RU2343398C2 - Protecting ammunition - Google Patents

Abstract

FIELD: weapons.

SUBSTANCE: invention concerns to working out of an engineering ammunition for statement of mine-explosive obstacles. The ammunition contains damage battle element with a cover and a bottom in the form of the piston, the electronic mechanism of involvement with a source of energy, the starting mechanism which has been carried out in the form of cylindrical directing, fixed in ground and fixing supplied in the knot of a battle element, expelling charge, to the check of a detonator of the fuze safety and arming mechanism of the battle element, fastened by flexible communication with the guide rail. Safety of operation in field conditions raises and the area of practical use.

EFFECT: increase of safety of operation in field conditions and expansion of area of practical use.

4 dwg

Description

The invention relates to military equipment, namely to engineering munitions designed to mine the terrain in order to defeat manpower and enemy equipment.

According to the Federal Republic of Germany patent No. 4330414, IPC F42B 23/16 (IMS, M., No. 10, issue 081, 1996, p. 4), a mine construction with an ejected submunition that is installed in a bowl-shaped launching device and connected to submunition drive unit at a given height. The drive unit is mounted on the bottom of the bowl-shaped starting device and contains a high-pressure chamber facing the bottom of the starting device, in which there is a propellant charge. There is also a low-pressure chamber facing the submunition. The high and low pressure chambers are separated from each other by a common hole plate having nozzles (openings).

In a known constructive solution, the ejection of ammunition from the starting device is carried out by burning a propellant charge in the high-pressure chamber and pumping its combustion products into the low-pressure chamber, where the accelerated submunition is located.

However, such a constructive approach is justified only when the propelling charge cannot work at relatively low working pressures. Therefore, when using smoke powders that are most often used in munitions, for example, multiple launch rockets, and which burn steadily at low levels of operating pressure, the considered approach to the development of a starting device seems irrelevant.

In addition, in this design, circuit solutions are presented that do not cover important practical issues related to the fixation of the ejected ammunition in the starting device, the methods of engaging and ensuring the reliability of the use of submunition in combat conditions, etc.

Thus, the objective of this technical solution was to demonstrate one of the possible design techniques aimed at firing submunitions from the launch device using a propelling charge that works stably at high pressure levels in the storage chamber.

Common signs of mines with the proposed ammunition is the presence of a launch guide, a combat element and an expelling charge placed in the working chamber.

The closest in technical essence and the achieved technical result is a fragmentation round-bomb mine, known from the book "Weapons of Russia", catalog, volume VII, "High-precision weapons and ammunition", AOZT "Military Parade", M., 1997, p. 644. The mine consists of a guiding glass, housing, explosive charge, expelling charge, impact mechanism and central sleeve.

The guide cup is made of steel, has a chamber at the bottom in which the exhaust cable of the percussion mechanism is fixed and laid.

The case is a cylindrical cage, consisting of ready-made fragments filled with polyethylene. Above and below, the cage is closed by steel covers connected by a central bushing and a discharge tube. In the center of the top cover there is a threaded hole closed with a stopper. Through this hole in the mine, a detonator capsule is installed. A sleeve with an igniter caps is fixed to the side of the central hole. The top cover is hermetically connected to the guide cup.

The explosive charge fills the cavity inside the holder and has a socket into which the detonator capsule is inserted.

The expelling charge is packed in a canvas bag and placed in a tube under the sleeve with the igniter capsule.

The percussion mechanism is located in the lower part of the central sleeve and is connected with a cable, the second end of which is fastened to the guide glass.

The fragmentation mine is one of the most powerful engineering ammunition that surpasses many foreign analogues in its striking effect. This is ensured by the sufficiently high efficiency of the combat equipment of the mines, firing at a given height. However, the mine has some disadvantages associated primarily:

- with the absence of a combined fuse (push and pull), and in the best case, radio-technical action;

- with the presence of unmasking signs, namely the tension sensors of the target, installation pegs, fuse sticking out of the ground;

- with the placement of the powder charge with the detonator capsule in the sleeve, offset from the center, which, firstly, reduces the effectiveness of the munition when the explosive is triggered, and, secondly, does not make it possible to use another type of munition, for example, volume-detonating action;

- with unsuccessful sealing of the receiving housing in the guide cup, which does not exclude the ingress of combustion products of expelling charge between the separated structural elements and requires the manufacture of the guide cup from strong materials (steel) that make the structure heavier;

- with the constant desire of the developer to increase the safety of handling the mine during its installation in the field.

Thus, the objective of this technical solution was to develop an effective ammunition without imposing strict requirements on the overall mass characteristics and safety of the use of ammunition, as well as the possibility of placing another type of striking combat element in the structure, for example, with volumetric detonating equipment.

Common design features with the proposed ammunition is the presence of a striking combat element with a triggering mechanism and a triggering mechanism made in the form of a cylindrical guide fixed in the ground and equipped with a combat element fixation unit, an expelling charge, as well as a flexible coupling of the required length connecting the detonator pin of the safety-executive mechanism of the combat element with a guide.

