIG. 5 is a diagram of a nozzle of a foam generator.

The fire extinguishing system in vertical tanks consists of a foundation 1, on which a telescopic lift movement restrictor 2, a support 3 with an axis and a cylinder with a piston 4 are rigidly fixed. A telescopic lift 5 with a foam generator 6 fixed on it is fixed to the axis of the support, a piston rod is attached to the lift 7 cylinder. Between the links of the telescopic lift there are seals 8 and stoppers 9. A hose for feeding the foam mixture 10 is connected to the foam generator, which is connected to the supply pipe 11. An air pipe 12 is connected to the cylinder and the telescopic lift.

Outside of the PBC, it is buried below the freezing ground, two horizontal reservoirs of appropriate capacity are installed, one of which is filled with water 13 and the other with foaming agent 14. The reservoirs are sealed and interconnected by a supply pipe 11, and the pipe connecting the tank to the blowing agent and the supply pipe has a dispenser 15. The can of compressed air 16 is connected by a pipe 17 to the air duct, a water tank and a foaming agent. The compressed air cylinder is equipped with a pressure regulator 18 and a pyro cartridge 19. In the upper part of the PBC 20 pressure and temperature sensors 21 are installed, which are connected to the pyro cartridge and have an autonomous power supply system (for example, batteries).

The generator 6 polydisperse high-fold foam consists of a housing 22 (Fig. 4 and 5), made in the form of a prismatic shell (for example a rectangular prism, the cross section of which is a square). On the one hand, a foam dispenser is attached to the housing 22, which is made in the form of at least one inlet pipe 24 with supporting 23 and network flanges (not shown in the drawing) vertically for connecting a foaming agent to the fire extinguishing system. At least two additional pipes 26 with plugs at both ends rigidly connected to it horizontally perpendicular to the inlet pipe 24 are arranged horizontally, the foam dispenser fitting into the inner contour of the housing 22, and the diameters of the internal cavities of the inlet 24 and the additional 26 pipelines are equal to each other, and the cavities themselves are interconnected. To the internal cavities of the inlet 24 and an additional 26 pipelines are connected from the side of the shell of the housing 22 and bends parallel to its axis: shortened 25, medium 27 and long 28, ending with nozzles 29 oriented to the guide mesh device 31.

The guide device 31 consists of three coaxial, coaxially arranged pyramidal shells in the form of generating grids: outer 36, intermediate 33 and inner 35. Each of the shells contains a wire frame of two bases in the form of a square and side edges of a truncated pyramidal surface. The outer shell 36 is attached with a large base to the housing 22, and its second smaller base 30 is at the same time a large base of the intermediate 33 of the shell with side ribs, and its smaller base 32 is at the same time a large base of the inner 35 of the shell with a smaller base 34. Generated grids in the form of truncated pyramidal surfaces are arranged in such a way that all their vertices lie on an axis coinciding with the axis of the housing, and the direction of the vertices of the outer 36 and inner 35 generating grids coincides, and the vertex is between original 33 of the generating grid is directed opposite to the vertices of the outer 36 and inner 35 of the generating grid, and towards the foam dispenser. The housing 22 is attached to the foam dispenser by means of fasteners 37.

Each of the nozzles 29 (Fig. 5) consists of a housing 38 with an inlet pipe 41 having an opening 40, an inlet cylinder chamber 46 coaxial with it, a swirl chamber 48 located coaxially with respect to the inlet chamber 46 and made in the form of a cylindrical cup 39, having at least three tangentially located openings 47 on the side surface, whose axes are located tangentially with respect to the swirl chamber 39, i.e. there is a one-channel tangential input.

