KR20180006196A - 40mm high explosive dual purpose - Google Patents

Abstract

The present invention relates to a 40mm dual purpose high explosive, and more particularly to a 40mm dual purpose high explosive that increases penetration force through shape modification and process condition design of a copper liner used in the 40 mm dual purpose high explosive. The 40mm dual purpose high explosive comprises: a fuse as a detonator; a ballistic body forming a body; a conical liner of conical length (D); a rotating barrel of a band surrounding the ballistic body; explosive gunpowder; a propellant generating propulsive forces; a percussion which is a metal pipe for blasting to ignite the propellant, wherein the conical length (D) of the liner is extended from an upper end portion by a predetermined length (L).

Description

40MM Dual Purpose High Bomb {40MM HIGH EXPLOSIVE DUAL PURPOSE}

The present invention relates to a 40MM dual purpose high explosive, and more particularly to a 40MM dual purpose high explosive which increases the penetration power by changing the shape of a copper liner used in a 40MM dual purpose high explosive and designing process conditions.

Generally, dual-purpose high-explosive technology differs from ordinary high-explosive bombs in that the gunpowder is not fully charged and there is a conical hollow space in front of the explosive, and a conical structure made of metal between the space and the explosive, Or cloth).

Shock waves generated when the explosive is ignited are transmitted to the liner and the liner collapses. The collapsed liner forms a metal jet and a slug in the axial direction at a high temperature and a high pressure, As the armored vehicles and tanks became more prominent in the World War II, maneuverability and intrinsic compatibility were required, dual-purpose high-bombs with excellent penetration performance became necessary and widely used.

The action mechanism of the dual-purpose high-bomb is to deform the liner by the shock wave generated by the explosion of the charged high-explosive powder, and this process is rapidly deformed in a very short time and a strain of 10 ⁴ to 10 ⁷ / s occurs And a phenomenon similar to the fluid behavior appears at the same time.

Through this phenomenon, the wall of the liner is depressed toward the center of the cone and has two types of flow: one is a metal jet located at the tip, and the other is located at the back of the flow. It is a slug.

The dual purpose bomb is a technology that optimizes the performance by concentrating the energy of the gunpowder in a certain direction by creating an empty space on the explosive surface of the explosive. It is a Neumann effect, a Monroe effect, a Hollow Charge effect, Or Shaped Charge Effect.

The technique of Monroe-Neumann effect is not only a penetration effect that penetrates thick armor plate with a small amount of gunpowder but also an explosive energy transfer of various guided weapons, a warhead cutting device, an aircraft pilot emergency escape device, And it is widely used for the purpose of removing or destroying the facilities for aerodrome, and its application range including blasting and demolition is increasing.

Factors affecting the penetration effect of these dual-purpose high-bombs include liner material, thickness, geometry (concave angle), gunpowder type, amount of gunpowder, and Stand-Off Distance (SOD).

Currently, the 40MM dual purpose high-explosive K212 used in the military has the ability to penetrate 63.5mm of steel plate using a metal liner. However, it is required to improve the penetration ability as the armored vehicle is modernized and the thickness is strengthened.

Korean Patent Registration No. 10-1226483

Department of Mechanical Engineering, Dong-A University Jung, Dong-Wol, "A Study on the Improvement of the Speed of the Jets at the Anaerobic Crossing with Monroe-Neumann Effect", 2013.12.

In order to achieve the above object, the present invention provides a 40MM dual purpose high explosive bomb, wherein the 40MM double purpose high explosive bomb with increased penetration power is designed by changing the shape of the copper liner used for the 40MM double purpose high explosive and designing the process condition. The purpose is to provide.

In order to accomplish the above object, the 40MM dual purpose high explosive of the present invention comprises: a fuse; A body forming a body; A conical liner of conical length D; and a rotating barb of a band surrounding said body; Explosives; explosives; A conical length (D) of the liner is extended from the upper end by a predetermined length (L) in a 40MM double-purpose high-explosive bomb composed of a propellant generating propulsion force and a primer serving as a blasting metal tube for igniting the propellant. .

The ratio of the liner cone length (D) to a predetermined length (L) extending from the liner upper end is 1: 0.126 to 0.159.

In addition, the focal distance of the liner and the penetrating object is increased by a predetermined length L extending from the upper end of the liner.

Further, the filling density of the gunpowder increases as a certain length L extending from the upper end of the liner is extended.

And the charging density of the gunpowder is 1.58 to 1.64 g / cm < ³ >.

The liner is made of copper.

Further, the extended length L of the liner extends from the upper end of the liner along the longitudinal direction of the body.

The present invention relates to a 40MM dual purpose high explosive, and more particularly to a method of increasing the weight of metal jets and slugs produced by a copper liner by extending a certain length from the top of a copper liner used in a 40MM dual purpose high explosive, It has the effect of increasing the charge density, which is the driving force required when the copper liner generates metal jets and slugs.

