RU2274823C1 - Tank antihelicopter projectile - Google Patents

Abstract

FIELD: ammunition, in particular, antihelicopter projectiles for tank smoothbore guns.

SUBSTANCE: the projectile has a warhead with a hinged stabilizer, explosive charge and an impact-time fuse. The projectile has a set of loads-stretchers with cables, device for radial ejection of the cables with loads-stretchers, device for keeping the ropes in tension in flight, and a system for blasting the projectile at touching of the target by the cables.

EFFECT: reduced dependence of the projectile action on the fuse accuracy.

17 cl, 10 dwg

Description

The invention relates to ammunition, and more specifically to anti-helicopter shells for tank smooth-bore guns. Conventional high-explosive fragmentation shells that are part of the ammunition load of domestic tanks (3OF19, 3OF26 shells) have a fuse and can hit aircraft, including anti-tank helicopters, only with a direct hit, which is unlikely for unguided shells. The probability can be significantly increased due to the use of guided projectiles or the use of trajectory detonation of shells in the area of an air target (non-contact or temporary). An example of a guided projectile is a 120 mm TERM US tank projectile. The main disadvantage of the projectile is its high cost (20-30 thousand dollars). An example of a tank projectile with a non-contact fuse is a 120 mm M830A1 multi-purpose fragmentation-shaped projectile, USA. The main disadvantage of non-contact detonation as applied to lay tank shooting is the possibility of spontaneous detonation of a projectile from a signal reflected from the surface of the earth and objects located on it, as well as the possibility of electronic countermeasures.

According to the noise immunity criterion, the most promising is a tank projectile with a temporary fuse, containing a body with an explosive charge, a deployable stabilizer and a temporary fuse (usually of an electronic type). An example of such a fuse is the ZVM18 fuse, developed by the Research Institute “Search” (L. Egorenkov et al. “New fuses for ammunition of the barrel artillery.” “Military Parade No. 2, 2000, p. 36, L. Egorenkov, N. Platonov“ Research Institute “Search” - 70 years of leadership in the design and manufacture of fuses ”,“ Military Parade ”, No. 1, 2000, p. 50) A 125 mm tank shell with this fuse was adopted as a prototype of the invention. The main disadvantage of this design is that, under the conditions of covering the target with a fragmentation stream, a high accuracy of time response is required (installation step and standard deviation no more than 0.0001 s), which cannot be achieved with a timely technological level. In other words, there is a strong dependence of the projectile on the fuse accuracy.

The present invention seeks to remedy this drawback. The technical solution consists in the fact that the tank anti-helicopter projectile for a smooth-bore gun contains a warhead with a drop-down stabilizer and explosive charge and a shock-temporary fuse. The projectile contains a set of stretch weights with cables connecting the stretch weights to the projectile, a device for radially ejecting cables with stretch weights, a device for maintaining the cables in flight in a taut state, and a projectile detonation system when the cables touch the target.

The proposed design introduces a set of stretch weights with cables connecting the stretch weights with the projectile, a device for radially ejecting cables with stretch weights, a device for maintaining the cables in flight in a taut state, and a projectile detonation system when the cables touch the air target.

In particular embodiments of the invention, the projectile comprises stretch weights with cables, a device for radially ejecting cables with stretch weights, a device for maintaining the cables in flight in a taut state, and a projectile detonation system when the cables touch the target. The devices are placed in a block located in the head of the projectile between the fuse and the warhead of the projectile.

The device for ejecting cargo-stretchers contains a set of nests located in planes normal to the axis of the projectile, while in the front of the nest there is a load-stretcher with a cable attached to it, in the middle part there is a cable bay, and in the bottom part there is an actuating device for blasting attached to it by the opposite end of the cable, a chamber with a knockout powder charge connected by a pyrotechnic channel to a fuse, while the camera is connected by channels to the cavities of the nests.

The load-stretcher can be fixed in the nest with the help of a cut-off stopper.

The cable is wound on a rotating coil, the axis of which coincides with the axis of the socket.