In contrast to the prototype, the proposed design solution introduced a new set of structural units and elements, namely:

- the unit for fixing the combat element is made in the form of a forcing unit made by rolling the end edge of the guide in the annular groove of the cover of the combat element located on the outer end surface of the cover and provided with a sealing seal;

- the bottom of the combat element is made in the form of a piston interacting with the annular stop through an obturator gasket fixing at the same time a flexible connection located in the peripheral annular groove of the piston and fastened to the side surface of the annular stop;

- the kick charge is placed in the piston zone formed by an annular stop between the bottoms of the combat element and the guide, and is connected to the igniter by means of a fire chain with a flag jumper equipped with a deceleration unit made in the form of a two-section cylindrical brake block with rubber filler having a spring-loaded movable rod with perforated piston;

- in the mechanism for activating ammunition, the radio unit is equipped with an energy source and an ammunition self-destruction unit, and the safety-executive mechanism has an additional protection level made in the form of a heat-receiving device, which is triggered by providing the required power and heat pulses during the firing of the combat element from the guide.

The distinguishing features noted, to which the requested amount of legal protection applies, are essential and sufficient to achieve a new technical result.

The objective of the invention is to improve quality, expand practical capabilities (primarily applications), as well as simplifying the design of engineering ammunition for the installation of mine-explosive barriers in order to combat the moving targets of the enemy.

The specified technical result is achieved due to the fact that in the design of the known mine containing a striking combat element, the electronic activation mechanism is made in the form of a cylindrical guide fixed in the ground and equipped with a fixation unit for the combat element, an expelling charge, as well as a flexible connection of the required length connecting the detonator pin of the safety-actuating mechanism of the combat element with a guide, a new set of structural elements and units was introduced, their mutual p memory location and communication.

In particular, the implementation of the piston with a diametrical sealing seal, the interaction of the piston with an annular stop through an obturator gasket fixing simultaneously flexible connection in the peripheral annular groove of the piston, as well as the implementation of the unit for fixing the combat element in the form of a forcing unit made by rolling the end edge of the guide in the annular groove the cover of a combat element located on the outer end surface of the cover and provided with a sealing seal allows solving the following practical skie tasks:

- to organize a reliable gas-dynamic shutter, eliminating the movement of combustion products of the expelling charge in the radial and axial directions and, thereby, remove power loads on the cylindrical guide and the combat element, which, ultimately, allows the use of less durable (light) alloys, reduce weight and to improve the quality of construction;

- to provide a more rigid fixation of the combat element in a cylindrical guide, eliminating the violation of the tightness of ammunition;

- to increase the stability of the operation of the forcing unit and ballistic parameters in the process of shooting a combat element from the guide, allowing to rationalize the power loads on the structural elements;

- to ensure reliable fixation of the flexible connection in the annular groove, to close it from possible damage of a mechanical and gas-dynamic nature, to keep it in the piston during transportation.

The execution of the bottom of the combat element in the form of a piston allows you to combine two different functions of the bottom, to place a flexible connection in the peripheral annular groove and fix it on the side surface of the annular stop, which allows to ensure:

- reducing the size and weight of the structure of the munition;

- deployment of flexible communications from an annular groove (as with a cylindrical coil);

- turning the cylindrical guide in the ground, more rigidly fixing it in the ground and reliable striking of the safety-actuating mechanism BE, which is especially important for loose and wet environments.

The placement of the expelling charge in the piston zone, formed by an annular stop between the bottoms of the combat element and the guide, most fully corresponds to the functional purpose of the munition with a vertical firing BE, a rational layout of the design with a radio unit and an igniter. At the same time, the connection of the air defense unit with the igniter via a fire chain with a flag jumper equipped with a deceleration unit made in the form of a two-section cylindrical brake block with rubber filler, having a spring-loaded movable rod with a perforated piston, can significantly increase the safety of work with ammunition in the field. This is achieved through the use of manual stripping, removing the flag jumper between the igniter and the expelling charge with the necessary delay due to the slow movement of the perforated piston in the brake cylinder with rubber filling under the influence of the spring (spring turns are released at the moment of stripping).

A similar functional load bears an additional stage of protection, introduced into the safety-executive mechanism and made in the form of a heat-receiving device. The operation of the device is ensured in the process of ejection of the combat element from the guide due to the formation of the required levels of power and thermal effects of the products of combustion of the expelling charge on the executive bodies (membrane, charge) of the heat receiver.

Of practical importance is also the fact that in the mechanism for activating ammunition, the radio unit is equipped with an energy source and an ammunition self-destruction unit that is triggered after the submission of an executive radio command. Using this approach eliminates the need for engineering operations to mine minefields after completing a mission.

Signs that distinguish the proposed technical solution from the prototype are not identified in other technical solutions in the process of conducting patent research, which allows us to conclude that the invention meets the criterion of "novelty."

Studying the level of technology during the patent search for all types of information available in the countries of the former USSR and foreign countries, it is established that the proposed technical solution does not explicitly follow from the prior art. Therefore, we can conclude that the invention meets the criterion of "inventive step".

The invention presented in the restrictive and distinctive parts of the formula is illustrated by drawings, where: in Fig.1 shows a General view of the protective munition; figure 2 is a fragment of the unit forcing ammunition; figure 3 is a fragment of the bottom of the combat element; figure 4 is a fragment of the fire chain with a flag jumper.

