RU2182025C2 - Fire-proofing device - Google Patents

Abstract

FIELD: fire-preventive equipment. SUBSTANCE: fire-proofing device has protective shield system for protecting people from fire effects, such as heat and light radiation, convective and gas flows, noise, combustible substance outbursts etc, which are dangerous for people's life and health. Fire-proofing device is made in the form of corridor defined by walls and ceiling into which cooling liquid is supplied. Device may be used for protecting firemen team, as well as people fulfilling rescue, emergency and recovery works in the vicinity of extensive fires, gas and petroleum gushes, lumber stores, combustible and lubricant stores, volatile flammable liquids and industrial buildings. EFFECT: simplified construction and increased efficiency. 21 cl, 4 dwg

Description

 The invention relates to fire fighting equipment and can be used as: 1) a protective agent for fire brigade personnel, as well as persons carrying out the necessary emergency rescue and emergency restoration work near large fires of gas and oil fountains, timber stores, fuels and lubricants, flammable liquids and GZh, industrial, residential buildings, etc., 2) a life-saving tool for people affected by fires, 3) as a stationary structure for industrial or other purposes.

 Known protective fence made in the form of a frame of interconnected pipes located in the vertical and horizontal planes. Holes are made on the side surface of the pipes. On both sides of the frame with a gap placed metal mesh. Connecting fittings connected to a container containing water are connected to the frame [patent of Uzbekistan 4665, cl. A 62 C 31/00, publ. 12/30/97].

A disadvantage of the known device is the low efficiency due to:
1) only the possibility of vertical protection from the front side perpendicular to the direction of propagation of thermal radiation. Protection is not provided for large fires from radiation, which, in principle, can come from all directions, from combustion products in case of fires with the possible release of combustible substances, which often leads to imminent death, as well as from the harmful effects of noise that can reach large gas and oil fountains of values dangerous to human life and health;
2) with existing water pressures, the holes in the pipes give only a jet outflow of liquid without spraying it, which does not allow creating a drip-water valve in the interstitial space, as was assumed in the known device.

 The objective of the invention is to develop a more efficient and mobile device to protect people from heat and light radiation coming from all sides, possible emissions of combustion products, as well as the harmful effects of noise.

 The problem is solved in that the fire protection enclosure comprises at least one module, a corridor, walls and ceiling of which are made of at least two parallel surfaces, and pipes with holes arranged parallel to the surfaces and provided with nozzles, directed into the space between the surfaces to form a vapor-droplet-air medium and films of coolant on the surfaces.

 The corridor floor is made in the form of parallel installed surfaces and a system of interconnected pipes. The pipe system is located on the inner surface of the corridor. The pipe system is located on the outer surface of the corridor. The pipe system is placed in the space between the planes. The surfaces are made in the form of woven or perforated or stamped grids. The nets are made of copper. The nets are made of brass. The nets are made of galvanized iron. Mesh made of stainless steel. The nets are made of a material coated with a thin layer of metal with a high degree of reflective properties. The nets are made of fireproof plastic. The nets are made of materials obtained by powder metallurgy. The nets are made of wire with a diameter of 0.1-3.0 mm. Grids are made with mesh sizes from 0.1 x 0.1 to 3.0 x 3.0 mm. The diameter of the wire, the mesh size of the outer mesh exceed the corresponding parameters of the inner mesh. The distance between the cells of the external grid exceeds the corresponding parameters of the internal grid. The nets are installed at a distance of 0.5-30 cm from each other. At the ends of the corridor there are fixed locks connecting the modules to each other. The fence is mounted on a platform with wheels. The modules are made telescopic.

The essence of the invention lies in the fact that the proposed design allows you to create favorable conditions for rescuers or firefighters to work in close proximity to the burning centers due to the fact that:
1) a vapor-droplet-air medium is formed in the intergrid space of walls, ceilings, and floor, formed from sprayed liquid droplets, which, when exposed to thermal radiation, evaporate both when approaching the grids and when in contact with them, a film of liquid is formed on the grids (at least for example, on the planes of internal grids) it also gives evaporation - these processes absorb part of the incident heat flux onto the grids and onto the vapor-droplet-air medium itself;
2) thermal radiation and convective gas flows are reflected from the nets, from a film of liquid formed on the nets, and a vapor-droplet-air medium;
3) external noise effects are damped due to the presence of a vapor-droplet-air medium, liquid films on the grids;
4) in the manufacture of each of the bounding walls of the corridor from more than two grids, the combined use of coolant is possible: in one of the grid spaces, the liquid is sprayed with nozzles, and in the space formed by another pair of grids, it is supplied in the form of air-mechanical or chemical foam .

 Thus, the degree of penetration of dangerous fire factors - thermal radiation, infrared and light radiation, convective gas flows and noise exposure into the internal volume of the protective corridor is sharply reduced.

 The execution of the fence in the form of a series of interconnected modules allows you to grow it to the required length.

 The dimensions of the module are selected in such a way that it can be freely moved manually, or by using mechanisms in order to increase it to the required length.

 Each next module at the time of its fastening to the end of the corridor being extended through connecting fittings is connected to the coolant supply system. Thus, each bounding surface, whether it be a wall, a ceiling (and, if necessary, a floor) is transformed into a fireproof screen, consisting of parallel grids forming a vapor-droplet-air medium, reflecting and partially absorbing dangerous fire factors.

