RU2247930C1 - Tank cluster shell "triglav" with fragmentation live components - Google Patents

Abstract

FIELD: cluster ammunition with fragmentation live components.

SUBSTANCE: the shell has a body with a trajectory fuse and a pyrotechnic duct located in it, bursting powder charge, axial rod-pusher and a set of fragmentation live components, having a body with an explosive charge and an impact fuse. The axial rod-pusher is made with an inner cavity, in which the explosive charge is positioned, semi-spherical recesses are extruded on the surface of the rod-pusher, the live fragmentation components, having a spherical shape or close to it, are extruded on the surface of the rod-pusher the trajectory fuse is additionally provided with a detonating duct.

EFFECT: enhanced functional potentialities of ammunition and enhanced its hitting effect.

10 cl, 10 dwg

Description

The invention relates to ammunition, and more particularly to cluster shells with fragmentation warheads. Known cluster artillery shells containing both fragmentation and fragmentation-cumulative warheads [1]. The 152 mm domestic 3-O-13 cartridge cluster [2], adopted as a prototype, contains a housing with a head trajectory fuse, an expelled powder charge, an axial push rod fastened with a screw bottom, and a set of eight cylindrical fragmentation warheads placed in two tiers and having natural crushing enclosures.

The main design flaw in relation to a tank shell is the unsuccessful cylindrical shape of the combat element. For tank guns, the main type of shooting is shooting along a flat trajectory with an incidence angle of combat elements of less than 5 °. The expansion of the fragments occurs mainly in the plane perpendicular to the axis of the combat element, i.e. the bulk of the fragments goes into the air and into the ground, and only a small part of them, spread along the surface of the earth, is used to hit targets. Another significant drawback is the lack of the ability of the shell to undermine its assembly (without ejection of combat elements), which excludes its use for firing at durable targets.

The present invention addresses these drawbacks. The technical solution consists in the fact that the tank cluster shell with fragmentation warheads comprises a body with a trajectory fuse with a pyrotechnic channel, an expelling powder charge, an axial pusher rod and a set of fragmentation warheads containing a body with an explosive charge and an explosive fuse. The axial pusher rod is made with an internal cavity in which an explosive charge is placed, hemispherical recesses are extruded on the surface of the pusher rod, in which fragmentation warheads are made made spherical or close to it, while the trajectory fuse is additionally equipped with a detonation channel.

In particular, the projectile can be configured to eject a set of fragmentation warheads in a direction opposite to the direction of movement of the projectile, while the expelling powder charge is located in the front of the projectile, and the push rod is fastened with a screw bottom or can eject a set of fragmentation warheads in the direction of movement of the projectile, while the knockout charge is located at the rear of the ammunition shell, and the pusher bar is attached to the head cap.

The trajectory fuse is either temporary, or non-contact, or command execution.

The detonation channel of the trajectory fuse is equipped with instant and delayed blasting devices.

The shell of the fragmentation warhead can be made with either natural or predetermined crushing, or with ready-to-use striking elements.

The shell of the fragmentation warhead can be made with curly tides on the outer surface, with a one-sided thickening of the wall in the form of a truncated sphere bounded on one side by a cylindrical surface made with a radius equal to the radius of the inner surface of the hull.

The charge of the rod can be equipped with an autonomous fuse with the ability to provide trajectory or shock blasting.

Figure 1 is a longitudinal section of a tank cluster shell with the ejection of combat elements backward, Figure 2 is a cross section of a projectile, figure 3 is a stacking of combat elements (scan), figure 4 is a longitudinal section of a projectile with the ejection of fragmentation warheads (RBE) forward , FIG. 5 - RBE of natural crushing, FIG. 6 - composite RBE with ready-made striking elements, FIG. 7 - RBE with one-sided thickening, FIG. 8 - RBE in the form of a truncated sphere, FIG. 9 - layout diagram of RBE in the housing, FIG. .10 - scheme of the projectile.

The tank cluster shell comprises a housing 1 with a head trajectory fuse 2 located therein, equipped with a pyrotechnic 3 and detonation 4 channels, an expelled powder charge 5, an axial push rod 6 filled with a charge of explosive 7 and connected to a screw bottom 8 made integral with the stabilizer 9 , and a set of fragmentation warheads 10, made in the form of multi-tiered laying on the surface of the axial rod. Each tier contains n fragmentation warheads (RBE) and is shifted relative to the adjacent one by an angle of 360 ° / 2n. The deployment scan of the RBE is shown in figure 3. The fuse is equipped with a receiver 11.

An embodiment of a cassette projectile with a command fuse (detonated by a command from the tank using a laser beam (RF patent No. 2102684)) and with an RBE emission in the direction of projectile movement is shown in Fig. 4. In this scheme, the bottom fuse 12 and the expelling charge 13 are located at the rear of the projectile. The laser beam is introduced through the axial channel 14 of the stabilizer and the optical window 15.

Types of RBE performance are presented in Fig.5-8. The combat element shown in figure 5, contains a spherical body 16 of natural crushing, made of high-fragmentation steel, for example 80G2S (patent No. 2153024 of the Russian Federation), explosive charge 17 and shock fuse 18. Figure 6 shows a composite combat element with ready-made striking elements 19, also made in the form of a sphere with curly tides deposited on its outer surface 20. The body of the combat element shown in Fig. 7 is made with one-sided thickening 21 and with predetermined crushing. The combat element shown in Fig. 8 is made in the form of a truncated sphere bounded on one side by a cylindrical surface 22 made by a radius equal to the radius of the inner surface of the hull. The layout of these elements in the housing is shown in Fig.9. Before firing through the command receiver 11, a projectile is installed on the cassette action (by switching on the pyrotechnic channel) or on the detonation assembly (by switching on the detonation channel) with subspecies: trajectory detonation, shock detonation (with subspecies - instant and slow action).

