KR101371390B1 - Warhead Assembly Of Armor Piercing Fin-Stabilized Discarding Sabot with a Sealing Mechanism - Google Patents

Abstract

The present invention effectively prevents the leakage of the combustion gas of the propellant between the barrel and the warhead assembly under ultra-high pressure chamber pressure by propellant combustion until the warhead assembly is fired and moved out of the muzzle while minimizing intra- and intra-ballistic non-uniformity. Provides a sealing mechanism for warhead assembly of wing stabilized iron shell bullets that can improve the impact dispersion of the target.
The sealing mechanism for warhead assembly of the wing stabilized iron shell bullet according to the present invention has a circumferential direction of the escape shell (12) on the outer circumferential surface between the front and rear core diameters (12a, 12b) formed in the escape shell (12) of the warhead assembly (10) Annular groove 15 formed along; An annular sealing ring 16 fixedly fixed to an outer circumferential surface of the annular recess 15 and integrally formed with at least one annular projection 16c, 16d having any one of a cross section, a trapezoid, a semicircle, or a quadrangle; Mounted along the outer circumferential surface of the annular sealing ring 16 rotatably along the steel wire of the barrel to accommodate at least one annular projection 16c, 16d having a shape corresponding to the shape of the annular projection 16c, 16d. An annular closing ring 17 having at least one projection receiving groove 17a, 17b; And a control unit.

Description

Warhead Assembly Of Armor Piercing Fin-Stabilized Discarding Sabot with a Sealing Mechanism

The present invention relates to a warhead assembly of a wing stabilizing iron shell bullet including a closure mechanism, and more particularly, between the barrel and the warhead assembly under ultra-high pressure chamber pressure by propellant combustion until the warhead assembly is moved out of the barrel by the launch of the warhead assembly. The present invention relates to a warhead assembly of a wing stabilized iron shell bullet containing an airtight mechanism, which can effectively prevent the leakage of the combustion gas of the propellant and improve the dispersion of the impact point of the target while minimizing intra- and extra-ballistic nonuniformity.

In general, wing stabilized armor shells are ammunition that destroys a target by using the kinetic energy of the penetrator, including a warhead assembly having a breakaway shell and a penetrator, and a shell casing coupled with the warhead assembly and loaded with a propellant.

Breakaway is a key component of the wing stabilized armor shell that defeats the enemy's target by penetrating the armor of enemy tanks through high kinetic energy. The breakaway skin consists of three pieces having a symmetrical structure, and a thread or groove-shaped uneven coupling portion is formed at the interface of the breakaway skin and the penetrator, and is separated into three pieces by the outer diameter of the penetrator. Is in close contact with the barrel. Breakaway of this structure transmits the propulsion energy generated by the combustion of the propellant filled in the casing assembly to the penetrator, allowing the penetrator to fly out of the barrel, and also supports the penetrator in the barrel and prevents the combustion of the propellant from firing the penetrator. It is a kind of auxiliary device that prevents high temperature and high pressure gas from getting out of the barrel, and separates it into three pieces by air resistance as soon as the penetrator leaves the muzzle.

FIG. 1 shows an example of a wing stabilized iron shell bullet having such a structure, FIG. 2 shows a warhead assembly of a wing stabilized iron shell bullet, and FIG. 3 shows a structure of the escape shell in FIG.

As shown in FIG. 1, in the conventional wing stabilized iron shell 100, a part of the warhead assembly 110 having a breakaway shell 111 and a penetrator 112 is accommodated in the shell casing assembly 120, and a portion of the wing stabilizer shell shell ( 200, that is, in the form of ammunition loaded in the steel wire of the barrel 200.

In the wing stabilizing iron shell 100 as described above, the wing assembly 113 having four wings at equal intervals is located at the rear of the warhead assembly 110, the glow assembly 114 at the rear of the wing assembly 113 Is located. Here, the preliminary assembly 114 is composed of a combustible gunpowder and a metal container, the preliminary agent is ignited by the combustion gas of the propellant to emit a bright light in the visible region while the warhead assembly 110 is flying to the target shooter Controls the direction of fire so that the player can hit the target quickly.

2 and 3, the warhead assembly 110 is provided with a warhead stopper 115 coupled to the front of the breakaway pin 111 and surrounding the penetrator tip portion 112a, and the breakaway pin 111. Between the rear, ie front and rear core diameters (the portion with the largest diameter of the warhead, excluding the burletlet diameter, the closing ring of the rotating ball or below closure mechanism, also referred to as the 'center') 111a, 111b) It is provided with a sealing mechanism 118 consisting of a sealing ring 116 is fixed to the groove 116a formed in the closing ring 117 coupled around the sealing ring 116. Here, the closing ring 117 is fitted with a certain gap with the sealing ring 116 so that the warhead assembly 110 rotates along the steel wire of the barrel 200 when the warhead assembly 110 passes through the barrel 200.

