RU2408837C1 - Anti-personnel fragmentation ammunition - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: anti-personnel fragmentation ammunition includes housing with two chambers, extractor, detonating cap, means of detonating mechanism, mechanism of above-ground actuation and fighting unit. Chambers of housing are connected to each other with gas outlet channel. Fighting unit consists of cylindrical fragmentation cover in the form of set of metal rings of the specified fragmentation. Set of rings is installed on thin-wall metal shell folded on annular inner groove of end rings. Height of internal groove exceeds critical thickness of explosive conversion of explosive agent, and its diametre is 0.8…0.9 of outer diametre of rings. Ignition seat of detonating means is closed with sealing plug. Above-ground actuation mechanism has housing with loosened section. Housing is made from plastic material, and external side surfaces of their chambers are connected by means of longitudinal and transverse stiffeners.

EFFECT: increasing ammunition action efficiency.

8 cl, 10 dwg

Description

The invention relates to engineering anti-personnel fragmentation munitions, namely, to the design of anti-personnel fragmentation barrage mines with a jumping warhead of circular destruction, manually installed in the ground to ensure their disguise in a mine-explosive boom.

Anti-personnel fragmentation mines with jumping round warheads are known, such as PRB 966 (Belgium), PSM-1 (Bulgaria), Type 69 (China), PP Mi - Sr (Czech Republic), JAP (Egypt), DM-31 (Germany) ), No 12 (Israel), P - 40, VS - JAP, V - 69 (Italy), P3 Mk2 (Pakistan), PS - 1 (Spain), No 69 Mkl (South Africa), M16A1, M16A2 (USA), PROM - 1, PROM - KD (Yugoslavia), OZM-3, OZM-4, OZM-160 (Russia), etc. (catalog "Jane's Mines and mine clearance. Edited by Colin King. Edition 2002-2003").

Known anti-personnel fragmentation barrage mine with a jumping out warhead of the circular defeat OZM-72 (Russia), manually installed in the ground, capable of using the fuse used to destroy unprotected enemy personnel with fragments within a radius of 25 m ("Russian Arms." Catalog. T.VII. "V.VII." High-precision weapons and ammunition. "Military Parade CJSC. M. - 1997.) - prototype.

Known engineering anti-personnel fragmentation munitions (mines) include the following main elements: a steel or plastic case in the form of a glass, an ejection device with an igniter capsule and an expelling charge, a jumping out warhead consisting of a natural fragmentation shell or fragmentation shell with compact ready-made striking elements in in the form of steel cylinders or balls, an explosive charge, a transfer charge in the form of a checker, a ground-based actuation mechanism (MNF) and inserted when used or integrated detonator capsule. MHC can be based on a pyrotechnic moderator or a punch mechanism with a cable of a certain length.

Known engineering anti-personnel fragmentation munitions (mines) have the following main disadvantages:

- a guide body made of steel, significantly increases the mass of mines;

- an ejecting device with an expelling charge placed in the side channel of the warhead leads to asymmetry of the jumping warhead and, as a result, to an increase in the angle of deviation from the vertical when it is triggered, which, as you know, leads to a decrease in the effectiveness of the damaging action;

- the use of compact ready-made striking elements (GGE) in the form of steel cylinders or balls, as well as fragmentation shells of natural crushing, performed in mines mainly from cast iron, does not provide effective destruction of manpower, protected by body armor;

- the use of the design of the explosive charge with a constant coefficient of load on the fragmentation shell and one transfer charge leads to an increase in the angle of expansion of PE in the vertical plane and, as a result, to a decrease in the density of the fragmentation field, which reduces the effectiveness of the fragmentation effect;

- the use in a number of mines of a pyrotechnic moderator in the above-ground triggering mechanism leads to an increase in the spread in the height of the detonation of the warhead, which also negatively affects the effectiveness of fragmentation;

- the use of a built-in detonator capsule in a number of mines, obviously, increases the danger of ammunition in operation.

