RU2756039C1 - Method for forming self-foaming jet of given multiplicity and device for its implementation - Google Patents

Abstract

FIELD: fire safety.

SUBSTANCE: invention relates to the field of foam fire extinguishing and is intended for preventing and extinguishing large-sized fires in hard-to-reach areas, creating barrier strips for the elimination of forest top and bottom fires. The proposed method includes a system for supplying a jet of an aqueous solution of a foaming agent with the introduction of a hydroreacting composition into it, which mixes and interacts with the aqueous solution of the foaming agent with the release of a gas that foams the foaming agent solution to the desired multiplicity. The desired multiplicity of foam and the specified distance of self-foaming of the jet from the cut of the barrel of the feed system is carried out by the consumption of the hydroreacting composition mixed into the jet and the choice of the delay of interaction of the hydroreacting composition with an aqueous solution of the foaming agent, respectively. The technical effect of the claimed device is that the device for producing a self-foaming jet of a given multiplicity of high range includes a sealed container with the foaming agent solution, a gas-generating device made in the form of a solid fuel gas generator placed on the top cover of this container and providing displacement of the aqueous solution of the foaming agent, as well as a cylindrical chamber with a hydroreacting composition placed inside the container with the aqueous solution of the foaming agent, connected in the upper part to the gas generating device through a filter cooler, so that part of the gas from the gas generator passes through the filter cooler, entering the chamber with a granular hydro-reacting composition, weighs it, turning it into a pseudo-liquid flowing into the lower part of the chamber, connected through an adapter with a barrel having nozzles for entering the aqueous solution of the foaming agent, and a nozzle for entering the pseudo-liquid with the hydro-reacting composition.

EFFECT: jet of the aqueous solution of the foaming agent with a hydro-reacting composition introduced into it flows out of the feed system in an non-foamed state, and foaming is provided at a given distance behind the cut of the barrel of the feed system, reducing the aerodynamic drag of the jet.

4 cl, 1 dwg

Description

The invention relates to the field of foam fire extinguishing, namely extinguishing and preventing fires in large hard-to-reach areas such as forest top and ground fires.

When extinguishing fires in large areas in hard-to-reach places such as forest fires, it is widely known to use heavy special aircraft equipped with multi-ton water tanks. But this method is ineffective due to the low targeting of water entering the fire zone and the rate of its deposition on the forest, moreover, part of the sprayed water is carried upward with the ascending flow of combustion products.

Known systems for extinguishing forest fires in the form of autonomous devices placed on the external suspension of helicopters, increasing the aiming of fire extinguishing compositions into the fire zone, but having a smaller reserve of them in one helicopter flight (spillways VSU-5, VSU-15, intended for transportation on the external suspension of helicopters and drainage of water on fires). In this case, part of the sprayed water is also carried away upward by the upward flow of combustion products.

In this regard, the use of highly effective fire-extinguishing compositions and an increase in the aim of their hitting the fire zone is required. There is an invention of high accuracy of fire extinguishing compositions hitting the fire zone due to expelling, explosive charges that disperse the extinguishing agent patent RU No. 2180600 C1 "Fire extinguishing device for extinguishing forest and steppe fires". The disadvantages of this invention are the complexity of the design and the need to re-equip the device, as well as the use of explosive systems that increase the danger of use and operation in real conditions.

It is known that air-mechanical foam is an effective and widespread means of extinguishing fires. In most devices, foam is formed by feeding a foaming agent solution into a foam generator (for example, RU patent No. 2180607 C1 "Method for forming a jet and foam of medium expansion with increased range and a device for its implementation" (Variants)). Moreover, the extinguishing efficiency (extinguishing area per unit of foaming agent consumption) is determined by the multiplicity of the foam formed.

It is known that in local fires, medium expansion foam has an increased (in relation to low expansion foams) fire extinguishing efficiency, however, these foam generators have a low range - 3-8 m, which makes it difficult to use them when extinguishing large-sized fires in hard-to-reach places (forest fire) due to the danger of approaching fires and foam settling on tree crowns, which makes it difficult to extinguish ground fires because foam is easily blown away by the wind, reducing the aim of the foam hitting the fire zone.

