EA003013B1 - Method for attenuating thermal gas flows for protection an operator of fire-hose barrel - Google Patents

Abstract

1. A method for attenuating thermal gas flows said method comprises creating a curtain of a cooling liquid that is sprayed into space formed by at least two surfaces one of the curtains is made in the form of a grid, characterized in that said cooling liquid is sprayed or dispersed controllably in the space between surfaces for creation of water drop aerated medium and films on said surfaces. 2. The method of claim 1, characterized in that in case of creating mote than one curtain foam is additionally used. 3. A device for protecting a fire-hose operator comprising a spraying unit provided with mounting assembly connected to the fire hose housing provided with mouth pieces in the form of a frame made of interconnected tubes with openings arranged in vertical and horizontal planes, in the central part of said spraying unit an aperture is made for said fire hose and inner and outer surfaces, at least one of them is designed as a grid, said surfaces arranged on both sides of said frame so as to define a gap, characterized in that nozzles are further mounted in the tube openings for finely dispersed reagent for creating on the surface water drop aerated medium and films of cooling fluid between said surfaces 4. The device of claim 3, characterized in that said grids are woven, and/or perforated and/or stamped. 5. The device of claims 3 and 4, characterized in that said grids of the frame are made of materials produced by a powder metallurgy method. 6. The device of claims 3 and 4, characterized in that said grids are made of fire-proof plastic. 7. The device of claims 3 and 4, characterized in that said grids are made of copper. 8. The device of claims 3 and 4, characterized in that said grids are made of a metal-coated material. 9. The device of claims 3 and 4, characterized in that said grids are made of galvanized iron. 10. The device of claim 3, characterized in that said gap between the frame and the surfaces is 1 to 200 mm. 11. The device of claim 3, characterized in that the frame is formed by the front and side parts of the fire hose. 12. The device of claim 3, characterized in that the frame is made over the perimeter of the fire hose, including, if necessary, the floor and the ceiling.

Description

The invention relates to fire fighting equipment, and can be used to protect equipment and people when fighting fires, dividing the volume of buildings of ground and underground structures and apparatuses into fire compartments, protecting against the collapse of ceiling ceilings and localizing the spread of the combustion front in case of large fires involving environmental disasters.

Closest to the technical nature of the proposed method is a method of creating a fire curtain, including the formation and installation of vertical protection. A protective curtain is formed by installing metal grids in the form of two parallel planes and supplying a cooling agent to the interstitial space. As a cooling agent use water, or water with a surfactant, or air-mechanical or chemical foam [1].

The disadvantage of this method is that the creation of only one strip of protection, which serves only one type of coolant, does not provide absolute safety and effectiveness of this method.

A device for a fire barrel is known for creating a protective shield against thermal radiation [2], containing nozzles with a spray unit located on the housing. The spraying unit is made in the form of a V-shaped jet divider and two mutually parallel guide plates, equipped with a mechanism for regulating the angle between the planes of the V-shaped jet divider and connected by a nozzle. Water supplied under pressure through the barrel and nozzle body, entering the spraying unit, changes the direction of motion, spreads along the plane of the plates, forms into two thin films separated by an air gap.

The disadvantage of this device is that in order to maintain a stable section of the films, a certain high-pressure water pressure is required, and it practically changes frequently, which makes it difficult to regulate it. The position of the fire barrel does not change, which is also an undesirable factor.

The closest in technical essence to the proposed device is a device for a fire barrel to create a protective shield against thermal radiation, containing nozzles and a spray unit connected to the barrel body, the spray unit is placed on a support and made in the form of a frame of interconnected pipes located in vertical and horizontal planes, with holes on the side surface of the pipes, and an opening in the central part of the frame to allow the fire barrel to move along erticals. At the same time, metal grids are fixed on both sides of the frame with a gap, and the lower part is equipped with rollers for moving the frame along the support. In addition, the support is equipped with an arcuate guide for moving the rollers [3].

