EA006672B1 - Device for high-sensitive explosive reactive protection - Google Patents

Abstract

The inventive device for highly-sensitive reactive explosive protection comprises a body, the cavity of which is filled with a charge of explosive agent 3, two opposite walls of the body embodied in the form of protective plates 1, 2, capable at the moment of explosion to move relative each other, and each other wall is a multilayer structure and formed by flanging of the protective walls 1, 2. The charge of the explosive agent 3 comprises a crystalline high explosive and an inert binder, besides, microspheres from an inert material dia. 0.03…0.3 mm are distributed evenly in the charge 3. The crystalline high explosive agent makes up 80…95% of the total mass, the inert binder is 4…15% and microspheres from the inert material are 1…10%. The microspheres can be hollow, for example, from phenol-formaldehyde. Hexogen can be used as a crystalline high explosive agent, synthetic butadiene rubber with dioctylsebacate addition can be used as an inert binder. The density of the charge 3 is 1200…1400 kg/m3.The protective plates 1, 2 can be made from two different materials, for example, one from an aluminium alloy, the other from structural steel. In case two protective plates 1, 2 are made from materials having identical acoustic impedance, an additional plate 4 made from a material which acoustic impedance differs from that of the protective plates 1, 2 can be arranged in the device body being in contact with the charge 3 and one of the protective plates 1 or 2.

Description

The present invention relates to the field of protection of military objects from armor-piercing weapons.

The most effective use of the proposed device is to protect armored military equipment, such as tanks, from kinetic weapons, such as armor-piercing sabot shells of tank and anti-tank guns, as well as from cumulative anti-tank ammunition, such as anti-tank guided missiles, artillery shells, anti-tank ammunition grenades.

A device for protection against high-speed weapons according to the patent of the Russian Federation No. 2060438 dated March 4, 1993 is known. It is a closed container, the cavity of which is filled with an explosive charge, and two opposite walls are made in the form of protective plates that can move relative to each other during the explosion. Each of the remaining walls of the container is made of at least three layers. The ratio of acoustic impedances of materials of adjacent layers is at least 2.

When hit in such a device means of destruction, for example, a cumulative action, a cumulative jet pierces the upper protective plate and is introduced into the charge of explosive. The velocity of the head sections of the cumulative jet exceeds 8000 m / s, therefore, a ballistic shock propagates through the explosive directly in front of the cumulative jet head. At the shock wave front, an abrupt increase in pressure to a significant value takes place, ensuring the initiating action of the cumulative jet with respect to the explosive. As a rule, explosives used in the construction of reactive armor are sufficiently sensitive to the initiating action of a cumulative jet. Then a detonation occurs in the explosive charge. Metallic explosive charge exploded metal plates strike the cumulative jet, destroying it into separate fragments and deflecting these fragments from the original trajectory of movement so that they no longer fall into one cavity, increasing its depth, but scatter over the surface of the obstacle. This ensures a reduction in the armor-piercing effect of the cumulative jet.

When hit in the device according to the patent of the Russian Federation No. 2060438 of 03/04/93, an anti-tank armor-piercing projectile is equipped with an anti-tank or tank gun, it is also capable of carrying out a destructive effect, subject to the initiation of detonation in the explosive charge. It is known that armor-piercing sub-caliber projectiles have a significantly lower initiating effect compared with the cumulative jet, since the impact velocity on the barrier of modern sub-caliber projectiles does not reach 2000 m / s, while the velocity of the head sections of the cumulative jet exceeds 8000 m / s. Accordingly, the pressure at the front of a shock wave moving along an explosive before an armor-piercing sub-caliber projectile is much less than for the case of penetration of a cumulative jet. Thus, for the implementation of the destructive effect on the means of destruction of the type of armor-piercing sub-caliber projectiles, it is necessary to ensure reliable initiation of the explosive charge in the protective device. One of the most simple and obvious solutions is to increase the sensitivity of an explosive charge. However, the simple use of known highly sensitive explosives does not allow to solve this problem. Such sensitive explosives can detonate when they hit not only the armor-piercing sub-caliber projectiles, but also when they hit small-arms bullets, small-caliber artillery shells, high-explosive shells and other weapons that do not pose an immediate threat to an armored object, such as a tank. This will lead to the fact that on the battlefield the tank will quickly lose the explosive reactive protection installed on it. In addition, high sensitivity to mechanical stress makes such explosives dangerous in service handling, for example, in case of accidental fall. Finally, it is known that with increasing sensitivity of explosives, their explosive characteristics decrease, such as detonation speed, heat of explosion, etc., which are important for effective influence on a penetrating anti-tank weapon.