The use of low expansion foam generators provides a jet range of 20-60 m, increases the penetration capacity of tree crowns, but does not provide efficiency and the required surface area of the coating.

Known inventions (foam supply systems), allowing to saturate the foaming agent with compressed gases inside the sealed container of the supply system, for example, by bubbling the volume of the foaming agent.

In the invention RU No. 2678257 C1 "A method for producing a self-expanding gas-filled foam and a device for its implementation" (Prototype), a method for producing a self-expanding gas-filled foam consists in bubbling combustion products through a foaming agent solution and saturating said solution with gases in a sealed container and supplying it to the combustion center from the formation of a self-foaming gas-filled foam on its surface, when creating a foaming agent solution, a concentrated foaming agent solution is intensively mixed with water in a container, and then, with a delay of 3 to 10 s, the resulting foaming agent solution is fed into the combustion center. The disadvantage of this method is that the jet of the foaming agent solution, saturated with gases of combustion products, supplied under pressure, immediately after leaving the barrel of the supply system, actively expands due to the expansion of these gases, saturating the jet to ambient pressure, and self-foaming occurs. At the same time, increased aerodynamic resistance acts on the foam, which reduces the range and accuracy of the jet hitting the flame zone. This method is the closest analogue and is taken as a prototype.

The objective of the invention is to prevent and extinguish large-sized fires in hard-to-reach areas, to create barrier strips to eliminate forest top and ground fires using autonomous devices that form a self-foaming jet of a given multiplicity of high range.

The task is achieved by the fact that the formation of a self-foaming jet of a given multiplicity of high range consists in saturating an aqueous solution of a foaming agent with gases with the formation of a self-foaming jet and feeding it from the barrel of the supply system, in which the saturation of an aqueous solution of a foaming agent with gases is performed when its jet expires from the barrel, introducing a hydroreactive a composition that reacts with an aqueous solution of a foaming agent at a predetermined distance from the cut of the barrel of the supply system, while the foam ratio is provided by the flow rate of the hydroreactive composition, and the range is provided by a delay in the interaction of the hydroreactive composition with an aqueous solution of the foaming agent.

To ensure the availability and low cost of the component base, a mixture of powdered acids and salts of an alkaline medium is used as a hydroreactive composition.

To simplify the technology and save auxiliary consumables, the delay in the interaction of the hydroreactive composition with the aqueous solution of the foaming agent is provided by placing the powders of the hydroreactive composition in separate capsules dissolving in the stream of the aqueous solution of the foaming agent at a predetermined rate, providing a predetermined range.

A device for obtaining a self-foaming jet of a given multiplicity of high range consists of a sealed container with an aqueous solution of a foaming agent, a device for feeding its contents into the barrel, a valve for relieving overpressure in the container, a solid fuel gas generator that ensures the outflow through the nozzle holes of its combustion products into a sealed container, inside this container a sealed chamber with a hydroreactive composition is installed, the gas generator is equipped with a receiver with a filter-cooler, communicated with the inner cavity of the sealed chamber through a nozzle device for supplying combustion products throughout the volume of the chamber, which, in turn, is communicated through a check valve with the barrel. In the barrel, this composition is mixed with an aqueous solution of a foaming agent and the jet accelerates to a predetermined speed.

The figure shows a device that implements the inventive method.

The device includes a sealed container (1) filled with an aqueous solution of a foaming agent in the form of a solution with surfactants with special additives, for example, the patent "Universal fire extinguishing composition for fighting forest fires" RU 2656035 C1. The upper part of the tank is equipped with a neck with a safety relief valve for overpressure (2) in the tank (1) and a gas generator (3). The gas generator (3) has a charge of solid fuel (4), the combustion of which produces gaseous combustion products, an igniter (5), a receiver with a cooling filter (6). The receiver with the filter-cooler communicates with the inner cavity of the sealed chamber (7), in which the granular hydroreactive composition is located, through the nozzle device (8) for supplying purified and cooled combustion products throughout the chamber (7). The receiver with a filter-cooler is equipped with nozzles (9) for the outflow of solid fuel combustion products into the container (1).

