KR102627761B1 - Non-initiating tandem warhead with precursor forming powder jet against explosive reactive armor - Google Patents

Abstract

The present invention is a dual warhead consisting of a precursor warhead that neutralizes the explosive reactive armor, which is an additional armor of a tank, without detonating it, and a main warhead that can destroy the main armor, and in order to maximize the penetration power of the main warhead jet, the residue of the precursor warhead jet is It relates to an explosive reactive armored micro-detonation dual warhead with a precursor warhead that forms a powder jet that prevents any residue.

Description

Non-initiating tandem warhead with precursor forming powder jet against explosive reactive armor}

The present invention is a dual warhead consisting of a precursor warhead that neutralizes the explosive reactive armor, which is an additional armor of a tank, without detonating it, and a main warhead that can destroy the main armor, and in order to maximize the penetration power of the main warhead jet, the residue of the precursor warhead jet is It relates to an explosive reactive armored micro-detonation dual warhead with a precursor warhead that forms a powder jet that prevents any residue.

Shaped charge is a representative warhead technology that has been applied to anti-tank weapon systems, and a jet with large kinetic energy penetrates the target and causes damage. Explosive reactive armor is attached to the main armor of the tank to effectively defend against these shaped charge jets that pose a threat to the tank. Explosive reactive armor is basically filled with gunpowder in a sandwich shape between two thin steel plates. When the explosive reactive armor is detonated by a shaped charge jet, the steel plate interferes with the jet while flying, making it a very efficient additional armor that can significantly reduce the penetration performance of the shaped charge jet.

A dual shaped charge warhead is applied to the anti-tank weapon system to counter tanks equipped with Explosive Reactive Armor (ERA), which is highly effective against single shaped charge warheads. The dual shaped charge warhead consists of a precursor warhead and a main warhead using shaped charge technology. The precursor warhead located at the front forms a jet with large kinetic energy to detonate and remove the explosive reactive armor attached to the tank, thereby detonating the main warhead. It is a warhead system whose jets destroy the main armor of a tank without being hindered by explosive reactive armor.

However, in order to increase the protection performance against the conventional double-shaped charge warhead developed in this way, thick steel plates were applied to the explosive reactive armor to affect the main warhead jet with steel plates with a low flight speed, or a large-area flight steel plate was applied to guided weapons. Explosive reactive armor has been developed through methods such as direct damage, and the technology of explosive reactive armor has advanced to the point where the penetrating power of the main warhead is lost because the existing precursor warhead cannot completely remove the reactive armor. Therefore, in order to respond to the latest explosive reactive armor, the need for a new concept of warhead system, different from the existing method of detonating and removing explosive reactive armor, has emerged.

In the applicant's pre-registered patent No. 10-2465010, the precursor warhead with Explosively Formed Penetrator (EFP) technology is used to secure a movement path that minimizes the impact on the main warhead jet without detonating the explosive reactive armor. Although a dual warhead was introduced that maximizes the main warhead penetration power, the general penetrator formed from a precursor warhead using explosive shaped penetrator technology has a limitation in that residue remains after penetrating the target, affecting the main warhead jet penetration power.

Prior Document 1 (Registered Patent 10-2465010 Explosive reactive armor, double warhead with non-detonation precursor warhead)

The present invention was devised to solve the above-mentioned problems, and forms a jet in the form of a low-density powder that does not explode the gunpowder of the explosive reactive armor while forming a through hole through which the main warhead jet can pass through the explosive reactive armor. The purpose is to provide an explosive reactive armored micro-detonation dual warhead using a precursor warhead that can

In order to solve the above problems, an explosive reactive armored non-detonated dual warhead applying a precursor warhead forming a powder jet according to an embodiment of the present invention includes a projectile body equipped with a warhead therein, and disposed at the front inside the projectile body, It is characterized by comprising a precursor warhead that forms a powder jet and a main warhead disposed inside the projectile body at the rear of the precursor warhead and penetrating the main armor through a through hole formed by the precursor warhead.

Here, the precursor warhead is capable of penetrating the tank's explosive reactive armor without detonating, and includes a powder jet forming liner made using metal powder and a first charge that applies explosive pressure to the powder jet forming liner. It is characterized by:

At this time, the liner for forming the powder jet is characterized in that it is formed concavely with respect to the front of the coal body.

At this time, the liner for forming a powder jet is characterized in that it is transformed into a powder jet that protrudes toward the explosive reactive armor and main armor by the explosive pressure of the first charge.

The liner for forming a powder jet is manufactured by mixing metal powder and a binder, powder injection molding into a liner shape, removing the binder with solvent and hot degreasing, pre-sintering, manufacturing a skeleton, and then impregnating it with a polymer-based material. do.

