RU2814055C1 - Method for comprehensive testing of axially-symmetrical high-explosive fragmentation ammunition with axially-symmetrical fragment field - Google Patents

Abstract

FIELD: testing high-explosive fragmentation ammunition.

SUBSTANCE: method for complex testing of axisymmetric high-explosive fragmentation ammunition with an axisymmetric field of dispersion of fragments includes detonation of ammunition installed in the centre of a profiled target wall, marked into zones corresponding to the directions of dispersion of fragments in the adopted coordinate system, recording hits, catching and counting fragments falling into each zone, measurement of the size and area of holes, assessment of the quantitative characteristics of the fragmentation field in terms of masses, velocities, shapes and sizes of fragments by registering, recording and processing signals from electret sensors located in the corresponding zones of the target wall and equal in size. The profiled target wall is made circular. The ammunition is installed so that its longitudinal axis coincides with the longitudinal axis of the target wall. The space between the ammunition and the target wall is divided into sectors by introducing an additional coordinate system, the longitudinal axis of which divides the profiled target wall into two equal parts and passes through the longitudinal axis of the ammunition parallel to the surface of the earth. The transverse axis of the coordinate system divides the target wall into two equal parts, passes through the longitudinal axis of the ammunition and is perpendicular to the longitudinal axis of the additional coordinate system. On the surface of the ground, along the axes of the introduced coordinate system, at a distance exceeding 20 given radii of the explosive charge of the ammunition, lines of pressure sensors connected to pressure meters are installed. After the ammunition is detonated, the values of excess pressure in the shock wave are recorded by distances and directions using lines of pressure sensors and pressure meters, and the shock wave pressure values are transmitted to the computer. The computer determines the excess pressure at the front and the shock wave impulse by distance and direction. The high-explosive action indicator is determined and the distribution of ammunition fragments by mass, angle, and velocity in sectors is formed. Indicators characterizing the fragmentation effect of ammunition are formed by sector and the result of the impact of the damaging factors of ammunition on vital compartments and elements of typical targets is determined using the method of mathematical modelling. The contours of projections of simulators of vital compartments and elements of typical targets are applied to the front surface of the target wall zones in each sector and their coordinates are determined in the accepted coordinate system. In place of the target wall, simulators of vital compartments and target elements with the necessary measuring equipment are installed in sectors. The ammunition is installed so that its longitudinal axis coincides with the longitudinal axis of the simulators of vital compartments and elements of standard targets, and the ammunition is detonated. The results of the impact of the damaging factors of ammunition on simulators of vital compartments and target elements are assessed and the test results are correlated with the results of mathematical modelling.

EFFECT: increasing the information content of the test results of ammunition with an axisymmetric field of dispersion of fragments.

1 cl, 1 dwg

Description

The invention relates to methods for testing high-explosive fragmentation ammunition and can be used when testing axisymmetric ammunition of natural and specified crushing with axisymmetric fragmentation fields.

It is known [1] that in order to assess the effectiveness of the destructive effect of high-explosive fragmentation ammunition on various targets, it is necessary to know the distribution of fragments by number, their masses and initial velocities in a given target area, as well as the particular characteristics and indicators of the high-explosive effect of ammunition. At the same time, the above distributions, characteristics and indicators must be brought into a form suitable for modeling.