In addition, by designing the length extending from the upper end of the copper liner, the speed of the metal jet is increased to the maximum, and the spray density, which means the amount of the metal jet per unit volume, is minimized, thereby enhancing the penetration force of the penetration object.

1 is a schematic diagram of a conventional 40 MM dual purpose high bomb.
2 is a schematic view of a conventional copper liner.
3 is a schematic view of a copper liner according to an embodiment of the present invention.
4 is a schematic view showing a metal jet and a slug generated by a conventional copper liner.
5 is a schematic view showing a focal length, which is an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings, which can be implemented in various different forms by those skilled in the art, The present invention is not limited to the description.

FIG. 1 is a schematic cross-sectional view of a general 40MM dual purpose high explosive. A 40MM dual purpose high explosive 100 includes a new pipe 10 as an explosive device for igniting explosives and exploding them according to the required conditions, a body 20 A conical copper liner 30 for generating a metal jet 35 and a slug 36, a rotating barb 40 for a band surrounding the body, a gunpowder 50 as an explosive material, A propellant 60 and a primer 70 as a blasting metal tube used to ignite the explosive.

As used herein, the term "copper liner" may be a metal liner, such as aluminum, nickel, or lead, including copper, and may include a copper material having excellent ductility and toughness, However, the scope of the present invention is not limited thereto, and materials known to those skilled in the art can be used.

The 40MM dual-purpose high-explosive bomb is first ignited by the primer 70, and the propellant 60 is ignited to obtain propulsion force and fired. Finally, after the final blown to the target point, the explosive 50 ignites the explosive 50 .

At this time, a shock wave generated when the explosive 50 is ignited is transferred to the copper liner 30 to collapse the copper liner 30, and the collapsed copper liner 30, as shown in FIG. 4, One of the flows is the metal jet 35 positioned at the tip and the other is the slug 36 located at the tail of the flow. The high-temperature and high-pressure metal jet 35 and the high- So that the slug 36 finally penetrates the target.

Thus, the 40MM dual purpose high-explosive (100) is generally developed to enhance penetration because it is used for penetrating armored vehicles. The factors affecting the penetration effect are the material, thickness, Shape, gunpowder type, gunpowder amount, and focal length (SOD). In the present invention, the shape of the liner among the above elements is changed.

3, the 40MM dual purpose high explosive of the present invention differs from the conventional copper liner 30 of FIG. 2 in that the cone length D of the liner in the conventional copper liner 30 is smaller than the cone length D of the body from the upper end of the liner And a copper liner 31 of a shape elongated by a predetermined length L along the longitudinal direction.

The reason why the shape of the copper liner is changed as described above is that the penetrating force is improved by extending a certain length L extending from the upper end of the copper liner.

First, when a certain length L extending from the upper end of the copper liner is extended, the weight of the copper contained in the 40MM dual purpose high-explosive increases, so that the collapsed liner is removed from the metal jet 35 of high temperature and high pressure, The metal jets 35 and the slug 36 can be formed in a larger amount when the slug 36 and the slug 36 are formed.

In practice, about 20% of the total weight of the copper liner will act as the metal jets 35, and the remaining about 80% will be transformed into slugs 36.

When a copper liner 31 having a certain length L is extended from the upper end when the gun body is charged with gunpowder and the copper liner is inserted and the new pipe is fastened, the copper liner 31 is moved in the direction of the primer 70 (L) to increase the filling density to further increase the filling density when the explosive is explosively increased, so that the driving force required when the copper liner (31) generates the metal jet (35) and the slug (36) So that the penetration performance can be improved.

In addition, if a certain length L extending from the upper end of the copper liner is extended, the focal distance SOD becomes longer as shown in FIG. 5, and the penetration performance is improved. 5, the distance from the point where the metal jet 35 is generated to the penetration object 80 such as an armored vehicle.

When the focal length SOD becomes long, the collapsed copper liners 30 and 31 generate the metal jet 35 and the slug 36 in the axial direction at high temperature and high pressure and penetrate the penetration object 80, To give the metal jack 35 and the slug 36 from the collapsed copper liners 30 and 31 a sufficient amount of time necessary to generate the metal jack 35, and at the same time to increase the speed of the metal jet 35, So that the metal jet 35 can hit the penetration object 80 at the instant of its maximum speed.

However, when the focal length SOD becomes longer than a certain distance, the speed drops sharply from the maximum speed due to the air resistance generated in the direction opposite to the firing direction of the metal jet 35, and the speed of the metal jet 35 per unit volume Which means the amount of spraying is reduced and the area through which the penetrating object 80 can penetrate is reduced.

