RU2524409C1 - Explosive device - Google Patents

Abstract

FIELD: blasting operations.

SUBSTANCE: explosive device comprises the main explosive charge, the detonation wave generator in the form of a matrix of inert material with a network of channels and openings with the common receiving part, filled explosive charges and coated, the source of initiation initiating the common receiving part. The matrix of the detonation wave generator is made of open-porous heat-resistant material having the property of sorption of explosive charge melt and free removal of gaseous products of decomposition of explosive charges. The matrix of detonation wave generator can be made of open-porous technical carbon material with nanopores, or of open-porous alumina with the porosity of 20 to 50%. The matrix material comprises explosive reagent chemically active reactive with respect to the melt and/or gaseous products of decomposition of explosive charge capable of reducing the rate of decomposition of explosive charges and its thermal effect.

EFFECT: increase in fire and explosion safety of explosive devices with detonation wave generator; preventing unwanted distribution of melt of explosive charges beyond the explosive device; providing thermal decomposition of explosive charges without acceleration, resulting in a flash, with reduction of the gaseous products of decomposition beyond the detonation wave generator.

7 cl, 4 dwg

Description

The invention relates to the field of explosive technology, comprising a detonation wave generator equipped with a fusible explosive substance, the melting point of which is below the temperature of the onset of intense decomposition. The invention can be used in the development of military munitions, explosive devices for use in economic activities (engineering charges, mining, mechanical engineering, etc.) and research activities.

The implementation of explosive technologies requires the use of various forms of detonation waves, which are usually obtained using discrete detonation wave generators (DVG) (Selivanov V.V., Kobylkin I.F., Novikov S.A. Explosive technologies: Textbook for universities / Under general Edited by V.V. Selivanov. - M.: Publishing House of MSTU named after N.E.Bauman, 2008 .-- 648 p.: ill., p. 67-70). The detonation wave generator is a network of channels and holes filled with explosives. The network of channels and holes is made in a special matrix made of a material inert to explosives. As a rule, metals and plastics are used as the matrix material for the detonation wave generator.

Explosives (BB), which are part of the DVG, are a source of increased danger, especially in emergency situations, accompanied by heating of the structure. As a rule, when explosives are heated, they decompose with the release of a large amount of gases. The danger of the presented situation is aggravated by the fact that the decomposition and combustion of explosives in confined spaces leads to an increase in pressure inside the DWG matrix and, as a consequence, to the transition of the combustion mode of the explosive to the explosive transformation mode. When the explosive is melted, it can flow out beyond the DVG and the melt gets on hot structural elements or a heating center, which can also lead to ignition of the molten explosive.

A device for generating a blast wave is known (US patent No. 3430563, IPC F42B 3/093, published 04.03.1969), containing the main explosive charge, an electrical initiation unit and an initiation unit, which is a matrix of plastic explosives with branched end sections located in the sheet an inert polymer in such a way that a blast wave diverging from the electric initiation assembly intersects a plurality of equal lengths of strips from the explosive and approaches a plurality of end sections of the explosive spaced uniformly across the sheet surface olimera. Thus, the main explosive charge is initiated simultaneously at points corresponding to the end sections in contact with it.

The disadvantage of this device is that when it is exposed to emergency thermal loading in the initiation unit, which is a matrix of plastic explosives with branched end sections located in an inert polymer sheet, the pressure of gaseous decomposition products of explosives will increase in the structure. In addition, due to the softening and deformation of the inert polymer sheet, the formation of local zones of accumulation of the molten explosive and its decomposition products is possible, which, in turn, can lead to ignition and subsequent explosion of the explosive. Also, during the deformation of the polymer sheet, gaps can be formed in the structure, through which the molten explosive can flow out and reach hot sections of the structure, which can also lead to ignition of the explosive melt and the entire structure as a whole.

The closest analogue is an explosive device (RF patent No. 2282818; IPC F42B 3/10; published in Bulletin No. 24 08/27/2006), containing the main explosive charge and an inert material matrix with a network of channels and holes filled to form protruding elements above the BB matrix, and used from the initiation source. The matrix from the side of the channels and holes is covered with a shell with through holes above the protruding elements of the explosives, the thickness of which exceeds the size of the protrusion of the explosives above the matrix.

The disadvantage of this device is that the proposed shell with through holes above the protruding elements of the explosive does not provide the possibility of an outflow of gases during the decomposition of the explosive in the design zones of the device with a tight pressing of the shell by the elements of the device body, for example, a lid, which can lead to increased pressure inside the sealed volumes explosion of explosives. In areas without preloading the shell, the presence of holes in the shell can contribute to the outflow of the molten explosive beyond the limits of the structure and the ignition of the molten explosive upon contact with hot elements or a fire.