There is a known method for determining the characteristics of the fragmentation field of ammunition [2], which consists in detonating ammunition located horizontally in the center of a semi-cylindrical target using an initiation system, while detonation of the ammunition is carried out in the explosion chamber, the time dependence of the filtered Doppler frequencies of signals reflected from part of the fragmentation field is obtained, relative to the moment of detonation of the ammunition by installing a radar velocity meter so that the axis of the antenna pattern is with the plane passing through the longitudinal axis of the ammunition and the longitudinal axis of the explosion chamber slit, an acute angle α, filtering the Doppler frequencies of signals reflected from part of the fragmentation field when it is in within the radiation pattern of the radar speed meter, determining the speed of the leading and trailing fragments, the average speed and depth of the fragmentation field from the time dependence of the filtered Doppler frequencies of signals reflected from part of the fragmentation field, relative to the moment of detonation of the ammunition, while additionally introducing a semi-cylindrical target made in the form of N sectors of non-contact sensors, each sector consisting of three perpendicular matrices of emitters and matrices of sensitive elements of photodetector arrays, determine the differential distribution law of fragments along the directions of dispersion in each echelon of the fragmentation field of ammunition based on sequential fixation of combinations of coordinates of triggered elements of the matrix of sensitive elements of photodetector arrays in the picture plane , relative to the first row of the matrix of sensitive elements of the line of photodetectors located along the X axis, determine the mass of fragments in accordance with the expression m _i =ρ*(n _i *n _j *n _k *k), where n _i n _j n _k is the number of simultaneously triggered elements, k - linear dimensions of the sensitive elements of the photodetector arrays, mm, ρ - density of the material of the ammunition body, kg/m ³ , determine the law of distribution of fragments by mass in each echelon of the fragmentation field of ammunition based on sequential fixation of the combination of trigger coordinates of the elements of the matrix of photodetector sensitive elements in space, relative to the first row of the matrix of sensitive elements of the photodetector line, located along the X-axis, determine the number of echelons of the fragmentation field of the ammunition, based on determining the triggering sequences of the first row of elements of the matrix of sensitive elements of the photodetector line, located along the X-axis, determine the dynamics of changes in the distribution of fragments in the direction and mass in each echelon of the fragmentation field of the ammunition, based on fixing combinations of triggered elements of the matrix of sensitive elements of the photodetector line in space relative to each line of elements of the matrix of sensitive elements of photodetectors located along the Z axis.

Common essential features with the proposed technical solution are the detonation of an axisymmetric ammunition using an initiation system, the determination of the law of distribution of fragments along the directions of expansion, the law of distribution of fragments by mass.

The disadvantages of the above method are the impossibility of determining with its help the quantitative characteristics of a high-explosive field of ammunition, determining particular characteristics and indicators of the damaging effect of ammunition, as well as assessing the results of the impact of the damaging factors of ammunition on vital compartments and elements of typical targets.

The closest to the claimed invention is a method for testing fragmentation ammunition with an axisymmetric field of dispersion of fragments [3], including detonation of ammunition installed in a given position in the center of a profiled target wall, marked into zones corresponding to the directions of dispersion of fragments in the adopted coordinate system, recording hits, catching and counting the number of fragments falling into each zone, measuring the size and area of the holes, while assessing the qualitative and quantitative characteristics of the fragmentation field in terms of mass, speed, shape and size of the fragments is carried out by registering, recording and subsequent processing of signals from electret sensors located at the appropriate zones of the target wall and equal in size.

The disadvantages of the above method are the impossibility of determining with its help the quantitative characteristics of a high-explosive field of ammunition, determining particular characteristics and indicators of the damaging effect of ammunition, as well as assessing the results of the impact of the damaging factors of ammunition on vital compartments and elements of typical targets.

The technical objective of the proposed invention is to create a method for comprehensive testing of axisymmetric high-explosive fragmentation ammunition with an axisymmetric dispersion field of fragments with the achievement of a technical result consisting in reducing the cost of testing, increasing information content by determining particular indicators of the damaging effect of ammunition, as well as a comparative assessment of the results of the impact of damaging weapons. ammunition factors for vital compartments and elements of typical targets.

