KR101458269B1 - Shell for Training - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a training cannon used in an artillery training of a train,
(10) which is flushed by the pressure generated by the combustion of the propellant and is crushed by the collision energy generated in collision with the target; A steel spike (20) located at the front of the body (10) and forming the heaviest warhead; And a flight stability plate (30) provided at the rear of the body (10) to maintain flight stability when the body (10) is in flight. The body (10) A crushing filler body 16 which is crushed by the crushing filler body 16 and which receives the crushing filler body 16 therein and concentrates the collision energy and internal pressure generated in collision with the target inside the crushing filler body 16, And a plastic pressure-resistant case (17) for raising the internal pressure of the crushing filler (16) to finely crush the crusher filler (16).
Therefore, when the practice-type shell of the present invention is used, it is possible to carry out almost the same shooting training as the actual-purpose shell, and it is possible to carry out stable shooting training and expect superior learning effect.

Description

Shell for Training {Shell for Training}

[0001] The present invention relates to a training cannon used in a training of a tank or the like, and in particular, it is formed to exhibit the same effect as that of a room-only cannon, and flight stability is secured during flight, The present invention relates to a training gun capable of reducing a distance.

Practice shells must have approximately the same trajectory as real-purpose shells, which can improve the efficiency of the practice. Accordingly, the practice shells are manufactured in substantially the same manner as the actual shells in terms of appearance, structure, weight, and the like. As such practice-type shells, there is known a technique disclosed in Japanese Patent Laid-Open No. 10-2008-0107616 (the name of the invention: a method for manufacturing a body crushing filler and an exercise bug containing the body crushing filler).

In general, the training shell used in the training of the tanks is used to replace the high-bombs of all slaves and is used to obtain similar or similar training effects to the low-cost, high-bombarded roundabout. Most of the tanks are designed to propel the warhead toward the target while maintaining the flight stability by the propulsion energy generated by the combustion of the propellant filled in the shell.

Therefore, it is a matter of course that the training shell or tank gun should be designed to have sufficient strength to withstand the high combustion pressure generated by the combustion of the propellant and the impact caused by the backward inertia force generated at the time of launching. For this reason, a warhead designed to withstand the bursting pressure and impact of a shot can fly to the target while maintaining the safety of the overhang, but the fragmentation of the warhead during target collisions is not constant and can be scattered far enough from the target, It has a problem that can cause accidents.

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a training shell capable of reducing a scattering distance of fragments generated when a warhead collides with a target, There is a purpose.

It is also an object of the present invention to provide an exercise shell capable of improving the effect of shooting training by having a shape and flight performance similar to those of a practical use shell.

According to an aspect of the present invention, there is provided a propulsion system comprising: a body that is flushed by a pressure generated by combustion of a propellant and is crushed by collision energy generated upon collision with a target; A steel spike located at the front of the body and forming the heaviest warhead; And a flying stabilizer installed at the rear of the torso so as to maintain flight stability when the torso is in flight, wherein the torso comprises: a crushing filler crushed by impact energy generated by collision with a target; A plastic pressure-resistant case accommodating a crushing filler, concentrating the collision energy and internal pressure generated when the crusher is collided with the target inside the fracture filler, and raising the internal pressure of the fracture filler at the time of collision to finely crush the fracture filler And a shredding body.

Further, according to the practice shell of the present invention, the shredding body is formed by a press-press forming method or a vertical insert injection method so that no gap is formed between the plastic pressure-resistant case and the crushing filler body when the plastic pressure- And is assembled.

Further, according to the practice shell of the present invention, the molding pressure at the time of the press forming is 10 to 50 kg / cm 2.

Further, according to the practice shell of the present invention, the fracture filler has a port shape having a pocket therein.

Further, according to the practice shell of the present invention, the shredding member is assembled using a shrink joint method.

According to the practice shell of the present invention, the shredding body is assembled in a state where the temperature of the shredding filler is maintained at 5 to 10 캜.

According to the practice shell of the present invention, the shredding body is assembled in a state in which the temperature of the pressure proof case is maintained at 40 to 65 캜.

Further, according to the practice shell of the present invention, the steel spike is characterized in that a notch portion is formed in the noze portion so that the steel spike can be easily broken when colliding with the target.

According to the practice shell of the present invention, the flight stabilizing plate has a port-shaped pressure groove for ensuring flight stability and volume reduction, and the pressure grooves are formed at 3 to 12 equally spaced along the circumferential direction .

The practice artillery shell of the present invention is provided with a shredding body having a structure easy to crush during impact, and has an outer shape similar to that of the actual shell. Therefore, it is possible to perform almost the same shooting training as the actual shell, And an excellent learning effect can be expected.

Also, according to the training gun of the present invention, the outer shape similar to the balloon for practical use and the flight stability can be maintained by the steel stabilizing plate forming the bullet and the steel spike forming the bullet, so that the same training effect as that of the conventional training bullet can be obtained .

According to the practice shell of the present invention, since the crushing body formed by assembling the crushing filler body with the pressure-resistant case is provided inside the body and the pressure-resistant case concentrates the collision energy and the internal pressure into the inside of the crushing filler, During the training, the debris is not scattered to a long distance, and the safety accident caused by the scattered debris can be prevented.

