RU2148244C1 - Projectile with ready-made injurious members - Google Patents

Abstract

FIELD: ammunition with guided fragmentation injury fields. SUBSTANCE: projectile has a casing, accommodating a body, bottom powder charge, fuze with a receiver of the time, non-contact or command type, and the body has a bursting unit in the form of a casing with an explosive charge and detonator located in the positioned in an annular gap between the external surface of the bursting unit and internal surface of the casing. The control system is made for blasting the bursting unit both after ejection of the unit from the projectile casing and when it stays inside the casing. In the first case an axial field of injury is formed, and in the other case - a circular field. EFFECT: realized compression and penetrating-high-explosive action of projectile, formation of axial, circular fields of the fields of injury or of both of them at a time. 22 cl, 36 dwg

Description

 The invention relates to ammunition technology, and more particularly to fragmentation munitions with a controlled field of destruction. Known shells with ready-to-use striking elements (GPEs) (shrapnel) containing a body with a movable body placed therein containing compact or arrow-shaped GPEs and a diaphragm, and a bottom expelling powder charge and a detonator associated with an expelling charge (Soviet Military Encyclopedia, v. 8 , p. 530), creating a GGE flow directed along the axis of the projectile. The shell of the shell at the same time performs the function of the barrel and is not involved in the defeat of the target. The disadvantage of the projectile is its lack of a circular lesion field and, as a result, the inability to fire on impact on the ground and on hitting a target on a miss. The absence of a charge of a blasting explosive in the projectile does not allow the implementation of compression and penetrating high-explosive forms of action.

 The objective of the present invention is to remedy these disadvantages and give the projectile the ability to implement, depending on the conditions of use, either an axial field, or a circular field, or both at the same time. The technical solution consists in the fact that a explosive block in the form of a housing with an explosive charge and a detonator located along the axis of the projectile is introduced into the movable body, and the finished striking elements (GGE) are located in the annular gap between the outer surface of the explosive block and the inner surface of the shell , while the control system allows the blasting unit to be detonated both after the unit is ejected from the shell of the projectile and when it is inside the shell. Graphic images are presented in FIG. 1-36. In FIG. 1, 2, 3, 4, 5, 6 are examples of specific designs. In FIG. 7, 8 show ribs on the bursting block body; FIG. 9, 10, 11, 12 - versions of the bursting unit in the assembly with the GGE. In FIG. 13 shows the process of shooting an explosive block with the release of the GGE and the formation of an axial field, FIG. 14 shows the corresponding configurations of the lesion fields. In FIG. 15, 16, 17 show the types of action of the projectile when the explosive block is located inside the shell of the projectile and the formation of the radial lesion field. In FIG. 18 shows the detonation of a bursting unit partially extended from the shell of the projectile with the formation of both axial and circular fields of destruction.

 In FIG. Figures 19-33 show projectile designs representing the development of the main idea. In FIG. 19, 20 shows the design of a projectile, the explosive block of which contains a jet engine. In FIG. 20, 22 are shown structures having, in addition to the cylindrical layer of the GGE, also a front GGE block. In FIG. 23 shows the combined action of the circular and axial fields. In FIG. 24 is a cross-sectional view of a projectile with a housing made with inner longitudinal ribs, and FIG. 25 - mating discontinuous block. In FIG. 26-32 are cross-sectional views of shells with an axisymmetric bursting block; FIG. 33 - tear block with a flat platform provided with meniscus recesses. In FIG. 34, 35 shows the action of a projectile with a non-axisymmetric field in embodiment B; FIG. 36 - action in option A.

 The projectile (Fig. 1) has a housing 1 with a bottom recess 2, in which the powder charge is placed 3. In the internal cavity of the housing 1 is placed a bursting unit 4 containing the housing of the unit 5 with a charge of BB 6 and a head fuse 7 with a receiver 8. The housing the projectile and the bursting unit are connected by means of a threaded connection 9. At the bottom of the bursting block there is an igniter 10 connected by an electric conductor 11 to the fuse. In the annular gap between the shells of the projectile and the bursting block, ready-made striking elements 12 are laid (in this case, the GGE of a spherical shape is shown) made, for example, of steel or heavy alloys based on tungsten or uranium. The space between the GGE can be filled with a lightweight aggregate 13, for example polyurethane foam.

 In FIG. 2 shows a design variant in which the bursting block body is provided with annular shelves 14, GGE 12 are made with a shape that ensures their tight packing, for example in the form of a cube, and a central tube 15 is connected along the axis of the projectile, connecting fuse 7 and igniter 10.