The solution to the technical problem and obtaining the specified technical result is achieved by the fact that in the method of complex testing of axisymmetric high-explosive fragmentation ammunition with an axisymmetric field of dispersion of fragments, including the detonation of ammunition installed in a given position in the center of a profiled target wall, marked into zones corresponding to the directions of dispersion of fragments in accepted coordinate system, recording hits, catching and counting the number of fragments falling into each zone, measuring the size and area of holes, assessing the qualitative and quantitative characteristics of the fragmentation field in terms of masses, velocities, shapes and sizes of fragments through registration, recording and subsequent processing of signals from electrets sensors placed in the corresponding zones of the target wall and equal in size, the additionally profiled target wall is made circular, the ammunition is installed so that its longitudinal axis coincides with the longitudinal axis of the profiled target wall, the space between the ammunition and the profiled target wall is divided into sectors by introducing additional coordinate system, the longitudinal axis of which divides the profiled target wall into two equal parts and passes through the longitudinal axis of the ammunition parallel to the surface of the earth, and the transverse axis of the coordinate system also divides the profiled target wall into two equal parts, passes through the longitudinal axis of the ammunition and is perpendicular to the longitudinal axis of the additional system coordinates, on the surface of the earth, along the axes of the introduced additional coordinate system, at a distance exceeding 20 given radii of the explosive charge of the ammunition, lines of pressure sensors are installed, connected to autonomous pressure meters; after detonation of the ammunition, the values of excess pressure in shock wave along distances and directions, transmit the obtained values of the excess pressure of the shock wave to a remote computer, on the remote computer determine the values of excess pressure at the front and the impulse of the shock wave over distances and directions, determine a particular indicator of high-explosive action, and form distributions of ammunition fragments by mass and angle , speeds by sector in a form convenient for mathematical modeling, form a set of partial indicators characterizing the fragmentation effect of ammunition by sector, determine by mathematical modeling the result of the impact of the damaging factors of ammunition on vital compartments and elements of typical targets, form sets of simulators of vital compartments and elements of typical targets, the contours of projections of simulators of vital compartments and elements of typical targets are applied to the front surface of the target wall zones in each sector and their coordinates are determined in the accepted coordinate system; sets of simulators of vital compartments and elements are installed in the places of the profiled target wall in sectors standard targets with the necessary measuring equipment, install ammunition so that its longitudinal axis coincides with the longitudinal axis of sets of simulators of vital compartments and elements of standard targets, carry out detonation of ammunition, carry out a qualitative and quantitative assessment of the results of the impact of damaging factors of ammunition on simulators of vital compartments and elements of typical goals, correlate test results with the results of mathematical modeling.

New essential features of the invention are:

- the profiled target wall is made circular, the ammunition is installed so that its longitudinal axis coincides with the longitudinal axis of the profiled target wall, the space between the ammunition and the profiled target wall is divided into sectors by introducing an additional coordinate system, the longitudinal axis of which divides the profiled target wall into two equal parts and passes through the longitudinal axis of the ammunition parallel to the surface of the earth, and the transverse axis of the coordinate system also divides the profiled target wall into two equal parts, passes through the longitudinal axis of the ammunition and is perpendicular to the longitudinal axis of the additional coordinate system, on the surface of the earth, along the axes of the introduced additional coordinate system, on at a distance exceeding 20 given radii of the explosive charge of the ammunition, install lines of pressure sensors connected to autonomous pressure meters, record after detonation of the ammunition with lines of pressure sensors and autonomous pressure meters the values of excess pressure in the shock wave over distances and directions, transmit the resulting values of excess pressure of the shock wave to a remote computer;

- on a remote computer, the values of excess pressure at the front and the shock wave impulse are determined by distances and directions, and a particular indicator of high-explosive action is determined;

- form distributions of ammunition fragments by masses, angles, velocities by sectors in a form convenient for mathematical modeling, form by sectors a set of partial indicators characterizing the fragmentation effect of ammunition;

- determine by modeling the result of the impact of the damaging factors of ammunition on vital compartments and elements of typical targets;

- sets of simulators of vital compartments and elements of standard targets are formed, the contours of projections of simulators of vital compartments and elements of standard targets are applied to the front surface of the target wall zones in each sector and their coordinates are determined in the accepted coordinate system, to the locations of the profiled target wall by sector install sets of simulators of vital compartments and elements of typical targets with the necessary measuring equipment;

- install the ammunition so that its longitudinal axis coincides with the longitudinal axis of sets of simulators of vital compartments and elements of standard targets, carry out detonation of ammunition, carry out a qualitative and quantitative assessment of the results of the impact of the damaging factors of ammunition on simulators of vital compartments and elements of standard targets, correlate test results with mathematical modeling results.

A new set of essential features ensures the solution of the set technical problem with the achievement of the stated technical result, namely, reducing the cost of testing, increasing information content by determining particular indicators of the damaging effect of ammunition and comparative assessment of the results of the impact of the damaging factors of ammunition on simulators of vital compartments and elements typical goals.