Further, according to the practice shell of the present invention, since the fracture filler and the pressure-resistant case are joined by the press-press forming method, the vertical insert injection method, or the shrinkage joint method, voids are not generated between the fracture filler and the pressure- So that the pressure-resistant case has the effect of concentrating the collision energy and the internal pressure in the crushing filler as much as possible.

Further, according to the practice shell of the present invention, since the notch portion is formed in the noze portion of the steel spike forming the warhead portion, the steel spike is easily broken upon collision with the target, So that the collision energy can be transferred.

In addition, according to the practice artillery shell of the present invention, since 3 to 12 pressure grooves are formed in the tamping portion along the circumferential direction, the flight stability of the warhead is improved when flying in the air, and the overall volume is reduced.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a configuration diagram showing a practice shell according to the present invention; Fig.
2 is a perspective view showing a part of a shredding member which is a main constituent of the present invention;
3 is a vertical sectional view of Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an exercise shell according to the present invention will be described with reference to the accompanying drawings.

The training cannon according to the present invention comprises a body (10) which is flushed by the pressure generated by the combustion of the propellant and is crushed by the impact energy generated upon collision with the target; A steel spike 20 positioned at the front of the body 10 to form the heaviest warhead in the shell; And a flight stability plate (30) provided behind the body (10) to maintain flight stability when the body (10) is in flight.

Here, the body 10 includes a fracture filler 16, which is fractured by the impact energy generated by collision with the target, and a collision energy generating unit 15 that receives the collision filler 16 therein, And a plastic pressure-resistant case 17 for concentrating the internal pressure inside the fracture filler 16 and raising the internal pressure of the fracture filler 16 at the time of impact so that the fracture filler 16 is finely crushed And a shredding body (15).

At this time, it is preferable that the fracture filler 16 is formed in a pot shape having a pocket 16 'therein. This is because the crushing filler 16 compensates for approximately the same weight as the actual shell and at the same time maximizes the impact energy and the crushing pressure inside the crushing filler body 16 by the plastic pressure- And the like.

The crushing body 15 is assembled with the crushing filler body 16 and the plastic pressure-resistant case 17. When a space is formed between the crushing filler body 16 and the pressure-resistant case 17, The impact caused by the pressure and the backward inertia force causes the breakage of the fracture filler 16 in the inner space of the body 10. Therefore, in order to maintain the close contact between the crushing filler body 16 and the pressure-resistant case 17, a pressurizing press which removes the gap between the crushing filler body 16 and the pressure-resistant case 17 by applying an equal pressure from above, The crushing filler (16) and the pressure-resistant case (17) are assembled using a molding method.

The molding pressure at the time of this press-molding is preferably 10 to 50 kg / cm 2. This is because the plastic pressure-resistant case 17 in the molding die may be welded or the shape of the pressure-resistant case 17 itself may be deformed when the molding temperature exceeds 80 deg. Therefore, the molding temperature should not exceed 80 ° C at room temperature.

The shredding body 15 may be assembled using a shrinkage joint method in which the fracture filler 16 and the pressure-resistant case 17 are bonded using a difference in thermal characteristics between materials.

In this case, it is preferable that the fracture filler 16 is held at a temperature of 5 to 10 ° C or the pressure-resistant case 17 is maintained at a temperature of 40 to 65 ° C. That is, when the shrinkage bonding method using the intrinsic thermal characteristics of the material is used, the temperature of the pressure-resistant case 17 is maintained at 40 to 65 ° C and the temperature of the fracture filler 16 is maintained at 5 to 10 ° C desirable.

When the temperature of the pressure-resistant case 17 is less than 40 ° C, the pressure-resistant case 17 does not expand and does not assemble. When the temperature exceeds 65 ° C, This is because permanent deformation occurs as deformation occurs. When the temperature of the fracture filler 16 is less than 5 ° C, a water film layer is formed due to the occurrence of condensation on the surface. When the temperature exceeds 10 ° C, the temperature difference with the pressure- A gap may be generated between the pressure-resistant case 16 and the pressure-resistant case 170.

Also, the shredding body 15 can be assembled by an insert injection method. When the crushing filler body 16 and the pressure-resistant case 17 are assembled by using the insert injection method, it is difficult to fix the crushing filler body 16 in the mold if it is assembled by horizontal injection molding, The shape change and the concentricity change of the pressure-resistant case 17 may occur. On the other hand, in the case of assembling by vertical injection, it is easy to fix the fracture filler 16 by using the center pin in the mold, and molding can be performed without changing the concentricity after injection molding. Therefore, it is more preferable to use the vertical insert injection method of vertical interlocking type rather than the horizontal interlock type horizontal injection.

