RU2233426C2 - Method for destruction by group action of ammunitions - Google Patents

Abstract

FIELD: military equipment.

SUBSTANCE: rubber is introduced in the composition of the explosive, which provides for adhesion of the ammunition charge to the walls of the body and a detonating velocity not exceeding 6000 ms, and an initiating charge with a detonating velocity of not lower than 7600 ms is placed in the center of the ammunition; the ammunition are positioned on the terrain at a reduced distance from one another

(where R - the distance between ammunition, m; m - the charge mass, kg), which ensures interaction of gas dynamic flows of reacting substances and afterburning of the mixture of active products by air oxygen. An essentially enhanced efficiency of a group burst is attained, when the initiating ammunition is placed in the geometric center of the group blast.

EFFECT: enhanced efficiency of destructive action of mine armament, salvo-fire jet projectile systems, cluster bombs and other means of destruction, enhanced energy release at a burst of ammunition filled with explosive systems with a high content of metallic fuels by activation of the processes of initiation, dispersion and combustion in air of the composition components.

3 cl, 1 tbl

Description

The invention relates to defense technology and can be used to increase the effectiveness of the destructive action of mine weapons, multiple rocket launcher systems, cluster munitions and other types of weapons.

An analysis of patent sources shows that one of the main ways to increase the effectiveness of ammunition is to use explosive compositions with a high content of metallic fuels (more than 20% by weight) for their equipment. A number of patents are known on the creation of such compositions and methods. For example, in British patent No. 1411822, CL. Since 1 D, 1975, a description has been given of an explosive system comprising 50% (by weight) of metal powders, as well as hexogen and wax. In US patent No. 3713915, CL. 149-2, 1973, describes the characteristics of an explosive composition consisting of 25% aluminum powder and 75% liquid explosive.

Closest to the essence of the present invention is a method of engaging in a group action of ammunition, comprising supplying ammunition shells with charge components based on explosives, rubbers and metal combustible components with a total content of more than 20% by weight, installing ammunition in the field, installing initiating ammunition, putting into action ammunition charge initiating ammunition and ensuring the interaction of the components of the charge of the installed ammunition in detonation mode and doge Hassium energy release / Patent RU 2024820, IPC 7 F 42, 1994 /.

One of the main disadvantages of this method is the use of rubbers for its implementation, which are not able to provide adhesion of equipment to the shell of the ammunition and provide the necessary level of detonation speeds of the explosive composition. For this reason, the possibility of the occurrence of the stage of interaction of the metals that make up the composition with atmospheric oxygen is completely excluded, although this interaction determines, mainly, the high efficiency of the compositions with a high metal content.

The present invention is to develop a method of defeating the group action of ammunition. The technical result is an increase in energy release during the explosion of ammunition filled with explosive systems with an increased content of metallic fuels, by activating the processes of initiation, dispersion and combustion in the air of the components of the compositions.

(где R - расстояние между боеприпасами, м; m - масса заряда, кг), которое обеспечивает взаимодействие газодинамических потоков реагирующих веществ и дожигание смеси активных продуктов кислородом воздуха.The technical result is achieved by the fact that rubber is introduced into the composition of the explosive charge, which ensures adhesion of the ammunition charge to the walls of the body and a detonation velocity not exceeding 6000 m / s, and an initiating charge with a detonation velocity of not lower than 7600 m / s is placed in the center of the munition, this ammunition placed on the ground at a given distance from each other

(where R is the distance between the ammunition, m; m is the mass of the charge, kg), which ensures the interaction of the gas-dynamic flows of the reacting substances and the afterburning of the mixture of active products with atmospheric oxygen.

One of the most preferred options for implementing this method is the distribution of ammunition in a circle. In addition, a significant increase in the efficiency of a group explosion takes place when an additional one ammunition is installed in the geometric center of the group explosion.

For the implementation of the developed method, of significant interest are compositions based on liquid explosives, for example, composition PBXN-103. This composition is referenced in US patent No. 5467714. It consists of 27% aluminum powder, liquid explosives - trimethylol trinitrate, triethylene glycol dinitrate, as well as ammonium prechlorate and nitrocellulose. The introduction of some types of rubbers into compositions of a similar type, for example, divinyl, butadiene nitrile or polyisobutylene, ensures adhesion of the charge to the shell of the ammunition, an acceptable level of detonation velocities and a high combustion temperature due to the presence of ammonium perchlorate in the system.