The proposed ammunition contains a striking combat element 1 with a radio electronic engagement mechanism, a trigger mechanism made in the form of a cylindrical guide 2 fixed in the ground 3 and provided with a fixation unit for the combat element 4, an expelling charge 5, as well as a flexible coupling 6 of the required length connecting the detonator 7 safety-executive mechanism 8 of the combat element with a guide.

The fixation unit of the combat element is made in the form of a forcing unit made by rolling the end edge of the guide 9 in the annular groove 10 of the combat element located on the outer end surface of the cover 11 and provided with a sealing seal 31.

The bottom of the combat element is made in the form of a piston 13 with a diametric seal 30, interacting with the annular stop 14 through an obturating gasket 15, fixing at the same time a flexible connection located in the peripheral annular groove 16 of the piston and connected with the side surface of the bottom of the guide 18.

The knockout charge is placed in the piston zone 17, formed by an annular stop between the bottom of the combat element and the bottom of the guide 18, and is connected to the igniter 19 by means of a fire chain with a flag jumper 20, equipped with a deceleration unit made in the form of a two-section cylindrical brake block 21 with rubber filler 22, having a spring-loaded movable rod 23 with a perforated piston 24.

In the mechanism for activating the munition, the radio unit is equipped with an antenna 26, an energy source 27 and a self-destruction unit of the munition 28, and the safety-executive mechanism has an additional stage of protection made in the form of a heat-receiving device 29, which is triggered when the required power and heat pulses are generated during the firing of the combat element from the guide .

The above device operates as follows. Before performing a combat mission, the barrage ammunition is located vertically in the ground at a given depth. After installation in the ground by pulling out the cord of the flag jumper 20, the mechanical stage of protection of the ammunition is removed. The radio channel through the antenna 26 ensures the transfer of ammunition to the combat position, in which all remaining electrical protection stages are removed. The product is ready to receive radio commands for combat work.

After applying the voltage, the igniter 19 is triggered, the combustion products of which act on thinning in the housing of the knockout charge 5, destroy them and ensure the inclusion of the explosive into operation.

VZ combustion products enter the piston zone 17 and, when the pressure on the piston 13 corresponds to the destruction pressure of the forcing unit 4, the firing of the combat element 1 from the guide 2 begins, accompanied by the release of the obturator pad 15 and the deployment of flexible coupling 6 from the piston 13. At the same time, the products of charge combustion act on the heat-receiving device 29 and when providing the required values of power and heat pulses in the piston volume, the first stage of protection is removed spolnitelnogo BE mechanism 8.

When the BE displacement is equal to the length of the flexible connection fixed on the lateral surface of the ring stop 14, the checks of the PIM detonator 7 are pulled out (removal of the second protection stage) and the central bursting charge 32 is triggered, accompanied by the formation of shock and heat waves.

If it is necessary to remove the obstacle, the corresponding executive command is sent to the radio unit 25, as a result of which the energy source 27 generates an initiating pulse to the self-destruction unit 28, which ultimately ensures the destruction of the ammunition by its operation.

The implementation of the barrage munition in accordance with the invention allows to significantly simplify the design of the munition and expand its scope by improving the method of using the expelling charge and the possibility of using combat elements of a different type. At the same time, due to reliable radial and axial sealing of the annular cavity between the separable structural elements (15, 30, 10), during the shooting of the BE, a reduction in power loads and, as a result, a decrease in the passive mass of ammunition are achieved. At the same time, the use of the radioengineering method of activation and the introduction of additional stages of protection ensures minimizing unmasking signs and increases the safety of handling ammunition during its installation.

The positive effect is confirmed by the results of bench and field work, and therefore the invention can be used in the development of ammunition with military elements for various purposes.

Based on the invention, design documentation for ammunition using the principle of volume detonation has been developed.

Claims (1)

Barrage ammunition containing a striking combat element with a cover and a bottom, an electronic triggering mechanism, a trigger mechanism made in the form of a cylindrical guide fixed in the ground and equipped with a combat element fixation unit, an expelling charge, a detonator pin of a safety-actuating element of the combat element fastened by flexible coupling with a guide, characterized in that the fixation unit of the combat element is made by rolling the end edge of the guide in the annular groove of the combat cover element made from the outer end surface of the cover and provided with a sealing seal, the bottom of the combat element is made in the form of a piston with a diametrical seal interacting with an annular stop through an obturating gasket fixing a flexible connection located in the peripheral annular groove of the piston and connected with the side surface of the annular stop, wherein the knockout charge is placed in the piston zone formed by an annular stop between the bottoms of the combat element and the guide, and is connected with the igniter using a fire chain with a flag jumper equipped with a deceleration unit made in the form of a two-section cylindrical brake block with rubber filler, having a spring-loaded movable rod with a perforated piston, and in the mechanism for activating the munition the radio unit is equipped with an energy source, and the safety-executive mechanism has an additional protection level, made in the form of a heat-receiving device, triggered by providing the required power and heat pulses in the process e shooting the combat element from the guide.

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