The crushing body 15 including the plastic pressure-resistant case 17 and the crushing filler body 16 assembled by the press-press molding method, the shrink-fit bonding method or the vertical insert injection method is capable of preventing the impact caused by the propellant combustion pressure and the reverse inertial force The flight stability of flying to the target without damaging the fracture filler 16 is ensured in the internal space of the body 10 irrespective of the shape of the fracture filler 16, And the inner pressure of the crushing filler body 16 is raised to a level exceeding the crushing threshold value so that the fracture filler body 16 is finely crushed. Accordingly, when the training shell provided with the shredding body 15 is used for shooting training, the shards are finely shredded so that the shards are scattered only within a short distance as compared with the conventional training shell having only the metal filling. That is, in the practice shell of the present invention, the fracture filler body 16 of the fracture body 15 is more finely crushed than a practice shell having only a conventional metal filler, so that fragments of a lighter weight are produced, .

The steel spike 20 is preferably formed with a notch 25 at its nose portion to facilitate fracturing when colliding with the target. The steel spike 20 may be made of an iron-based metal or a metal sintered body containing a dissimilar metal other than iron. The notched portion 25 is formed in the nose portion of the steel spike 20, the weight of which is the greatest in the training cannon, so that the training cannon quickly forms a debris after collision with the target.

Normally, as the practice shell collides with the target, the kinetic energy of the training shell decreases, and the collision energy begins to develop. Therefore, when the notched portion 25 is applied to the nose portion of the steel spike 20 where the breakdown first occurs in collision with the target, it can be broken by less kinetic energy or impact energy than in the case where there is no notch. Since the amount of reduction of the kinetic energy or the collision energy due to the breakage of the steel spike 20 is small in this manner, a larger amount of collision energy is transferred to the crushing of the body 10 and the flight stabilizer 30, .

The flight stabilizer 30 is provided with a pressure groove 35 in the form of a pot for ensuring flight stability and volume reduction and the pressure grooves 35 are formed at equal intervals 3 to 12 It is preferable that a dog is formed. That is, the interval between the pressure grooves 35 is in the range of 30 to 80 degrees with respect to the axis. The stabilizing plate 30 has a shape and volume different from those of the conventional wing but has the same flight stabilizing function as the existing wing and contributes to reducing the scattering distance after collision with the target in the form of reduced weight. That is, since the volume is reduced as compared with the existing wing, the propellant space can be secured by a reduced volume, and the weight is reduced by the volume reduction, so that the distance for scattering after the collision with the target can be reduced.

Further, the three to twelve pressure grooves (35) cause rotation due to air resistance when the training gun is flying to the target after firing, thereby ensuring higher flight stability. When the number of the pressure grooves 35 is less than 3, two pressure grooves are formed at an interval of 180 degrees, so that the rotational force is weakened during flight of the training cannon. When the number of the pressure grooves 35 exceeds 12, The thickness of the pressure groove 35 becomes thin, and the pressure groove 35 may be deformed by the pressure generated by the combustion of the propellant when the training shell is fired, which may cause the flying stability to be lowered. Therefore, it is preferable that three to twelve pressure grooves 35 are formed in the flight stabilizer 30.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Changes will be possible.

10 ...
15 ... Crusher
16 ... crushing filler
17 ... Plastic pressure resistant case
20 ... steel spikes
25 ... Notch portion
30 ... Flight Stable
35 ... pressure groove

Claims (9)

A body 10 which is flushed by the pressure generated by the combustion of the propellant and is crushed by the collision energy generated upon collision with the target;
A steel spike (20) located at the front of the body (10) and forming a warhead;
And a flight stability plate (30) provided behind the body (10) to maintain flight stability when the body (10) is in flight,
The body 10 includes a fracture filler 16 which is fractured by impact energy generated by collision with a target, a collision energy absorbing unit 15 which receives the collision filler body 16 therein, And a plastic pressure-resistant case (17) which concentrates the inside of the fracture filler (16) and raises the inner pressure of the fracture filler body (16) (15), and at the same time,
The reduction amount of the kinetic energy or the collision energy due to the breakage of the steel spike 20 is reduced so that the collision energy is transferred to the body 10 and the flight stabilizer 30 when the target collides with the steel spike 20, Wherein a notch portion (25) is formed in a nose portion of the shell. The method according to claim 1,
The shredding body 15 is formed by a press-press forming method or the like so that no gap is formed between the plastic pressure-resistant case 17 and the fracture filler body 16 when the plastic pressure-resistant case 17 and the shredding filler body 16 are assembled Wherein the assembly is assembled by a vertical insert injection method. 3. The method of claim 2,
Wherein the molding pressure at the time of the press forming is 10 to 50 kg / cm < 2 >. The method according to claim 1,
Wherein the fracture filler (16) has a pot shape having a pocket (16 ') therein. The method according to claim 1,
Wherein the shredding body (15) is assembled using a shrinkage joint method. 6. The method of claim 5,
Wherein the shredding body (15) is assembled while maintaining the temperature of the shredding filler (16) at 5 to 10 占 폚. 6. The method of claim 5,
Wherein the shredding body (15) is assembled with the temperature of the pressure resistant case (17) maintained at 40 to 65 占 폚. delete 8. The method according to any one of claims 1 to 7,
The flight stabilizer 30 is provided with a pressure groove 35 in the form of a pot for ensuring flight stability and volume reduction and the pressure grooves 35 are formed in the circumferential direction at 3, And the like.

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