The sealing mechanism 118 is to prevent the leakage of the combustion gas of the propellant by sealing the gap generated between the inner surface of the barrel 200 and the outer surface of the warhead assembly 110, inflow through the escape end after the escape propellant. It expands to the outside by the high pressure gas of the propellant, which serves to maintain a secure airtight state. In general, when the propellant charged in the casing is combusted, a constant chamber pressure (pressure of gas generated in the chamber) is generated. When such chamber pressure is generated, the warhead assembly 110 is advanced forward along the rupture, wherein the high-temperature, high-pressure combustion gas generated by the combustion of the propellant is inside the barrel 200 by the closing mechanism 118. Leakage between the steel wire and the outer surface of the warhead assembly 110, in particular the closing ring 117, is prevented. The closure ring 117 of the closure mechanism 118 is damaged in front of the muzzle when the warhead assembly 110 is out of the muzzle.

However, since the sealing mechanism 118 according to the prior art has a flat contact surface between the sealing ring 116 and the closing ring 117 as shown in Fig. 4, the sealing ring 116 under ultra-high pressure chamber pressure. ), There is a problem that the combustion gas leaks between the closing ring (117). In general, chamber pressures vary by gun diameter, for example, for 40 mm guns, the normal chamber pressure ranges from 58,000 psi to 62,000 psi, while the ultra-high pressure chamber pressure ranges from 70,000 psi to 74,000 psi, which is normal for 120 mm guns. Chamber pressure and ultra high pressure chamber pressure is higher than 40mm gun. Under such normal chamber pressure, since the leakage of combustion gas of the propellant is not severe, even if the contact surface of the sealing ring 116 and the closing ring 117 of the sealing mechanism 118 is flat, it is not a big problem, but it is higher than the normal chamber pressure. Under high ultrahigh pressure chamber pressure, a portion of the combustion gas of the propellant enters the gap between the sealing ring 116 and the closing ring 117, leaking a considerable amount of combustion gas in front of the muzzle before the warhead assembly 110 exits the muzzle. There is a problem that can affect the intra and intra-ballistic trajectory, resulting in ballistic non-uniformity, and as a result can reduce the impact point dispersion of the target.

Accordingly, the present invention has been made in view of the above-described problems of the prior art, and the combustion gas of the propellant between the barrel and the warhead assembly under ultra-high pressure chamber pressure by propellant combustion until the warhead assembly is fired and moved out of the barrel. It is an object of the present invention to provide a warhead assembly of a wing stabilized iron shell bullet containing an airtight mechanism, which can improve the dispersion of the impact point of the target while minimizing intra- and extra-ballistic non-uniformity by effectively preventing the leakage of oil.

In order to achieve the above object, the present invention provides a warhead assembly comprising a penetrator and a breakaway skin detachably coupled to the outer diameter portion of the penetrator, due to the combustion of the propellant when it is advanced forward in the barrel by the combustion of the propellant. In the warhead assembly of the wing stabilized iron shell bullet shell including a sealing mechanism for sealing the gap between the barrel inner surface and the outer surface of the warhead assembly to prevent the leakage of combustion gas,

The sealing mechanism includes an annular groove formed along the circumferential direction of the breakaway blood on the outer circumferential surface between the front and rear core diameters formed on the breakaway blood;

An annular sealing ring which is tightly fixed to an outer circumferential surface of the annular groove and is formed integrally with at least one annular protrusion;

An annular closing ring rotatably mounted along an outer circumferential surface of the annular sealing ring rotatably along the steel wire of the barrel and having at least one projection receiving groove for accommodating the at least one annular projection;

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An outer diameter extension is formed on the outer surface of each piece of the escape shell so that a part of the escape shell is contacted with the inner surface of the barrel when the warhead assembly is fired and moved in the barrel, and the outer diameter extension extends from the rear end of the closure mechanism to the rear end of the escape shell. It extends along and provides a warhead assembly of a wing stabilized iron shell bullet including a closure mechanism characterized in that the end portion is made of an inclined surface.

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In the present invention, the sealing ring is formed in a cross-section 'b' or 'a' shape having a plane and a vertical surface connected to one end of the plane and in contact with one end of the front core, the closure The ring is characterized in that it has a height projecting from the front and rear cardiac diameter of the breakaway skin so as to contact the inner surface of the barrel.