The well-known anti-personnel mine OZM-72, which is not fully equipped, consists of a housing in the form of a guiding glass, into which an jumping warhead (warhead) is inserted, fixed in the glass by rolling. The fragmentation shell of the warhead is a cylindrical ferrule of randomly placed GPEs in it, having the form of cylinders filled with polyethylene. The cage is closed from above and below by thick-walled steel covers connected by a central bushing and a side tube. A nipple with an igniter capsule and a ball is fixed on the top cover, a kick charge from the smoky rifle threshold in a fabric bag is placed in the side tube, making up a throwing device. In the upper thick-walled cover there are two openings, closed with plugs, through which the warhead chamber’s equipment is charged with an explosive charge. In the upper part of the central sleeve there is a transfer charge checker with an ignition slot for installation when using a detonator capsule, which forms a detonating agent. A sleeve with an igniter capsule is installed under the checker in the central bushing, and in the lower part of the central bushing there is a spring mechanism in the form of a spring-loaded striker, the striker is connected to the drummer’s heel with a detachable lock, the drummer’s heel is fixed to the guide bush with a safety cap, and a tension cable is also attached to it, the second end of the tension cable is mounted on a cup, rigidly attached by rolling to the inner surface of the bottom of the chamber of the guide cup, forming the mechanism of the above-ground slab Tivany (MHC).

Experience in the production and use of the OZM-72 mine shows that its device has several disadvantages. The presence in the jumping warhead of massive end caps designed to reduce the scattering angle of the striking elements in the vertical plane, and a steel guide body in the form of a glass, significantly increase the mass of the mine, thereby deteriorating its operational characteristics.

Compact prefabricated damaging elements (PE) with a mass sufficient to defeat manpower have to be stacked on the explosive charge in an inert matrix with low acoustic rigidity in several layers, which leads to a significant decrease in the speed of throwing PE remote from the outer surface of the explosive charge. In addition, compact GGEs are not effective enough for breaking through modern bulletproof vests that have multi-layer protection from Kevlar fabric, as the compact fragment intensively loses speed when introduced into the fabric of Kevlar filaments.

One of the well-known ways to increase the effectiveness of anti-personnel fragmentation munitions against multilayer fabric protection is the use of plate-shaped striking elements that create an increased lateral load when targeting under the condition of oriented flight with a minimum forward face. Penetrating into a fabric body armor, such an element cuts the threads of the body armor base, providing effective damage to tissue personal protective equipment of 1-2 classes. For the first time, the use of plate-shaped striking elements for ammunition with a circular fragmentation field is described in US patent No. 3677183 "Pre-shaped fragmentation device" (ed. C. Talley, M., CL F42B 13/48, application. 31.10.66, registered 18.07. .72). The invention is a fragmentation munition (mainly an artillery shell), the body of which is composed of rings containing plate elements stabilized in flight by rotation around their center of mass. The rotation of the elements is provided by the eccentricity of the masses of the elements relative to the center of application of the load from the detonation products. In the patent of the Russian Federation No. 2237859 "Anti-helicopter mine" (M. CL F42B 23/00, 12/56, Research Institute CM MSTU named after Bauman, declared. 28.12.2001, registered. 10.10.2004, claims 8, 9) and Application No. 2004131458 "Means of destruction with plate-shaped splinters" (NII SM, application form. 10.29.2004) presents various design options for the warheads of engineering munitions using explosive throwing stabilized by rotation of plate-shaped striking elements.

However, these well-known options for the design of warheads of engineering fragmentation munitions with plate-shaped striking elements cannot be implemented in mine designs with a sufficient level of effectiveness without the use of the following design versions of the explosive charge and means of the detonating declared anti-personnel fragmentation munition.

The placement of the elements of the device emitting in the side tube in the jumping out warhead of known analogues and prototype due to the resulting displacement of the center of mass of the warhead from the vertical axis leads to a turn of the warhead and an increase in its angle of deviation from the vertical in an explosion after firing from a guiding glass, which reduces the efficiency the damaging effect of the fragmentation field, because part of the PE goes down or up from the zone of the possible location of the target. The deflection angle is also increased due to the recoil force acting on the warhead from the side of the cable cocking the war spring of the drummer of the above-ground operation mechanism.

The design of the ejection device and the above-ground triggering mechanism of the well-known OZM-72 mine does not ensure their assembly-by-site assembly, which increases the complexity of the ammunition in serial production.

The aim of this invention is to increase the effectiveness of anti-personnel fragmentation munitions (mines) by eliminating the above disadvantages of the prototype and analogues.

