RU2363923C1 - "likhoslavl" tank cluster projectile with splinter subprojectiles - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: invention relates to ammunition. Proposed projectile comprises shell with nose electronic-contact fuse and screw-in bottom, set of cylindrical splinter subprojectiles arranged inside the shell. Aforesaid subprojectiles feature flat bottoms and diametre equal to the shell ID. The projectile comprises also luster powder charge arranged between the fuse and aforesaid set of splinter subprojectiles. Note here that every subprojectile comprises explosive charge and fuse. Both flat bottoms of subprojectile allow producing preset weight splinters. Note here that the projectile head wall thickness makes, at least, 0.1 of projectile caliber, while subprojectile fuses are arranged displaced relative to subprojectile axes and furnished blast time delay elements, the delay time being different for all subprojectiles. Note also that aforesaid elements incorporate inertial starting mechanisms.

EFFECT: higher hitting ability.

9 cl, 14 dwg

Description

The invention relates to ammunition, and more specifically to tank cluster shells with fragmentation submunitions.

Israel Military Industries (IMI) developed the 120 mm XM329 ARAM-MP-T (Anti Personnel / Anti Material - Multi Purpose - Tank) tank cassette designed to combat tank infantry and anti-tank helicopters, as well as to destroy concrete structures.

The closest analogue is a 105 mm similar projectile for a rifled tank gun (US Pat. EP 0961098 A2, publ. 01.12.1999).

The projectile comprises a housing with an electronic trajectory contact fuse and a screw bottom with a stabilizer attached to it. Inside the casing there is a set of cylindrical fragmentation submunitions made with a diameter equal to the inner diameter of the casing, and an expelling powder charge placed between the head part of the fuse and the set of submunitions. Each submunition is equipped with a fuse. Ready submunition damaging elements are laid in one layer along the lateral surface of the explosive charge.

The main disadvantage is that only the side surface of the submunition is used for throwing the GGE, and both bottoms are not used for the formation of fragments. The upper bottom is almost completely occupied by the actuator, the lower bottom is a monolithic disk, not crushed by the explosion.

Since the submunitions after being ejected from the hull are in a state of random rotation, there may be cases when, at the moment of detonation, the axis of the submunition, located at a height of several meters, is perpendicular to the surface of the earth, i.e. the fragmentation of fragments from the side surface of the submunition occurs parallel to the surface of the earth at a height of several meters, and the fragments do not have any effect on the target. The bottom is directed downwards, i.e. on the target, does not produce useful fragments and does not contribute to the defeat of the target.

Another significant drawback of the projectile is the complexity of the fuse, consisting of a head part that controls the expelling charge, and the bottom part containing a temporary and contact device. This raises the problem of ensuring reliable communication of these parts. The adopted scheme for command input and temporary installation into the bottom of the fuse through the capsule sleeve of the sleeve is convenient for the unitary cartridge of tanks of NATO countries, but is unacceptable for separate loading rounds of domestic tanks T-72, T-80, T-90.

A certain disadvantage is the possibility of failure to transfer detonation between submunitions due to the significant thickness of the upper bottom containing the submunition fuse.

Among the shortcomings should also be attributed to the small thickness of the warhead, which does not ensure the strength of the projectile when introduced into brick and concrete barriers, which reduces the combat capabilities of the tank during operations in settlements.

Shell XM329 ARAM adopted as a prototype of the invention. It is aimed at eliminating the disadvantages of the prototype.

The technical solution consists in the fact that the tank cartridge shell contains a body with a head electronic trajectory-contact fuse and a screw bottom, a set of cylindrical fragmentation submunitions made with flat bottoms and a diameter equal to the inner diameter of the body, an expelled powder charge placed between the fuse placed inside the body and a set of fragmentation submunitions, with each submunition containing an explosive charge and a fuse. Both flat bottoms of the submunition are made with the possibility of forming fragments of a given mass, while the wall thickness of the shell of the head of the projectile is at least 0.1 caliber, and the submunition fuses are offset from the axis of the submunitions and are equipped with detonation delay elements for a time different for all submunitions, moreover, the elements of delayed detonation are equipped with inertial mechanisms for their launch.