The technical result associated with a reduction in testing costs is due to the fact that, in comparison with known technical solutions, at the second stage of testing, the penetrating, incendiary, initiating and destructive effects of ammunition are assessed in one experiment, and not in four, as is currently the case.

The increase in the information content of the method is due to the fact that, in comparison with the prototype, the particular characteristics of the high-explosive action of the ammunition are additionally measured, and a particular indicator of the high-explosive action is determined.

In addition, based on the modeling results, particular indicators of the fragmentation effect of ammunition are additionally determined. Also, the adequacy of the models obtained at the first stage of testing is confirmed by the coincidence of the modeling results with the results of the impact of the damaging factors of ammunition on simulators of vital compartments and elements of typical targets.

The use of a single set of essential distinctive features in known technical solutions has not been found, which characterizes the compliance of the technical solution under consideration with the “novelty” criterion.

The above set of new essential features in combination with common known ones ensures the solution of the problem with the achievement of the required technical result and characterizes the proposed technical solution with significant differences compared to the known level of technology.

The drawing shows typical schemes for the implementation of the proposed method, where a is a scheme for detonating ammunition in a circular profiled target wall, b is a diagram for detonating ammunition surrounded by simulators of vital compartments and elements of typical targets. The drawing shows:

1. Ammunition being tested.

2. Electret sensors placed on a circular profiled target wall, connected to a remote computer.

3. Pressure sensors.

4. A set of simulators of vital compartments and elements of typical targets.

5. Autonomous pressure meter.

A, B, C, D - sectors into which the space between the ammunition and the profiled target wall is divided.

The inventive method is the result of research and experimental work to reduce the cost of testing, as well as increase the information content by determining particular indicators of the destructive effect of ammunition and assessing the results of the impact of the damaging factors of ammunition on vital compartments and elements of typical targets.

An example of the implementation of the proposed method.

The proposed method of complex testing consists of two stages, at the first of which the particular characteristics and indicators of the destructive effect of the tested ammunition are determined, private methods for assessing the effectiveness of its destructive effect are formed, the totality of which, in the form of software, is a specialized digital twin of the tested ammunition. At the second stage of implementation of the method, the adequacy of the private methods for assessing the effectiveness obtained at the first stage (a specialized digital twin of ammunition) is checked using sets of simulators of vital units and compartments of typical targets. Based on the test results, the degree of quantitative and qualitative agreement between the modeling results and the results of full-scale tests is determined.

At the first stage of implementation of the method, an axisymmetric high-explosive fragmentation ammunition 1 is detonated with an axisymmetric field of dispersion of fragments, installed in a given position in the center of a profiled target wall, marked into zones corresponding to the directions of dispersion of fragments in the adopted coordinate system. In this case, the profiled target wall is made circular. Ammunition 1 is installed so that its longitudinal axis coincides with the longitudinal axis of the profiled target wall. The space between the ammunition and the profiled target wall is divided into sectors by introducing an additional coordinate system, the longitudinal axis of which divides the profiled target wall into two equal parts and passes through the longitudinal axis of the ammunition 1 parallel to the surface of the earth, and the transverse axis of the coordinate system also divides the profiled target wall into two equal parts, passes through the longitudinal axis of ammunition 1 and is perpendicular to the longitudinal axis of the additional coordinate system on the surface of the earth. Along the axes of the introduced additional coordinate system, at a distance exceeding 20 given radii of the explosive charge of ammunition 1, lines of pressure sensors 3 are installed, connected to autonomous pressure meters 5. After detonation of ammunition 1, the values of excess pressure in shock wave over distances and directions, transmit the resulting values of shock wave excess pressure to a remote computer. They register hits, catch and count the number of fragments falling into each zone, measure the size and area of holes, assess the quantitative characteristics of the fragmentation field in terms of masses, velocities, shapes and sizes of fragments by registering, recording and subsequent processing of signals from electret sensors 2 located along corresponding zones of the target wall and equal in size to them. Then, on a remote computer, the values of excess pressure at the front and the shock wave impulse are determined by distances and directions, a partial indicator of high-explosive action is determined, distributions of ammunition fragments 1 are formed by masses, angles, velocities by sector in a form convenient for mathematical modeling, a set of partial values is formed by sector indicators characterizing the fragmentation effect of ammunition 1. Next, the result of the impact of the damaging factors of ammunition 1 on vital compartments and elements of typical targets 4 is determined using the method of mathematical modeling.