To achieve this goal (technical result), a new design of anti-personnel fragmentation ammunition is declared, characterized by the following set of essential features.

The inventive anti-personnel fragmentation munition contains a guiding body with two chambers interconnected by a gas channel, a device ejected with an igniter capsule and an expelling charge of powder grains placed in one of the chambers, as well as a warhead placed in another chamber body and consisting of fragmentation shells in the form of a set of metal rings, an explosive charge, a detonating agent and an above-ground triggering mechanism, as well as a capsule-deto inserted when using ammunition nator.

Unlike the prototype, the guiding body of the claimed anti-personnel fragmentation munition is made of plastic, has, as mentioned above, two chambers connected to each other by a gas channel, while an ejection device with an igniter capsule and an expelling charge is inserted into one of the chambers, which eliminates the asymmetry the warhead, and to ensure the strength of the guide body when exposed to pressure of the powder gases of the expelling charge, the bottom of its chamber has stiffeners placed by a fan It is clear that it provides a uniform distribution of deformation along the bottom of the hull, on the hull in its lower and upper parts 2–3 times thickening of the side wall is made, in the lower part to a height of up to 0.3 hull height, which ensures durability when shooting the warhead and manufacturability of the hull, in the upper part, to a height of up to 0.2 from the hull height, which ensures rigidity of the hull and prevents the warhead from deviating from a vertical position when flying over the upper section of the guide body, and the outer side ti Camore connected longitudinal and transverse ribs that provide strength hull deformation from pressure of powder gases in the cross sections.

The inventive anti-personnel fragmentation munition in the device ejecting between the igniter capsule and the expelling charge has a nipple gas hole with a diameter not exceeding the size of the powder grain, which ensures reliable transfer of the fire pulse from the ignition capsule to the expelling charge and the minimum expiration of the powder gases from the chamber to the return side.

The fragmentation shell of the warhead, unlike the prototype and analogues, of the claimed anti-personnel fragmentation ammunition is made in the form of a set of metal rings, the metal rings having grooves arranged with periodic symmetry along the circumference of the outer diameter, reducing the radial width of the ring by 3 ... 4 times and made in the form of non-isosceles triangles, which ensures a decrease in the shell mass and the formation of plate-shaped damaging elements (PES) stabilized by rotation during explosion, and The positions between the vertices of adjacent grooves are equal to 0.5 ... 2.0 of the radial width of the ring, and additional rectangular grooves are made at the vertices of the grooves of the rings, reducing the width of the ring to a value of 0.2 ... 1.0 of its thickness, which is necessary to obtain sufficient for gyroscopic stabilization. PES of the angular velocity of rotation, while the metal rings with the grooves are located relative to each other so that the line drawn through the tops of the grooves makes an angle of 5-30 ° to the longitudinal axial line of the warhead, which ensures uniform distribution the formation of plate PE along the equatorial angle of expansion during warhead explosion, and in the center of the warhead in the zone where detonation waves meet, a set of metal rings of natural fragmentation is placed, the thickness of which is 3 ... 5 times the thickness of metal rings with grooves, which ensures the formation of fragments with a mass exceeding the mass PES designed to defeat elements of armored protection class 3-6 of protected manpower and manpower in automotive vehicles, as well as easily vulnerable and lightly armored vehicles, while sets of metal rings are installed s on the shell, rolled onto metal end rings, which ensures the manufacturability of the assembly of the cylindrical shell of the warhead, and the end metal rings have outer grooves in which the sealing upper and obturating lower rings of rubber are installed, as well as internal grooves adjacent to the end thin-walled flanges with internal axial protrusions with threaded holes, while between the threaded holes of the end flanges there is a detonating means, the chamber of the fragmentation shell between the media detonating, shell and end flanges, as well as internal grooves in the end steel rings are filled with a charge of explosive, which ensures the manufacturability of the equipment, and the presence of a layer of explosive from both ends of the jumping warhead and the diameter of the internal end grooves of 0.8 ... 0, 9 from the outer diameter of the metal rings with grooves provides pressure loading of the detonation products of the end rings with lamellar PE and reducing the expansion angle in the vertical plane during their explosion throwing, while the ignition slot of the detonating agent is closed by a sealing plug mounted on the thread of the upper end flange, which ensures reliable re-installation of the detonator capsule when using the detonator, the overhead actuation mechanism is screwed into the thread of the lower end flange by the igniter capsule towards the ignition slot of the detonating means and is fixed on the sealant with a threaded conical nut for the central outer bottom conical surface of the plastic guide body, both of which ensures, assembling workability and self-centering of the warhead in the breech of the guide body, and a sealing plug mounted on the outer side of the capsule is a transparent material filled with antifreeze liquid and having an air bubble that performs leveling function during installation of the munition into the soil, i.e. allowing to determine the verticality of the installation of ammunition in the field without the use of additional tools, and the outer surface of the capsule is made in the form of a spherical segment, axisymmetric with the thread of the tube, and the deflection and diameter of the segment are connected by a ratio of 1: 50 ... 1: 200, which ensures measurement of the angles of deviation of the ammunition from vertical when installed within 10 degrees, while the diameter of the air bubble is less than the radius of the segment.

