RU2177598C1 - Method for hitting by liquid-filled warhead, liquid-filled warhead and method for its filling - Google Patents

Abstract

FIELD: war equipment, applicable in liquid-filled warheads. SUBSTANCE: method for hitting by liquid-filled warhead consists in the fact that before dispersing and initiation of the military load, the latter is subjected to impact-wave disturbances with formation of cavitation bubbles. The warhead has a generator of impact-wave disturbances formed in the cavity of placement of the detonator, and the central tube accommodating the ignition- explosive charge forms a waveguide-cavitator. The method for filling of the warhead provides for action on its body at filling by impact loads with flowing of the charge components in the macro- and micro-roughnesses of the central tube surface, and the contour of the generator of impact-wave disturbances is mounted around the detonator. EFFECT: enhanced efficiency of liquid-filled warheads. 9 cl, 1 dwg

Description

 The invention relates to defense equipment and can be used in the construction of warheads (warheads) of virtually any ammunition (grenades, bombs, artillery shells, mortars for mortars, and mounted on (in) soil, etc.), conjugated in liquid, pasty and curable multicomponent warheads (LB): incendiary, smoke, incendiary-smoke, single-cycle volume-detonating, etc.

 Ammunition is in great demand in the armies of all countries, whose warheads have a high combined effect on the target: especially high-explosive and incendiary. This is due to the fact that during the high-explosive action the structural elements of the target are destroyed and this ensures the high reliability of their ignition and the creation of a stable fire on the target, which completely destroys it.

 One of the known directions for increasing the effectiveness of such warheads is the use of self-igniting mixtures in them, which act (ignite) from contact with oxygen, and therefore require only their dispersion with the necessary crushing on the target.

 The design of the warhead for a grenade with such a filling [1] is a sealed enclosure filled with a self-igniting mixture. Inside the body along its axis there is a central tube in which a bursting charge and its initiator in the form of a fuse with a detonator are sequentially placed and fixed. The first is made of condensed explosive. A method for defeating warheads of this design involves dispersing the mixture with a bursting charge when a grenade hits a target.

 However, this method of destruction and the design of the warhead that implements it are effective only in the case of using a mixture homogeneous in physical condition, not stratified during storage and operation and containing self-igniting additives, which complicates and increases the cost of manufacturing the mixture, warhead equipment with it and the operation of ammunition with such a warhead. In addition, the high-explosive action of such ammunition is achieved only by increasing the mass of the explosive charge, which leads to a decrease in the mass of the mixture and its destruction almost into dust when dispersed. This circumstance almost completely excludes the possibility of igniting the main combustible materials of the target (wood, plastics, etc.), except for flammable liquids.

The equipment of this warhead with a warhead, ignition-explosive charge (ARI) and its initiator with a detonator is produced in the following order: first, in an inert gas medium, a mixture of components forming an AR is poured into the body, hermetically closed by a lid, then installed in the central tube of the ARW in air and its initiator and separately fix them
There is also a known method of destruction and warheads for grenade ampoule flamethrower [2], which are the prototype of the proposed technical solution.

 The specified warhead in certain conditions makes it possible to effectively use knowledge bases containing liquid and solid components with different densities, prone to delamination during storage and operation. The effective use of such a warhead is achieved by optimizing the state of its knowledge base before undermining.

 The way to defeat this warhead is to mix the components of its warhead when launching a grenade from the barrel of the flamethrower and simultaneously heat its body with propellant gases of a propellant charge, to separate the components of the warhead on the flight path to the target with the deposition of heavy ones on the wall of the warhead warhead and their subsequent heating, dispersing and initiating central ARH on the target.

To implement this method, the warhead contains a sealed enclosure filled with BZ, including liquid and solid components with different densities, and a central tube, in which a VRZ and its initiator with a detonator in the form of a fuse are installed in series, while:
- to mix the stratified components of the BS, the central tube has a conical protrusion, expanding towards the bottom of its body,
- for separation of components with the deposition of heavy ones on the wall of the warhead housing on the central tube or the bottom of the housing there are radial protrusions that involve the components of the defense system in conjunction with the grenade rotational movement;
- to heat the components deposited on the wall of the hull, and thereby ensure their reliable transfer to a combat state when undermining between the hull and the barrel, powder gases are passed during firing, which is not always possible and, as a rule, reduces firing accuracy;
- to communicate warhead rotational motion on the flight path, it has a stabilizer with skew plumage plumage.