In the present invention, the annular projection is formed in the shape of any one of a cross-sectional triangle, trapezoidal, semi-circular or square in cross section, the projection receiving groove is characterized in that it has a shape corresponding to the shape of the annular projection.

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According to the present invention, in the outer shell constituting the warhead assembly of the wing stabilizing iron shell bullet shell provided on the outer surface of the escape shell in the closure mechanism consisting of a closed ring and a closed ring which is rotated along the steel wire in the barrel, At least one annular projection is formed in the sealing ring fixed to the groove, and at least one annular projection receiving groove is formed in the closing ring to receive the annular projection, thereby closing the gap generated between the inner surface of the barrel and the outer surface of the warhead assembly. Of course, the interlocking action between the protrusion of the sealing ring and the protrusion receiving groove of the closing ring effectively prevents the leakage of the combustion gas of the propellant between the sealing ring and the closing ring under the chamber pressure of ultra high pressure. It can greatly improve the impact dispersion of the target's impact point while minimizing the ballistic unevenness, which greatly improves military combat power. It can contribute.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic configuration diagram of an example of a wing stabilized iron shell bullet according to the prior art.
Figure 2 shows the warhead assembly of the wing stabilized iron shell in Figure 1, (a) is a front view, (b) is a cross-sectional view.
Figure 3 is an external view of the escape shell of the wing stabilizing iron shell in Figure 2;
Figure 4 shows a closure mechanism for warhead assembly of the wing stabilized shell armor according to the prior art, (a) is a front view and sectional view of the closure mechanism, (b) is a front view and sectional view of the sealing ring constituting the closure mechanism, (c) Is a front view and a sectional view of a closing ring constituting the sealing mechanism.
Figure 5 is a schematic configuration diagram of the wing stabilized iron shell bullet to which the present invention is applied.
Figure 6 shows the warhead assembly of the wing stabilizing iron shell according to the present invention, (a) is a front view, (b) is a cross-sectional view.
7 is an external view of the escape shell of the wing stabilizing iron shell in FIG.
Figure 8 is a photograph showing the closure mechanism for warhead assembly of the wing stabilized iron shell bullet according to the present invention, a photo showing a part of the closure ring in order to show the sealing ring constituting a part of the closure mechanism.
9 is a cross-sectional view showing the sealing mechanism for warhead assembly of the wing stabilized iron shell bullet according to the present invention
Figure 10 shows a sealing ring constituting the sealing mechanism for the warhead assembly of the wing stabilized iron shell bullet according to the present invention, (a) is a front view, (b) is a sectional view.
Figure 11 shows a closure ring constituting the closure mechanism for warhead assembly of the wing stabilized iron shell bullet according to the present invention, (a) is a front view, (b) is a sectional view.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 5 is a schematic configuration diagram of a wing stabilized armor shell bulletin to which the present invention is applied, and FIG. 6 is a view showing a warhead assembly of a wing stabilized iron shell bullet shell according to the present invention, and FIG. .

As shown in FIG. 5, the warhead assembly 10 of the wing stabilized iron shell bullet according to the present invention is housed in a casing assembly 20 loaded with a propellant. In the present specification, the present invention has been described with respect to the wing stabilized armor shell of an ammunition-type ammunition type in which the warhead assembly is accommodated in the casing assembly 20. However, the present invention is not necessarily limited thereto, and the warhead assembly is not limited thereto. It is also applicable to wing stabilized armor shells in the form of general ammunition contained within shell casings.

The warhead assembly 10 of the wing stabilized iron shell bullet according to the present invention is coupled to the penetrator 11 and the outer diameter portion of the penetrator 11, as shown in Figure 6, the barrel (not shown) And a propagation energy to the penetrator 11 at the same time, so that the warhead assembly 10 escapes from the barrel and is separated from the penetrator 11, and a wing coupled to the rear end side of the penetrator 11; It has a structure including the assembly (13).

The escape shell 12 of the warhead assembly 10 according to the present invention has a cylindrical structure formed by combining three pieces formed in a symmetrical structure to be separated into three pieces as in the prior art. As shown in FIGS. 6 and 7, outer diameter extension portions 14a, 14b, and 14c are formed on the outer surface of the escape shell 12. Three outer diameter extension parts 14a, 14b, 14c are integrally formed on the outer surface of each piece of the escape shell 12 at regular intervals. These outer diameter extensions 14a, 14b, 14c are in the form of blades, so that when the warhead assembly 10 is moved in the barrel, at least some of the three outer diameter extensions 14a, 14b, 14c. Since one comes into contact with the inner surface of the barrel in a state of sliding like a skate blade, it plays a role of minimizing intra-warm movement of the warhead assembly.