 In the embodiment of FIG. 3, the projectile is equipped with a bottom fuse 16, a bottom receiver 8, a head contact assembly 17 connected by electrical or pyrotechnic connection (not shown in FIG. 3) with a fuse, a bottom detonator 18 with a delay device in contact with the fuse 16, and elongated (arrow-shaped) GGE 19.

 In FIG. 4 shows a projectile for a smoothbore, for example, a tank gun, stabilized by the opening tail unit 20. In this embodiment, the bursting unit is equipped with a cumulative funnel 21, a detonator 22, a opening stabilizer 23 and a tracer 24. In FIG. 5 shows a projectile with a barrel-shaped explosive block and a central arrangement of the detonator 25. FIG. 6 shows the design of a projectile with a composite body including several explosive blocks 4. Each block is equipped with an autonomous detonator 27. An example is shown of the execution of a explosive block with a concave plate 28 located at the front end and intended to form a shock core.

 The bursting block body may be provided with longitudinal ribs 26 (FIG. 7) or longitudinal and annular ribs forming rectangular cells (FIG. 8). The diameter of the explosive block on the outer surface of the annular shelves, longitudinal ribs, rectangular cells is equal to the inner diameter of the shell of the projectile. GGE laying in this case is performed in the cells formed by the ribs. In FIG. 9, 10, 11, 12 show options for the execution of the body (bursting block in the assembly with the GGE). In the construction shown in FIG. 11, the housing of the bursting unit for increasing the expansion angle is made in the form of a series of spheres connected by cylindrical jumpers.

The projectile is multifunctional and, in the version equipped with a remote-impact fuse, allows implementing 7 types of actions:
A. With the release of the explosive block and the formation as the main axial field of defeat (Fig. 12, 13)
1) explosion of the explosive block with an adjustable delay after the ejection;
2) an instant explosion of the explosive block upon impact on an obstacle;
3) a delayed explosion of the explosive block after penetrating into the barrier;
B. Without ejection of the explosive block, with the formation of a circular lesion field
4) tractor rupture (Fig. 15);
5) instantaneous rupture upon impact from an obstacle (Fig. 16) with the implementation of fragmentation and compression effects;
6) a delayed explosion after penetrating the barrier (Fig. 17) with the implementation of a high-explosive action;
B. With partial extension of the bursting unit
7) the formation of both axial and circular lesion fields (Fig. 18).

 A command that determines the type of action and, if necessary, a temporary installation, is entered before firing into the fuse through the command receiver using contact or non-contact methods. It is also possible to contactlessly enter the command and temporary installation after the projectile leaves the bore with the help of muzzle magnetic coils, a laser beam entering the bottom receiver, etc. The feasibility of entering a temporary installation after a shot is determined by the ability to enter the exact flight time taking into account the actual speed of a given projectile, measured, for example, using a muzzle ring system.

 When fired, the inertial load of the GGE mass is perceived through the annular shelves by the body of the explosive block, which is the main power element of the projectile. This prevents deformation of the GGE in the lower layers, which is especially important for elongated (arrow-shaped) GGE. The inertial force from the block body is transmitted to the bottom of the projectile, while the shell shell is unloaded, which allows it to be made quite thin. Longitudinal ribs 26 (Fig. 6) prevent the scrolling of the GGE layer relative to the block body.

 When approaching the target at a given point in the trajectory, the remote fuse gives a command to ignite the expelling powder charge 3, as a result of which the explosive block 4 is pushed out of the shell of the projectile with thread cutting 9, emitting a GGE. The stabilization of elongated (arrow-shaped) GGEs in flight for the shells of rifled systems is carried out by the gyroscopic method, since GGEs in portable motion receive the same angular velocity of rotation around their own longitudinal axis as the whole shell. For non-rotating shells, for example, for shells of smooth-bore tank guns, the stabilization of the GGE can be carried out using plumage.

 The choice of the method of detonation (type of action) of the flying explosive block is determined by the type of target and shooting conditions. It is advisable to use action type 1 when shooting at ground surface targets, and the presence of an adjustable delay allows you to organize the defeat zone that is optimal for a given area target configuration. The same view can be used for firing at air targets at parallel courses, which allows you to hit both the frontal and side projections of the target.

 View 2 creates a combined effect on the target of the axial flow of the GGE and the direct hit projectile and is effective when firing at single targets, which include compartments with high anti-shatter resistance. When executing a bursting unit with a cumulative funnel (Fig. 4), the bursting cylinder is capable of hitting lightly armored targets and side armor of tanks. View 3 with the slowdown of the block rupture can be used when shelling manpower accumulations, partially located in the trenches and passages of communications.