The disadvantages of this method of defeat and the design of warheads that implement it, in addition to those noted above, include the following main ones:
1. With an increase in the muzzle velocity of a grenade, the heating of the wall of its hull decreases and its cooling increases with the free flow of air along the path. This is aggravated by increasing the firing range and lowering the air temperature, and under certain conditions it can lead to overcooling of the wall of the warhead housing and the heavy BZ components attached to it, and since they are not mixed with lighter and more flammable liquid components, their ignition requires significant an increase in the mass of VRZ and this reduces the effectiveness of warheads in general.

 2. In recent years, highly effective KBs have appeared that contain a large number of components of different density and state of aggregation, the effectiveness of which primarily depends on the degree of uniform distribution of all components over the volume of KB. In order to maintain this uniformity achieved during the manufacturing process of the bulk of the base material, under all conditions of storage and operation of warheads, inert substances from the point of view of its purpose are introduced into the composition of the base unit in the amount of 0.3 - 0.5%, with the help of which the mass of the base unit after pouring it the casing of the warhead is cured to form a honeycomb structure, the cells of which are filled with the liquid components of the knowledge base.

 It is obvious that the use of curable BRs in the prototype is either impossible or will require a significant increase in the mass of VRZ and this will reduce the effectiveness of warheads in general.

 Outfitting this warhead of the BZ, VRZ and its initiator with the detonator is carried out in the following order: first, in air or in a fume hood (depending on toxicity), the mixture of components forming the BZ is poured into the housing, hermetically close the housing with a lid, and then if the mixture of components is curable , then it is cured with the formation of a honeycomb structure, the cells of which are filled with liquid components, and only then in air they are installed in the central tube of VRZ and its initiator and separately fixed.

 The technical task of the present invention is to increase the efficiency of warheads equipped with knowledge bases, including liquid components in their composition, by reducing the mass of the SEC, i.e. due to a more effective transfer of the BZ to a combat state.

 The prerequisites for solving this problem are the following known phenomena.

 The presence in the combustible and explosive liquids (BS components) of bubbles filled with their vapors sharply increases the flammability and sensitivity of these components to detonation.

 Such bubbles in a liquid can be obtained by exposure to shock wave disturbances through cavitational waveguides.

 This effect is based on the fact that the creation of shock wave perturbations on rods, plates, tubes, etc. (waveguides-cavitators) immersed in a liquid and made of a material whose sound propagation velocity is higher than its propagation velocity in a liquid, causes the formation of cavitation bubbles in adjacent fluid layers filled with vapor of this liquid. Moreover, the higher the surface roughness of the cavitator, the more intense it creates cavitation bubbles in the liquid.

 In accordance with the justifications [3], the shock-wave perturbation generator can be formed by a cavity with a pulsed initiator located in it, when triggered, shock waves are generated due to the jump-like nature of the pressure buildup alternately at one or the other end of this cavity.

The problem is solved by a group of inventions, in which:
1. In the method of defeating a warhead of a jellied equipment with a warhead including liquid components, including dispersing and initiating a warhead with a central ignition-explosive charge placed in a central tube, according to the invention, before dispersing and initiating a warhead against it through a central tube act by shock-wave disturbances and form cavitation bubbles filled with pairs of these in the liquid components of the warhead adjacent to the central tube components.