When fired, the force inertial effect of RBEs on each other is significantly reduced due to the fact that the main part of the load is perceived by the bar along its contact surfaces with RBE surfaces. In the case of installation on a cassette action at the approach to the target, the fuse ignites the charge through the pyrotechnic channel, which acts on the push rod with the transfer of force to the bottom of the projectile (Fig. 1) or to the head cap (Fig. 2). The threads of the latter are cut off and the rod and the RBE kit are ejected into the air.

There are options for oriented and non-oriented flight of RBE. In the first case, the orientation is carried out either by gyroscopic stabilization - by setting the RBE axis in the flow and spinning it due to curly tides (Fig.6), or by shifting the center of mass of the RBE (Fig.7). In these cases, a conventional contact or inertial impact fuse may be used. In the case of an unstabilized RBE flight with free rotation, it is necessary to use an inertial fuse of all-slaughter action.

When RBEs fall on the ground or hit other obstacles, their fuses detonate and RBEs are detonated with the formation of a fragmentation field close to spherical and a lesion zone on the earth's surface that is close to oval (taking into account the intrinsic velocity of the projectile). The reduced lesion area in this case is determined using the ratio

- приведенная площадь поражения одним боевым элементом, k≤1 - коэффициент, учитывающий снижение эффективности вследствие перекрытия площадей (фиг.10). При настильной стрельбе суммарная площадь поражения сферическими ОБЭ в 2-3 раза превышает тот же показатель для цилиндрических ОБЭ той же суммарной массы.where n is the number of RBEs,

- reduced area of destruction by one combat element, k≤1 - coefficient taking into account the decrease in efficiency due to overlapping areas (figure 10). In case of lay-off shooting, the total area affected by spherical RBEs is 2-3 times higher than the same indicator for cylindrical RBEs of the same total mass.

With the introduction of the installation to detonate the complete assembly of the fuse in the target area through the detonation channel, it detonates the explosive charge of the 7th axial pusher rod. Detonation through a spherical contact surface is transmitted by the explosive charge of the RBE. In this case, the shell of the shell is destroyed and a fragmentation field is formed containing both fragments (or ready-to-use striking elements) of the RBE and fragments of the natural fragmentation of the shell. When performing the RBE according to FIGS. 8, 9, the crushing of the body and the yield of useful fragments increases due to an increase in the contact area of the RBE with the inner surface of the body.

An option is provided for increasing the efficiency of a projectile with a cassette action due to the additional fragmentation effect of a bar explosion with an explosive charge. To this end, the charge of the rod is equipped with an autonomous fuse (not shown in Figs. 1, 4), which ensures, after ejecting it from the housing, a trajectory or impact detonation. Moreover, the presence of hemispherical recesses on the surface of the rod provides high-speed explosive-shaped shells ("shock nuclei"), which in turn will ensure the effect of the projectile on light armored vehicles.

The presence of four types of action of a tank cluster shell (cluster action, trajectory undermining assembly, instantaneous and delayed assembly undermining assembly) gives it the properties of an adaptive type of weapon suitable for solving various fire missions, which is of great importance with limited tank ammunition.

List of references

1. Odintsov V.A. The main directions of the development of field artillery ammunition and the problems of transition to the caliber of 155 mm // Defense Technology. - 1996. - No. 8-9.

2. Odintsov V.A. Designs of shrapnel ammunition. Part II. Artillery shells. Publishing House of MSTU. N.E.Bauman, 2002, p. 17, Fig. 9.

Claims (10)

1. Tank cluster shell with fragmentation warheads, comprising a housing with a trajectory fuse with a pyrotechnic channel, an expelled powder charge, an axial pusher rod and a set of fragmentation warheads containing a body with an explosive charge and an explosive fuse, characterized in that axial pusher rod is made with an internal cavity in which an explosive charge is placed; hemispherical recesses are squeezed out on the surface of the pusher rod, in which conventional warheads made in a spherical or close to shape, while the trajectory fuse is additionally equipped with a detonation channel. 2. The projectile according to claim 1, characterized in that it is configured to eject a set of fragmentation warheads in the direction opposite to the direction of projectile movement, while the expelling powder charge is located in front of the projectile, and the push rod is fastened with a screw bottom. 3. The projectile according to claim 1, characterized in that it is capable of ejecting a set of fragmentation warheads in the direction of projectile movement, while the knockout charge is located in the rear of the munition housing, and the pusher bar is fastened to the head cap. 4. The projectile according to claim 1, characterized in that the trajectory fuse has either temporary, or non-contact, or command execution. 5. The projectile according to claim 1 or 4, characterized in that the detonation channel of the trajectory fuse is equipped with instant and delayed blasting devices. 6. The projectile according to claim 1, characterized in that the shell of the fragmentation warhead is made either with natural or predetermined crushing, or with ready-to-use striking elements. 7. The projectile according to claim 1 or 6, characterized in that the shell of the fragmentation warhead is made with curly tides on the outer surface. 8. The projectile according to claim 1 or 6, characterized in that the shell of the fragmentation warhead is made with one-sided thickening of the wall. 9. The projectile according to claim 1 or 6, characterized in that the shell of the fragmentation warhead is made in the form of a truncated sphere bounded on one side by a cylindrical surface made with a radius equal to the radius of the inner surface of the shell. 10. The projectile according to claim 1, characterized in that the charge of the rod is equipped with an autonomous fuse with the ability to provide trajectory or shock blasting.

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