The disadvantage of this device is that water from the openings of the side surfaces of the pipes from which the frame of the protective device is made, flows in the form of thin jets at all existing water pressures in the fire monitors, which does not lead to the formation of a continuous water screen. Spraying of water here occurs only in places of impact of jets with metal structures of the frame and in places of impact with a boundary net.

The disadvantage of this device is that the rotations of the protective screen in the horizontal plane can only be done with both hands holding the handles attached to the frame. In this case, the monitored barrel remaining free under the action of a reactive force flowing out of the barrel of a jet of water begins to move arbitrarily inside the frame opening in a vertical plane, which can lead to undesirable consequences.

The objective of the invention is to develop a method of attenuating the heat flux with increased efficiency and the development of a device for protecting the fire barrel operator from thermal radiation with a high degree of reliability, safe and convenient to use and allowing protection from heat and light radiation and convective gas flows.

The problem is solved in that in the method of attenuating the heat flux, including creating a curtain of coolant by feeding the latter into the space formed by at least two surfaces, the curtain is created by adjustable expansion of the contact surface of the cooling agent with the heat or light flux, for example, controlled by spraying, spraying liquid, for example by ejection with compressed gas or sparging.

When more than one curtain is formed, use a combined coolant supply.

At least one of the curtains is created by spraying liquid, and the subsequent supply of air-mechanical or chemical foam.

The problem is also solved by the fact that in the device for protecting the operator of the fire barrel, including the spray unit, placed on a support connected to the barrel body, equipped with a nozzle, and made in the form of a frame of interconnected pipes with holes located in the vertical and horizontal planes, in the central part of which an opening for the fire barrel is made, and internal and external surfaces, for example in the form of nets, placed with a gap on both sides of the frame, according to the invention in the holes RUB frame mounted nozzles for spraying finely divided coolant.

The nets are made of braided and / or perforated and / or stamped.

Frame nets are made of materials obtained by powder metallurgy.

The nets are made of fireproof plastic. The nets are made of copper.

The nets are made of a material coated with a metal film.

The nets are made of galvanized iron.

The mesh size is 0.1 * 0.1 to 8.0 * 8.0 mm.

The gap between the frame and the surface is 1 - 200 mm.

The diameter of the wire, the material of the wire, the mesh size of the external mesh, as well as the mesh itself (woven or perforated) are identical to the corresponding characteristics of the internal mesh.

The diameter of the wire, the material of the wire, the mesh size of the external mesh, as well as the mesh itself (woven or perforated) are different from the corresponding characteristics of the internal mesh.

The frame is made from the front and side parts of the fire barrel.

The frame is made around the perimeter from the fire barrel, including, if necessary, the floor and ceiling.

The essence of the invention lies in the fact that the sprayed liquid stream consists of a stream of separately flying droplets, for which special nozzles are used - nozzles [4]. The sprayed liquid jet is characterized by dispersion, droplet size, their distribution over the jet cross section, the angle of the taper of the jet, range, pressure in front of the nozzle and fluid flow rate. In practice, centrifugal, pneumatic and mechanical spraying methods are most widely used.

With increasing pressure in front of the nozzle, the average droplet diameter decreases.

Fire pumps create a pressure of 1.2 MPa, and in practice the average droplet diameter on the spray barrels is about 400,500 microns. At high pressure installations, the pressure drop across the nozzles can reach 15 MPa, while the diameter of the droplets is about 5-10 microns. Liquid droplets sprayed with the help of nozzles, absorbing thermal radiation, begin to evaporate both upon approaching the planes and when they come in contact with them, which is enhanced when the liquid droplets with high kinetic energy have time to repeatedly reflect in space from the surfaces.