Unlike the prototype, the initiation of a bursting charge is carried out synchronously from the ends of the charge, which provides a narrowing of the fragmentation field in the vertical plane, an increase in its density and an increase in the radial velocity of the fragments. For this purpose, a detonating agent with transfer charges of the warhead of the claimed anti-personnel fragmentation munition is made in the form of end and side clips of plastic, with end charges of plastic inserted transfer charges in the form of checkers at a distance of 0.02 ... 0.2 warhead height from its ends , which provides the necessary to reduce the angle of expansion of PE in the vertical plane, the position of the points of initiation of the explosive charge, and the side clips of plastic have two grooves, made mirror-like, in which are laid cord charge charges made of elastic explosive, the ends of which are placed on one side between the ends of the side clips and the transfer charges, and on the other hand end-to-end with the ignition slot for the detonator capsule to be installed when using, which ensures reliable simultaneous transfer of detonation from the detonator capsule, while a steel tube is installed in the lower part of the ignition socket to provide gaps between the side clips of plastic and the detonator caps installed during use, which provides protection lower cord charges from the premature impact of the detonator capsule, and in the place of its docking with the ends of the cord transfer charges on the clips installed with air gap steel casing of steel and plastic tapes, which protects the main explosive charge from the premature impact of the detonator capsule and cord charges .

In addition, in the inventive anti-personnel fragmentation munition, the above-ground triggering mechanism has a body with a weakened section, while the weakened section is located between the lower end flange of the jumping warhead and the bottom of the plastic housing of the guide housing, and the MHC also has a ball mechanism in the form of a spring-loaded striker held by a ball moreover, the ball is held by a metal plate, on which a wire or thread of heat-resistant material having a length exceeding the height is wound in several layers from the claimed anti-personnel fragmentation munition, and the end of the thread or wire is sealed tightly in the tail threaded part of the body of the overhead actuation mechanism in the place of its attachment with a threaded conical nut for the central bottom conical surface of the plastic guide body, which ensures the manufacturability of the assembly, the reliability of the munition and the absence of effort with sides of a wire or thread on the warhead before undermining it.

The figure 1 presents the design of the inventive anti-personnel fragmentation munitions not fully equipped in its longitudinal section.

In figures 2 and 3 shows the laying of sets of steel rings with grooves and steel rings of natural crushing in the warhead.

The figure 4 shows the inner bottom of the guide housing made of plastic.

The figure 5 shows the outer stiffening ribs of the guide body.

Figure 6 shows the design of the ejector device.

The figure 7 shows the design of the mechanism of aboveground operation.

In figures 8 and 9 shows the design of the means of detonating in its longitudinal and transverse sections.

The figure 10 shows the installation of anti-personnel fragmentation ammunition in the ground in a fighting position.

