RU2562871C1 - Targets layout for testing ammunition with circular fragmentation field - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: targets layout comprises a vertical wall, a rack for placing the ammunition in a horizontal position, a system of undermining, and a system of registration of the fragments. The vertical wall is made in the form of a set of shields that cover the angle of flight of the fragments in a horizontal plane and located from the centre of the targets layout at distances proportional to the density of the fragmentation field in the direction of flight.

EFFECT: improved accuracy of measurements with the ability of using automated systems for collecting and processing information about the fragmentation fields of the test ammunition.

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Description

The invention relates to target environments and shield type stands for determining the characteristics of a fragmentation field formed during the explosion of ammunition with artificial or natural fragmentation of the hull, namely, to experimentally find the distribution of the initial velocities and densities of the fragmentation field by the angle of expansion of the fragments in the meridional section of the munition.

The calculation of the effectiveness of ammunition (the coordinate and conditional law of target destruction) is based on the above characteristics of the fragmentation field determined in the target environment when the ammunition is detonated under static ground conditions.

Known target environment, which is a vertical wall made in the form of a half cylinder, in the center of which in a horizontal position is mounted ammunition / 1 /. According to the test results, in accordance with the nature of the distribution of the area of the wall holes by fragments, the calculation establishes the law of the distribution of fragments in groups of different masses.

The disadvantage of such a target situation is the low accuracy of determining the mass of fragments at high speeds of their flight, especially in the explosion of ammunition with natural fragmentation of the hull and the insufficient efficiency of processing the experiment.

A known method of testing fragmentation munitions with an axisymmetric field for the expansion of fragments and a stand for its implementation / 2 /.

The disadvantage of this method and the stand is the inability to fix high-density fragmentation fields with the same speed of individual fragments that fall into the zone of electret sensors, due to the imposition of electrical signals when impacting more than 2 fragments in the electret part of the wall sheathing.

There is also a method of testing fragmentation ammunition with a circular field of expansion of fragments and a stand for its implementation / 3 /.

This method consists in installing the ammunition in the center of the shield target environment, which is made in the form of a semi-cylindrical vertical wall, placing the ammunition in a horizontal position on a rack with a height equal to half the height of the wall, combining the axis of the ammunition with a straight line connecting the vertical ends of the wall, drawing on the inner surface covering the projection contours of the part of the projectile bounded by two meridional sections with an angle between them, as well as the boundary lines of the angular sectors with a step, recording holes p tearing in each sector of the sheathing, measuring the size and area of the holes, converting them to the mass of the fragment, determining the distribution of the fragments in the corners, in addition, two non-contact sensors are additionally introduced, which are placed at a predetermined distance between themselves and are made in the form of semi-cylindrical vertical walls consisting of from N-sectors, made in the form of perpendicularly placed lines of photodetectors and emitters. In the future, determine the speed of movement of echelons of fragments and carry out operational determination of histograms of the distribution of fragments.

Actually, the test bench for fragmentation of ammunition consists of a shield target environment made in the form of a semi-cylindrical vertical wall sheathed with sheet material, into which sensors, measuring units, an analog-to-digital converter, a memory unit, a receiving device, and a computer are additionally introduced.

The disadvantage of this method of testing fragmentation ammunition and a stand for its implementation is the complexity of its manufacture, the almost one-time use of sensors and other equipment placed on a vertical wall due to the destructive effect of an air shock wave arriving at the wall. However, another disadvantage of the method is that it allows you to fix the echelons of fragments, while you want to fix the parameters of each fragment, their speed and direction of expansion. The method and the stand do not have high accuracy (less than 5%) for determining the parameters of the field of expansion of fragments. In addition, its use is difficult, and in some cases impossible when testing ammunition with a wide angle of flight of fragments in the meridional plane.

Closest to the proposed invention in technical essence and the achieved result is a method for testing fragmentation ammunition with a circular field for the expansion of fragments and a stand for its implementation / 4 /, including detonation of the ammunition in a horizontal position in the center of a vertical semi-cylindrical target wall, marked into zones corresponding to the corner zones the expansion of fragments in the equatorial and meridional planes, counting the number of fragments falling into each zone, measuring the size and area of holes. The fragments are captured by a trap placed on the wall, removed from the trap with fixation of the place of impact and sorted inside each corner zone by mass groups.

The test bench for fragmentation munitions designed to implement the specified method, contains a vertical target wall made in the form of a half cylinder and sheathed with metal sheet material with the zones deposited on it, corresponding to the angular zones of the expansion of the fragments in the equatorial and meridional planes, a trap placed between the skin and the wall , a rack located in the center of the semicylinder for installation on it in a horizontal position of ammunition along the line connecting the midpoints of the ends of the semicylinder and as well as circuitry and register and undermining-rebound semicylindrical wall.

The above method for testing fragmentation munitions and a stand for its implementation is also not without drawbacks for the following reasons:

- The implementation of the method and the stand for its implementation requires large material costs for the manufacture of the target wall in the form of a half cylinder with a constant radius.

- In most ammunition during their explosion, the bulk of the fragments fly in directions close to the normal to the cylindrical part of the shell. Some of the fragments from the head and tail of the ammunition flies to the peripheral zones with a lower density. Density of a fragmentation field is understood to mean the number of fragments flying in a two-degree angular sector and per square meter of shield environment. In this case, when outbreaks are recorded during the passage of fragments through the target wall, there is an overlap of flashes from the nearest fragments, which does not allow one to determine the time of arrival of each individual fragment on the target wall. As a result, the total average velocity of the fragment group is determined. This circumstance is most important when testing ammunition in reel form, as well as in the case of their bilateral end initiation.