The selection of the type of surfaces and their material, for example, the implementation of surfaces in the form of grids, the selection of their characteristics, cell size, diameter and material of the wire, etc., are made in such a way that, due to the forces of surface tension, a film of the liquid used must be formed, the consistency of which is maintained by a dynamic equilibrium between the process of evaporation during absorption of thermal energy by the film and the process of constant replenishment of the film itself by droplets of spray liquid colliding with it.

Thus, we can say that, basically, in the inter-surface space a continuous vapor-droplet-air medium is formed. Infrared, light radiation and convective gas flows from the fire will be partially reflected from surfaces, in particular from grids, from the created film, from the vapor-droplet-air medium, partially absorbed by the created vapor-droplet-air medium and carried away in the direction perpendicular to the movement of thermal radiation from the fire.

Obviously, a similar symbiosis of the processes of reflection and absorption of the incident energy stream is carried out has a unique feature: the efficiency of the heat-shielding properties of this device increases with increasing value of the incident energy stream.

Spraying liquid using high-pressure installations in a finely dispersed state with a droplet diameter comparable to the wavelengths of thermal radiation from a fire (about 1.5-7 microns) will also help increase the efficiency of the heat-shielding properties of such devices. In this case, according to the laws of geometric optics, the optimal fine dispersion of liquid droplets several times enhances the scattering of thermal radiation [5].

The need to control M - the amount of cooling agent supplied to the space between two enclosing surfaces, which can be used as metal fabric, fiberglass, metal plates or other materials, is due to the strong variation in the values of heat flux V existing in real fires - from 0 to 200-250 kW / m ² . At the same time, even at values of ν = 3-4 kW / m ² , special protection is required for personnel.

Let the heat flux ν ₀ perpendicularly fall on the plane of the screen, with ν0 = ν1 + ν2 + ν ₃ , where VI is part of the heat flux reflected from the screen;

ν2 - part of the heat flux passing through the screen;

ν ₃ - part of the heat flux absorbed by the cooling agent of the screen. Obviously, when M changes, W ₃ changes most strongly. Consider the hypothetical case when all the heat flux Ш ₀ incident on the screen is absorbed by a cooling agent, in which, in particular, water is taken.

Let 100 g of water be sprayed in the grid space of the screen with an area of 1 m ² . Let us estimate the value of Ш ₀ , assuming that the process of heating to 100 ° С and vaporization takes place within 1 s.

In this case, 00 = 0 ,, + 0,, where Ts ₀ is the total amount of heat;

0 _n = SM (1 ₂ -1 ₁ ) - the heat required for heating M = 100 g of water, with a specific heat capacity of C = 4.2 kJ / kg deg, with a temperature of 1 ₁ = 0 ° С to 1 ₂ = 100 ° C.

О ,, = λΜ is the heat of vaporization, λ = 22.6 '10 ² kJ / kg is the specific heat of vaporization of water.

O = 4.2'10 ⁴ j + 22.6'10 ⁴ j.

Note that the heat of vaporization of O ,, is more than 5 times greater than 0 _n .

For the conditions under consideration, this amount of heat corresponds to the heat flux

W ₀ = 268 kW / m ²

Such a large value of Ш ₀ is observed near large fires in forest stands. When burning gas fountains, heat fluxes reach 30-40 kW / m ² . When creating a water droplet curtain, the maximum attenuation of XV _{0 is} achieved by reducing the average diameter of the drops to values comparable to the wavelength of thermal radiation from the fire (about 5-10 microns) [5].

In this case, an attenuation of W _{0 by} a factor of 5–7 was obtained experimentally. And since the speed of water droplets was of the order of 10.100 m / s; the processes of vaporization did not make a significant contribution to the absorption of heat.

In the case of using one mesh curtain, cooled by water [6], the weakening of Ш ₀ also occurs 4-5 times.