The basis of the present invention is to create a protection device with sufficient sensitivity to the initiating action of the armor-piercing sub-caliber projectile, while maintaining the absence of detonation when hit by small arms bullets, small-caliber artillery shells and debris, as well as safe in service use.

The problem is solved in that the device is highly sensitive reactive explosive protection, comprising a housing, a housing cavity filled with a plastic explosive charge, which consists of a crystalline high explosive and a polymeric binder, two opposite walls of the housing are made in the form of protective plates that can move during an explosion one relative to the other, and each of the other walls is made of a multilayer and formed by flanging of protective plates.

According to the invention, microspheres of inert material with a diameter of 0.03-0.3 mm are evenly distributed in the charge of a plastic explosive. The mass fraction of crystalline blasting explosive is 80-95%, the mass fraction of inert binder is 4-15%, and the mass fraction of microspheres of inert material is 1-10%.

- 1 006672

To obtain a given level of sensitivity of the explosive charge to the initiating action of the armor-piercing sub-caliber shells, the microspheres are made hollow. As shown by the experiments, one of the most suitable materials for the manufacture of microspheres is phenol formaldehyde. Microspheres can also be made of sodium borosilicate glass.

The most efficient use of hexogen as a crystalline blasting explosive, synthetic butadiene rubber with the addition of dioctyl sebacate as a polymer binder. The choice of the composition of the components is determined, on the one hand, by the explosive characteristics of the resulting composition, on the other, by its technological characteristics. Butadiene rubber serves as a binder for the remaining components. The addition of dioctyl sebacate increases the plasticity of the mixture, which is beneficial when the explosive charge is formed and when the device case is filled with an explosive charge, and it also helps to avoid an excessive increase in the sensitivity of the explosive charge to mechanical stress. The range of ratios of rubber and dioctyl sebacate is, respectively, from 1: 1.5 to 1.5: 1. The charge density of plastic explosive is 1200-1400 kg / m ³ .

An additional increase in the sensitivity of the device to the initiating action of the armor-piercing sub-caliber projectile is due to the fact that the protective plates of the device are made of two different materials, and the acoustic impedance of the material of the protective plate located first along the penetrating means of destruction is less than the acoustic impedance of the material of the second protective plate. One of the protective plates of the device (the first) can be made of aluminum alloy, while the second is made of structural steel.

In the event that both protective plates of the device are made of materials whose acoustic impedance is the same, an additional plate may be placed in the cavity of the device in contact with the explosive charge and one of the protective plates.

Moreover, if the additional plate is in contact with the protective plate, which is located first along the penetrating means of destruction, the acoustic impedance of the material of the additional plate must be less than the acoustic impedance of the protective plate in contact with it. For example, if both protective plates of the device are made of steel, then the additional plate that comes in contact with the protective plate located first along the lesion can be made of aluminum alloy.

If the additional plate is in contact with the protective plate, which is located second along the penetrating means of destruction, the acoustic impedance of the material of the additional plate must be greater than the acoustic impedance of the protective plate in contact with it. For example, if both protective plates of the device are made of aluminum alloy, then the additional plate in contact with the protective plate located along the second means of destruction may be made of steel.

Below, the present invention is explained in the detailed description of a specific embodiment with reference to the accompanying drawings, in which FIG. 1 shows a highly sensitive reactive explosive protection device made according to the invention, a longitudinal section;

FIG. 2 depicts a radiograph of the process of interaction of a highly sensitive reactive explosion protection device with a cumulative jet;

FIG. 3 shows a highly sensitive reactive explosive protection device made according to the invention, with an additional plate in contact with one of the protective plates and with an explosive charge, installed as part of the reactive armor of the protected object, a longitudinal section.

