RU2300073C2 - Fragmentation-bundle shell "vasilisk" - Google Patents

Abstract

FIELD: ammunition having simultaneously axial and circular destruction fields.

SUBSTANCE: the shell has a body with an explosive charge located in it, fragmentation block located in its front part, nose fuse of the trajectory-contact type with a timer, detonator, pyrotechnical and detonation ducts. The shell caliber is smaller than the barrel caliber, the shell is provided with a caliber separating pan and an extractable receiver of laser radiation from the fire unit located on the front part of the fuse or on the rear and face of the shell, the shell fuse is made for separation of the line between the timer and the detonator when the laser radiation receiver is in the area covered by the laser beam of the fire unit.

EFFECT: enhanced accuracy of fire.

2 tbl, 5 dwg

Description

The invention relates to high-explosive fragmentation ammunition having simultaneously axial and circular fields of destruction.

Known fragmentation-beam shells containing a shell with a charge of explosive (BB), a single-layer or multi-layer block of finished striking elements located in front of the explosive charge, head or bottom trajectory fuse.

The location of the head fuse in front of the GGE block leads to a decrease in their speed, loss of a portion of the GGE and field shape deterioration. This disadvantage is eliminated in the design of the fragmentation-beam projectile (US Pat. No. 2237231 of the Russian Federation), adopted as a prototype, which contains a pyrotechnic mechanism for separating the warhead before detonating the explosive charge.

The main disadvantage of a caliber fragmentation-beam projectile, especially when used in tank guns, including when shooting anti-tank helicopters, is the long flight time to the target, due to the relatively low initial velocity of the caliber shells of tank guns (usually 800-900 m / s) . Long flight time leads to significant misses, on the one hand, due to the displacement of the projectile in flight due to the influence of the transverse wind, and on the other, due to the transverse movement of the target itself.

An object of the invention is to increase accuracy.

The technical solution consists in the fact that the projectile contains a housing with an explosive charge located therein, a fragmentation block located in its front part, a trajectory-contact type head fuse with a temporary mechanism, a detonator, pyrotechnic and detonation channels. The caliber of the projectile is made smaller than the caliber of the barrel, the projectile is equipped with a caliber detachable tray and a retractable laser receiver from the firing system located at the head of the fuse or at the rear end of the projectile, while the projectile fuse is capable of disconnecting the line between the temporary mechanism and the detonator when the laser receiver is located radiation in the area captured by the laser beam of the firing system.

Preferably, if its relative mass is 5 ... 7 kg / dm ³ .

Increasing the speed of the projectile creates another advantage. As is known, bottom initiation of an explosive charge is usually used in known designs of fragmentation-beam projectiles, since it provides a significant increase in throwing speed due to reflection of the detonation wave from the GGE block. With a large intrinsic velocity of the projectile, the magnitude of the additional velocity reported by the explosive charge does not play a significant role, therefore, the bottom location of the detonator can be replaced by the front location, which provides a lower throwing speed (in the "outgoing" detonation wave mode), but is simpler in technical implementation.

The obvious advantage of reducing flight time and, as a result, improving firing accuracy is a significant increase in the likelihood of a direct hit on the target. In the case when, when approaching the target, a direct hit is predicted in it, the temporary mode of detonation should be turned off, and the mode of shock detonation is turned on.

The invention is illustrated by drawings. Figure 1 - diagram of a projectile to smooth-bore tank gun. Figure 2 - dependence of the probability of damage to an anti-tank helicopter from the mass of a fragmentation-beam projectile (together with a pallet) of a 125 mm gun having a muzzle energy of 8.4 MJ. Figure 3 - dependence of the probability of defeat of the anti-tank helicopter subcaliber and caliber fragmentation-beam shells on the firing range. Figure 4 - firing subcaliber fragmentation-beam projectile: a direct hit on target. Figure 5 - firing with trajectory detonation at a predicted point and covering the target with a beam of GGE.

The projectile diagram is presented in figure 1. The projectile contains a housing 1, equipped with a charge of explosive 2 and containing a multilayer gas-turbine power unit 3 in the front part. A detonator 4 is mounted along the axis of the unit, connected to a temporary mechanism 5. A head cap 6 is attached to the body on the thread, into which a trajectory-impact fuse is screwed into the front part 7, equipped with a pyrotechnic channel 8, a detonation channel 9 and a laser radiation receiver 10. In the inner space of the cap there is a powder charge of separation 11. The outer surface of the projectile mates with a separating tray 12, with toyaschim of 2-3 sectors. The sectors are fastened by an annular belt 13. In the rear of the projectile is a hard-type stabilizer 14.

An option is provided for installing a radiation receiver 10 in the bottom 15 of the projectile. In this case, the signal must be provided to the head fuse, for example, by means of an electric or fiber optic cable passing inside the housing along the explosive charge.