The chamber (7) is communicated through the check valve (10) with the barrel (11). The adapter (12) connects the container (1) and the chamber (7) with the barrel (11). The adapter (12) has nozzle devices (13) for supplying an aqueous solution of the foaming agent to the barrel. To accelerate the jet, the barrel has a conical nozzle nozzle.

The combustion products of solid fuels usually have a high temperature and contain particles of the condensed phase. The filter-cooler provides the required purity and temperature of solid fuel combustion products to obtain pseudo-liquid and prevent premature decomposition of the hydroreactive composition.

The device works as follows.

When an electrical signal from the operator or sensor is applied, the solid fuel charge is ignited (4). Gases - the products of its combustion, through the nozzles (9) enter the container (1). Gathering over the mirror of the liquid in the container (1), pressure is created on the liquid, forcing it through the nozzle device (13) into the barrel (11).

At the same time, the gases flowing through the receiver with the cooler filter (6) are fed through the nozzle device (8) into the chamber (7). In chamber (7), these gases create an equilibrium between gravitational forces and the dynamic effect of the flow.

In this case, the gas flow rate is determined by the expression:

where d, ρ _t - diameter and density of particles (capsules of the hydroreactive component);

v, ρ are the viscosity and density of the gas. "Gas generators of rocket systems" Moscow "Mechanical engineering" 1981

As a result, the granules are weighed and the granular hydroreactive composition, turning into a pseudo-liquid, moves like an ordinary liquid and flows out into the nozzle. Experimental studies have shown that jet and screw nozzles are suitable for injection of pseudo-liquid. The central jet of the granular hydroreactive composition, flowing out of the nozzle, interacts with the jets of an aqueous solution of the foaming agent supplied separately along the periphery.

To determine the effectiveness of the invention, we assess the increase in the range of the foam jet with a multiplicity of K = 20 (the ratio of the foam volume to the volume of the non-foamed foaming agent), implemented by foaming the jet of an aqueous solution of the foaming agent at a given distance behind the barrel cut with a granular hydroreactive composition including: citric acid (45%) , sodium bicarbonate (50%) and glycerin (5%) in relation to the foam jet created by the prototype.

When a given granular hydroreactive composition is introduced into a non-foamed stream of an aqueous solution of a foaming agent, mixing (with a predetermined delay) occurs, the powders dissolve in an aqueous solution of the foaming agent and a chemical neutralization reaction with the release of 30% carbon dioxide (based on the mass of powders), as well as the formation of ~ 20% additional water , and ~ 50% of the condensed phase that does not participate in foaming. Assuming that ~ 70% of the generated carbon dioxide goes to pricing, to ensure a foam rate of 20 (taking into account the formed water), 13% (by weight) of the granular hydroreacting composition (powders) of the foaming agent consumption (with an increased concentration of the foaming agent solution by 4%) is required, since additional water is formed during the reaction). The neutralization reaction in this case is endothermic, and when mixing and foaming an aqueous solution of the foaming agent, the temperature of the solution drops by ~ 20 degrees.

According to the results of laboratory studies, it was found that when placing granules of a hydroreactive composition with a diameter of 2 mm in an aqueous solution of a foaming agent, an intense release of gases occurs, foaming this solution in a time of ~ 2 s.

The delay in the interaction of the hydroreactive composition with the foaming agent solution in the jet is selected based on the specified range and velocity of the jet when leaving the barrel, and is implemented by phlegmatizing the surface of the hydroreactive composition granules with special compositions decomposed by an aqueous solution of the jet, or by encapsulating this composition into capsules dissolved in an aqueous solution of the foaming agent ...

Gelatin 10% and glycerin 90% are used as the phlegmatizing composition of the surface of granules or composition for capsules dissolved by a jet of an aqueous solution of a foaming agent. The linear dissolution rate of this composition in an aqueous solution is ~ 0.2 mm / s. By selecting the thickness of the capsules, a predetermined delay in the interaction of the hydroreactive composition with the foaming agent solution is provided.