At the second stage of testing, sets of simulators of 4 vital compartments and elements of standard targets are formed, the contours of the projections of simulators of 4 vital compartments and elements of standard targets are applied to the front surface of the target wall zones in each sector and their coordinates are determined in the accepted coordinate system. In place of the profiled target wall, sets of simulators of 4 vital compartments and elements of standard targets with the necessary measuring equipment are installed in sectors. Then the ammunition 1 is installed so that its longitudinal axis coincides with the longitudinal axis of the sets of simulators of 4 vital compartments and elements of typical targets, the ammunition 1 is detonated, a qualitative and quantitative assessment of the results of the impact of the damaging factors of the ammunition 1 on the simulators of 4 vital compartments is carried out and elements of typical goals, the obtained test results are correlated with the results of mathematical modeling.

It should be noted that in sectors A, B, C, D there are various sets of simulators of 4 vital compartments and elements of typical targets. For example, in sector A a set of simulators of 4 vital compartments and elements of typical targets is placed, allowing one to evaluate the penetrating effect of the fragmentation field of ammunition 1, in sector B - a set of simulators of 4 vital compartments and elements of typical targets, allowing one to evaluate the incendiary effect of ammunition 1, in sector B - a set of simulators of 4 vital compartments and elements of typical targets, allowing to evaluate the initiating effect of ammunition 1, in sector D - a set of simulators of 4 vital compartments and elements of typical targets, allowing to assess the phenomenon of an airstrike that occurs in the compartments of a structure as a result of exposure to a fragmentation field ammunition 1.

At the same time, sets of simulators of vital compartments and elements of typical targets in sectors may change depending on the technical problem being solved.

A set of simulators of vital compartments and elements of typical targets, which allows one to evaluate the penetrating effect of the fragmentation field of ammunition 1, consists of a simulator of a semi-infinite barrier, a simulator of a compartment with LVA of the first type, and a simulator of a compartment with LVA of the second type [4].

A set of simulators of vital compartments and elements of typical targets, allowing one to evaluate the incendiary effect of ammunition 1, consists of simulators of a fuel tank of the first and second types, as well as a simulator of a compartment with pipelines. The first type of fuel tank simulator is filled 100% with polyurethane foam (PPU) and flammable liquid (for example, aviation kerosene). The fuel tank simulator of the second type is filled 100% with polyurethane foam soaked in a flammable liquid. The simulator of a compartment with pipelines is a closed caisson with a replaceable front cover, which is made of aluminum, titanium alloy, composite or other material with a thickness of no more than 5...6 mm and holes in the side wall into which the pipelines are inserted. A sealed plug is installed on the end part of the pipeline inserted into the caisson. Through the open end of the pipeline, a flammable liquid (for example, aviation kerosene) is supplied under excess pressure into several atmospheres. The empty space in the caisson is partially filled with electrical harnesses, the insulation of which can serve as fuel to maintain combustion in the compartment.

A set of simulators of vital compartments and elements of typical targets, which allows one to evaluate the initiating effect of ammunition 1, consists of simulators of ammunition of the first, second and third types, differing in sensitivity to impact from fragments. In this case, the simulator of the first type is a cylindrical charge of high explosive in a steel shell, which has low sensitivity to impact from fragments (for example, TNT). The second type of simulator is a cylindrical charge of high explosive in a steel shell, which has average sensitivity to impact from fragments (for example, TG-40). The third type of simulator is also a cylindrical charge of high explosive in a steel shell, which is highly sensitive to impact from fragments (for example, okfol).