The device of reactive armor, made according to the invention (Fig. 1), includes a case, two opposite walls of which are made in the form of protective plates 1, 2. The protective plates 1, 2 are made of structural steel, flanged, inserted one into the other and connected between by means of local rolling of the edges of the flanging of the plate 2. The flanging of the protective plates 1, 2 form a cavity in which the charge of explosive 3 is placed with a thickness of 6 mm. Flanging protective plates 1, 2 limit the charge of the explosive 3 from the front sides, preventing it from moving. The gap between the flanging plates 1, 2 is filled with a sealing material to prevent moisture from entering the cavity between the protective plates 1, 2, in which the explosive charge 3 is located. The charge of explosive 3 in this specific example includes crystalline hexogen, the mass fraction of which is 87%, polymer binder - 10% (low molecular weight synthetic rubber - 4.5%, dioctylsebacate 5.5%). The remaining 3% of the mass of explosive charge are microspheres with a diameter of 0.03-0.25 mm, made hollow and made of phenol-formaldehyde.

The operation of the proposed device (Fig. 1) is as follows.

When hit in a reactive armor containing the proposed device (Fig. 1), a cumulative means of destruction, such as anti-tank guided missiles, the device operates

- 2 006672 is as follows. A cumulative jet pierces the first protective plate 1 of the device case and is inserted into the charge of the explosive 3, in which it initiates detonation. This has a positive effect on the effectiveness of the protection of the fact that detonation occurs in the explosive charge 3 as a result of the action of a transmitted shock wave, and not as a result of a shock wave reflected from the back protective plate 2, as is the case in the prototype. The process of detonation of the charge 3 of the explosive develops faster, the protective plates 1 and 2 start to move earlier and carry out a destructive effect on the penetrating cumulative jet earlier. As a result, the length of the so-called "leading part" of the cumulative jet passing through the proposed device (Fig. 1) at the initial time without impact during the development of the detonation in explosive charge 3 and speeding by the protective plates 1, 2 sharply decreases. Fig. 1) the "leading part" is practically absent, as shown by the results of X-ray impulse studies shown in Figs. 2. As seen from the radiographs of FIG. 2, the cumulative jet received significant damage, lost continuity, part of the material of the cumulative jet dispersed in the dusty fraction. It is obvious that the armor-piercing effect of the cumulative jet that received such damage is significantly reduced.

When an armor-piercing sub-caliber projectile hits a reactive armor protection containing the proposed device (Fig. 1), the projectile first pierces the armor cover of the reactive armor cell, made, as a rule, of armor steel of high hardness. Then the projectile pierces the protective plate 1 of the proposed device. In this case, a shock wave arises in the material of the protective plate 1, advancing the penetration of the projectile into this plate 1. The shock wave penetrates into the charge 3 of the explosive. In the process of movement of the shock wave in charge of 3 explosives, the front of the shock wave is curved, bending around the microspheres of inert material. Around the front of each microsphere, a shock front region is formed, having a shape close to spherical. When moving inside the microsphere having a cavity, the shape of the shock wave front is additionally aligned, acquiring a shape that is even closer to spherical. As a result of the collapse of the spherical portion of the shock front in the center of the microsphere, pressure and temperature sharply increase. Since the microspheres are evenly distributed over the charge 3 of the explosive, a plurality of initiation foci arise in it, providing the initiation of detonation of the charge 3 of the explosive. Under the action of the explosion of the explosive charge 3, the protective plates 1 and 2 of the proposed device are thrown (FIG. 1). The protective plates 1, 2 strike the penetrating projectile, in addition, they involve other parts of the reactive armor in motion, such as an armored cell cover, which also strike the penetrating projectile. As a result of such a complex effect, the armor-piercing ability of an armor-piercing sub-caliber projectile decreases significantly.

It is known that the pressure in the shock wave arising from the impact of the projectile on the barrier, significantly depends on the speed of the collision. Starting speed when firing modern feathered armor-piercing piercing shells can be from 1650 to 1800 m / s. When moving along the trajectory as a result of aerodynamic drag, the velocity of the projectile decreases by 50-100 m / s for the first 1000 m distance. At the second thousand meters of distance, the velocity of the projectile decreases by another 130-170 m / s. As a result, when firing from a long range, the velocity of the impact of a projectile with a target can be 1300-1400 m / s. Accordingly, the pressure in the shock wave will also be reduced and, possibly, its value will be insufficient to initiate the detonation of the explosive charge. In order to increase the sensitivity of the claimed device to the initiating action of a low intensity shock wave, in the device of FIG. 3 protective plates 1, 2 are made of aluminum alloy. Between the protective plate 2, and the explosive charge 3 is placed an additional plate 4, which is made of structural steel.