On the other hand, a sealing mechanism 18 for sealing the gap generated between the inner surface of the barrel and the outer surface of the warhead assembly 10 is provided in the groove 15 on the outer surface of the tip side of the breakaway skin 12. The groove 15 is an annular groove formed along the circumferential direction of the escape shell 12 on the outer circumferential surface between the front and rear core diameters 12a and 12b formed on the escape shell 12 of the warhead assembly 10, and the outer diameter The expansion parts 14a, 14b, 14c are formed from the rear end of the sealing mechanism 18 provided in the groove 15 to the rear end of the breakaway skin 12.

The closure mechanism 18 will be described with reference to FIGS. 8 to 11.

Figure 8 is a photograph showing the closure mechanism for warhead assembly of the wing stabilized iron shell bullet according to the present invention, Figure 9 is a cross-sectional view showing the closure mechanism for the warhead assembly of wing stabilized iron shell bullet according to the present invention, Figures 10 and 11 Figures showing the sealing ring and the closing ring constituting the sealing mechanism for warhead assembly of the wing stabilized iron shell bullet by the.

As shown in Figs. 8 to 10, the closure mechanism 18 is an annular seal ring 16 which is tightly fixed by an adhesive means to the outer circumferential surface of the groove 15 as shown in Fig. 7, It consists of an annular closing ring 17 rotatably coupled around the ring 16, both the sealing ring 16 and the closing ring 17 is formed of a fiber-reinforced plastic material.

The sealing ring 16 has a plane 16a and a vertical face 16b which is connected to one end of the plane 16a and in contact with one end of the front concentric mirror 12a of the breakaway 12. It is formed in the shape of a ruler or 'a', the annular projection (16c, 16d) is integrally provided on the outer peripheral surface of the plane (16a). In the figure, it is illustrated that two annular projections 16c and 16d are formed at regular intervals, but the present invention is not necessarily limited thereto, and one or more annular protrusions 16c and 16d may be provided. Up to three may be formed in consideration. The annular protrusions 16c and 16d may be formed in any one of a cross-sectional triangle, trapezoidal shape, semi-circle shape or quadrangle as shown in Fig. 10B.

Here, the vertical surface 16b of the sealing ring 16 is in contact with one side end of the front core mirror 12a of the breakaway skin 12, and the height of the vertical surface 16b is approximately equal to the height of the front core mirror 12a. The reason why the vertical surface 16b protrudes on the side of the front core mirror 12a is that smooth rotation of the closing ring 17 when the warhead assembly 10 exits forward in the barrel by combustion of the propellant. It is to plan. That is, when the propellant filled in the casing assembly is burned, the high pressure combustion gas escapes the closing ring 17 mounted on the sealing ring 16 in the process of pushing the warhead assembly 10 forward. It is pushed toward the front heart mirror 12a side. In this case, when the closing ring 17 of the plastic material is in contact with the part of the escape shell 12 of the metal material, there is a concern that the rotation of the closing ring 17 may not be smooth due to the difference in the dissimilar materials. Therefore, in the present invention in consideration of this point, by forming a vertical surface 16b at one end of the sealing ring 16, that is, the front end, the front end of the closing ring 17 rotated along the steel wire of the barrel is a sealing ring of the same material. The closing ring 17 is smoothly rotated by being in contact with the vertical surface 16b of (16).

On the other hand, the closing ring 17 is mounted along the outer circumferential surface of the sealing ring 16 so as to project slightly higher than the front and rear core diameters 12a and 12b of the breakaway skin 12 so as to contact the inner surface of the barrel. In order to accommodate the annular projections 16a and 16b formed in the 16 and to rotate smoothly along the annular projections 16a and 16b, as shown in FIG. The protrusion accommodation grooves 17a and 17b which have a shape are provided. The number of the projection receiving grooves 17a and 17b is the same as the number of the annular projections 16a and 16b.

This closure ring 17 is mounted to the closure ring 16 using the inherent properties of the plastic. That is, the closing ring 17 is heat-treated and mounted on the sealing ring 16. More specifically, the closed ring 17 having an inner diameter slightly larger than the outer diameter of the groove 15 is stretched in a flexible state due to ductility when heated for a predetermined time by water or steam at 80 to 100 ° C. After being inserted into the groove 15 through the rear core mirror 12b is cooled to room temperature and hardened to be mounted on the outer circumferential surface of the sealing ring 16.