In the case of using two mesh curtains located with a gap, multiple drops of water reflect from the inner surfaces of both grids. At the same time, the droplet velocity slows down, the droplets themselves, when they collide with the nets, split into even smaller ones, part of the water mass of the droplets adheres to the nets, forming a film both on the surface of the nets wire and, possibly, on the nets themselves (depending on the size cells). These processes make noticeable the expenditure of incoming heat energy both on the heating of water droplets and films, and on their evaporation. In turn, these phenomena, due to the presence of two enclosing surfaces, lead to an increase in the scattering and reflection of heat radiation and convective heat fluxes - Ш ₁ , both from the grids themselves, and from the water films formed on them, as well as from the vapor-droplet-air the environment generated in the interconnect.

It should also be noted about the phenomenon of interaction of light and IR radiation and convective heat fluxes visually observed in the experiment with a vapor-droplet-air medium formed in the immediate vicinity of the outer surface of the protective shield from the side of the incident heat flux.

In the collision of water droplets with enclosing nets, the droplets split into even smaller ones and part of them are sprayed into the area outside the interstitial space. In the case of a frontal grid located on the fire side, finely dispersed spray slipping through the water grid and evaporating water form a visually noticeable layer of vapor-air medium adjacent to the outer surface of the frontal grid on the fire side.

The interaction of the convective flows of hot gases incident on the outer surface of the frontal mesh and reflected from it with this outer layer of the vapor-air medium leads to visually observed unstable pulsation of this medium and the flow of thermal energy along the outer surface of the frontal mesh in directions perpendicular to the flux vector V).

Thus, the proposed method of attenuating heat flows is fundamentally different from previously known. It qualitatively changes the situation when the processes of absorption and evaporation begin to play a significant role in weakening heat fluxes. As shown in the above calculations, it is these processes that are theoretically capable of completely solving the problem of protection against thermal damage, even in the largest fires. It should be noted that in this method, the values of V and Ш ₂ increase with increasing Ш ₀ , i.e. there is a self-regulating attenuation of the incident heat fluxes. At the same time, as here, the processes of energy absorption and evaporation significantly affect the degree of attenuation of Ш ₀ , i.e. this invention allows to make this process artificially controlled. This regulation is carried out either automatically - using computer programs, information into which is entered from thermal radiation sensors located in the protected object, or manually. Experimentally, this was done by turning on (off) the part of the nozzles through which water is supplied to the intergrid space, or by regulating the pressure of the supplied water or cooling agent. This allows you to significantly save water consumption for the creation and maintenance of steam 003013 drip-air environment under acceptable conditions of weakening And ₀ .

Adding dyes to the supplied liquid will also increase the efficiency of the heat-shielding properties of this device, since in this case, the absorption coefficient of the incident energy of the vapor-droplet-air medium will increase [7].

The implementation of the spraying unit in the form of a system of nozzles specially placed on the frame makes it possible to ensure a uniform distribution of liquid droplets in the space formed by the surfaces, in particular, grids fixed on both sides of the frame with a gap.

The implementation of the protective screen in the form of a half ring allows you to protect the operator from dangerous fire factors from the front and sides. In cases of extinguishing especially dangerous objects, the screen can be made as a fence around the perimeter, as well as from above, fencing the operator from the front, sides, rear and top. Placing the entire structure on a platform with wheels makes it easy to move the entire structure, and supplying it with a drive makes the structure mobile.

The invention is illustrated in the drawing, where in FIG. 1 shows one embodiment of a method for attenuating a heat flux, in particular a general view of a plant for protecting a fire barrel operator in a stationary embodiment, FIG. 2 is a top view of the installation, in FIG. 3 is a fragment of a spray unit with nozzles (view A in FIG. 1), in FIG. 4 is a side view of the device, in FIG. 5 is a top view of the device with a perimeter fence, in FIG. 6 - a device equipped with wheels and a drive.