Coaxial to the swirl chamber 48 is a nozzle insert 42 with an outer diameter D ₁ made of solid materials: tungsten carbide, ruby, sapphire. Three calibrated holes are made sequentially located and coaxial to each other and to the cylindrical surface of the swirl chamber 48 inside the insert: a conical hole 43 with a diameter D of the lower base of the truncated cone, a central cylindrical hole 44 with a diameter of d ₂ and an exit conical hole 45 with a diameter of d _{3 of the} lower base of the truncated cone . The diameter d _{2 of the} central cylindrical hole 44 of the nozzle insert 42 is equal to the diameter of the upper base of the truncated cone of the conical hole 43, and also the diameter d _{2 of the} central cylindrical hole of the nozzle insert is equal to the diameter of the upper base of the truncated cone of the conical hole 43 and the diameter of the upper base of the truncated exit cone tapered bore 45.

Inside the liner 42 there are three calibrated holes arranged in series and aligned with each other and the cylindrical surface of the swirl chamber: a conical hole with a diameter D of the lower base of the truncated cone, a central cylindrical hole 44 with a diameter of d ₂ and an exit conical hole 45 with a diameter of d _{3 of the} lower base of the truncated cone, the diameter d _{2 of the} Central cylindrical hole of the nozzle insert is equal to the diameter of the upper base of the truncated cone of the conical hole 43 and the diameter of the upper th base of the truncated cone of the outlet conical hole 45.

For the operation of the nozzle in optimal mode, the following ratios of its parameters are provided:

the ratio of the diameter d _{3 of the} outlet conical hole 45 of the nozzle insert 42 to the diameter d _{2 of the} central cylindrical hole 44 lies in the optimal range of values: d ₃ / d ₂ = 1.5 ÷ 2.5;

the ratio of the outer diameter D _{1 of the} nozzle insert 42 to the diameter D of the lower base of the truncated cone of the conical hole 43 of the insert 42 lies in the optimal range of values: D ₁ / D = 1.2 ÷ 1.8;

The foam generator is installed directly above the zone of possible ignition; the length of the created jet in the horizontal or vertical position of the generator does not exceed 1.8 m.

The fire extinguishing system in vertical tanks is as follows.

When a petroleum product ignites or an air-vapor mixture explodes, sensors that trigger an electrical signal to the pyrocartridge are triggered. The pyrocartridge crane is activated and opens the air supply from the cylinders through the pressure regulators simultaneously to the telescopic boom, cylinder with piston and to the tanks with water and foaming agent. Air entering the cylinder pushes the piston, which in turn moves the telescopic boom to the operating position, as shown in FIG. 2, that is, the telescopic boom moves until it abuts against the movement limiter. In addition, the air entering the telescopic elevator pushes it apart, while the elevator links, reaching the extreme position, become the stopper, as shown in FIG. 3. Seals prevent air from leaving the lift. At the same time, compressed air enters the tank with water and a foaming agent, creates excessive pressure in them, which displaces the water and the foaming agent into the supply pipe. Water and a foaming agent, mixed in the appropriate proportion, flow along the sleeve to the foam generator. The foam generator is located above the upper zone of the tank, foam is supplied directly to the combustion zone. The resulting foam effectively extinguishes the fire.

Generator polydisperse high-fold foam works as follows.

In the event of a fire, the pumping unit (not shown in the drawing) delivers the foaming agent solution from the metering tank to the inlet pipe 24 of the foam generator, from where it is supplied through the foam dispenser under pressure to the bends 25, 27, 28, whose nozzles 29 form atomized jets.

The nozzle works like this. The fluid is supplied through the inlet 40, then passes into the inlet cylindrical chamber 46 and enters through a multi-channel tangential inlet through the openings 47 into the swirl chamber 48, made in the form of a cylindrical cup 39. A rotating fluid flow from the swirl chamber 48 passes through a calibrated conical hole 43 of the nozzle insert 42, the central cylindrical hole 44 and the conical outlet 45 of the nozzle insert 42, resulting in the formation of a spray of liquid, the root angle of which is determined is given the angle at the apex of the cone of the outlet conical hole 45 of the nozzle insert 42.