Using the proposed technical solution, the problem of the safe operation of structures and devices containing explosive high-energy materials (explosives) is solved by localizing the explosive melt in the zone of its location and by removing the gaseous products of explosive decomposition from the structural zone of the detonation wave generator.

The technical result of the claimed invention is to increase the fire and explosion safety of explosive devices with a detonation wave generator; prevention of undesirable spread of the explosive melt outside the explosive device; providing thermal decomposition of explosives without acceleration leading to an outbreak, with the removal of gaseous decomposition products outside the detonation wave generator.

The technical result is achieved in that in an explosive device containing the main explosive charge, a detonation wave generator in the form of an inert material matrix with a network of channels and holes with a common receiving section filled with explosives and coated, an initiation source initiating a common receiving section, detonation matrix the wave generator is made of an open-porous heat-resistant material with the property of sorption of the explosive melt and free removal of gaseous decomposition products. The total absorption capacity of the matrix material is selected from the condition of sorption of at least the entire explosive mass included in the design of the detonation wave generator. The matrix of the detonation wave generator can be made of open-porous technical carbon material with nanopores. The matrix of the detonation wave generator can also be made of open-porous aluminum with a porosity of from 20 to 50%. The matrix material contains a reagent chemically active with respect to the melt and / or gaseous products, capable of reducing the decomposition rate and its thermal effect. The shell of the detonation wave generator is made of open-porous heat-resistant technical carbon material with nanopores. The detonation wave generator shell is made of open-porous aluminum with a porosity of 20 to 50%.

The use of open-porous heat-resistant material as a matrix of a detonation wave generator makes it possible to ensure the free outflow of gases generated during thermal decomposition of explosives outside the FER, eliminating the possibility of the formation of pressurized volumes and the danger of an increase in pressure in the explosive deployment zone. The heat resistance of the matrix material should ensure that the properties of the matrix are maintained at temperatures higher than the melting and thermal decomposition of explosives.

The sorption of the explosive melt is provided by the lyophilic properties of the matrix material, i.e. the ability to wet the matrix material with an explosive melt. When the DDA is heated to a temperature exceeding the explosive melting temperature, the formed melt, wetting the matrix material, is absorbed into its volume, eliminating the risk of the melt flowing out of the limits of the detonation wave generator. In this case, the volume of the DDA matrix should ensure sorption of at least the entire mass of explosives filling the network of channels and openings of the DDA.

When a detonation wave generator is introduced into the composition of the porous matrix of chemically active reagents with respect to the explosive melt, the decomposition rate of the explosive material absorbed into the material of the DWD matrix and its thermal effect are reduced.

When the matrix material is made of a material having relatively high heat capacity and thermal conductivity, there will be a rapid heat removal from the explosive melt that decomposes in the pores of the matrix, which reduces the decomposition rate and eliminates the flash.

The claimed explosive device is illustrated by the drawings presented in figure 1, figure 2, figure 3 and figure 4, where 1 is the main explosive charge; 2 - detonation wave generator of open-porous heat-resistant material with a network of channels and holes; 3 - fusible explosive filling the network of channels and openings of the DVR; 4 - source of initiation; 5 - common receiving area; 6 - a shell covering the network of channels and openings of the DVR; 7 - reagent chemically active to the explosive melt; 8 - pores.

Figure 1 presents the state of the design of the explosive device under normal operating conditions. Figure 2 - the state of the design of the explosive device after thermal exposure, leading to the melting of a fusible explosive located in the channels of the FDA.

The explosive device operates as follows. Under normal operating conditions, the detonation pulse from the initiation source 4 is transmitted through a common receiving section 5 to the explosive 3 filling the network of channels and openings of the detonation wave generator 2. The explosive 3 through the network of channels and openings initiates the main explosive charge 1, providing the necessary form of the initiation front main explosive charge. The shell 6, covering the network of channels and openings of the DDA, provides protection of the explosive 3 from external influences.