The device to the fire barrel, to create a protective shield includes a fire barrel 1 with a nozzle located on the support 2, which can be used as a support structure similar to the support for the fire monitor, or the design of the frame itself. The spraying unit is made in the form of a frame 3 of interconnected pipes 4 located in horizontal and vertical directions. The pipes 4 are equipped with nozzles

5. In the central part of the frame, an opening 6 is made to allow the fire barrel 1 to be moved. On both sides of the frame 3, grids 7 and 8 are fixed with a gap (indicated in Fig. 2 and 4 by special hatching, in Fig. 5 and 6 - fragmented by special hatching , in Fig. 1, schematically mutually perpendicular lines 9 with a mesh size much larger than what is actually used.

2. The fire barrel 1 is equipped with a handle 12. The frame 3 of the interconnected pipes 4 and the grids 7 and 8 fixed to it form a fire shield.

The vertical axis of rotation of the gun mount - Οι is shifted to the side of the protective screen 3, with respect to the vertical axis of the screen itself - О ₂ . The displacement of the Οι axis provides greater security for the operator of the fire barrel, allowing it to be located closer to the frame - screen 3.

The support 2, connected to the barrel 1, is placed on the platform 13, which is equipped with wheels 14 and an engine 15. Frame - protective shield 3 can be located, covering the operator from the front and sides (Fig. 2) and can be placed around the perimeter, enclosing the operator from the front, from the sides, behind and from above (Figs. 5 and 6). Mesh 7 and 8 of the protective screen 3 can be made of wicker or perforated. In the case of using braided nets, the wire diameter can be selected from 0.1 * 0.1 to 8.0 * 8.0 mm. A wire with a diameter of less than 0.1 mm will not withstand mechanical damage, and a wire with a diameter of more than 3.0 mm significantly complicates the design and interferes with maneuverability. The sizes of the woven mesh cells are selected equal to from 0.1 * 0.1 mm to 8.0 * 8.0 mm, depending on the thickness of the wire. The mesh external to the operator may be made of thicker wire and with a larger mesh size.

Grids can be made of wire of the same diameter and with the same cell size. For the manufacture of the mesh, any metal wire can be used, for example, copper, brass or ceramic, made from powder metallurgy alloy. The mesh can be made of fireproof plastic. The mesh can be perforated or stamped.

The enclosing surfaces 7 and 8 can be made combined. For example, the outer surface 8 can be made in the form of a mesh surface (woven, stamped or perforated), and the inner surface 7 can be made of sheet metal (or a transparent material made of fire-resistant polymer, possibly reinforced with a metal mesh), or made up of parts. For example, at the eye level of the operator, the inner surface 7 is mesh and the rest of it is made of sheet metal.

The device operates as follows: at the time of the fire, water or another liquid (water with the addition of surfactants, with the addition of a foaming agent, dyes, etc.) is supplied through the connecting fittings (not shown) to the fire barrel 1 and through the pipe system 4 to the nozzles 5. The fire barrel delivers a powerful stream of water (or other liquid) to the fire and, at the same time using nozzles 5, the liquid is sprayed in the space between the grids 7 and 8. The liquid sprayed by the nozzles, the vapors generated by exposure to Ashes of the fire flow to sprayed droplets create a vapor-droplet-air medium in the intergrid space, which effectively reflects and absorbs heat fluxes from the fire, which ensures the safety of the fire barrel operator. At the same time, silhouette visibility of the situation in the fire is preserved.

In addition to the self-consistent enhancement of the effect of attenuation of the heat flux, it is possible to regulate its attenuation using known methods using computer-controlled automatic control systems or manually.

Such regulation is feasible by installing infrared thermal sensors in front of the protective screen with a spectral range covering the visible and infrared regions of the spectrum.

During a fire, information is continuously read from the sensors, a computer is analyzed, which corrects the number of devices used that disperse the cooling agent, the pressure of the liquid, and the amount of foam supplied to the grid.

A similar regulation of the protective properties of the screen can also be carried out by the operator of the fire barrel by known methods.

The installation of the protective screen 3 on the rollers allows you to rotate it around the vertical axis O ₂ and install using the handle 12 in the desired direction.