One of the main factors determining the high efficiency of the developed method is the group use of ammunition with charges optimized by introducing rubbers.

As you know, the group method of destruction is implemented in mine weapons, various types of cluster munitions, multiple launch rocket systems. Mining systems, cluster munitions and various types of multiple launch rocket systems are described in detail in the book Weapons of Russia, Moscow: Military Parade Publishing House, 2000. In this catalog, devices for implementing this method are described in detail. From the materials presented it follows that, for example, using mine layers, it is possible to regulate the installation of mines on the ground within certain limits. For example, a universal mine layer allows you to set minefields at a depth of 15-240 m, the number of installed mines, depending on the destination, is 180-11520 pcs.

The main advantage of the existing methods of group destruction is that they exclude the possibility of taking additional measures of protection or relocation of the affected objects in the zone of group action of ammunition.

However, the known methods of destruction, based on the group action of ammunition in equipment with traditional types of explosives, as well as high-energy compositions with a high content of metallic fuels, have no advantages in the efficiency of the use of explosive energy compared to the action of single ammunition due to the lack of methods for influencing explosive processes that allow to exclude the effect of soil ejection on the completeness of the response of the components, as well as the lack of approaches to accelerate the processes of interactions in mixtures of explosion products with atmospheric oxygen. At the same time, a group detonation of ammunition in combination with other operations specific to the present invention provides the possibility of active impact on explosive processes.

, что обеспечивает оптимальные режимы взаимодействия газодинамических потоков реагирующих веществ в смесях с кислородом воздуха и высокие степени превращения энергии компонентов в энергию ударных волн.A characteristic difference between the group use of ammunition in the implementation of the developed method is the placement of ammunition in the range of given distances from each other

This ensures optimal modes of interaction of gas-dynamic flows of reacting substances in mixtures with atmospheric oxygen and high degrees of conversion of the energy of the components into the energy of shock waves.

Compositions with a high content of metallic fuels, as a rule, initiate and disperse an ignition-explosive device located in the bottom or head of the munition. At the same time, in a number of patents of recent years, there is a tendency to bring ammunition into action with a central (axisymmetric) ignition-explosive charge (for example, patent of the Russian Federation No. 2024820). Central ignition-explosive charge provides a more uniform crushing of the shell and ammunition equipment and is therefore more preferred for use in ammunition filled with metallized explosive compositions. Providing the level of detonation velocities of the central igniting explosive charge exceeding 7600 m / s and the level of detonation velocity of the main charge not exceeding 6000 m / s, the developed and proposed method not only performs uniform crushing of the hull and equipment, but also creates intensive mixing modes for active substances with oxygen.

One of the most preferred options for implementing this method is the placement of ammunition in a circle. In addition, a significant increase in the efficiency of a group explosion takes place when an additional one ammunition is installed in the geometric center of the group explosion.

A new set of operations characteristic of the developed method, as well as the presence of relations between them allow:

- the introduction of rubbers to ensure the adhesion of the explosive system to the walls of the body of warheads, and the combination of good adhesion properties with a high degree of filling of the compositions with metals leads to the fact that the chemical transformation of the filler particles located on the surface of the shell in the irregularities characteristic of metal shells proceeds in the combustion mode with temperature exceeding 2000 ° C, providing heating of fragments. Therefore, such fragments are able to accelerate the processes of chemical transformation in mixtures of explosion products with air.

- creating a difference in the detonation velocities of the main equipment and the explosive-explosive charge, ensure the destruction of the shell of the ammunition until the formation of the explosion products is completed, contributing to the acceleration and turbulence of the process of mixing the explosion products with air oxygen.

обеспечивают оптимальные режимы взаимодействия газодинамических потоков реагирующих веществ в смесях с кислородом воздуха, создавая при этом высокие степени превращения химической энергии компонентов в энергию ударных волн.- placement of ammunition in the range of reduced distances from each other

provide optimal modes of interaction of gas-dynamic flows of reacting substances in mixtures with atmospheric oxygen, while creating high degrees of conversion of the chemical energy of the components into the energy of shock waves.

- when a group of ammunition is distributed in a circle and when one additional ammunition is installed in the center of symmetry of a group of detonation of chemical energy into the energy of shock waves increase due to additional turbulence of the flow by compression and rarefaction waves propagating from the center of the group explosion region.