 Under the action of species 1, 2 under certain meeting conditions for the purpose, the circular fragmentation action can be significantly increased due to the desired shape of the bursting block body, as well as the corresponding initiation system. For example, a barrel-shaped (Fig. 5), cylindrical (Fig. 10) or composite spherical (Fig. 11) shape with central initiation provides an increase in the meridional angle of the field of expansion of the fragments Δφ (Fig. 14), which increases the probability of covering the target on a miss with a significant the spread of the relative velocity of the meeting of the projectile with the target. The conical shape of the explosive block (Fig. 12) with the detonator located on the large end allows you to create a significant declination of the fragmentation flow, which is useful when implementing some meeting conditions for the purpose.

 In case of detonation of the explosive block inside the projectile (option B), a circular (radial) fragmentation field is formed, which includes ready-made damaging elements and fragments of natural fragmentation of the shell and explosive block. In this case, the same types of action are implemented (4, 5, 6) as with conventional high-explosive shells.

In the case of detonation of the explosive block, partially extended from the shell of the projectile (type 7), an axial field of the finished PE is formed, which includes part of the GGE, and a circular field consisting of three parts (Fig. 18): field R ₁ containing GGE and fragments of natural crushing both cases, the field R ₂ containing the GGE and the fragments of the explosive block and the field R ₃ containing the fragments of the explosive block and partially the GGE. All parts of the field have different radial velocities (V ₃ > V ₂ > V ₁ ), which leads to the formation of a layered field of the "curtain" type, and the mass ratio of all fields, including the axial, depends on the length of the extended part x. The back of the shell is not crushed. The blasting charge of the explosive block at the moment of its extension to a given length x is carried out using an adjustable blasting delay relative to the moment of operation of the igniter of the expelling charge. The required value of this delay is calculated according to known firing conditions and is introduced into the fuse before firing or at the time of departure from the barrel through the command receiver. If the projectile has a calculating device and sensors that determine the meeting conditions with the target, the delay value can be entered on the trajectory immediately before the detonation.

 There is also an option to equip a projectile with a non-contact fuse, which can function both in mode A and mode B.

 In FIG. Figures 19-33 show projectile designs representing the development of the main idea. In FIG. 19 shows a design of a projectile in which the explosive block 4 is equipped with a solid-fuel jet engine 29. The engine contains a charge of solid fuel 30 made with a combustion mode that ensures charge combustion during passage of the main part of the explosive block and GGE in the shell of the projectile. The application of the method of accelerating the explosive block using a combination of the knockout charge of a jet engine allows to increase the ejection rate of the explosive block and the GGE without increasing the mass of the knockout charge 3, i.e. ultimately without increasing the wall thickness of the chamber 2.

In the construction of FIG. 20, the charge of solid fuel 31 is made of a detonation composition, for example, based on RDX or HMX, the fuse contains both a pyrotechnic channel 32 and a detonation channel 33, and the shell of the projectile is equipped with an axial nozzle 34, a plug 35 and an ejection mechanism for the plug 36, electrically or pyrotechnically connected with a fuse. When operating in mode B (without ejecting the body), charge 31 is used as a blasting explosive, excited by the detonation channel 33. When acting with the ejection of the body, one of the following actions is performed:
a body with a fuel charge is ejected by an expelling charge followed by its undermining or with subsequent acceleration of the body of the explosive block due to the combustion of the fuel charge (the plug 35 is not shot);
the fuel charge is used to disperse the projectile as a whole with the expiration of the combustion products through the nozzle 34 (the plug 35 is removed). After the acceleration is completed, the explosive block is ejected by an expelling charge 3.

 A separate group of structures is formed by shells, in which, along with the cylindrical layer of the GGE 12, there is also a front (end) block of the GGE 37 (Fig. 1, 22). These shells represent the development of structures, the so-called fragmentation-beam shells (see the author’s article "A new shell for tanks", "Military Parade", November-December 1996, pp. 50-52, study guide "Axial-action structures", ed. - at the MSTU named after Bauman, 1995, the textbook "Designs of fragmentation ammunition, part 1", publishing house of the MSTU named after Bauman, 1997, and also patents N 2018779, 2108538 of the Russian Federation).