 2. In the warhead of jellied equipment containing a housing filled with a combat charge, including with liquid components, an explosive-explosive charge and its initiator with a detonator, sequentially mounted and separately secured in a central tube having protrusions on the outer surface, according to the invention, a shock generator generated by a detonator, ends of an initiator, a wall of a central tube and ends of a threaded sleeve with a gas-dynamic hole is placed at the bottom of the housing, while the detonator is in the initiator is placed in the cavity formed by the wall of the central tube and bounded by the end walls of the initiator and the threaded sleeve with a gas-dynamic hole that secures the ignition-explosive charge, the cavity length being less than the longitudinal distance between the detonator and the end of the ignition-explosive charge, and the detonator is placed in front of the gas-dynamic hole of the threaded bushings or partially recessed in it, the central tube forms a waveguide-cavitator and is made of material, the speed of sound of which is large the speed of sound in the liquid components of the warhead, the ignition-explosive charge is installed in the central tube with a radial clearance, and its side surface is covered with a shell of material with a low propagation velocity in it, the protrusions on the outer surface of the central tube are formed by ring or helical grooves with their increased roughness surfaces.

 In addition, the end of the central tube is recessed into the combat charge to a depth equal to or less than the maximum thickness of the charge in the radial direction between the central tube and the body.

 The central tube is made of steel, and the increased surface roughness of the annular or helical grooves is provided by sandblasting or shot blasting.

 The central tube is made of aluminum alloy, and the increased surface roughness of the annular or helical grooves is provided by etching or anodic oxidation.

 The radial clearance between the ignition-explosive charge and the central tube is provided by means of caps placed on the ends of the ignition-explosive charge.

 As the material of the ignition-bursting charge shell, paper or plastic is used.

 3. In the method of equipping the warhead of the jellied equipment with a warhead containing, including liquid components, including pouring the warhead into the warhead housing, installing and securing the ignition-explosive charge and initiator with a detonator in the central tube, according to the invention, when warhead is charged in the case on the latter is affected by shock loads, ensuring the flow of components of the warhead, in macro- and microroughness on the outer surface of the central tube, when mounted in the central tube osplamenitelno-burster form therebetween a radial gap, and when attaching it around the initiator detonator mounted generator circuit shock-wave disturbances and ensure a gas-dynamic relationship with the detonator igniter-bursting charge.

 In addition, after pouring the warhead into the warhead’s hull, it is possible to solidify the warhead, giving it a honeycomb structure, the cells of which are filled with liquid components of the warhead.

 The essence of the invention is illustrated in the drawing, where the warhead is presented in section.

 The warhead consists of a sealed housing 1, inside of which there is a central tube 2, rigidly fastened to its bottom along the axis, and a warhead 3, which is a mixture of liquid and solid components. The end face of the central tube 2 is recessed in the mass of the warhead charge 3 by an amount A equal to or less than the maximum radial thickness of the warhead charge 3 between the central tube 2 and the body 1. The front end of the body 1 is closed through a sealing seal by a cover 4 fixed by screws.

 The housing 1 and the central tube 2 are made of material, the speed of sound propagation in which is higher than the speed of sound propagation in the combat charge 3, for example, of steel or aluminum alloy. To increase the contact area of the central tube 2 with the warhead 3 on its outer surface, macro - and microroughnesses are made.

 The former are formed by grooves 5, mainly screw, made by cutting or knurling rollers, for example, in the manufacture of a central tube by rolling (rotational extrusion), and the latter: for a steel tube by sandblasting or shot blasting of its outer surface, and for an aluminum alloy tube, by etching and anodic oxidation. Both last processes create a strong porous layer on the surface of aluminum alloy parts that is well wetted by liquids.

 For the same purpose, when the combat charge 3 is poured into the housing 1, the latter is subjected to shock loads with a frequency of 5 - 20 Hz, as a result of which the mass of the combat charge fills the cavities of the grooves 5, completely displacing air from them, and its liquid components penetrate microroughnesses. It is obvious that in the future, for any kind of external loads on the warhead (shock, vibration, temperature control, etc.), the part of even a completely liquid warhead that has fallen into grooves 5 and microroughnesses will always remain in them.

 Ignition-explosive charge 6 and its initiator 7 with detonator 8, for example, an inertial fuse, are placed and fixed inside the central tube 2.

 Ignition-explosive charge 6 is a checker (or checkers) of a condensed explosive, wrapped in adhesive layers of cartridge paper in several layers, forming on the cylindrical surface of the ignition-explosive charge a shell 9 having a low speed of sound propagation in it. On both ends of the ignition-bursting charge 6 are put on caps 10, which center it in the Central tube 2 with the formation of a radial clearance B.