In private versions, the bottom of the submunitions is made with corrugations on its surface in contact with the explosive charge or with ready-made striking elements or with recesses whose vertices are directed towards the explosive charge. The head fuse is equipped with pyrotechnic and detonation channels. The head part of the projectile contains a honeycomb core or is made with longitudinal stiffeners. Along the axis of the bottoms of the submunition, from the side facing the explosive charge, recesses with transfer charges of the explosive are made. The fuse of the submunition is fixed in its side wall, the axis of the fuse being perpendicular to the axis of the submunition.

Figure 1 shows a longitudinal section of the projectile, figure 2 - the head part in the form of a spatial structure, figure 3 ... 6 - examples of the execution of sub-shells, figure 7 - the departure of sub-shells from the body, figure 8 - fragmentation fields of the sub-shell, figure 9 ... 14 - types of projectile action.

The cassette shell shown in figure 1, contains a housing 1 with a screw bottom 2 and a stabilizer 3 attached to it, containing a tracer 4. A set of cylindrical sub-shells 5 is placed inside the housing. A trajectory-impact fuse 6 with a pyrotechnic channel 7 is placed in the head of the housing; detonation channel 8 and the receiver of the commands 9. Between the fuse and a set of submunitions placed powder explosive charge 10.

According to the conditions of strength when the projectile penetrates into solid obstacles, the head of the projectile has a power design in which the wall thickness of the head is at least 0.1 caliber. In this case, the head part may contain a honeycomb core in the inner cavity or be made in the form of a spatial structure, for example, with radial ribs 11 (figure 2).

Schemes for the execution of submunitions are presented in figure 3 ... 6. The submunition of FIG. 3 comprises a housing 12 with a charge of explosive 13, a temporary fuse 14, a set of ready-made striking elements (GGE) 15, laid on the inner surface of the housing. GGEs are made of steel or heavy alloys of tungsten, tantalum, etc., mainly in a form that allows them to be densely packed in a layer. Figure 3 and the following are shown for clarity, the performance of the GGE in the form of balls. Along the axis of the bottoms of the submunition, including those containing the GGE layer, from the side facing the explosive charge, recesses were made containing the explosive transfer charges 16. The detonation channel of the head fuse is located along the axis of the projectile. The fuses of the submunitions are located with an offset relative to the axis of the submunitions and contain an element for delaying the detonation for a time different for all submunitions, as well as an inertial mechanism for starting the element for the delay.

Figure 4 shows the execution of the submunition with the GGE mounted in the walls of the housing, for example, using press powder technology. Figure 5 presents the execution of the bottoms with corrugation 17 for a given crushing. In this design, the submunition fuse is mounted in the side wall of the submunition, which allows it to be used more productively for fragmentation of the bottom. For this case, an option is provided for incorporating into the fuse an engine 18 of a reactive or firing-ballast type, intended for breeding submunitions before their detonations in radial directions. Figure 6 shows the execution of the submunition with meniscus recesses 19 applied on its outer surface, intended for the formation of shock nuclei.

The projectile is multi-purpose and is designed to carry out the following types of tank shooting:

I. Shooting to suppress tank-hazardous manpower in open areas, in trenches and on reverse slopes and anti-tank helicopters with a significant error in determining the range to the target. The ejection of submunitions occurs at a proactive point in front of the target (Fig. 9).

II. The same type of fire at a precisely defined range. The projectile is detonated assembly (figure 10).

III. Shooting for the suppression of manpower on the ground using a shock gap with the installation of the fuse for instant (fragmentation) action (11).

IV. Shooting at buildings and field structures with installation on a penetrating high-explosive action (Fig. 12).

V. Ricochet shooting with trajectory gap assembly (Fig.13).

VI. Ricochet firing with the release of submunitions after a rebound (Fig. 14).

The type of action I-VI is set, and for types I-II, the flight time is set by contactless input of commands through the settings receiver on the charging path. On the flight, the projectile does not rotate and is stabilized due to plumage. When firing type I at the calculated point of the trajectory, a temporary fuse is triggered, a fire beam is fed through the pyrotechnic channel 7 to ignite the knockout charge 10, which pushes the set of submunitions back with the cutting of the bottom 2 thread.

When the subunit block is pushed, the inertial trigger mechanism of the delay element is triggered. The delay time for submunitions has a different value. After the departure of the sub-shells from the hull (Fig. 7), they separate and diverge, while the orientation of the sub-shells becomes arbitrary.