At the head of the fuse is the receiver of the installations 16. The choice of the optimal total mass of the proposed projectile for a given caliber is determined by the firing conditions and characteristics of the target. Figure 2 presents a graph of the calculated dependence of the probability of defeat W ₁ helicopter with one shot of a 125 mm tank gun at a distance of 3 km from the relative mass of the projectile Q (with a pallet). In this case, both the probability of a direct hit and the probability of being hit by a GGE beam in case of a break at a predicted point are taken into account. The muzzle energy of the gun is assumed to be fixed and equal to 8.4 MJ, the mass of one GGE is 5 g, the steel equivalent of the target is 5 mm. With an increase in the mass of the projectile, the number of GPEs increases, but the muzzle velocity of the projectile decreases, and hence the accuracy of the fire. The competitive interaction of these factors leads to the appearance of some optimal projectile mass (~ 11.6 kg). Comparative characteristics of the fragmentation-initial fragmentation projectile (a 125 mm tank high-explosive fragmentation projectile ZOF26 for the D-81 gun is accepted as the basic version) and the optimal sub-projectile projectile are presented in the table (Cq = Q / d ³ - relative projectile mass (with a pallet), Cq, kg / dm ³ , Q, kg, d - caliber, dm).

Table Characteristic Caliber Subcaliber Gross weight Q, kg 23.0 11.6 Initial velocity Vo, m / s 850 1200 Relative mass Cq, kg / dm ³ 11.8 5.9 The total mass of the GGE, kg 2,3 1,2 The number of GGE 460 240 Probability of defeat at a distance of 3 km 0.35 0.5

Figure 3 shows the advantage of the sub-caliber fragmentation-beam projectile over the caliber at all ranges, excluding the range 0-1500 m, where the advantage of firing accuracy is not decisive. Numerical simulation of the firing of tanks with anti-tank helicopters showed that the range of optimal values of Cq is 5 ... 7 kg / dm ³ .

The projectile is as follows. Before firing through the receiver of the installation 16, the installation is set to the type of action, and when shooting at a trajectory gap, also the flight time to the gap. The projectile is multifunctional and, depending on the installation, has the following types of actions.

Helicopter shooting

At the time of the shot, the countdown starts. At the same time, a laser beam receiver 10 extends from the fuse case. The target and the flying projectile are continuously illuminated by this beam 17 generated by the installation of the tank. Laser target illumination is used, for example, in the 9K 120 Svir complex of the T-72 tank. During normal flight, the reflection of the laser beam from the receiver 10 of the projectile is located inside the beam reflected from the target. This means that the projectile goes exactly at the target. Communication with the temporary mechanism under this condition is turned off. When maintaining this position before meeting with the target, the projectile penetrates into it and explodes inside the target (figure 4).

In the case when the projectile deviates from the direction toward the target during the flight (target maneuver, projectile drift by side wind, etc.), it leaves the beam channel and ceases to receive a signal. In this case, the connection with the temporary mechanism is automatically restored, at the anticipated point I, the pyrotechnic channel is triggered and the head cap 6 is reset, and then at point II the explosive charge is detonated and the axial flow of the GGE is formed (Fig. 5). Firing at an air target can also be conducted with a trajectory rupture on a miss without shooting a warhead with a target hitting a circular field of fragments of the hull.

When firing at ground targets, a ground shock can be realized with the installation either for instantaneous (fragmentation) action, or for inertial (high-explosive) action, or for slow (penetrating high-explosive) action.

The proposed fragmentation-fragmentation projectile projectile will significantly increase the capabilities of the tank during its self-defense against anti-tank helicopters and other tank-hazardous targets and increase its survival on the battlefield (see V. Odintsov Tragedy of the tank: there is nothing to fight with infantry and helicopters // Technique and armament, No. 5, 2003). In conclusion, we emphasize once again that the proposed projectile is uncontrollable, but only switched to different types of actions, i.e. significantly simpler and cheaper to manufacture.

Claims (2)

1. A fragmentation-beam projectile containing a body with an explosive charge located therein, a fragmentation unit located in its front, a trajectory-contact head fuse with a temporary mechanism, a detonator, pyrotechnic and detonation channels, characterized in that the projectile caliber is made smaller than the caliber of the barrel of the firing system, the projectile is equipped with a caliber detachable tray and a retractable receiver of laser radiation from the firing system located in the head of the fuse or on the rear m of the butt of the projectile, while the fuse of the projectile is made with the possibility of disconnecting the line between the temporary mechanism and the detonator when the laser radiation receiver is in the area captured by the laser beam of the firing system. 2. The projectile according to claim 1, characterized in that its relative mass is 5 ... 7 kg / dm ³ .

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