The main warhead is characterized in that it is provided with a main warhead liner that is open to form a space on the precursor warhead side, and a second charge capable of providing explosive pressure to the main warhead liner side is provided behind it.

Here, the main warhead liner is characterized in that it is formed concavely with respect to the front of the shell.

At this time, the main warhead liner is characterized in that it is transformed into a jet shape protruding toward the explosive reactive armor and main armor by the explosive pressure of the second charge.

At this time, the main warhead may further include an explosion wave modulator provided inside the second charge to change the path of the explosion.

Here, the explosion wave modulator is characterized in that it can be manufactured from any one of plastic materials and metal materials.

According to one embodiment of the present invention, the explosive reactive armored non-detonated dual warhead using a precursor warhead that forms a powder jet allows the precursor warhead to penetrate the main warhead without detonating the explosive reactive armor provided on the tank in an anti-tank weapon system. It has the effect of maximizing the penetration power of the main warhead by securing a clear path.

In addition, the liner provided in the precursor warhead is a liner for forming a powder jet. When the precursor warhead penetrates the explosive reactive armor, no residue is left, thereby securing a path for the main warhead jet to pass through, thereby maximizing the main warhead penetration power. There is an effect.

In addition, a liner manufactured with a structure to form a powder jet has a lower density than a liner manufactured through forging/processing that was previously used, which has the effect of reducing the weight of the warhead.

Figure 1 is a conceptual diagram of an explosive reactive armored unexploded dual warhead applying a precursor warhead that forms a powder jet according to an embodiment of the present invention.
Figure 2 shows (a) a powder jet, (b) a typical shaped charge jet, and (c) a typical explosive shaped penetrator ( c) Shape comparison diagram
Figure 3 is an X-ray comparison photo of (a) the powder jet of an explosive reactive armored micro-explosion dual warhead applying a precursor warhead forming a powder jet according to an embodiment of the present invention and (b) a typical shaped charge jet.
Figure 4 is a flow chart of manufacturing a liner for forming a powder jet in an explosive reactive armored unexploded dual warhead applying a precursor warhead that forms a powder jet according to an embodiment of the present invention.
Figure 5 is a conceptual diagram of the operation of a typical dual-type charge warhead.
Figure 6 is a conceptual diagram of the operation of an explosive reactive armored unexploded dual warhead applying a precursor warhead that forms a powder jet according to an embodiment of the present invention.
Figure 7 is a photograph showing the test results of a precursor warhead forming a powder jet according to an embodiment of the present invention.

The present invention relates to a dual warhead consisting of a precursor warhead that neutralizes the explosive reactive armor, which is an additional armor of a tank, without detonating it, and a main warhead that can destroy the main armor. In particular, the precursor warhead forms a powder jet and leaves no residue. It is characterized by maximizing the penetration power of the main warhead jet by preventing any residue.

Hereinafter, an explosive reactive armored unexploded dual warhead using a precursor warhead forming a powder jet according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

Figure 1 is a conceptual diagram of an explosive reactive armored unexploded dual warhead using a precursor warhead that forms a powder jet according to an embodiment of the present invention.

Referring to Figure 1, the present invention is a shell 100 equipped with a warhead inside, which is disposed at the front inside the shell 100, and creates a through hole without exploding the steel plate and gunpowder of the explosive reactive armor 20. A precursor warhead (200) and a main warhead (300) disposed inside the projectile body (100) at the rear of the precursor warhead (200) and penetrating the main armor through the through hole formed by the precursor warhead (200). It is composed including.

Here, the precursor warhead 200 is capable of penetrating the explosive reactive armor 20 of the tank without detonating, and includes a powder jet forming liner 210 made using metal powder and the powder jet forming liner ( It is configured to include a first charge 220 that applies pressure to the 210) side.

At this time, the liner 210 for forming a powder jet is formed concavely with respect to the front of the shell 100, and has various shapes such as a cone, a trumpet shape, and a dish shape applied to the explosive forming penetrator technology. It can be applied.

And, if necessary, an explosion wave modulator may be applied to the first charge 220.

The liner 210 for forming such a powder jet can be made of metal powder materials such as aluminum, tungsten, and copper.

When the powder jet forming liner 210 is used, it is transformed into a powder jet that protrudes toward the explosive reactive armor 20 and the main armor 10 by the explosive pressure of the first charge 220, effectively transforming the main warhead 300. It becomes possible to form a path that can pass through.

The liner 210 for forming such a powder jet has a lower density than the liner manufactured through forging/processing that was previously used, allowing the weight of the warhead to be reduced.

The gunpowder of the first charge 220 may be a high-explosive gunpowder containing RDX, HMX, etc. as main ingredients.