The inventive anti-personnel fragmentation munition contains a guiding body 1, an ejection device 2 with a primer 3 and an expelling charge 4 of powder grains, a warhead 5 consisting of a cylindrical fragmentation shell 6, consisting of a set of metal rings of a given fragmentation 7, an explosive charge 8, detonating means 9 with transfer charges 10 and 11 and an overhead actuation mechanism 12 with a pin mechanism 13 and an igniter capsule 14, as well as a detonator capsule 55 inserted in the application In particular, the guide body 1 has two chambers 15 and 16 connected to each other by a gas-duct channel 17, while an ejection device 2 with an igniter 3 and an expelling charge 4 is inserted into one of the chambers 15, and a warhead 5 is inserted into the other chamber 16, the guide body 1 made of plastic in the bottom of its chamber 16 for installing the warhead 5 has stiffeners 18 arranged fan-shaped, and also has external thickenings 19 in the lower and upper parts of the chamber 16, the outer bottom surface 20 around the perimeter of the guide body 1 of astmassy surface 21 and in its central bottom part are conical and the outer side surfaces 22 and 23 Camore 15 and 16 are connected to the longitudinal 24 and transverse 25 and 26 stiffening ribs.

In the device emitting 2 of the claimed anti-personnel fragmentation ammunition between the primer 3 and the expelling charge 4 there is a nipple gas hole 27 with a diameter not exceeding the size of the powder grain.

The cylindrical fragmentation shell 6 of the leaping warhead 5 of the claimed anti-personnel fragmentation munition is made in the form of a set of 7 metal rings of predetermined crushing 29, and grooves 30 in the form of isosceles triangles are made around the circumference of the outer diameter of the metal rings 29, reducing the radial width of the metal rings 29, and in the center of the warhead A set of 31 metal rings of natural crushing 32, the thickness of which is 3-5 times greater than the thickness of the metal rings 29 from the groove, is placed in the zone where the detonation waves meet. and, while the sets 7 and 31 of the steel rings 29 and 32 are mounted on the casing 33, rolled on the end metal rings 34 and 35, and the end metal rings 34 and 35 have outer grooves 36 and 37, in which the sealing upper 38 and the sealing lower 39 rubber rings, as well as internal grooves 40 and 41 adjacent to the thin-walled end flanges 42 and 43 with internal axial protrusions 44 and 45 with threaded holes 46 and 47, while between the internal axial protrusions 44 and 45 of the end flanges 42 and 43 are placed detonating agent 9, the chamber of the fragmentation shell 6 between the detonating means 9, the shell 33, the end flanges 42 and 43 and the internal grooves 40 and 41 in the end metal rings 34 and 35 are filled with a charge of explosive 8, the ignition slot 48 of the detonating means 9 is closed with a longitudinal sealing plug 49 a protrusion 72 mounted on the thread of the upper end flange 42, and the above-ground actuation mechanism 12 is screwed into the thread of the lower end flange 43 with the igniter caps 14 towards the ignition slot 48 of the detonating means 9 and fixed to the YETİK conical threaded nut 50 for the central bottom conical outer surface 20 of the guide body 1.

In the claimed anti-personnel fragmentation munition, the detonating agent 9 with the transfer charges 10 and 11 of the leaping warhead 5 is made in the form of end 51 and side 52 clips of plastic, and the transfer charges 10 in the form of checkers are inserted into the end clips 51 of plastic and the side clips 52 of plastics have two grooves 53 and 54, made mirror-like, in which are placed cord transfer charges 11 of elastic explosive, the ends of which are placed on one side between the ends of the side clips 52 with transfer charges 10 in the form of checkers, and on the other hand end-to-end with the ignition slot 48 for the detonator capsule 55 installed when using, and at the place of its connection with the ends of the cord transfer charges 11 on the plastic side clips 52, a steel casing 57 is provided with an air gap 56.

The above-ground triggering mechanism 12 of the claimed anti-personnel fragmentation munition has a casing 58 with a weakened cross-section 59, which is located between the lower end flange 43 of the jumping warhead 5 and the bottom of the chamber 16 of the guiding body 1 with two chambers, and also has a firing mechanism 13 in the form of a spring-loaded striker 60, held by the ball 61, and the ball 61 is held by a metal strip 62, on which a wire 63 of heat-resistant material with a length exceeding the height of the guide body is wound in several layers 1, the end of which is sealed in the rear threaded portion of the casing 58 of the overhead actuation mechanism 12 at its attachment with a threaded conical nut 50 for the central outer bottom conical surface 21 of the guide housing 1, the last turn of the wire being kept from unwinding by a loop of wire tucked at both ends under adjacent turns.