 In the construction shown in FIG. 21, the front GGE block is located directly in the shell of the projectile, and in the structure shown in FIG. 22 - in the housing of the bursting unit. In this case, the front block of the GGE can be equipped with a explosive charge 38 located along its axis and having a detonator 39, electrically or pyrotechnically connected to the fuse. For shells with a front block, the bottom location of the fuse is advisable, which reduces the ballast mass attached to the block when throwing.

 The main advantage of shells with two GGE blocks is manifested in fragmentation action without ejecting a block with an air gap (Fig. 23). In this case, due to the combined action of both fields (circular and axial), a significant increase in the affected area on the surface of the earth and an improvement in its configuration are ensured. The optimal mass ratio of the cylindrical layer of the GGE and the front block of the GGE is determined using a multicriteria assessment of effectiveness in various conditions of the projectile.

One of the most important parameters of the projectile, also subject to optimization, is the wall thickness of the shell of the projectile. Since the shell of the shell is not used directly for destruction when operating with the bursting block, i.e., it is essentially a ballast mass, it is highly desirable to reduce the wall thickness to a minimum value, which, taking into account the bearing capacity of the bursting block body, ensures the strength and longitudinal stability of the shell when firing and penetrating an obstacle, for example, for shells of tank guns to a relative thickness δ _d = 1 / 25-1 / 20 (δ _d = δ ₀ / d ₀ is the relative wall thickness in calibers). One of the possible measures to increase the strength of the hull is to perform it with a power set. In FIG. 24 shows a cross section of a projectile with a housing made with inner longitudinal ribs 40. In this case, the shelves 14 of the bursting block body are made with radial slots 41, conjugated with the ribs 40 and sliding along them when the bursting block is ejected.

 The cross section of shells with a non-axisymmetric bursting block is shown in FIG. 26-31. The housing of the explosive block is made with a one-sided platform 42 flat (Fig. 26), convex (Fig. 27), concave (Fig. 28) or biconcave (Fig. 29) and with a diameter equal to the inner diameter of the shell of the projectile. GGE fill the space 43 between the pad and the inner surface of the shell of the projectile 1. In FIG. 30 shows the execution of the housing of the bursting block in the embodiment discussed above, i.e. with the presence of a cylindrical layer of GGE between the outer surface of the explosive block and the inner surface of the shell of the shell. The options for multilateral arrangement of GGE blocks are provided. As an example in FIG. 31, 32, variants with two-sided and four-sided arrangement of GGE layers, having zero eccentricity of the center of mass, are presented. In FIG. 33 shows a design of a projectile in which a flat platform 41 is provided with one or more meniscus recesses 44 for forming shock nuclei. The explosive charge is initiated according to the usual scheme, either by a point or linear detonator 45 (Fig. 27, 30), offset from the projectile axis, in the direction opposite to the location of platform 42. In the embodiment shown in FIG. 29, the detonation assembly comprises an offset detonator 45 and an explosion-proof insert (lens) 46.

 The presence of a one-sided arrangement of the GGE mass can lead to the appearance of an eccentricity of the mass relative to the axis of the charge. This eccentricity can be eliminated by appropriate selection of the geometry of the shells and densities of the GGE material, or compensated by well-known projectile control methods.

 In the non-ejection variant, the structures are designed to create radially directed fields (see the author’s article "Fragmented warheads of missiles: development prospects", "Military Parade" N 4 (28), 1998, p. 60). In this case, the projectile must be equipped with a target sensor and a device that provides detonation at the time of alignment of the beam "initiation point - GGE block" with the direction to the target (Fig. 34). The embodiment of FIG. 31 is intended for shells with a flat trajectory, for example, shells of tank guns equipped with a sensor for the angular position of the shell, in order to realize a two-sided field of the GGE creeping along the surface of the earth (Fig. 35).

 The ejection action of the bursting unit is shown in FIG. 36. Further use of the bursting block depends on its design. For example, for the circuit shown in FIG. 29, the biconcave wall of pad 42 is used to form an impact core (explosive shock body) that hits a ground or air target in a miss with proper targeting.

 Comparison of the proposed projectile with a high-explosive fragmentation projectile having a front GPE block (fragmentation-beam projectile) (Ross. Patents N 2018779, 2108538, see also article by A. Odintsov “New projectile for tanks”, “Military Parade”, N 6, 1996) showed that the effectiveness of the destruction of the proposed infantry shell in bulletproof vests and unarmored vehicles exceeds the corresponding value for a fragmentation-beam projectile under the action of an axial field (beam) by 1.5-2 times, with a circular field by 2- 3 times.