 Ignition-explosive charge 6 is fixed in the Central tube 2 by a threaded sleeve 11, screwed into the Central tube and compresses the charge in the axial direction to its bottom.

 The initiator 7 with the detonator 8 is placed in the Central tube 2 at the bottom of the housing 1 and secured in it by a cover 12, for example, screwed into the Central tube. When attaching the initiator 7 in the central tube 2 between its front end and the threaded sleeve 11, a longitudinal clearance G is formed, and the initiator detonator 8 is either placed in front of the hole in the threaded sleeve or partially recessed in it, but with an ignition-bursting between its end and the end charge 6 of the longitudinal gap D is larger than the longitudinal gap G.

 The longitudinal gap D is made as large as possible, but sufficient for reliable transmission of the detonation pulse from the detonator 8 to the ignition-bursting charge 6.

 The detonator 8, as a pulse initiator, and the ends of the threaded sleeve 11 and initiator 7, as well as the wall of the central tube 2 between them, as an oscillating circuit, form a shock-wave disturbance generator for the central tube immersed in the combat charge 3.

 The work of the warhead consists in the fact that when the initiator 7 is triggered, its detonator 8 and its detonation products strike the end face of the initiator, which is transmitted through the cover 12 to the central tube 2 in the form of a longitudinal disturbance directed backward.

 Upon reaching the detonation front of the detonator 8 of the end of the threaded sleeve 11, the detonation products strike him, which is transmitted through the sleeve to the central tube 2 in the form of a longitudinal perturbation directed forward. Then the detonation front reaches and through the longitudinal gap D with a delay to the end of the ignition-explosive charge 6, it initiates it and the products of detonation transformations of the ignition-explosive charge 6 are dispersed and the warhead 3 is initiated. Since at the moment of dispersion and initiation of the warhead 3, the central tube 2 manages to make at least one high-frequency longitudinal oscillation in it, then cavitation bubbles are formed in the liquid components of the combat charge in contact with the central tube filled with pairs of these components. When the warhead is dispersed, these bubbles collapse, the pairs of liquid components that are in them are released and reliably ignited (detonated) by the ignition-explosive charge, as if increasing its mass.

The way to equip the warhead of jellied equipment with a combat charge, including liquid components, is as follows:
- pour the charge of war 3 into the case 2 of the warhead through the neck at the place of installation of the cover 4 and simultaneously impact the body with shock loads with a frequency of 5-20 Hz, as a result of which the liquid components of the charge penetrate micro- and macro-irregularities on the outer surface of the central tube 2;
- if necessary, carry out the curing of the combat charge with the provision of a honeycomb structure, the cells of which are filled with liquid components of the charge;
- set the ignition-explosive charge 6 in the central tube with the formation of a radial gap between them (due to the caps put on the end of the ignition-explosive charge);
- mount the circuit of the generator of shock wave disturbances due to the fact that:
- fasten the ignition-explosive charge with a threaded sleeve with a gas-dynamic hole;
- set the initiator 7 so that:
its detonator 8 was placed against the gas-dynamic hole of the threaded sleeve 11 or was partially recessed in it;
the gap G between the threaded sleeve 11 and the initiator 7 was less than the gap D between the end of the ignition-explosive charge and the detonator 8;
fasten with a cover 12 initiator 7.

 The presence in the warhead of the generator of shock-wave disturbances for the central tube and the fulfillment of macro- and microroughnesses on the central tube allow, as practice shows, to reduce the mass of ignition-bursting charge from 20 - 30% to 10 - 15% and thereby increase the efficiency of combat parts by 10-15%.

 This is achieved by decreasing the length of the central tube and the ignition-bursting charge located in it by an amount equal to the maximum thickness of the warhead in the radial direction (between the central tube and the body), and most importantly, by involving cavitation bubbles in the liquid components of the BR, significantly increased over account of macro- and microroughnesses of surfaces on the central tube.

 The radial clearance B between the central tube and the ignition-explosive charge and the shell on the lateral surface of the latter are designed to exclude accidental transmission of disturbances from the central tube to the ignition-explosive charge - this prevents its unauthorized operation.