.With the simultaneous use of a large number of ammunition, they can be distributed between two and a large number of concentric circles, while the reduced distance between such circles corresponds to the optimal reduced distance between products

.

In addition to providing an increased level of energy release, the advantage of the developed method of group action of ammunition is the absence of the need for a rigid reference to the time of operation of the ammunition relative to each other, given the active role of hot fragments in the combustion of mixtures of explosion products with oxygen.

To determine the parameters of a group explosion of ammunition in accordance with the developed method, a series of experimental studies was carried out to measure the parameters of shock waves. For measuring pressure and momentum, knife-type piezosensors and sensors from Bruhl & Kj фирмыr were used. Sensors were installed at various points in the explosion field. Calculations of the energy of a unit of mass of equipment for munitions of munitions were carried out in accordance with the well-known formulas of Sadovsky.

For experimental work, steel models of high-explosive fragmentation munitions with a diameter of 130 mm were used. The mass of the explosive mixture in the layout was 5.0 kg. Conducted single and group trials of layouts. When conducting group bombings in one experiment, 4 to 20 mock-ups were used. Some of the prototype cases were filled with an explosive system, which includes 27% aluminum, liquid explosives, ammonium perchlorate, a number of processing aids and polymers that are unable to provide charge adhesion to the case.

To conduct the main series of tests, the mock-ups were filled with an analog of the indicated composition, the introduction of rubbers into which ensured the ability of the composition to adhere to the inner surface of the munition shell and reduce the detonation velocity (less than 6000 m / s). To achieve this goal, from 0.5 to 10% by weight of rubbers such as nitrile butadiene or polyisobutylene rubbers were introduced.

The main part of the mock-ups was brought into combat state by ignition-explosive charges, the detonation velocity of which was equal to or exceeded 7600 m / s. A number of models were used by ignition-explosive charges with a detonation velocity below 7600 m / s. As a criterion characterizing the effectiveness of the developed method of destruction, we used the TNT equivalent of the explosion.

The test results of various options for the implementation of the developed method (see table) indicate that the maximum levels of energy release occur in the presence of the entire set of operations inherent in the developed method, providing increased efficiency, namely when introducing the explosive system into the explosive system, the explosive charge is activated with a detonation velocity exceeding 7600 m / s, the distribution of ammunition in the range of distances that ensure the interaction of gas-dynamic flow ov reactive components in the air, and afterburning of active substances with heated fragments.

The distribution of ammunition in a circle and the activation of additional ammunition installed in the geometric center of a group detonation, provide an increase in the share of the realized energy potential of the explosive system.

For experimental testing of the developed method, various compositions based on liquid nitrates and nitro compounds with a high content of metallic fuels were used as equipment for the models.

An increase in the effectiveness of the group action took place in all cases when the introduction of rubbers into the filling ensured the adhesion of equipment to the warhead body and the detonation velocity of the compositions was less than 6000 m / s and when the detonation velocities of the ignition-explosive charge exceeded 7600 m / s and the ammunition was distributed on the ground in the range of reduced distances of 2.7-15.0 from each other. In addition, this effect is confirmed by group detonations of various types of full-scale munitions, differing in design and overall mass characteristics.

In all experiments conducted, the developed method provides a significant increase in the parameters of shock waves, energy indicators of the explosion, and damage levels of typical objects.

Claims (3)

1. The method of destruction by the group action of ammunition, including the equipment of ammunition shells with charge components based on explosives, rubbers and metal fuels with a total content of more than 20% by weight, the installation of ammunition on the ground, the installation of initiating ammunition, the activation of ammunition by the charge of the initiating ammunition and providing the interaction of the charge components of the installed ammunition in the mode of detonation and afterburning with the release of energy, characterized in that in the composition of the charges using comfort rubber, providing adhesion of the charge of the ammunition to the walls of the shell and a detonation speed not exceeding 6000 m / s, ammunition with an initiating charge with a detonation speed of at least 7600 m / s is located in the center of the location of the ammunition, while the ammunition is set on the ground at a given distance from each other from a friend defined from the expression

where R is the distance between the ammunition, m; m is the mass of charge, kg), which ensures the interaction of gas-dynamic flows of reacting substances and afterburning of a mixture of active products with atmospheric oxygen. 2. The method according to claim 1, characterized in that the ammunition is evenly distributed in a circle. 3. The method according to claim 1 or 2, characterized in that one initiating ammunition is installed in the center of symmetry of the group detonation.