In addition, the igniter capsule 3 of the ejection device 2 in the transport position is closed by a sealing foil 64 and a cap 65, and a capsule 67 of transparent material filled with a non-freezing liquid and having an air bubble 68 can be installed in the protrusion 66 of the sealing plug 49, and the outer surface of the capsule made in the form of a spherical segment, axisymmetric with thread plug.

The effect of the claimed anti-personnel fragmentation ammunition is as follows.

Before use, the transport cap 65 is unscrewed from the ejection device 2, the fuse mechanism 13 of the fuse used, not shown in the accompanying drawings, is screwed in its place, the sealing plug 49 is unscrewed, the detonator means 55 are inserted with the detonator capsule 55 down, and again screwed with providing a guaranteed gap 28 between the longitudinal protrusion 72 and the detonator caps 55.

Anti-personnel fragmentation ammunition is installed in the ground and disguised, the fuse used is put into combat mode. When the fuse used by the enemy infantry is fired, the fuse mechanism 13 of the fuse leads to ignition of the igniter capsule 3 in the device ejecting 2, by force of fire the capsule of the igniter 3 through the gas nipple opening 27 with a diameter not exceeding the grain of powder ignites the expelling charge 4, thereby that the diameter of the nipple gas hole 27 does not exceed the diameter of the powder grain, the pressure of the powder gases in the chamber 15 is released by a small amount, under the pressure of the powder gases gazovodny transmitted through the channel 17 in the bolt 16 between the lower end flange 43 jumping out of the warhead 5 and the bottom of the guide body 1, the ribs 18, 24, 25 and 26 ensure its strength arising loads.

Under the influence of powder gases, the casing 58 of the above-ground actuation mechanism 12 breaks along a weakened cross-section 59, and due to the normalized rupture force, a stable boost pressure is created and reliable burning of the out-charge powder is ensured. The tail threaded part of the housing 58 with the wire 63 fixed in it remains in the guide body 1 made of plastic, and when moving along the chamber 16, the lower rubber obturating ring 39 prevents premature breakthrough of the powder gases, when the jumping warhead 5 is moved from the above-ground trigger 12, the wire is pulled 63 without transmitting force to the warhead 5 and is pulled out when the warhead 5 is above the surface of the earth, while the metal plate 62 and ball 61, a spring-loaded striker 60 the igniter capsule 14, the fire force of which initiates the detonator capsule 55, in turn, the detonator capsule 55 initiates cord transfer charges 11 of elastic explosive, the detonation wave through which reaches almost simultaneously the lower and upper transfer charges 10 in the form of checkers, which initiate from two ends the charge of explosive 8, while the tube 69 and the air gaps 70 and 71, as well as the casing 57 and the air gap 56 prevent the premature initiation of cord transfer charges 11 and explosive charge 8 when the detonator capsule 55 is triggered.

Detonation waves, simultaneously initiated by transfer charges 10 in the form of checkers, move along the explosive charge 8 and converge at the place of installation of the metal rings 31 of natural crushing, forming here a zone of increased pressure of detonation products, in addition, by backing up the layers of explosive 8 at the end flanges 42 and 43 and in the grooves 40 and 41 in the end steel rings 34 and 35, an increased pressure of detonation products is also formed, which ensures a decrease in the expansion angle in the vertical plane of metal ble plate rings 29 submunitions and increase the initial speed of throwing submunitions.

When exposed to detonation products of the explosive charge 8, the metal rings 29 break down along the grooves 30, while the shell 33 expands and prevents premature breakthrough of the detonation products between the steel rings 29, 31 and into the grooves 30, due to the variable load of the explosive charge 8 on the material of the rings 29 between in the grooves 30, the formed plate-like striking elements are twisted, which ensures stabilization of the flight path of the latter and, as a result, improves the efficiency of the breakdown for a target, especially a protected bulletproof vest, due to the approach of the plate striking elements to the target with a cutting edge with the creation of an increased lateral load on the protective elements, the fragments of steel rings 31 also acquire an increased initial throwing speed, in addition, the mass of these fragments of natural fragmentation exceeds the mass of plate striking elements due to the fact that their thickness is 3-5 times greater than the thickness of the steel rings 29, and the installation of steel rings 29 grooves 30 at an angle of 5 ° -30 ° to the axis of the circular immetrii warhead 5 ensures a uniform distribution plate submunitions equatorial scattering angle that collectively provide increased efficiency damaging effect on the enemy infantry, including body armor protected, and also being in a vehicle.