Meanwhile, as can be seen in the [mathematical formula] below regarding the detonation standard for gunpowder, the density of the jet is one of the main factors in exploding gunpowder.

Accordingly, in order to prevent the gunpowder of the explosive reactive armor 20 from exploding, a powder jet forming liner 210 capable of forming a low-density powder jet is applied.

In other words, it is important to design the precursor warhead so that it can form a powder jet with an appropriate density and speed that can penetrate the reinforced steel plate without exceeding the critical value I _Cr so that the gunpowder applied to the latest explosive reactive armor does not detonate.

The powder jet formed in the precursor warhead 200 by the powder jet forming liner 210 manufactured as described above forms a relatively large through hole compared to the jet of a typical shaped charge warhead, and forms a path through which the main warhead jet can pass. can be made.

At this time, the through hole formed in the explosive reactive armor by the precursor warhead 200 is formed at least 0.3 times the charge diameter (CD).

[Equation]

I _Cr : Detonation threshold of gunpowder in explosive reactive armor

v: Velocity of the penetrator (jet)

ρ _p : Density of penetrator (jet)

ρ _t : Density of gunpowder in explosive reactive armor

d: diameter of penetrator

The main warhead 300 is provided with a main warhead liner 310 that is open to form a space toward the precursor warhead 200.

And behind it, a second charge 320 is provided that can provide explosive pressure to the main warhead liner 310.

Here, the main warhead liner 310 is formed concavely with respect to the front of the projectile 100, and various shapes such as cone and trumpet can be applied.

And, if necessary, an explosion wave modulator 330 may be applied inside the second charge 320.

The main warhead liner 310 may use metal materials such as copper, aluminum, and iron.

The second charge 320, like the precursor warhead 200, can use high-explosive gunpowder mainly containing RDX and HMX, and the explosive wave modulator uses plastic materials such as polycarbonate and PTEF (polytetrafluoroethylene), and metals such as aluminum and iron. Materials, etc. can be used as materials.

Depending on each gunpowder, liner, and blast wave modulator material, the jet generated from the main warhead must have high kinetic energy to penetrate the main armor.

The main warhead liner 310 is transformed into a jet shape protruding toward the explosive reactive armor 20 and the main armor 10 by the explosive pressure of the second charge 320, and penetrates the penetration path formed by the precursor warhead 200. This allows the main warhead jet to pass smoothly.

Due to this, when used in a tank, the precursor warhead 200 does not detonate the gunpowder of the explosive reactive armor 20, but forms a through hole and a powder jet so that no residue is left, so the main warhead moves smoothly. It is possible to penetrate the armor (10).

Figure 2 shows the shape of a powder jet (a) of an explosive reactive armored micro-explosion dual warhead applying a precursor warhead forming a powder jet according to an embodiment of the present invention with a general shaped charge jet (b) and an explosive shaped penetrator (c). is compared.

Figure 3 is an X-ray photograph comparing the powder jet (a) of an explosive reactive armored micro-detonated dual warhead using a precursor warhead forming a powder jet according to an embodiment of the present invention with a typical shaped charge jet (b).

Referring to Figures 2 and 3, a typical shaped charge jet (a) has high kinetic energy due to its very high speed, and such a jet penetrates the explosive reactive armor and collides with the gunpowder inside, causing an explosive reaction.

Such a jet according to a typical shaped charge has the possibility of detonating the gunpowder of the explosive reactive armor (20), and if the explosive reactive armor (20) is not removed by explosion, it actually interferes with the penetrating power of the main warhead (300). It can be.

On the other hand, referring to (a) of FIG. 2 and (a) of FIG. 3, the powder jet generated by the precursor warhead 200 has a relatively low density in the form of powder, so it penetrates the gunpowder in the explosive reactive armor 20 and releases the gunpowder. The detonation threshold may not be exceeded.

That is, the precursor warhead 200 can form a penetration hole without detonating the explosive reactive armor 20.

And in forming a path through which the main warhead 300 can pass through the main armor 10, a powder jet is formed so that no residue is left, thereby reducing the penetration power of the main warhead 300 due to the residue. It can be prevented.

Figure 4 is a flow chart for manufacturing a liner for forming a powder jet in an explosive reactive armored non-detonated dual warhead applying a precursor warhead for forming a powder jet according to an embodiment of the present invention.

Referring to FIG. 4, the liner 210 for forming a powder jet mixes metal powder and a binder (volume ratio: 40 to 60%) and injects the powder into a liner shape.

Afterwards, the binder is removed by solvent and hot degreasing, and the skeleton is manufactured by pre-sintering, and then impregnated with a polymer-based material to secure a strength sufficient to handle and to homogeneously disperse the powder particles. A liner 210 for forming a powder jet. can be produced.

Additionally, the liner 210 for forming a powder jet can be manufactured only from a metal material with weak brittleness.

