RU2232040C1 - Bomb - Google Patents

Abstract

FIELD: equipment for exerting active influence upon natural and artificial objects, particularly for fire-fighting, ice jam breakage, snow slide prevention and old houses breaking.

SUBSTANCE: bomb is preferably delivered to object by airplane or helicopter.

EFFECT: reduced cost, widened application fields, increased efficiency due to increased kinetic energy of fire-extinguishing substance.

9 cl, 1 dwg

Description

The invention relates to the field of means of active influence on natural and artificial objects, preferably delivered to these objects by air and helicopters, and can be used to eliminate fires, ice jams, avalanche situations, as well as for the complete destruction of emergency buildings.

In what follows, the term “conical surface” will be used, which in the context of the proposed description corresponds to the definition set forth in the Polytechnic Big Encyclopedic Dictionary (M .: Big Russian Encyclopedia, 1998, pp. 240, 243).

A device for extinguishing fires (GB, application 2020971, 1979) is known, comprising a housing with an opening for extinguishing a substance, a charge generating a fire extinguishing substance, and a site for initiating the operation of said charge.

In the event of a fire, the initiation unit (squib) undermines the specified charge, and the extinguishing agent (aerosol) formed as a result of the explosion through the specified hole enters the fire zone.

A disadvantage of the known device should recognize the possibility of an additional source of fire due to the operation of the initiation node.

It is known to use air bombs to destroy ice jams on rivers, as well as to deal with avalanche danger.

However, the use of aircraft bombs for these purposes leads to a violation of the ecology of the reservoir due to the explosion of explosives, and it is also possible to destroy biological objects (people and animals) with fragments of the bomb body and the blast wave.

The closest analogue of the proposed device can be recognized as a device for extinguishing fires (RU, patent 2073541, 1997). The known device contains an elastic shell filled with a fire extinguishing agent, enclosed in a container, a means of holding the container over the fire zone and a means for destroying the shell, the container being made of a mesh elastic material, and the destruction means is an explosive charge mounted inside the elastic shell in its center and immersed into a fire extinguishing agent.

In a basic embodiment, the device comprises an elastic shell in the form of a bag made, in particular, of polyethylene. The shell is filled with a fire extinguishing agent, in particular liquid, and placed in a container made in the form of an elastic metal mesh. The destruction tool of the shell is an explosive charge mounted inside the shell and immersed in a fire extinguishing substance. The retention means is made in the form of a cork, to the contoured surface of which, by means of an elastic cage, a mesh container and an elastic shell are pressed. The retention means has a filler neck with a hole blocked in the operating mode by a threaded plug, which is made with a hole for the cord to charge. The mesh sheath has openings that are uniformly spaced around the perimeter of the cell into which sections of the elastic sheath sag.

The known device operates as follows. The cord receives a signal to detonate an explosive charge. As a result of the explosion, the pressure in the elastic shell increases sharply, which through the fire extinguishing agent evenly spreads over the entire wall area of the specified shell, the sections of which are pressed through the cells with their subsequent destruction under the pressure of the fire extinguishing agent. After the destruction of the elastic shell, a fire extinguishing agent is freely poured onto the fire.

A disadvantage of the known means should be recognized as its low efficiency, due to the low kinetic energy of the particles of the extinguishing agent, pouring out onto the fire.

The technical problem solved by the proposed device is to increase its efficiency and at the same time expand its capabilities.

The technical result obtained by the implementation of the proposed device is to reduce its cost while expanding the scope with increasing efficiency by increasing the kinetic energy of the particles of the missile.

To achieve the technical result, it is proposed to use a bomb containing a shell filled with liquid or powder, in particular a fire extinguishing agent, and an explosive charge mounted inside the shell, the shell having a side surface expanding to the bottom (preferably conical and, in particular, pyramidal) and a convex bottom, while the bottom surface contains at least one depression, the depth of which does not exceed the distance from the bottom surface to the plane of the section passing along the perimeter of the soy stretching the bottom and side surface (part) of the shell. It was experimentally established that the execution of the shell in a similar way: the conical lateral surface expanding in the lower part and the convex bottom with hollows leads to a sharp increase in the kinetic energy of the propelled substance. In the case of the use of a liquid fire extinguishing substance (mainly water-based), open flame is knocked down with the penetration of liquid into the previously burning material. In the case of the use of a powder extinguishing agent, an open flame is also brought down with the powder sticking tightly to the surface of the previously burning material. When using these bombs to prevent fire, a liquid or powder not only covers the surface of a combustible material, but also penetrates it or insulates it tightly from fire. If the proposed bomb is used to discharge avalanches or mudflows, the kinetic energy of the water causes a programmed avalanche or mudflow descent. If it is necessary to destroy the ice lintels, the kinetic energy of the falling water leads to the appearance of cracks in the lintel without harming the environment. The final destruction of structures damaged as a result of natural disasters or man-made disasters is also carried out due to the high kinetic energy of the propelled substance.