A set of simulators of vital compartments and elements of typical targets, allowing to evaluate the phenomenon of an airstrike, consists of simulators of structural compartments of the first, second type and third type. The first type compartment simulator is 100% filled with air, the second type simulator is 100% filled with inert gas (for example, helium), the third type simulator is 100% filled with polyurethane foam (PPU). Simulators of construction compartments of the first, second and third types are made of welded steel caisson. As the front (input) wall of the simulators, replaceable sheets of the studied structural materials (for example, duralumin, titanium, steel, composite) with a thickness of δ _st are used. A sealant is attached along the perimeter of the front wall of the caisson to seal it. The side walls of the simulators of the first, second and third types are equipped with piezoelectric sensors connected to devices for measuring pressure and impulse of the shock (ballistic) wave, which measure the value of the average maximum pressure of the air strike that occurs in the compartment simulator after fragments of the tested ammunition penetrate its entrance wall.

The use of the proposed method makes it possible to reduce the material and financial costs of testing, increases its information content by determining particular indicators of the destructive effect of ammunition, and also quantitatively and qualitatively evaluates the results of the impact of the damaging factors of ammunition on vital compartments and elements of typical targets.

Information sources

1. Aviation ammunition. Ed. V.A. Kuznetsova, M.: Publishing house. VVIA im. Zhukovsky, 1968

2. Patent RU 2519611. A method for determining the characteristics of the fragmentation field of ammunition and a device for its implementation. IPC F42B 35/00, published June 20, 2014

3. Patent RU 2493538. A method for testing fragmentation ammunition with an axisymmetric field of dispersion of fragments and a stand for its implementation (prototype). IPC F42B 35/00, published September 20, 2013

4. Patent RU 2788241. Method for assessing the penetrating effect of fragments of axisymmetric fragmentation ammunition with an axisymmetric field of dispersion of fragments. IPC F42B 35/00, publ. 01/17/2023

Claims (1)

A method for complex testing of axisymmetric high-explosive fragmentation ammunition with an axisymmetric field of dispersion of fragments, including detonation of ammunition installed in a given position in the center of a profiled target wall, marked into zones corresponding to the directions of dispersion of fragments in the adopted coordinate system, recording hits, catching and counting the number of fragments, falling into each zone, measuring the size and area of holes, assessing the quantitative characteristics of the fragmentation field in terms of masses, velocities, shapes and sizes of fragments by registering, recording and subsequent processing of signals from electret sensors located in the corresponding zones of the target wall and equal in size, different in that the profiled target wall is made circular, the ammunition is installed so that its longitudinal axis coincides with the longitudinal axis of the profiled target wall, the space between the ammunition and the profiled target wall is divided into sectors by introducing an additional coordinate system, the longitudinal axis of which divides the profiled target wall into two equal parts and passes through the longitudinal axis of the ammunition parallel to the surface of the earth, and the transverse axis of the coordinate system also divides the profiled target wall into two equal parts, passes through the longitudinal axis of the ammunition and is perpendicular to the longitudinal axis of the additional coordinate system, on the surface of the earth, along the axes of the introduced additional coordinate system , at a distance exceeding 20 given radii of the explosive charge of the ammunition, install lines of pressure sensors connected to autonomous pressure meters, after detonation of the ammunition, use lines of pressure sensors and autonomous pressure meters to record the values of excess pressure in the shock wave over distances and directions, transmit the resulting values of excess pressure of the shock wave on a remote computer; on the remote computer, the values of excess pressure at the front and the impulse of the shock wave are determined by distances and directions, a particular indicator of high-explosive action is determined, distributions of ammunition fragments are formed by masses, angles, velocities by sectors in a form convenient for mathematical modeling , form by sector a set of particular indicators characterizing the fragmentation effect of ammunition, determine by mathematical modeling the result of the impact of the damaging factors of ammunition on vital compartments and elements of standard targets, form sets of simulators of vital compartments and elements of standard targets on the front surface of target wall zones in each sector, contours of projections of simulators of vital compartments and elements of standard targets are drawn and their coordinates are determined in the accepted coordinate system; sets of simulators of vital compartments and elements of standard targets with the necessary measuring equipment are installed at the locations of the profiled target wall in sectors; the ammunition is installed so that its longitudinal the axis coincides with the longitudinal axis of the sets of simulators of vital compartments and elements of standard targets, they detonate ammunition, carry out a qualitative and quantitative assessment of the results of the impact of the damaging factors of ammunition on simulators of vital compartments and elements of standard targets, and correlate the test results with the results of mathematical modeling.