Obviously, depending on the composition of the warhead and its state (liquid, paste-like or solidified), as well as the material of the central tube, it is necessary to experimentally select:
the dimensions of the longitudinal clearances D and G,
detonator mass 8,
the lateral surface of the grooves 5 on the Central tube 2 (their number, depth and width).

 Thus, the proposed technical solution provides an increase in the effectiveness of warheads equipped with warheads, including liquid components, by reducing the mass of the explosive explosive charge in them, i.e., by more efficiently transferring the warhead to warhead state.

Sources of information
1. US patent N 3974774, CL. F 42 B 13/46, 1976 - analogue.

 2. RF patent N 2024820, cl. F 42 B 13/52, 1994 - prototype.

 3. Betekhtin S. A. et al. "Gas-dynamic foundations of internal ballistics", Moscow, State Publishing House of the Defense Industry, 1957, p. 292-301 - an analogue.

Claims (9)

 1. The method of defeating the warhead of jellied equipment with a warhead, including liquid components, including dispersing and initiating a warhead with a central ignition-explosive charge placed in the central tube, characterized in that before dispersing and initiating a warhead at it through the central the tube is exposed to shock wave disturbances and form cavitation bubbles filled with pairs of these components in the liquid components of the warhead adjacent to the central tube components.  2. The warhead of the jellied equipment, comprising a housing filled with a warhead, including with liquid components, an ignition-explosive charge and its initiator with a detonator, sequentially mounted and separately secured in a central tube having protrusions on the outer surface, characterized in that at the bottom of the housing there is a generator of shock-wave perturbations formed by the detonator, the ends of the initiator, the wall of the Central tube and the ends of the threaded sleeve with a gas-dynamic hole, while the detonator the ionizer is placed in the cavity formed by the wall of the central tube and bounded by the end walls of the initiator and the threaded sleeve with a gas-dynamic hole that secures the ignition-explosive charge, the cavity length being less than the longitudinal distance between the detonator and the end of the ignition-explosive charge, and the detonator is placed in front of the gas-dynamic hole of the threaded bushings or partially recessed in it, the central tube forms a waveguide-cavitator and is made of material, the speed of sound of which is greater sound velocity in the liquid components of the warhead, an ignition-explosive charge is installed in the central tube with a radial clearance, and its side surface is covered with a shell of material with a low sound propagation velocity in it, the protrusions on the outer surface of the central tube are formed by ring or helical grooves with increased roughness their surfaces.  3. The warhead according to claim 2, characterized in that the end of the central tube is recessed into the warhead to a depth equal to or less than the maximum thickness of the charge in the radial direction between the central tube and the body.  4. The warhead according to claim 2 or 3, characterized in that the central tube is made of steel, and the increased surface roughness of the annular or helical grooves is provided by sandblasting or shot blasting.  5. The warhead according to claim 2 or 3, characterized in that the central tube is made of aluminum alloy, and the increased surface roughness of the annular or helical grooves is provided by etching or anodic oxidation.  6. The warhead according to any one of claims 1 to 5, characterized in that the radial clearance between the ignition-bursting charge and the central tube is provided by means of caps placed on the ends of the ignition-bursting charge.  7. The warhead according to claim 2, characterized in that paper or plastic is used as the material of the ignition-explosive charge shell.  8. The method of equipping the warhead of the jellied equipment with a warhead, including including liquid components, including pouring the warhead into the warhead housing, installing and securing the ignition-explosive charge and the initiator with a detonator in the central tube, characterized in that when filling the warhead the latter is impacted into the casing by impact loads, ensuring the flow of components of the warhead in macro- and microroughnesses on the outer surface of the central tube, when mounted in the central tube, lamenitelno-burster form therebetween a radial gap, and when attaching it around the initiator detonator mounted generator circuit shock-wave disturbances and ensure a gas-dynamic relationship with the detonator igniter-bursting charge.  9. The equipment method according to claim 8, characterized in that after pouring the warhead into the warhead housing, the warhead is solidified, giving it a honeycomb structure, the cells of which are filled with liquid components of the warhead.