Depending on the purpose, the bomb may have various sizes, including the size of the bottom on which the depressions are located. In a preferred embodiment, the bottom contains at least four of these depressions. It was also experimentally noted that the presence of regularity in the location of the depressions at the bottom makes it possible to somewhat increase the kinetic energy of the propelled substance. It is preferable, in the case of a conical shape of the side surface of the shell with a circle at the base, to have a distance between the centers of the depressions from 40 to 80% of the radius of the circumference of the connection of the bottom and the conical (side) part, and with a pyramidal shape of the side surface of the shell, the distance between the centers of the depressions is preferably from 20 to 40% of the largest base of the perimeter of the rectangle connecting the bottom and side. The depth of the depressions usually ranges from 20 to 100% of the distance from the bottom surface to the plane of connection of the bottom and side surface. The shell may be made of a polymeric material (polyethylene, polyvinyl chloride, rubbers, etc.) or of woven materials, preferably coated with a permeable material. The main requirements for the shell are the ability to create a raised bottom and ease of destruction of the shell. These depressions can be molded during the manufacture of the shell, and can also be performed by attaching point sections of the bottom to a solid support placed inside the shell. The specified solid support may be a perforated partition attached to the inner side of the shell at the junction of the bottom and side of the shell, or a cord on which an explosive charge is fixed. To enhance the directed action of the bomb, the side part of the shell is made of a more durable material than the material of the lower part; in the simplest case, the same material is used to make the side part, from which the bottom is made, but with a larger thickness.

The drawing shows a sectional view of the proposed bomb, with the following notation used: 1 - shell, 2 - liquid or powder, in particular a fire extinguishing agent, 3 - explosive charge, 4 - support, 5 - means of forming depressions, 6 - depressions. The drawing shows one of the ways to perform the device.

In the future, possible embodiments of the invention will be considered in the following implementation examples.

1. To extinguish a forest fire, a 0.72 m ³ bomb was used, the shell of which is made of polyvinyl chloride, the side surface being pyramidal with sides of the base 0.8 m. On the bottom part there are 16 lattices in the form of a regular lattice, the centers of which are regular the structure, and the distance between the centers was 0.2 m. The depressions were formed during the formation of the shell at the manufacturing stage. The volume of the bomb is filled with water. Inside the bomb, on a rigid cable at half the distance between the neck of the side surface and the bottom bottom point, a 1.2 kg trotylhexogen block is fixed. To detonate the checkers used a detonator and moderator. The bomb is designed to be dropped from a helicopter. The retarder is adjusted so that the burst of the checkers (with subsequent rupture of the shell) occurs at a height of 20-40 m above the fire. The kinetic energy of propelled water allows you to bring down even a horse fire with water saturation of the surface of trees and land.

2. To extinguish the fire of peat bogs, a 1.6 m ³ bomb was used, the shell of which is made of rubberized tarpaulin, and the side surface is conical with a base radius of 0.6 m. On the bottom part, 18 depressions are made according to the concentric pattern, the distances between the centers of which amounted to 0.25 m. The depressions are formed by sewing at the stage of manufacturing the shell sections of the bottom to a perforated base, fixed around the perimeter of the connection of the bottom and side. The volume of the bomb is filled with water. Inside the bomb, on a rigid cable, one-third of the distance between the neck of the side surface and the bottom bottom point is fixed to a pressed explosive bomb with a density of 1.7 kg / m ³ , a detonation speed of 7.6 km / s, and a weight of 2.5 kg. To detonate the checkers used a radio detonator. The bomb is designed to be dropped from a helicopter. A radio detonator is detonated after a bomb is dropped so that a burst of drafts (followed by a rupture of the shell) occurs at an altitude of 20-40 m above the fire site. The kinetic energy of the propelled water allows you to extinguish the beginning fire of peat bogs.