 The invention is illustrated by drawings, where figure 1 shows a General view of a protective fence; in FIG. 2 - general view of the wall; figure 3 is a section of a wall; figure 4 is a variant of the fence mounted on wheels.

 The protective fence contains a module 1, which is a corridor, walls 2 and ceiling 3 of which are made in the form of parallel installed grids 4 and 5, the gap between which is equal to 0.5 - 30 cm. Parallel to the surfaces of the grids 4 and 5 there is a system of interconnected pipes 6 with holes 7, in which the nozzles are installed 8. The latter are oriented so that the sprayed liquid (water with the addition of surfactants, water with the addition of dyes, etc.) forms a vapor-droplet medium in the intergrid space 9. At the ends 10 of the modules 1, locks 11 are fixed, allowing them to be connected to each other, while their pipe systems 6 are connected to each other, which are connected, for example, to a fire hydrant (not specified). If necessary, can module 12 be fitted with floor 12 of a similar design? like walls 2 and ceiling 3. In order to facilitate the movement of the module, it can be installed on the platform 13 with wheels 14. In order to quickly penetrate the burning structures, the modules are telescopic.

 A system of interconnected pipes 6 can be placed on the inner surface of the corridor (Figs. 1, 2), or on the outer surface of the corridor (Fig. 4), or in the intergrid space (Fig. 3), grids 4 and 5 can be made of metal, for example, stainless steel, galvanized iron, copper, brass, fire-resistant plastic, alloys obtained by powder metallurgy, etc. Mesh 4 and 5 can be woven, or perforated, or stamped.

 Braided nets 4 and 5 can be made of wire with a diameter of 0.1-3 mm and with mesh sizes from 0.1x0.1 to 3.0x3.0 mm.

 The sizes of the mesh cells, the diameter and the material of the wire are selected so that when spraying coolant on the inner 4 mesh (possibly on the outer 5 mesh), a film of coolant should form. When using brass (or copper) wire with a diameter of 0.2 mm in our experiments, the mesh size was chosen to be 0.5x0.5 mm for the inner mesh. In order to increase the strength of the guard against mechanical damage, the wire diameter and mesh size of the outer 5 mesh can be selected larger than the wire diameter and mesh size of the inner mesh 4.

 In the case of using a perforated or stamped mesh, the cell size and the distance between the cells of the outer mesh 5 may exceed the corresponding parameters of the inner mesh 4.

 The protective fence works as follows: the pipe system of module 1 is connected to the fire hydrant, the fire truck, the fire pump installed near the tank with liquid through the fire hoses and brought to the fire site. Coolant through a system of pipes 6 enters the nozzles 8 and, spraying in the intergrid space 9, creates a film on the grids, a vapor-droplet-air environment in the intergrid space, which creates conditions that reduce the penetration of harmful fire factors into the enclosure. If necessary, to the first module 1 through the locks 11 connect the next similar module, etc., increasing the protective fence to the required length.

 In cases of especially dangerous conditions, air is supplied by a compressor or fan to the inside of the protective enclosure from the base, and an end protective wall with possible openings for people to enter and exit is installed from the opposite end.

Claims (21)

 1. A fireproof enclosure containing a corridor made in the form of at least one module, the walls and ceiling of which are made of at least two parallel surfaces, and pipes with holes arranged parallel to the surfaces and equipped with nozzles directed into the space between the surfaces to form a vapor-droplet - air and films of coolant on surfaces.  2. The fence according to claim 1, in which the floor of the corridor is made in the form of parallel mounted surfaces and communicating pipes.  3. The fence according to claim 1 or 2, in which the pipes are placed on the inner surface of the corridor.  4. The fence according to claim 1 or 2, in which the pipes are placed on the outer surface of the corridor.  5. The fence according to claim 1 or 2, in which the pipes are placed in the space between the surfaces.  6. The fence according to claim 1 or 2, in which the surfaces are made in the form of woven or perforated or stamped grids.  7. The fence according to claim 1 or 2, in which the mesh is made of copper.  8. The fence according to claim 1 or 2, in which the mesh is made of brass.  9. The fence according to claim 1 or 2, in which the mesh is made of galvanized iron.  10. The fence according to claim 1 or 2, in which the mesh is made of stainless steel.  11. The fence according to claim 1 or 2, in which the mesh is made of a material coated with a thin layer of metal with a high degree of reflective properties.  12. The fence according to claim 1 or 2, in which the mesh is made of fireproof plastic.  13. The fence according to claim 1 or 2, in which the mesh is made of materials obtained by powder metallurgy.  14. The fence according to any one of paragraphs. 1, 2, 6-13, in which the mesh is made of wire with a diameter of 0.1-3 mm  15. The fence according to any one of paragraphs. 1, 2, 6-13, in which the mesh cell size is from 0.1 • 0.1 to 3.0 • 3.0 mm.  16. The fence according to claim 1 or 6, in which the diameter of the wire, the mesh size of the external mesh exceed the corresponding parameters of the internal mesh.  17. The fence according to claim 1 or 6, in which the distance between the cells of the external grid exceeds the corresponding parameters of the internal grid.  18. The fence according to claim 1 or 2, in which the mesh is installed at a distance of 0.5-30.0 cm from each other.  19. The fence according to claim 1, in which at the ends of the corridor there are fixed locks connecting the modules to each other.  20. The fence according to claim 1, in which it is mounted on a platform with wheels.  21. The fence according to claim 1, in which the modules are made telescopic.

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