As a result, the powder jet forming liner 210 does not detonate the explosive reactive armor 20 and forms a penetration hole without leaving any residue, and thus when the main warhead 300 penetrates the main armor 10 , it is possible to prevent reduction in penetration due to residue.

Figure 5 is a conceptual diagram of the operation of a general double star warhead.

Referring to FIG. 5, in a typical dual-type charge warhead, the jet according to the precursor warhead (30) is removed by detonating the explosive reactive armor (20), and the jet according to the main warhead (40) causes damage to the main armor (10). It will be put on.

Figure 6 is a conceptual diagram of the operation of an explosive reactive armored micro-detonation dual warhead using a precursor warhead forming a powder jet according to an embodiment of the present invention, and Figure 7 is a diagram of the operation of a precursor warhead forming a powder jet according to an embodiment of the present invention. This is a photo showing the test results.

Referring to Figures 6 and 7, in the operation of a dual warhead to which the powder jet forming liner 210 is applied, the powder jet forming liner 210 is powdered by the explosion pressure of the first charge 220 in the precursor warhead 200. It is transformed into a jet shape and forms a through hole in the explosive reactive armor (20), and the main warhead liner (310) is transformed into a jet form by the second charge (320) in the main warhead (300), forming the main armor (10). It becomes possible to penetrate.

At this time, the diameter of the through hole of the explosive reactive armor 20 formed by the precursor warhead 200 is formed to be 0.3 times or more than the gunpowder diameter of the precursor warhead 200.

Meanwhile, the powder jet forming liner 210 minimizes residue by forming a powder jet when penetrating the explosive reactive armor 20, so that when the main warhead 300 penetrates the main armor 10, the residue is This can prevent penetration efficiency from decreasing.

In the present invention made as described above, when destroying the armor of a tank, the precursor warhead first contacts the explosive reactive armor, forms a penetration hole without detonating the explosive reactive armor, and forms a path through which the main warhead can penetrate the main armor. In addition to allowing the main armor to penetrate the main armor without being affected by the explosive reactive armor, the precursor warhead is equipped with a liner for forming a powder jet to prevent residues from being left by the powder jet, thereby eliminating the residue of the precursor warhead. This prevents the penetration power of the main warhead from being reduced.

100: Cartridge 200: Pioneer warhead
210: Liner for forming powder jet 220: First peony
300: Main warhead 310: Main warhead liner
320: Second Peony 330: Explosion wave modulator
10: Main armor 20: Explosive reactive armor

Claims (15)

A shell body (100) equipped with a warhead therein;
A precursor warhead 200 disposed at the front inside the shell 100 and forming a powder jet; and
A main warhead (300) disposed behind the precursor warhead (200) inside the projectile body (100) and penetrating the main armor through a through hole formed by the precursor warhead (200);
The precursor warhead includes a powder jet forming liner 210 made using metal powder and a first charge 220 that applies explosive pressure to the powder jet forming liner 210,
The liner 210 for forming a powder jet of the precursor warhead has a front-end narrow shape that widens toward the front,
The liner 210 for forming a powder jet is powder injection molded into a liner shape by mixing the metal powder and a binder (volume ratio: 40 to 60%), then removing the binder with a solvent and hot degreasing and pre-sintering to form a skeleton. After manufacturing, it is manufactured by impregnating polymer-based materials.
The powder jet forming liner 210 is transformed into a powder jet toward the explosive reactive armor 20 by the explosive pressure of the first charge 220,
The precursor warhead 200 forms a through hole in the explosive reactive armor 20 by the powder jet,
The main warhead liner (310) is an explosive reactive armored micro-detonation double warhead using a main warhead, characterized in that the main warhead liner (310) is transformed into a jet shape toward the explosive reactive armor (20) by the explosive pressure of the second charge (320).
In claim 1,
The precursor warhead (200) is an explosive reactive armored non-detonated double warhead using a precursor warhead that forms a powder jet, characterized in that it penetrates the main armor without detonating the explosive reactive armor (20) of the tank.
In claim 2,
The through hole is formed in the explosive reactive armor and the main armor, respectively. An explosive reactive armored micro-detonation dual warhead applying a precursor warhead forming a powder jet,
delete delete delete delete delete In claim 1,
An explosive reactive armored micro-detonation double warhead using a main warhead, characterized in that a certain space is formed between the main warhead and the precursor warhead (200).
delete delete In claim 1,
The main warhead 300 is provided inside the second charge 320 and further includes an explosive wave modulator 330 that changes the path of the explosion. .
In claim 12,
The explosive wave modulator 330 is an explosive reactive armored non-detonated double warhead using a main warhead, characterized in that it contains either a plastic material or a metal material.
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