When an armor-piercing piercing projectile 6 hits the steel armor cover 5 of the reactive armor cell, a shock wave arises in it. In the process of propagation of a shock wave, it crosses the interface between two media, moving from a steel armor cover 5 into an aluminum protective plate 1 of the proposed device (Fig. 3). At the same time, according to calculations, the pressure at the front of the shock wave arising in the aluminum protective plate 1 will be 80–100% higher than if this plate were made of steel. A shock wave with such elevated parameters is more likely to initiate a detonation in the explosive charge 3. If the pressure at the shock front is still insufficient to initiate detonation, then in the process of further propagation through the explosive charge 3, the shock wave encounters an additional plate 4 made of steel. Upon reflection of the shock wave from this plate 4, the pressure at the front of the reflected shock wave increases even more (doubles in the first approximation), resulting in the initiation of the charge of the explosive 3. Further work of the proposed device (Fig. 3) is carried out as it was indicated earlier. It should be noted that the proposed device with the above characteristics in the composition of the layout of explosive reactive armor was fired at by armor-piercing sub-caliber shells in-situ. In this case, the initiation of explosive charges in the proposed device occurred at the impact speed of a sabot projectile, equal to 1350-1400 m / s.

- 3 006672

The proposed device is most efficiently used as a set of such devices as part of explosive reactive armor installed on armored ground objects, mainly of medium and heavy mass categories: tanks, tank support combat vehicles, special vehicles, as well as building structures for various purposes.

Claims (12)

CLAIM 1. The device is highly sensitive reactive explosive protection, comprising a case, a case cavity filled with an explosive charge, which includes a crystalline high explosive and a polymer binder, two opposite walls of the case are made in the form of protective plates capable of moving one relative to the other during the explosion, each of the remaining walls are made of multilayer and formed by flanging protective plates, characterized in that in the explosive charge the microns are evenly distributed spheres of inert material, made with a diameter of 0.03-0.3 mm, the mass fraction of crystalline high explosive is 80-95%, the mass fraction of the polymer binder is 4-15%, and the mass fraction of microspheres of inert material is 1-10 % 2. The device according to claim 1, characterized in that the microspheres of inert material is made hollow. 3. The device according to claim 1, characterized in that the microspheres of inert material made of phenol-formaldehyde. 4. The device according to claim 1, characterized in that the microspheres of inert material made of sodium borosilicate glass. 5. The device according to claim 1, characterized in that hexogen is used as a crystalline blasting explosive, and synthetic butadiene rubber is used as a polymeric binder with addition of dioctyl sebacinate in a ratio from 1: 1.5 to 1.5: 1, and the density explosive charge is 1200-1400 kg / m ³ . 6. The device according to claim 1, characterized in that its protective plates are made of two different materials, wherein the acoustic impedance of the material of the protective plate located along the means of destruction of the first one is less than the acoustic impedance of the material of the second protective plate. 7. The device according to claim 1, characterized in that an additional plate is placed in the cavity of the device in contact with an explosive charge and one of the protective plates. 8. The device according to claim 6, characterized in that one of its protective plates is made of aluminum alloy, and the second is made of structural steel. 9. The device according to claim 7, characterized in that the additional plate is in contact with the protective plate, which is located along the means of destruction of the first, and the acoustic impedance of the material of the additional plate in contact with the explosive charge is less than the acoustic impedance of the material in contact with it protective plate. 10. The device according to claim 7, characterized in that the additional plate is in contact with the protective plate, which is located along the means of destruction of the second, and the acoustic impedance of the material of the additional plate in contact with the explosive charge is greater than the acoustic impedance of the material in contact with it protective plate. 11. The device according to claim 9, characterized in that its protective plates are made of structural steel, and the additional plate is made of aluminum alloy. 12. The device according to claim 10, characterized in that its protective plates are made of aluminum alloy, and the additional plate is made of structural steel.