The proposed design of a wide-torch nozzle with a central cylindrical bore diameter of 44 equal to 9 mm, with a working fluid pressure of 150 ... 250 kPa provides an opening angle of the water plume up to 150 ° and preserves the plume stability at a liquid pressure in front of the nozzles from 40 kPa and higher, while the nozzle performance Depends on the fluid pressure at the inlet inlet.

Tests have shown that even in conditions of intense smoke, foam is formed in predetermined volumes and has good resistance to decay. As a foaming agent in such fire extinguishing systems, a fluorosynthetic foaming agent of the "Multipena" type is used. It also works on a 6% aqueous solution of fluorinated foaming agent "Sublayer" in the conditions of smoke in the room.

The foam generator is also designed for automatic fire extinguishing systems of closed technological rooms (supplying foam to the place of ignition), where the formation of vapor and gas mixtures is possible, for example, in pump rooms of pumping stations, pressure control chambers, etc.

The foam generator works efficiently with the following optimal technical parameters:

The working pressure of the foaming agent, MPa 0.9 ± 0.1 Foaming agent solution consumption, l / s, not less 7 Productivity on foam, m ³ / s, not less 2,8 Multiplicity of foam, not less 400

Claims (1)

A fire extinguishing system in vertical tanks containing a telescopic lift and a foam generator mounted on a support, a foam generator mounted on a movable telescopic lift outside the tank and connected by a sleeve to tanks containing water and a foaming agent and connected to compressed air cylinders, while the telescopic lift extends and moves into the working position using compressed air from these cylinders, and the foam generator is made in the form of a polydisperse generator of high containing a housing, a distribution and a guiding device, the housing being made in the form of a prismatic shell, and on one side of the housing is connected a foam dispenser, which is made in the form of at least one inlet pipe with supporting and network flanges for connecting to a system of a fire extinguishing liquid solution of a foaming agent, and at least two additional pipes rigidly connected to it are horizontally perpendicular to the inlet pipe wires with plugs at both ends, and the foam dispenser fits into the inner contour of the housing, and the diameters of the internal cavities of the input and additional pipelines are equal to each other, while the cavities themselves are interconnected, and to the internal cavities of the input and additional pipelines are connected from the side of the shell of the housing and bends parallel to its axis: shortened, medium and long, ending with nozzles oriented to a guiding mesh device, which consists of three coaxial, coaxial pyramidal shells located in the form of generating grids: external, intermediate and internal, each shell containing a wire frame of two bases in the form of a square and side edges of a truncated pyramidal surface, while the outer shell is attached to the body with a large base, and its second smaller base is simultaneously a large base of the intermediate shell with side ribs, and its smaller base is simultaneously a large base of the inner shell with a smaller base, and generating grids in the form of truncated pyramidal surfaces are arranged in such a way that all their vertices lie on an axis coinciding with the axis of the casing, and the direction of the vertices of the external and internal generating grids coincides, and the top of the intermediate generating grid is opposite to the vertices of the external and internal generating grids, and in the side of the foam dispenser, characterized in that each of the nozzles contains a housing with a swirl chamber and a nozzle insert, while the housing is made with an inlet pipe, having a hole coaxial with it of the input cylindrical chamber, a swirl chamber located coaxially with respect to the inlet chamber and made in the form of a cylindrical cup having at least three tangentially arranged holes on the side surface, the axes of which are located relative to the swirl chamber , i.e. there is a multi-channel tangential input, and a nozzle insert with an external diameter D ₁ is located coaxially with the swirl chamber, and three calibrated holes are made sequentially located and coaxial to each other and the cylindrical surface of the swirl chamber inside the insert: a conical hole with a diameter D of the lower base of the truncated cone, a central cylindrical a hole with a diameter of d ₂ and an exit conical hole with a diameter of d _{3 the} lower base of the truncated cone, while the diameter of d _{2 of the} Central cylindrical the hole of the nozzle insert is equal to the diameter of the upper base of the truncated cone of the conical hole and the diameter of the upper base of the truncated cone of the outlet conical hole.

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