When the granular hydroreactive composition is fluidized, the bulk density of these components decreases (~ 50), and the free space between the particles is occupied by the gas-products of the combustion of the gas generator. In this case, the volume occupied by the gas is close to the volume occupied by the particles in the pseudo-liquid. Entering a stream of an aqueous solution of a foaming agent together with particles of a granular hydroreacting composition, the gas will foam this solution, but due to the small volume of gas in a pseudo-liquid in relation to the volume of an aqueous solution of a foaming agent ~ 5%, the foam ratio is: K ~ 1.05 and foaming of an aqueous a foaming agent solution with a pseudo-liquid gas is negligible.

Assuming that when the barrel is installed at an angle to the horizon, the horizontal component of the jet velocity changes from a given value at the barrel cut of the foam supply system to zero due to aerodynamic braking, the jet speed at the barrel cut, barrel tilt angle, foam speed and aerodynamic drag coefficients of the jets are the same for the proposed invention and the prototype, the ratio of the jet range of the proposed invention and the prototype is determined by the ratio of the aerodynamic drag forces acting on the jets in flight, and are inversely proportional to the masses of the jets:

where L _from , L _pr - range of the proposed invention and prototype;

- силы аэродинамического сопротивления, действующие на струи в полете, для предлагаемого изобретения и прототипа;

- the forces of aerodynamic drag acting on the jets in flight, for the present invention and the prototype;

M _from , M _pr - masses of jets of the invention and prototype.

The aerodynamic drag forces acting on the jets in flight are proportional to the transverse areas of the jet, and assuming that the expansion of the jet during foaming is all-round, the ratio of the transverse areas of the foamed jet of the prototype in flight to the non-foamed jet of the proposed invention in flight is equal to:

Where V _CR is the volume of the non-foamed jet of the present invention, V _CR is the volume of the prototype foam. The volume ratio corresponds to the foam ratio:

Thus, the ratio of the jet range of the proposed invention and the prototype is estimated:

According to the authors of the present invention, the features given in the claims are necessary and sufficient to achieve the specified technical result, that is, they are essential.

Thus, the distinctive features of the proposed technical solution are new and meet the "novelty" criterion.

The proposed method makes it possible to increase the range of ~ 6.5 times of the foam due to the self-foaming of the foaming agent solution directly near the flame zone and / or near the necessary zone when creating barrier strips when eliminating, for example, forest top and bottom fires.

Claims (4)

1. A method of forming a self-foaming jet of a given multiplicity, which consists in saturating an aqueous solution of a foaming agent with gases with the formation of a self-foaming jet and feeding it from the barrel of the supply system, characterized in that the saturation of an aqueous solution of a foaming agent with gases is performed when its jet expires from the barrel, introducing a hydroreactive composition entering into a reaction with an aqueous solution of a foaming agent at a given distance from the cut of the feed system barrel, while the foam ratio is provided by the flow rate of the hydroreactive composition, and the range is provided by a delay in the interaction of the hydroreactive composition with an aqueous solution of the foaming agent. 2. A method according to claim 1, characterized in that a mixture of powdered acids and salts of an alkaline medium is used as the hydroreactive composition. 3. The method according to claim. 2, characterized in that the delay in the interaction of the hydroreactive composition with the aqueous solution of the foaming agent is provided by placing the powders of the hydroreactive composition in separate capsules that dissolve in the stream of the aqueous solution of the foaming agent at a predetermined rate. 4. A device for obtaining a self-foaming jet of a given multiplicity, including a sealed container with an aqueous solution of a foaming agent, a device for feeding its contents into the barrel, a valve for relieving excess pressure in the container, a solid fuel gas generator that ensures the outflow through the nozzle openings of its combustion products into a sealed container, characterized in that, that a sealed chamber with a hydroreactive composition is installed inside this container, the gas generator is equipped with a receiver with a filter-cooler communicated with the inner cavity of the sealed chamber through a nozzle device for supplying combustion products throughout the volume of the chamber, which in turn is communicated through a check valve with the barrel.

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