RU2374601C1 - Igniting ammunition - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: igniting ammunition is suggested, which consists of body, central bursting charge of explosive substance and combustible fill, arranged in body inside ready elements and in free space between them. Central bursting charge is made with radial beams, which divide internal volume of ammunition into sectors, at the same time the following ratios are maintained: number of radial beams is equal to 2 - 4, thickness of beams on explosive substances δ≈(0.01…0.03)D≥d_cr, where D is ammunition caliber, d_cr is critical diametre of explosive substance detonation, length of beams by radius of ammunition 0.3R≤ℓ≤R, where R=(D-2δ₀)/2 is radius by combustible fill, δ₀ is thickness of body wall, and ready element is made with arbitrary shape with minimum and maximum dimensions, which are selected from interval of 30…60 mm.

EFFECT: increased efficiency of combustible action of ammunition by increased distance of scattering of ready combustible elements.

7 cl, 3 dwg

Description

Technical field

The invention relates to defense technology and is intended for use in various incendiary ammunition (BP). In addition, it can be used in chemical, smoke, volume-detonating, and other BPs, in which explosive dispersal of BP equipment occurs.

State of the art

A large number of similar PSUs of various designs are known. So, in [1] an incendiary bomb was described, containing a housing, fuse, incendiary and igniter compositions, a bursting charge, the housing being made in the form of a cylindrical shell rigidly connected to a sleeve in the form of a glass, in the cavity of which an igniter adjacent to the sleeve was coaxially placed composition and explosive charge, and in the cavity between the shell of the housing and the sleeve placed incendiary composition. It is argued that increasing the reliability of ignition of the incendiary composition and its uniform distribution over the area is ensured by the axisymmetric placement of the explosive charge, igniter and incendiary compositions in the body of the bomb, which leads to:

- preliminary crushing of incendiary and igniter compositions by detonation products of a bursting charge until the destruction of the body of the bomb;

- further crushing and mixing of pre-crushed compositions at the time of dispersion during the destruction of the body of the bomb;

- crushing the bomb shell by detonation products of a bursting charge into many fragments that do not impede the uniform crushing of incendiary and igniter compositions and their thorough mixing.

It is known that for incendiary PSUs, the most important technical result is the crushing of the incendiary composition into pieces (elements) of a certain size, since the incendiary ability when exposed to targets depends on the size of the burning piece.

It is difficult to expect that in [1] the incendiary composition will be crushed in the necessary way, first “preliminary”, and then also with further “destruction of the bomb body”. The assertion about “crushing an aerial bomb shell by detonation products of a detonating charge into many fragments” is also doubtful, since it is known that crushing a shell into small fragments (as is the case with fragmentation PSUs) is possible only in the case of direct contact between the PSU shell and explosive (BB) . Here, such contact is not observed - there are incendiary and igniter compositions between the shell of the bomb and the explosive charge, together with shells, through which the explosive load on the shell of the bomb from the detonation products of a relatively small (again in comparison with fragmentation PS) explosive charge will be damped (significantly reduced ), which can only worsen the process of crushing the body (the size of the resulting fragments increases).

To ensure the crushing of incendiary (chemical, smoke, etc.) composition into elements of the right size in incendiary (chemical, smoke, etc.) PSUs, special measures are taken, such as controlled crushing, segmentation, encapsulation, etc.

So, in [2] described BP, which is the closest analogue of the invention and selected as a prototype, consisting of a housing with a central explosive explosive charge and liquid equipment, in which cylindrical elements of the required size are freely located, open from one of the ends in such a way that liquid equipment completely fills the internal volume of the elements. After detonation of the bursting charge, the BP case is destroyed and the elements expand with the dispersal of liquid equipment from the internal volume.

The undoubted advantage of this technical solution is the controlled size of the elements that provide the solution to the problem. However, this device is not free from flaws. In particular, it should be noted that:

- the expansion of the elements occurs using a relatively small mass of the Central explosive charge (selected from the conditions of conservation of elements), therefore, with a low speed and a short range;

- although longitudinal cuts are made on the PSU case, helping to destroy the case during explosive loading and thereby reducing the load on the elements, such measures are not always possible, such as in thick-walled shells of shells, since such notches can lead to premature destruction of the case projectile when fired. Therefore, for thick-walled enclosures, special constructive techniques are needed to help open the PSU enclosure.

Disclosure of invention

The problem of the present invention is to increase the efficiency of the incendiary effect of the PSU, providing the spread of the elements of the desired size over a long range (over a large area) to ensure their safety.