In the event of an emergency related to thermal exposure, the entire structure of the explosive device is heated. After reaching the melting point of the explosive 3, the matrix material of the detonation wave generator 2 begins to absorb the melt of the explosive 3. Next, the explosive 3 in the pores 8 begins to decompose and gaseous products are discharged through the open-porous structure outside the detonation wave generator 2 into the construction zone, which is connected to the external Wednesday. This eliminates the increase in pressure of decomposition products and the accumulation of explosive melt in the cavities of the structure. The heat released during the decomposition of EXPLOSIVES 3 is removed due to the high heat capacity and thermal conductivity of the DVR 2 material, reducing the decomposition rate and eliminating the danger of explosive outbreaks. Reagent 7, chemically active for the melt of explosive 3, also reduces the speed and thermal effect during the decomposition of explosives. When the shell 6 is made of an open-porous material similar to the material of the DEM matrix, an additional outflow of gases is provided.

Thus, the claimed explosive device, due to the applied technical solutions, provides increased safety for the operation of structures and devices containing a detonation wave generator with explosive, the melting temperature of which is lower than the temperature at which intensive decomposition began.

An example of a specific embodiment of an explosive device is shown in FIG. 3 (cross section) and FIG. 4 (top view).

The main explosive charge 1 is made of a heat-resistant explosive composition based on HMX. The matrix of the detonation wave generator 2 is made of open-porous technical carbon material with nanopores (TUMaN) with a network of channels and evenly spaced openings. The network of channels and openings of the DDA 2 is filled with plastic explosive 3 made of PT83 material (83% - TEN, 17% - polyisobutylene). An electric detonator installed on a common receiving section 5, consisting of a receiving hole and a channel connected to the network of channels of the DVR, is used as the initiation source 4, the receiving hole and the channel are also filled with PT83 material. The shell 6 of open-porous aluminum, covering the network of channels and openings of the DVR 2, is installed on the surface of the DVR using epoxy adhesive EL20. Diphenylamine, which is previously introduced into the matrix material of the detonation wave generator in the form of a solution, is used as a reactive reactant 7 reactive to the melt.

The explosive device operates as follows. When an electric detonator is activated, a PT83 plastic explosive is charged, loaded into the channels and openings of the common receiving section and the network of channels and openings of the detonation wave generator. A detonation pulse passing through a network of channels and openings of the DVR initiates the main explosive charge from a heat-resistant explosive composition with the necessary detonation front of the explosive device. Shell 6 of open-porous aluminum protects the network of channels and openings of the DDA from external influences.

When the explosive device is thermally exposed, the structure as a whole and the detonation wave generator structure in particular are heated. The explosive TEN, which is part of the plastic explosive PT83, decomposes rapidly at temperatures up to 139 ... 141 ° C with the formation of a large amount of gases. The gases formed, freely passing through the pores of the TUMaN material, are removed beyond the design of the detonation wave generator. When the temperature reaches 139 ... 141 ° C, the heater enters the melt and is absorbed by the pores of the TUMaN material, which has the property of lyophilicity (wetting) with respect to the heater. During the interaction of the TENA melt with diphenylamine, previously introduced into the matrix material of the detonation wave generator, the TEN decomposes under the influence of temperature at a lower speed and lower thermal effect, which ensures the absence of an explosive outbreak and increases safety during thermal emergency actions.

The effectiveness of the proposed technical solution is confirmed by a number of experimental studies conducted with full-scale explosive devices in real conditions of thermal exposure.

The proposed explosive device provides explosion safety of structures containing a detonation wave generator.

Claims (7)

1. An explosive device containing the main explosive charge, a detonation wave generator in the form of an inert material matrix with a network of channels and holes with a common receiving section, filled with explosives and coated, an initiation source initiating a common receiving section, characterized in that the detonation wave matrix the generator is made of an open-porous heat-resistant material having the property of sorption of the explosive melt and free removal of gaseous decomposition products of the explosive. 2. The explosive device according to claim 1, characterized in that the total absorption capacity of the matrix material is selected from the condition of sorption of at least the entire mass of explosives included in the design of the detonation wave generator. 3. The explosive device according to claim 1, characterized in that the matrix of the detonation wave generator is made of open-porous technical carbon material with nanopores. 4. The explosive device according to claim 1, characterized in that the detonation wave generator matrix is made of open-porous aluminum with a porosity of from 20 to 50%. 5. The explosive device according to claim 1, characterized in that the matrix material contains a reagent chemically active with respect to the melt and / or gaseous decomposition products of the explosive, capable of reducing the decomposition rate of the explosive and its thermal effect. 6. The explosive device according to claim 1, characterized in that the shell of the detonation wave generator is made of open-porous heat-resistant technical carbon material with nanopores. 7. The explosive device according to claim 1, characterized in that the shell of the detonation wave generator is made of open-porous aluminum with a porosity of from 20 to 50%.

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