3. To create a fire clearing in the steppe, 0.1 m ³ bombs dropped from a helicopter were used, the shells of which are made of polyethylene, and the side surface of the bomb is made conical with a base radius of 0.2 m. 6 depressions are made on the bottom, the distance between the centers of which were 0.15 m. The depressions are formed during the formation of the shell at the manufacturing stage. At the center of the bomb is a BB bomb, similar to that used in Example 2, weighing 0.5 kg. The volume of the bomb is filled with water. To detonate the checkers used a detonator and moderator. The moderator is adjusted so that the explosion (with subsequent rupture of the shell) occurs at a height of 10-20 m above the surface of the earth. The kinetic energy of the propelled water allows you to create a barrier to fire with a width of 6 m and a depth of 0.4 m.

4. To extinguish a burning transformer, a 0.5 m ³ bomb was used, the shell of which is made of polyvinyl chloride, and the side surface is conical with a base radius of 0.4 m. 9 depressions are made on the bottom, the distances between the centers of which are 0.2 m. Depressions formed during the formation of the shell at the manufacturing stage. The volume of the bomb is filled with a powder extinguishing agent that insulates the burning surface. Inside the bomb, on a rigid cable at half the distance between the neck of the side surface and the bottom of the bottom, a piece of trotylhexogen weighing 1 kg is fixed. A radio fuse was used to detonate. The bomb is designed to be dropped from a helicopter. Undermining is carried out in such a way that the explosion occurs at a height of 10-30 m above a burning transformer. The kinetic energy of the propelled powder allowed to completely bring down the flame and isolate the surface of the transformer from the surrounding atmosphere.

5. To provoke a snow avalanche, two bombs with a volume of 0.4 m ³ were used, the shells of which are made of polybutyl vinyl, and the side surface of each bomb was made close to the pyramidal with sides of the base 0.6 m. 4 depressions were made on the bottom, distances between the centers of which amounted to 0.2 m. Depressions are formed during the formation of the shell at the manufacturing stage. Bombs are filled with water. Inside each bomb, an ammonal powder weighing 0.5 kg is fixed on a rigid cable at half the distance between the neck of the side surface and the bottom of the bottom. To detonate, they used a detonator and a fire cord. Bombs dropped from a helicopter. The fire-resistant cord is set on fire before the bomb is dropped so that the explosion (with subsequent rupture of the shell) occurs at an altitude of 20-40 m above the surface. The kinetic energy of the water caused a snow avalanche.

6. A bomb similar to Example 2, also dropped from a helicopter, was used to bring down the remains of the building that was damaged by the earthquake. The kinetic energy of the water allowed the building to be completely destroyed without danger to the Ministry of Emergencies.

7. To destroy the ice bridge, 8 bombs were used, similar to those used in example 1, but with a radio fuse. Bombs were dropped from a plane on a dive. As a result of such treatment, cracks appeared on the ice jumper, which allowed the icebreaking tug to destroy the jumper.

The use of a bomb of the proposed design allows the relatively closest analogue to expand due to the design features the scope of the bomb, increase its effectiveness and significantly reduce the cost of its production.

Claims (9)

1. A bomb containing a shell filled with liquid or powder, and an explosive charge mounted inside the shell, characterized in that the shell has a side surface expanding towards the bottom and a convex bottom, the bottom surface containing at least one cavity, the depth of which is not exceeds the distance from the bottom surface to the sectional plane passing along the perimeter of the bottom connection and the side surface of the shell. 2. The bomb according to claim 1, characterized in that it contains at least four of these depressions. 3. The bomb according to claim 1, characterized in that said depressions form a regular structure. 4. The bomb according to claim 1, characterized in that the side surface of the shell has a conical shape. 5. The bomb according to claim 4, characterized in that when the conical shape of the shell, the distance between the centers of the depressions is 40-80% of the radius of the circumference of the connection between the bottom and the conical part. 6. The bomb according to claim 1, characterized in that the side surface of the shell is made of a pyramidal shape. 7. A bomb according to any one of claims 1 to 6, characterized in that the depressions are made by attaching point portions of the bottom to a solid support located inside the shell. 8. The bomb according to claim 7, characterized in that the solid support is a perforated partition attached to the inner side of the shell at the junction of the bottom and side of the shell. 9. The bomb according to claim 7, characterized in that the support is a cord on which an explosive charge is fixed.