This problem is solved by the fact that in the known technical device, consisting of a housing, a central explosive charge of explosive and combustible equipment located in a housing inside the finished elements and in the free space between them, the central explosive charge is made with radial rays dividing the internal volume of the PSU by sectors, while the following relationships should be fulfilled:

- the number of radial rays N = 2 ... 4;

- the thickness of the rays along the explosives δ≈ (0.01 ... 0.03) D≥d _cr , where D is the caliber of the ammunition, d _cr is the critical diameter of the detonation of the explosive;

- the length of the rays along the radius of the PSU 0.3R≤l≤R, where R = (D-2δ ₀ ) / 2 is the radius of the PSU on combustible equipment; δ ₀ - wall thickness of the PSU;

- the minimum and maximum dimensions of the finished elements of arbitrary shape are selected from the interval of 30 ... 60 mm.

The free space between the finished elements can be filled with a flammable composition. The shell of radial rays can be made of sheet combustible material, including aluminum, an electron (an alloy of magnesium with aluminum), etc. Cumulative recesses can be made to reduce the explosive load on the finished elements by opening the case more quickly at the ends of the radial rays adjacent to the case. The shell of the finished elements can be made of combustible material that can withstand large deformations, and through holes with a diameter of 3 ... 5 mm are made over the entire surface of the shell. Sectors formed by radial rays can be made with different angular sizes, and different compositions can be placed in different sectors, for example, incendiary, chemical, smoke, etc.

List of drawings

The design of the proposed BP is illustrated by drawings. Figure 1 shows a cross section of the proposed incendiary PSU, figure 2 - options for the end surfaces of radial rays, figure 3 is an assembly of incendiary PSU from individual cylindrical modules.

The implementation of the invention

In the drawings, numbers and letters denote: 1 - PSU case; 2 - guides on the PSU case into which radial rays are inserted; 3 - a thin shell of a radial beam; 4 - cumulative recess with facing; 5 - finished element; 6 - explosive explosive charge; 7 - combustible equipment filling the space between the finished elements; D - caliber BP; δ ₀ - wall thickness of the housing.

The theoretical analysis shows that the implementation of the central bursting charge with radial rays in the proposed BP design allows you to increase the throwing speed of the finished elements (respectively, they fly a greater distance and disperse over a larger area) with a decrease in the load on them, since simultaneously with the expansion of the detonation products from the central charge and rays, the PSU case is opened using cumulative recesses on the end surfaces of the rays. The latter is especially important because it allows you to expand the possibilities of applying a technical solution, for example, for thick cases, ensuring the safety of finished elements.

The indicated number of rays N = 2 ... 4 is explained by the fact that when N = 1 there is no destruction of the body into parts, but only its opening, when N≥5 there are problems of fitting finished elements into sectors with a smaller value of the angle of the solution, as well as their safety, especially for elements in the central region of the BP, where they experience severe deformations under the action of detonation products of the central charge and both rays.

For the thickness of the rays, measured by the explosives contained in them, the proposed condition δ≈ (0.01 ... 0.03) D≥d _cr allows you to choose the minimum value from the conditions for the propagation of detonation along the rays (δ≥d _cr ).

For the beam length l, the proposed condition 0.3R≤l≤R allows, within a wide range, to control the magnitude of the load on the finished elements and their direction of expansion. Indeed, for fragile housings, where additional measures are not required to destroy the housing into parts, it is possible to reduce the explosive load on the elements by reducing the beam length l, and the minimum length l = 0.3R is determined by the condition that for smaller values of l the flow inside the sector (movement elements and combustible equipment between them behind the transmitted shock wave) quickly “forgets” about such a “slight distortion of the shape” of the central bursting charge. It is clear that in strong cases the condition l = R must be fulfilled, and cumulative recesses on the end surfaces of the radial rays are necessary here. Possible embodiments of the end surfaces of the radial rays are shown in figure 2. Shown here are cumulative recesses with conical (FIG. 2, a) and semi-cylindrical (FIG. 2, b) claddings, as well as without cladding (FIG. 2, c).

The dimensions of the finished element should be selected from the interval of 30 ... 60 mm, with the spherical shape of the element being preferred. However, PSU designs may occur when the shape of the element must be different from the sphere, but in any case, the specified size interval provides the desired mass of the element, which , in turn, ensures its high incendiary ability, since such an element when hit on the target and subsequent burning will inform the target of sufficient thermal energy for ignition. For reliable ignition of combustible equipment located inside the finished elements, it is possible to fill the space between the elements with an igniter composition.