The technical task of the invention is to reduce material costs while increasing the accuracy of measurements in order to use automated systems for collecting and processing information about the fragmentation fields of the tested ammunition.

The solution is achieved by the fact that in a known target environment for testing ammunition with a circular fragmentation field containing a vertical wall, a rack for placing ammunition in a horizontal position and a system for detonating and registering fragments, in accordance with the invention, the vertical wall is made in the form of a set of shields that cover the corner the expansion of fragments in the horizontal plane and placed from the center of the target environment at distances proportional to the density of the fragmentation field in the direction of expansion.

In practice, when testing ammunition, the fragmentation field density is defined as the number of fragments per unit area of the shield of the target wall. In this case, before undermining the ammunition, the target wall is marked into zones 1 × 1 m in size. In these zones, the number of fragments falling into the area of 1 m ² is counted. Subsequently, the number of fragments falling in the corner zones and flying in a space limited by the angular intervals Δα, Δφ (φ _i-1 ÷ φ _i ), where Δα and Δφ are dihedral angles, respectively, in the meridional and equatorial planes of the munition, is recalculated.

The total area of the shield-wall is a function of its length and height. The length depends on the radius of the shield from the center of the detonation of ammunition. With a semi-cylindrical shield, it is equal to πR, where π = 3.14, and R is the radius of the shield. The height of the shield usually remains constant when the ammunition is detonated in a horizontal position.

Given that the number of fragments that fall into the central part of the shield-wall is significantly higher than the similar characteristic in its peripheral zones, it is advisable to place the central part of the shield at large distances from the center of the munition detonation.

The implementation of the target wall in the form of a set of shields that overlap the angle of fragmentation of the fragments and located at different distances proportional to the plane of the fragmentation field allows you to more accurately set its configuration in accordance with the predicted front of the expansion of fragments of ammunition, which provides a more accurate assessment of the characteristics of the fragmentation field.

It should be noted that the law of the distribution of fragments along the directions of expansion can also be obtained by calculation. The main content of the calculations is to determine the shape of the shell of the charge at the time of its destruction, which determines the direction of flight of fragments formed from each given section of the shell.

Before conducting ammunition tests, it is necessary to assess the density of the fragmentation field and the number of fragments flying in areas bounded by the dihedral angle Δα in the meridional and Δφ in the equatorial plane of the munition. The number of fragments flying in this dihedral angle is constant, and the area of the distance to the shield R can be determined by the dependence

The density of the fragmentation field, i.e. the number of fragments arriving per unit area decreases in proportion to the square of the distance to the shield from the center of the detonation. The width of the corner zone is usually 2 °.

For practical purposes, you can use the following calculated data. With a double increase in the radius of the shield R, the fragmentation field density ρ decreases four times; with an increase in R three times, ρ decreases nine times; with an increase in R by a factor of five, ρ decreases twenty-five times.

As an example, the invention is schematically illustrated by drawings for two variants of a fragmentation field:

- with a maximum density in the central part - FIG. one;

- with a maximum density in the peripheral parts along the ends of the ammunition - FIG. 2.

In FIG. Figure 1 shows a diagram of a three-shield target environment with a law of the distribution of the number of fragments in directions in which the maximum density of the fragmentation field 1 falls on the central zone of the shell (shell) of the munition 2 in the direction perpendicular to its longitudinal axis. Shields 3 are located at different radii R ₁ , R ₂ and R ₃ , providing interception of 100% of the fragments. Moreover, R ₁ > R ₂ > R ₃ , which corresponds to the distribution law of the number of fragments N.

In FIG. 2 is a diagram of the target environment with the law of the distribution of the number of fragments in the directions in which the largest number of them is located in the peripheral zones of the fragmentation field 1 created by the munition 2. Shields 3 are also located at different distances R ₁ , R ₂ and R ₃ from the blast epicenter, but R ₃ > R ₁ > R ₂ .

The required number of shields required for the installation of a specific target environment is determined by the design of the ammunition and, accordingly, the predicted distribution law of the density of its fragmentation field.

Modern ammunition is characterized by an extremely high density of fragmentation field, reaching more than 90 fragments per square meter. Therefore, during the registration of the test process by photographic methods, superposition of flashes is observed when a shield is pierced by fragments flying close to each other, regardless of their mass / size. This complicates the ability to automatically obtain reliable information only from the survey results and requires additional visual assessment of the results, i.e. additional labor costs.

The implementation of the target situation described above in the form of a set of differently spaced shields makes it possible to significantly reduce the overlap of flashes when pierced by shield fragments, which will provide more reliable information about the velocity parameters of the fragmentation field at different fragment flux densities, improve the accuracy of measuring the velocity of fragments as in a stream, each separately, and also reduce material costs for the production of the target environment.

Information sources

1. A.N. Dorofeev, P.P. Morozov, R.S. Sargsyan "Aviation Ammunition", ed. VVIA them. N.E. Zhukovsky, 1978? p. 211

2. Russian Patent No. 2493538, F42B 35/00, 2012

3. Russian patent No. 2482439, F42B 35/00, 2012

4. Patent of Russia No. 2131583, F42B 35/00, 1999 (Prototype)

Claims (1)

The target situation for testing ammunition with a circular fragmentation field, containing a vertical wall, a rack for placing ammunition in a horizontal position and a system for detonating and registering fragments, characterized in that the vertical wall is made in the form of a set of shields that cover the angle of flight of fragments in the horizontal plane and placed from center of the target environment at distances proportional to the fragmentation field density in the direction of expansion.

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