The response time of the first submunition is calculated in such a way that the submunitions manage to disperse at distances at which the probability of damage to the remaining submunitions by fragments of the first submunition becomes negligible. After a predetermined period of time, the second sub-projectile and further subsequent ones are undermined. A chain of discontinuities is built along the trajectory, which provides compensation for the error in determining the range to the target.

The scheme of action of the submunition at its arbitrary position relative to the surface of the earth is shown in Fig. A submunition, when detonated, forms two fields: a circular field of 20 GGE and fragments of the lateral surface and an axial field of 21 GGE and fragments of one of the bottoms. The total probability P of target destruction is determined by the formula:

P = 1- (1-Pr) (1-Pz)

Pr, Pz - respectively, the probability of hitting the target with a circular and axial field. When firing type II (trajectory discontinuity without throwing throwing blocks, Fig. 10), the fuse detonates the set of submunitions along the detonation channel 8. The transfer of detonation between the submunitions is facilitated by the transfer charges 16. The GGE located on the bottoms of the submunitions, with this type of action, have a small radial speed, but nevertheless make a certain contribution to the overall fragmentation effect. In this type of action, the compression action of the projectile (the action of the air shock wave and explosion products) begins to play a noticeable role.

Shooting type III (11) is used in case of failure of the trajectory blasting system.

Shooting type IV (Fig. 12) is used to suppress tank-dangerous targets inside structures. In this case, the fuse provides a delay in the detonation for the time necessary for the penetration of the projectile into the after-space. The same type of shooting can be used for ricochet shooting with the implementation of air blasting of the projectile assembly (Fig. 13).

A fundamentally new type of fire, not provided for the prototype, is ricochet shooting with the release of submunitions after a rebound (Fig. 14). For this, a special fuse installation is introduced. The design of a projectile with a more intensive breeding of submunitions is proposed. Moreover, in addition to the main knockout charge of the entire set, each submunition is equipped with an additional separation powder charge pyrotechnically connected to the element for slowing down the projectile fuse. The deceleration elements of all submunitions have different deceleration times, and these times increase in the arrangement of the submunitions from the bottom of the projectile to its warhead. The elements of slowing down the detonation in the bottom scheme for submunitions can be the same.

The proposed projectile can be used in domestic tanks T-72, T-80, T-90 with the introduction of an automatic induction installer for the head fuse in the gun loading path. On the T-90S tank such a system (Aynet) has already been installed.

The technical result of the invention is to increase the effectiveness of self-defense of the tank from tank dangerous infantry, including in structures, and from anti-tank helicopters.

Claims (9)

1. Tank cluster shell comprising a body with a head electronic trajectory-contact fuse and a screw bottom, a set of cylindrical fragmentation submunitions located inside the body, made with flat bottoms and a diameter equal to the internal diameter of the body, an expelled powder charge placed between the fuse and a set of fragmentation submunitions wherein each submunition contains an explosive charge and a detonator, characterized in that both flat bottoms of the submunition are configured to form fragments of the given mass, while the wall thickness of the shell of the head of the projectile is at least 0.1 caliber, and the fuses of the submunitions are displaced relative to the axis of the submunitions and are equipped with elements for delaying detonation for a time different for all submunitions, and the elements for delaying detonation are equipped with inertial mechanisms for starting them . 2. The projectile according to claim 1, characterized in that the bottom of the submunitions is made with corrugations on its surface in contact with the explosive charge. 3. The projectile according to claim 1, characterized in that the bottom of the submunitions are made with ready-to-use striking elements. 4. The projectile according to claim 1, characterized in that the bottom of the submunition is made with recesses, the vertices of which are directed to the explosive charge. 5. The projectile according to claim 1, characterized in that the head fuse is equipped with pyrotechnic and detonation channels. 6. The projectile according to claim 1, characterized in that its head part contains a honeycomb core. 7. The projectile according to claim 1, characterized in that its head is made with longitudinal stiffeners. 8. The projectile according to claim 1, characterized in that along the axis of the bottoms of the submunition from the side facing the explosive charge, recesses with transfer charges of the explosive are made. 9. The projectile according to claim 1, characterized in that the fuse of the submunition is mounted in its side wall, the axis of the fuse being perpendicular to the axis of the submunition.

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