The reel can be fastened with a load-stretcher or with the bottom of the socket.

The device for supporting the cable in flight in tension when placed on a stretcher cargo can be made in the form of a jet engine.

The device for maintaining the cable in flight in tension can be made in the form of a three-bladed glider, laid in the body of the load-stretcher.

The device for maintaining the flight in tension when in tension contains a jet engine located in the load-stretcher, equipped with rear and side nozzles, and a stabilizer, while the side nozzle is located in the center of mass of the load-stretcher between two points of attachment of the cable to the side surface of the housing.

A blasting system attached to the inner end of the cable can be performed using the tensioning action of a mechanical device with a pin or a voltage pulse generator, for example, based on a piezoelectric element or magnetic inductor.

The blasting system can be performed using the discontinuous action of a loop sensor formed by a cable and an insulated electric drive woven into it.

The shock-temporary fuse is made with the possibility of introducing installations for three types of shock: instant, inertial and slow.

The shell of the projectile can be made of high-fragmentation steel, for example, silicon-manganese steel 60G2S or silicon steels 60C2, 80C2.

On the axis of the rotating coil is a pyrotechnic device of a jet or ballast type, made with the possibility of creating a torque directed against the moment created by the load-stretchers at the time of unwinding the cables to full length.

A damping element is included in the cable.

The cables are connected by annular elements forming a radial-ring configuration of the cable network, while the nests are made with longitudinal slots.

Figure 1 - projectile in flight after the release of cables with cargo-stretch-type reactive; figure 2 is a longitudinal section of a projectile; figure 3 is a cross section of the projectile along the plane aa; figure 4 - load-stretcher reactive type; figure 5 - load-stretcher aerodynamic type in flight; Fig.7 - load-stretcher combined type; Fig. 8 is a diagram of a projectile with a rotating coil located along the axis of the projectile; Fig.9 is a projectile with a network of radial-ring type; figure 10 - slot stretcher with a side groove for the passage of the cable.

The projectile (Fig. 1) contains a high-explosive fragmentation warhead 1 with a stabilizer, a block 2 in which the said devices are placed, a shock-time head fuse 3, tensile weights 4 and cables connecting them to the projectile 5. In this design, the number cargo equal to four. A longitudinal section of the structure is presented in figure 2. The warhead consists of a casing 6, inside which a charge of explosive 7 is placed with a detonator 8. To enhance the fragmentation effect, the casing can be made of high-fragmentation steel, for example, silicon-manganese steel 60G2S (RF patent No. 2153 024) or silicon steel 60C2, 80C2.

In the housing 9 of block 2, connected by a threaded connection 10 to the body of the warhead 6, an axial transfer charge of explosive devices And, sockets 12, a chamber of expelling powder charge 13, connected by channels with sockets, a pyrotechnic channel 14 of the fuse, are placed. Slots 12 are located in planes normal to the axis of the projectile. In the embodiment shown in figure 3, two parallel cylindrical nests are located symmetrically with respect to the axis of the projectile, with the outputs of the nests directed in opposite directions. Receptacles 4 are placed in the sockets 12 with the cables 5 attached to them, wound around the discharge coil 15. The opposite end of the cable is connected to a voltage pulse generator 16, which in turn is connected by an electrical conductor 17 to the head fuse 3. The cavity of the nests is connected using channels 18 s camera 13 expelling powder charge.

The reactive stretcher 4 (Fig. 4) contains a housing 19 in which a solid fuel charge 20 and a diaphragm 21 are placed. The housing is equipped with nozzles 22. The reactive tensioner is mounted in the block housing by a shear stop 23. The upper part of the barrel is closed by a plastic stopper 24.

Another embodiment of a device for maintaining cables in flight in a taut state based on the use of aerodynamic forces is shown in FIG. The stretcher contains a housing 25, in the bottom of which an opening 26 is made for the passage of powder gases. The cable 5, as in the case of a reactive tensioner, is wound on the outer surface of the housing. Inside the housing there is a three-bladed glider, consisting of a piston 27 and blades 28 mounted on it. The configuration of the blades in the open state simultaneously ensures the orientation of the glider in the direction of movement and the creation of a lifting force that provides tension to the cable (Fig.6).