According to the sealing mechanism 18 having such a structure, as well as sealing the gap generated between the inner surface of the barrel and the outer surface of the warhead assembly 10, as well as the projections (16c, 16d) of the sealing ring 16 and the closing ring ( By interlocking action with the projection receiving grooves 17a and 17b of 17), it is possible to effectively prevent the leakage of the combustion gas of the propellant between the sealing ring 16 and the closing ring 17 under the ultra high pressure chamber pressure. That is, in the process where the warhead assembly 110 moves forward along the burst under the ultra-high pressure chamber pressure (for example, 70,000 psi to 74,000 psi in the case of 40 mm gun) generated while the propellant charged in the casing assembly is burned, the propellant The combustion gas of high temperature and high pressure due to combustion of the gas is prevented from leaking between the steel wire inside the barrel and the closing ring 17 of the warhead assembly 10, and between the sealing ring 16 and the closing ring 17 as before. The combustion gas passing through is also blocked by the projections 16c and 16d of the sealing ring 16 and the projection receiving grooves 17a and 17b of the closing ring 17. Thus, by maintaining the airtight state between the barrel and the warhead assembly 10 by the closing mechanism 18, combustion gas does not leak in front of the muzzle before the warhead assembly 10 exits the muzzle. Ballistic nonuniformity can be minimized, and thus the impact point dispersion of the target can be improved.

As mentioned above, although this invention was demonstrated in detail through the preferable embodiment, this invention is not limited to this, It is obvious to those skilled in the art that it can be variously changed and applied in the range which does not deviate from the technical idea of this invention. Accordingly, the true scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of the same should be construed as being included in the scope of the present invention.

10: warhead assembly
11: penetrator
12: escape
12a: Anterior heart mirror
12b: rear heart mirror
13: wing assembly
14a, 14b, 14c: outer diameter extension
15: groove
16: sealing ring
16a: flat
16b: vertical plane
16c, 16d: projection
17: closing ring
17a, 17b: projection receiving groove
18: sealed mechanism
20: shell casing
21: ignition primer

Claims (5)

When the warhead assembly 10 including the penetrator 11 and the escape shell 12 formed by combining a plurality of pieces formed by dividing the outer diameter portion of the penetrator 11 forward in the barrel by the combustion of the propellant, In the warhead assembly of the wing stabilized iron shell bullet shell including a sealing mechanism for closing the gap between the inner surface of the barrel and the outer surface of the warhead assembly 10 to prevent leakage of combustion gas generated by combustion,
The sealing mechanism includes an annular groove (15) formed along the circumferential direction of the breakaway skin (12) on the outer circumferential surface between the front and rear core diameters (12a, 12b) formed on the front end side of the breakaway skin (12);
An annular sealing ring 16 which is tightly fixed to an outer circumferential surface of the annular groove 15 and in which at least one annular projection 16c, 16d is integrally formed;
Is mounted along the outer circumferential surface of the annular sealing ring 16 rotatably along the steel wire of the barrel having at least one projection receiving groove (17a, 17b) for accommodating the at least one annular projection (16a, 16b) Annular closing ring 17;
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On the outer surface of each piece of the escape shell 12, outer diameter expansion portions 14a, 14b, 14c are formed so that a part of the warhead assembly 10 contacts the inner surface of the barrel when the warhead assembly 10 is moved in the barrel. Expansion portion 14a, 14b, 14c includes a sealing mechanism characterized in that extending along the longitudinal direction from the rear end of the closure mechanism to the rear end of the breakaway skin 12 and the end portion thereof is made of an inclined surface. The warhead assembly of the wing stabilized armor shell. The method of claim 1,
The sealing ring 16 has a flat face 16a and a vertical face 16b connected to one end of the flat face 16a and in contact with one end of the front concentric mirror 12a. 'Shaped in shape,
The closure ring (17) warhead of the wing stabilizing iron shell bullet containing a closure mechanism characterized in that it has a height protruding from the front and rear center diameter (12a, 12b) of the escape shell 12 so as to contact the inner surface of the barrel. Assembly. 3. The method according to claim 1 or 2,
The annular projections 16c and 16d are formed in the shape of any one of a triangle, a trapezoid, a semicircle or a quadrangle in cross section, and the projection receiving grooves 17a and 17b correspond to the shapes of the annular projections 16c and 16d. A warhead assembly of a wing stabilized iron shell bullet comprising an airtight mechanism characterized in that it has a shape. delete delete

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