Also, using the same handle, you can move the fire barrel 1 in a vertical plane at the required angle relative to the horizon to supply coolant to the required distance.

The use of the combined curtain is due to the special conditions for protecting the lives of people in places of their mass stay, for example, when using the theater curtain. In this case, the curtain located on the first side of the stage is formed by two surfaces between which water is sprayed, and the second curtain is formed by applying air-mechanical or chemical foam to the next inter-surface space. In this case, a stepwise decrease in powerful heat and gas flows occurs during a developed fire on the stage. In this case, a droplet-air curtain, frontal to the fire, plays a damping role and allows one to reduce heat fluxes, thereby protecting against the possible destruction of the second curtain from the foam. All this allows you to increase the reliability and duration of this combined curtain in extreme cases, for example, before evacuating people from the audience, as well as completely eliminate the penetration of toxic gases into the audience.

References

1. Preliminary patent of the Republic of Uzbekistan No. 5193, IPC А62С 2/02, 1998 (the closest analogue).

2. A.S.SSSR No. 1666129, IPC A62C 31/00, 1991

3. Preliminary patent of the Republic of Uzbekistan No. 4665, IPC А62С 31/00, 1997 (the closest analogue).

4. Pages D.G., Galustov V.S. Fundamentals of spraying liquids. - M., Chemistry:

1984, with 256.

5. Morozyuk Yu.V. - “Ensuring the safety of fire engines from the effects of thermal irradiation of forest fires with drip water protection,” diss. for the title of candidate of technical sciences, VIPPSH of the Ministry of Internal Affairs of the Russian Federation. M., 1994, p. 243.

6. Roytman M.Ya. "Fire regulation in construction", M., Stroyizdat,

1985, p. 590.

7. Alexandrov E.E., Stenchikov G.L. “Numerical modeling of the climatic effect of aerosol pollution of the atmosphere” Dokl. USSR Academy of Sciences, 1985, v. 282, No. 6, p. 1324-1326.

Claims (12)

CLAIM 1. A method of attenuating heat fluxes, including the creation of a curtain of coolant by feeding the latter into a space formed by at least two surfaces, at least one of which is made in the form of a grid, characterized in that the coolant is supplied by adjustable spraying or spraying in the space between the surfaces to create a vapor-droplet-air medium and films of coolant on the surfaces. 2. The method according to claim 1, characterized in that when the formation of more than one curtain, additionally use foam. 3. A device for protecting the operator of a fire barrel, including a spray unit located on a support connected to the barrel body, equipped with a nozzle, and made in the form of a frame of interconnected pipes with holes located in the vertical and horizontal planes, in the central part of which is made opening for the fire barrel, and the inner and outer surfaces, at least one of which is made in the form of a grid, placed with a gap on both sides of the frame, characterized in that in the openings of the pipes of the frame nozzles for finely dispersed spraying of a cooling agent for the formation in the space between the surfaces of the vapor-air-air medium and films of coolant on the surfaces are installed. 4. The device according to claim 3, characterized in that the mesh is made of wicker, and / or perforated, and / or stamped. 5. The device according to PP.3 and 4, characterized in that the grid frame is made of materials obtained by powder metallurgy. 6. The device according to PP.3 and 4, characterized in that the mesh is made of fireproof plastic. 7. The device according to PP.3 and 4, characterized in that the mesh is made of copper. 8. The device according to PP.3 and 4, characterized in that the mesh is made of a material coated with a metal film. 9. The device according to PP.3 and 4, characterized in that the mesh is made of galvanized iron. 10. The device according to claim 3, characterized in that the gap between the frame and the surfaces is 1-200 mm 11. The device according to claim 3, characterized in that the frame is made with front and side parts from the fire barrel. 12. The device according to claim 3, characterized in that the frame is made around the perimeter from the fire barrel, including, if necessary, the floor and ceiling.