If we constructively construct the shell of radial rays from sheet combustible material, for example aluminum, electron, etc., then as a result of its destruction we will receive additional burning fragments, and the general ignition ability of the PSU will increase. The same can be said about the shell of the finished elements, it should also contribute to the common cause of increasing the ignition ability of the PSU, but increased requirements are placed on it to ensure the safety of the elements during their deformation. Indeed, no matter how quickly detonation along the rays spreads, it still takes some time, plus time for the destruction of the hull, which also does not occur instantly. During this total time, the detonation products of the central charge and rays expand and thereby deform the elements. Therefore, the shell material must also be such that the elements can withstand large deformations without fracture. Moreover, if the shell of the elements will have through holes with a diameter of 3 ... 5 mm, the fuel equipment will be able to squeeze through these holes from the elements under severe deformations, protecting the elements from destruction, but the indicated hole sizes are small enough so that the fuel freely flows through them when flight of an element (as thickened combustible mixtures are usually used). In addition, through these openings, preliminary equipment of the elements with combustible equipment is carried out. Depending on the type of PSU and the tasks to be solved, arrangements are possible in which different sectors of the same PSU can have different angular sizes and be filled with different compositions - incendiary, chemical, smoke, volume-detonating.

It should be noted that the use of a central bursting charge with radial rays in the proposed technical solution leads to some change in the directional pattern of the expansion of the finished elements in the angle - most of the elements will fly inside the sectors (in their central part) and smaller in the direction of radial rays. Since the position of the target relative to the PSU is usually unknown, there is a possibility of missed flying elements flying around the target. This situation is easily corrected if the full PSU is assembled from separate modules, and during assembly each of the modules rotates relative to the previous one by a certain angle, for example, equal to half the angle of the sector solution (Fig. 3).

The proposed BP works as follows.

An impulse is supplied from the head or bottom fuse of a power supply to undermine the central explosive charge. The detonation wave (DW) propagates along the axis of symmetry of the discontinuous charge and radial rays. After the exit of the DW to the surface of the cumulative recess, a cumulative jet is formed, which pierces the PSU body along a generatrix equal to the height of the explosive charge. With a sufficiently strong case, parts are formed from it in an amount equal to the number of rays, and these parts begin to move from the symmetry axis of the PSU with a deviation from the vertical, diverging to the sides (the case opens from the side of the fuse). Finished elements and fuel equipment from the interelement space fly into the gap formed between the parts of the body in the radial and end directions.

Information sources

1. Patent RU 2284461, 2005.03.03.

2. Patent US 3636874, 1972.01.25.

Claims (7)

1. Incendiary ammunition, consisting of a shell, a central explosive charge of explosive and combustible equipment located in the housing inside the finished elements and in the free space between them, characterized in that the central explosive charge is made with radial rays dividing the internal volume of ammunition into sectors, the following relations are fulfilled: the number of radial rays is from 2 to 4, the thickness of the rays in the explosive is δ≈ (0.01 ... 0.03) D≥d _cr , where D is the caliber of the ammunition, d _cr is the critical diameter of the detonation of the blast substance, the length of the rays along the radius of the ammunition 0.3R≤

≤R, where R = (D-2δ ₀ ) / 2 is the radius of the combustible equipment, δ ₀ is the wall thickness of the body, and the finished element is made of arbitrary shape with minimum and maximum sizes selected from the interval 30 ... 60 mm. 2. Incendiary ammunition according to claim 1, characterized in that the free space between the finished elements is filled with a flammable composition. 3. Incendiary ammunition according to claim 1 or 2, characterized in that the shell of the radial rays is made of sheet combustible material, including aluminum, an electron. 4. Incendiary ammunition according to claim 1 or 2, characterized in that at the ends of the radial rays adjacent to the casing, shaped cavities are made. 5. Incendiary ammunition according to claim 1, characterized in that the shell of the finished elements is made of combustible material that can withstand large deformations, and through holes with a diameter of 3 ... 5 mm are made over the entire surface of the shell. 6. Incendiary ammunition according to claim 1 or 2, characterized in that the sectors formed by radial rays are made with different angular dimensions. 7. Incendiary ammunition according to claim 1 or 2, characterized in that different compositions, including incendiary, chemical, smoke, volume-detonating, are placed in different sectors.

Images