Combined action options are available. One of the options is presented in Fig.7. In this embodiment, the outer end of the cable is attached to the side surface of the stretcher at two points located along the generatrix. The jet engine is equipped with two nozzles 29 and 30. The nozzle 29 is located on the rear end of the stretcher, the nozzle 30 is on the side surface between the points of attachment of the cable in the region of the center of mass of the stretcher. The stretcher is also equipped with a retractable stabilizer 31. The rear stretch of the cable 32 is made with a length that ensures in flight parallelism of the axes of the stretcher and the projectile.

The projectile is as follows. Before firing, an action type setting is introduced into the fuse. The projectile is multi-program and depending on the installation can implement 5 types of actions:

- action on an aerial target with a trajectory ejection of the network at an anticipated point and subsequent contact detonation when the cables touch the target;

- trajectory rupture without the release of cables, for example, when firing at ground targets in trenches, embankments, on reverse slopes;

- shock rupture with settings for instantaneous (fragmentation), inertial (high-explosive) and delayed (high-explosive) actions.

If the temporary fuse mechanism is set to the first type of action, the firing pulse drops through the pyrotechnic channel 14 at the anticipated point to ignite the expelling powder charge, resulting in the ejection (shooting) of reactive stretchers with the cutting of the stoppers 23. At the same time, their solid fuel charges ignite. The stretchers scatter in radial directions, winding cables from coils 15 and forming a "network" around the projectile. After winding the cables, their tension is supported by the thrust of jet engines, the operating time of which is longer than the projectile’s flight time to the maximum firing range.

In shells with aerodynamic stretchers in FIGS. 5, 6, at the moment the stretchers are pushed out of the barrel, the powder gases through the hole 26 enter the housing 25 and push the piston 27 with a three-blade drop-down glider mounted on it. When the piston is raised to its upper position, it is fixed by a stop (not shown in FIG. 5). After opening and fixing the blades of the glider, the tension of the cables is supported by the aerodynamic force arising during the flight of the glider with an angle of attack (by the principle of a kite).

In the case of combined tension according to the scheme of Fig. 7, after winding the cable under the influence of jet engines 29, 30, stabilizer 31 and oblique extension 32, the stretcher body is mounted in flight with an angle of attack with respect to the axis of the projectile.

On Fig shows another scheme for winding the cables, namely winding from a rotating coil 32 located along the axis of the projectile. The torque imparted to the projectile by the stretchers when unwinding the cables to their full length is compensated by the moment created by the pyrotechnic device 33 of the jet or ballast type.

The generator 16 is equipped with a safety device that provides the transfer of force to the core or piezoelectric element only when a certain threshold value is reached. In the diagrams shown in figures 3, 4, both pairs of sockets are installed in such a way that the moments arising due to the displacement of the axis of the nests relative to the longitudinal axis of the projectile are mutually compensated and the rotation of the projectile does not occur.

The optimal cable length for a projectile of a caliber of 125 mm is in the range of 2.5-3 m. If the slip does not exceed the cable length, a cable hit on one of the parts of the aircraft leads to the appearance of a force in the cable that exceeds the threshold value of the generator safety device, and triggering the latter. The voltage pulse through the electric wire 17 is supplied to the fuse, which through the transfer charge 11 delivers a detonation pulse to the detonator 8. As a result, the projectile explodes in close proximity to the air target. The target is affected by fragments of the body and block, as well as by the compression action of the explosive charge. Additional damaging effect is created due to the impact on the target of cables and stretchers.

In shells equipped with a detachable loopback target sensor, detonation of the projectile occurs when the conductor breaks at the moment the cable hits the target. It is possible to use a combined method of undermining.

A design option is provided with the placement of block 2 in the bottom of the projectile between the stabilizer and the warhead.

The probability of covering the target with a network of cables can be increased by introducing ring elements 34 into the network (Fig. 9). In this case, the stretchers are installed in sockets 35 having a through lateral groove 36 (Fig. 10).