 Giving the shell multifunctional properties is especially important for autonomous weapon systems with limited ammunition, for example, for tanks. The survival of a modern tank on the battlefield is determined mainly by its ability to combat a variety of anti-tank weapons (infantry armed with grenade launchers, in open areas, in trenches and on reverse slopes, anti-tank systems, anti-tank guns, helicopters and anti-tank anti-tank guns, etc. ) With an increase in the caliber of tank guns, for example, up to 140 mm, the ammunition of the tank can be reduced to 20-30 rounds, with the bulk of them being shots with armor-piercing fired under-caliber shells unsuitable for solving the above fire tasks. Under these conditions, the only real way out of the situation is the possibility of reconfiguring the projectile for one or another type of action.

Claims (22)

 1. A shell with ready-made striking elements, including a body, a body placed in it, containing ready-made striking elements, a bottom powder charge and a fuse associated with a knockout charge, characterized in that the body contains one or more explosive blocks consisting of a metal the case and the explosive charge with a detonator located in the inner cavity of the case, and a layer of ready-made striking elements laid on the outer surface of the metal case, the expelling charge is equipped with an igniter , Fuse made or remote, or non-contact, or batch type, and is provided with a command receiver and a percussion mechanism, and between the fuse, igniter and electric detonator has a connection or a pyrotechnic element with adjustable delay blasting.  2. The projectile according to claim 1, characterized in that the fuse with the command receiver and detonator are located in the head of the explosive block.  3. The projectile according to claim 1, characterized in that the fuse is located in the bottom of the projectile, the detonator with the deceleration element is located in the bottom of the explosive block, there is a detachable connection between the fuse and the detonator, and a head contact assembly is installed in front of the explosive block.  4. The projectile according to claim 3, characterized in that the command receiver is located in the bottom of the projectile.  5. The projectile according to claim 3, characterized in that the command receiver is located in the head of the explosive block.  6. The projectile according to claim 1, characterized in that the finished striking elements are made in a shape that ensures their tight laying on the surface of the explosive block.  7. The projectile according to claim 1, characterized in that the finished striking elements are made of steel or a heavy alloy, for example, based on tungsten or uranium.  8. The projectile according to claim 1 or 4, characterized in that the bursting block body has annular shelves or longitudinal ribs or rectangular cells on the outer surface.  9. The projectile according to claim 8, characterized in that the diameter of the explosive block along the outer surface of the annular shelves, longitudinal ribs, rectangular cells is equal to the inner diameter of the shell of the projectile.  10. The projectile according to claim 1, characterized in that the shell of the projectile and the bursting unit are provided with drop-down stabilizers.  11. The projectile according to claim 1, characterized in that the bursting unit in the front part contains a cumulative funnel.  12. The projectile according to claim 1, characterized in that the housing of the bursting unit is made with a barrel-shaped form.  13. The projectile according to claim 1, characterized in that the housing of the bursting unit is made in the form of a series of spheres connected by cylindrical jumpers.  14. The projectile according to claim 1, characterized in that in the laying of the finished striking elements on the surface of the explosive block, the space between them is filled with a lightweight aggregate, for example polyurethane foam.  15. The projectile according to claim 1, characterized in that the explosive block is equipped with a solid propellant jet engine.  16. The projectile of claim 15, wherein the solid fuel of the jet engine is detonation-capable, the explosive block is provided with detonation and pyrotechnic channels, and the bottom of the projectile is equipped with an axial nozzle with a plug and its firing mechanism, electrically or pyrotechnically connected to the fuse.  17. The projectile according to claim 1, characterized in that in the front of the shell is a set of ready-made striking elements.  18. The projectile according to claim 1, characterized in that in the front of the explosive block there is a set of ready-made striking elements, the axis of which is set to charge an explosive with a detonator, electrically or pyrotechnically connected to the fuse.  19. The projectile according to claim 1, characterized in that the shell of the projectile on its inner surface is provided with longitudinal ribs, and the annular shelves of the housing of the bursting unit are made with radial slots associated with the longitudinal ribs of the shell of the projectile.  20. The projectile according to claim 1, characterized in that the bursting unit is made with an axisymmetric shape.  21. The projectile according to claim 1, characterized in that the explosive block is made with a non-axisymmetric shape, namely with one or more side platforms of a flat, convex or concave shape, the space between the platform and the inner surface of the shell being filled with ready-made striking elements.  22. The projectile according to item 21, wherein the lateral area of the explosive block is equipped with one or more meniscus recesses.

Images