In addition, when releasing the guide body 1 from plastic, due to the fact that its outer surface 19 along the perimeter of the bottom part is conical, the body 1 self-centers in the ground when the warhead 5 takes off, which reduces the angle of its deviation from the vertical.

The presented design differences of the claimed anti-personnel fragmentation ammunition in comparison with the prototype and analogues mentioned above can reduce its weight by 2 times with the same dimensions and increase the effectiveness of the damaging effect on the enemy’s manpower, protected by bulletproof vests of 2-3 classes, and also located in automotive vehicles.

Callout number in the presented drawings and its interpretation

1 - a directing case;

2 - throwing device;

3 - igniter capsule in the ejecting device;

4 - kick charge;

5 - warhead;

6 - cylindrical fragmentation shell;

7 - sets of metal rings of a given crushing;

8 - explosive charge;

9 - detonating agent;

10 - transfer charges in the form of checkers;

11 - cord transfer charges from an elastic explosive;

12 - the mechanism of aboveground operation;

13 - firing mechanism used fuse;

14 - igniter capsule in the mechanism of aboveground operation;

15 - cam guide housing for installing the ejector device;

16 - cam guide housing for installation of the warhead;

17 - gas channel;

18 - stiffeners in the bottom of the guide housing made of plastic;

19 - thickening of the wall of the chamber of the guide housing;

20 - outer conical surface around the perimeter of the bottom of the guide housing made of plastic;

21 - the outer conical surface of the Central bottom of the guide housing made of plastic;

22 - the outer side surface of the chamber of the guide housing made of plastic for installing the ejector device;

23 - the outer side surface of the chamber guide housing for installing the warhead;

24 - longitudinal stiffener;

25 - upper transverse stiffener;

26 - lower transverse stiffener;

27 - nipple gas outlet;

28 - guaranteed clearance;

29 - metal rings of a given crushing;

30 - grooves in the metal rings of a given crushing;

31 - a set of metal rings of natural crushing;

32 - metal rings of natural crushing;

33 - shell;

34 - upper end steel ring;

35 - lower end steel ring;

36 - outer groove on the upper end steel ring;

37 - outer groove on the lower end ring;

38 - upper sealing ring made of rubber;

39 - lower obturating ring of rubber;

40 - inner groove on the upper end steel ring;

41 - inner groove on the lower end steel ring;

42 - upper end flange;

43 - lower end flange;

44 - internal axial protrusion of the upper end flange;

45 - internal axial protrusion of the lower end flange;

46 - threaded hole of the inner axial protrusion of the upper end flange;

47 - threaded hole of the internal axial protrusion of the lower end flange;

48 - ignition slot means detonating;

49 - sealing plug with a longitudinal protrusion;

50 - threaded conical nut;

51 - end clip made of plastic;

52 - side clip made of plastic;

53 - grooves in a side holder made of plastic;

54 - grooves in the side clip of plastic, made mirror;

55 - a detonator capsule inserted during use;

56 - air gap;

57 - steel casing;

58 - casing of the mechanism of surface activation;

59 is a weakened section;

60 - spring loaded drummer;

61 - ball;

62 - metal plate;

63 - wire;

64 - sealing foil;

65 - transport cap;

66 - protrusion of the sealing tube;

67 - capsule with non-freezing liquid;

68 - air bubble;

69 - tube;

70 - air gap;

71 - air gap;

72 is a longitudinal protrusion of the sealing plug.