The main advantage of the proposed scheme over the prototype is the possibility of reducing by approximately an order of magnitude the required accuracy of a temporary fuse. Accuracy of 0.01 s (in terms of installation step and standard deviation), which is currently provided by the existing elemental base and technological level of production, is quite sufficient.

It is promising to use the proposed demolition scheme for other types of non-rotating ammunition (guided cruise missiles stabilized by the roll of air bombs, etc.) designed to destroy ground targets representing a spatial composition of linear elements (bridge trusses, power lines, antenna fields, radio relay masts communications, mast radar stations, etc.).

Claims (17)

1. Tank anti-helicopter projectile for a smoothbore gun, comprising a warhead with a drop-down stabilizer and a charge of explosive and a shock-temporary fuse, characterized in that it contains a set of load-stretchers with cables connecting the load-stretchers with a projectile, a device for radial ejection of cables with cargo stretchers, a device for maintaining the cables in flight in a taut state and a projectile detonation system when the cables touch the target. 2. The projectile according to claim 1, characterized in that the load-stretchers with cables, a device for radial ejection of cables with load-stretchers, a device for maintaining the cables in flight in a taut state and a system for detonating the projectile when the cables touch the target are placed in the unit located in the head parts of the projectile between the fuse and the warhead of the projectile. 3. The projectile according to claim 1, characterized in that the device for ejecting cargo-stretchers contains a set of sockets located in planes normal to the axis of the projectile, while a load-stretcher with a cable attached to it is placed in the front of the socket, in the middle part cable bay, and in the bottom part there is an actuating device for detonating with the opposite end of the cable attached to it, a chamber with a knockout powder charge connected by a pyrotechnic channel to a fuse, while the camera is connected by channels with nest cavities. 4. The projectile according to claims 1 and 3, characterized in that the tensile load is fixed in the nest with the help of a cut-off stopper. 5. The projectile according to claim 1, characterized in that the cable is wound on a rotating coil, the axis of which coincides with the axis of the socket. 6. The projectile according to claim 5, characterized in that the coil is fastened with a load-stretcher. 7. The projectile according to claim 5, characterized in that the coil is fastened to the bottom of the socket. 8. The projectile according to claim 1, characterized in that the device for maintaining the cable in flight in tension is placed on the load-stretcher and is made in the form of a jet engine. 9. The projectile according to claim 1, characterized in that the device for maintaining the cable in flight in tension is made in the form of a three-bladed glider, laid in the body of the load-stretcher. 10. The projectile according to claim 1, characterized in that the device for maintaining the cable in flight in a taut state comprises a jet engine located in the load-stretcher, equipped with rear and side nozzles, and a stabilizer, while the side nozzle is located in the region of the center of mass of the load-stretcher between two points of attachment of the cable to the side surface of the housing. 11. The projectile according to claim 1, characterized in that the blasting system attached to the inner end of the cable is made using the tensile action of a mechanical device with a pin or a voltage pulse generator, for example, based on a piezoelectric element or magnetic inductor. 12. The projectile according to claim 1, characterized in that the blasting system is made using the discontinuous action of a loop sensor formed by a cable and an insulated electric drive woven into it. 13. The projectile according to claim 1, characterized in that the shock-temporary fuse is made with the possibility of introducing installations for three types of impact: instant, inertial and slow. 14. The projectile according to claim 1, characterized in that the shell of the projectile is made of high-fragmentation steel, for example, silicon-manganese steel 60G2S or silicon steels 60C2, 80C2. 15. The projectile according to claim 5, characterized in that on the axis of the rotating coil there is a pyrotechnic device of a jet or ballast type, made with the possibility of creating a torque directed against the moment created by the load-stretchers at the time of unwinding the cables to full length. 16. The projectile according to claim 1, characterized in that a damping element is included in the cable structure. 17. The projectile according to claim 1, characterized in that the cables are connected by annular elements forming a radial-ring configuration of the cable network, while the slots are made with longitudinal slots.

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