Therefore, the speed of the gradually accelerating metal jet 35 is maximized, and the optimum focal length (SOD), which can minimize the jet density, which is the amount of metal jet 35 per unit volume, is minimized In the present invention, a penetration test was performed on a 75 mm flat steel plate while changing a constant length (L) extending from the upper end of the copper liner 31, which affects the focal length (SOD) Respectively.

division Comparative Example 1 Example 1 Example 2 Example 3 Example 4 Extended length (L) [mm] - 1.634 to 1.67 2.221 to 2.326 3.276 ~ 4.07 4.07 ~ Cone length (D) [mm] 25.61 to 25.85 25.61 to 25.85 25.61 to 25.85 25.61 to 25.85 25.61 to 25.85 L / D - 0.063 to 0.065 0.085 to 0.091 0.126-0.159 0.159 ~ Penetration rate [%] ㅡ 75.0 83.3 100 96.3 or less

Table 1 shows the results of the 75 mm soft steel sheet penetration rate according to the change of the constant length L extending from the upper end of the copper liner with respect to the cone length D of the copper liner 31 as shown in Fig.

It can be seen that Comparative Example 1 did not penetrate the 75 mm soft steel sheet at all as a result of the conventional shape of the copper liner 30 without an extended constant length L because the focal distance SOD was too short to cause the copper liner 30 Did not give enough time to produce the metal jets 35 and the slug 36 and also struck the soft steel plates before the metal jets 35 were accelerated to the maximum velocity after production.

On the other hand, in Examples 1 to 3, as a result of an experiment in which the value of the constant length (L) extending from the top of the copper liner to the cone length (D) of the copper liner 31 was increased from 0.063 to 0.159, The penetration rate of steel plate gradually increased from 75% to 100%.

This is because as the constant length L extending from the upper end of the copper liner 31 increases, the focal distance SOD which means the distance from the point where the metal jet 35 is generated and started to the penetration object 80 is increased Thereby giving the copper liner 31 sufficient time to produce the metal jets 35 and the slugs 36 and at the same time allowing the metal jets 35 to be accelerated gradually to the required distance It can be seen that time has been provided.

However, in the case of Example 4, the value of the constant length L extending from the top of the copper liner with respect to the cone length D of the copper liner 31 was increased, but the penetration rate was decreased as compared with Example 3, This is because if the focal length (SOD) is increased by a certain distance or more, the velocity of the metal jet 35 rapidly drops from the maximum velocity due to the resistance of the air generated in the direction opposite to the direction of the firing, and the amount of the metal jet 35 per unit volume The injection density is also reduced, leading to a decrease in the penetration rate.

That is, in the case of the copper liner 31 having a predetermined length L extending from the upper end as in the case of the first to fourth embodiments, as compared with the conventional copper liner 30 having no extended constant length L as in Comparative Example 1 And the copper liner 31 can form a larger amount of the metal jets 35 and the slug 36. In this case, The copper liner 31 is pressed against the metal jets 35 and 35 by the length L in the direction of the primer 70 to further increase the filling density of the powder, The driving force required to generate the slug 36 can be increased.

4, the metal lugs 35 and the slugs 36 are generated from the collapsed copper liner, and at the same time, the metal lugs 35 accelerated to a maximum speed The metal jet 35 can hit the instantaneous penetration object 80 having the maximum velocity.

The best condition of the penetration rate is Example 3 wherein the value of the constant length L extending from the upper end of the copper liner with respect to the cone length D of the copper liner 31 is 0.126 to 0.159, It can be seen that the velocity of the metal jets 35 is maximally increased and that the spray density, which means the amount of the metal jets 35 per unit volume, is the most desirable condition to be minimized.

The filling density of the gunpowder 50 of the 40MM double-purpose high-explosive produced under the conditions of Example 3 was the same as that of Comparative Example 1 except that the conventional 40MM double-purpose high- The filling density of the explosive was increased to 1.58 to 1.64 g / cm < ³ >.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, The scope of the present invention is not limited thereto. It will be apparent to those skilled in the art that various changes, substitutions, and alterations can be made hereto without departing from the spirit of the present invention, and it is obvious that those parts easily changeable by those skilled in the art are included in the scope of the present invention.

100: 40MM Dual Purpose High Bomb 10: Fuse
20: body 30 to 31: copper liner
35: Metal jet 36: Slug
40: Round 50: Gunpowder
60: Propellant 70: Primer
80: Through object

Claims (7)

A detonating fuse; A body forming a body; A conical liner of conical length D; and a rotating barb of a band surrounding said body; Explosives; explosives; A 40MM dual purpose high explosive bomb consisting of a propellant generating propulsion force and a primer which is a blasting metal tube for igniting the propellant,
Characterized in that the conical length (D) of the liner is extended by a constant length (L) from the top end. The method according to claim 1,
Wherein the ratio of the liner cone length (D) to a constant length (L) extending from the liner upper end is 1: 0.126 to 0.159. The method according to claim 1,
Wherein the focal distance by the liner and the penetrating object is increased by a constant length (L) extending from the upper end of the liner. The method according to claim 1,
And the filling density of the gunpowder increases as a certain length L extending from the upper end of the liner is extended. 5. The method of claim 4,
Wherein the filling density of the gunpowder is 1.58 to 1.64 g / cm < ³ >. The method according to claim 1,
Wherein the liner is a copper material. The method according to claim 1,
Wherein an extended length L of the liner extends along the length of the body from an upper end of the liner.

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