Claims (8)

1. Anti-personnel fragmentation munition containing a guiding body with two chambers interconnected by a gas channel, a device ejecting an igniter capsule and an expelling charge from powder grains placed in one of the chambers, as well as a detonator capsule and warhead (warhead) placed in another chamber chamber and consisting of a cylindrical fragmentation shell in the form of a set of metal rings of a given crushing, forming, when the munition explodes, plate-shaped striking elements, explosive charge , detonating means and an above-ground triggering mechanism, characterized in that the set of metal rings is mounted on a thin-walled metal shell rolled on an annular inner groove of the end metal rings, and the end metal rings have an outer groove, for which end flanges are fixed with internal axial protrusions with threaded holes, in the same grooves are installed a sealing upper and obturating lower rings made, for example, of rubber, while between the axial the threaded protrusions of the end flanges contain the detonating agent, and the internal volume of the fragmentation shell between the detonating agent, the shell, the end flanges, and the internal grooves in the end metal rings are filled with an explosive charge (BB), the height of the internal groove exceeding the critical thickness of the explosive explosive transformation and its diameter is 0.8 ... 0.9 of the outer diameter of the metal rings, while the ignition slot of the detonating means is closed with a sealing plug mounted on p the flange of the upper end flange is axisymmetric with the warhead, and the overhead actuation mechanism has a housing with a weakened cross section, while the weakened cross section is located between the threaded part screwed into the lower end flange of the warhead and the tail threaded part connected by a threaded nut with a tapered outer surface beyond the central conical recess of the bottom parts of the guide body, which is made of plastic, and the outer side surfaces of its chamber are connected by longitudinal and transverse stiffeners, while the cam ra Fitting CU has a thickening of the side wall 2 ... 3 times a height of 0.2 from its height in the upper part and up to 0.3 of its height at the bottom. 2. Anti-personnel fragmentation munition according to claim 1, characterized in that the thickness of the metal rings of the fragmentation shell of the warhead is 3-10 times less than their radial width, the crushing of metal rings is set using grooves arranged with periodic symmetry along the circumference of the outer diameter, reducing the radial the width of the ring is 3 ... 4 times and made in the form of isosceles triangles, and the distances between the vertices of adjacent grooves are 0.5 ... 2.0 of the radial width of the ring. 3. Anti-personnel fragmentation munition according to claim 2, characterized in that at the tops of the grooves of the metal rings, additional rectangular grooves are made, reducing the width of the ring to a value of 0.2 ... 1.0 of its thickness. 4. Anti-personnel fragmentation munition according to claim 1, characterized in that in the device ejecting between the igniter caps and the expelling charge, there is a nipple gas outlet with a diameter not exceeding the grain size of the powder. 5. Anti-personnel fragmentation munition according to claim 1, characterized in that the warhead is made with a height exceeding its diameter, and the detonating warhead means is made in the form of end and side clips of plastic, and in the end clips of plastic at a distance from the ends of the warhead equal to 0.02 ... 0.2 of its height, explosive transfer charges in the form of circular checkers are inserted, and the side clips of plastic have two grooves, made mirror-like, in which cords of elastic explosives are laid, the ends of which are placed on one side between the ends of the side clips and gear and charges, and on the other hand, in the center of the side clips end-to-end with a slot for a detonator capsule installed when using ammunition, while a steel tube is installed in the lower part of the ignition slot of the detonating means, providing air gaps between the plastic side clips and installed when using a detonator capsule, and in the place of its docking with the ends of the cords of elastic explosive on the side clips of plastic, a casing of steel and plastic tapes is installed to provide clearance. 6. Anti-personnel fragmentation munition according to claim 1, characterized in that the above-ground triggering mechanism in the part located in the lower part of the warhead has a firing igniter capsule and a spring-loaded striker held by a ball, the ball being held by a metal plate on which several layers are wound the wire is made of heat-resistant material, while the end of the wire is fixed in the tail threaded part, and its last turn is kept from unwinding by a loop of thread, tucked at both ends under adjacent turns. 7. Anti-personnel fragmentation munition according to claim 1, characterized in that the metal rings with grooves are mounted in a holder relative to each other so that the line drawn through the tops of the grooves makes an angle of 5-30 ° to the longitudinal center line of the warhead, and in the middle part of the holder , between sets of metal rings with grooves, a set of metal rings of natural crushing is placed, the thickness of which is 3-5 times greater than the thickness of metal rings with grooves. 8. The anti-personnel fragmentation munition according to claim 1, characterized in that a capsule of transparent material, filled with a non-freezing liquid and having an air bubble, is installed in the sealing plug on the outside, and the outer surface of the capsule is made in the form of a spherical segment, axisymmetric with the thread of the plug, and the deflection and diameter of the segment are connected by a ratio of 1: 50 ... 1: 200, while the diameter of the air bubble is less than the radius of the segment.

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