RU2593518C1 - Method for determining ammunition fugacity characteristics - Google Patents

Abstract

FIELD: measuring equipment; test equipment.

SUBSTANCE: invention relates to methods for detecting objects tests heaving action. Method involves arrangement pressure sensors on the surface of the measurement site on the measuring beams, in given directions and at given distances from explosion point, installation of test ammunition at a given point with further blasting or its explosion at a given point during movement recording characteristics of the passing air blast wave in the measurement points. Explosion point is placed over the surface of the measurement site at a given height, at that, several sensors are additionally installed at the blasting height, and ammunition is optionally displaced in vertical direction. Additional sensors are placed at the height of blasting on the measuring beam, which is parallel to one of the ground one, or alternatively linearly at several heights at inclined beam, projection of which coincides with the ground one. Vertical movement of the test ammunition is performed by mortar start.

EFFECT: invention increases accuracy of measurements and range of impact-wave characteristics.

5 cl, 6 dwg, 3 tbl

Description

The invention relates to the field of testing and measuring equipment, and in particular to methods for determining the high-explosive action of test objects.

A known method for determining the high-explosive action of test objects / 1 /, including registration by sensors of an air shock wave (VVV), accompanying the detonation of the object, as follows.

WUVs are recorded by sensors located on the surface of the test site at least three measuring points, in addition to the test control point, an information sensor (for example, a radar station) is installed, having a geodetic reference to the spatial coordinate system of the test site, a beacon is installed on the object (for example, a radar ) include a test object lighthouse and pressure gauges having a transceiver antenna, each connected to a matrix of n sensors located at each measuring point, receive the measuring sensor signals from the beacon of the test object and pressure gauges, process the received signals, determine the spatial coordinates of the test object and pressure gauges on the site, save their computer memory, remove the beacon from the test object, make it detonate, measure the profile and WAV parameters at each measuring point, at the request of the information sensor, transmit readings recorded in the pressure meters to the control point, record the parameter The IWL tracks at each measuring point in the computer memory block form the test document.

The disadvantages of this method are as follows.

1) The method does not stipulate the conditions for the placement of sensors on the measuring site - in the case of the presence of natural barriers on the propagation path of the HVW, a superposition of the “direct” wave and the reflected “side” wave from the obstacle is possible.

2) In the case of a measuring platform with a flat surface, the sensors, along with the direct IWS, also sense directly reflected from the surface, i.e. anyway, a certain “sum” of waves is perceived by the sensor.

3) The method does not provide for determining the high-explosive action of test objects that explode at a certain height above the earth's surface.

4) Finally, complicated, expensive, environmentally unsafe in relation to the personnel and difficult to implement geodetic reference of the charge, sensors and control point to the conditions of the measuring site.

Closest to the proposed invention in terms of technical nature and the achieved result is a method for determining the characteristics of high explosiveness / 2 /, which eliminated a number of disadvantages inherent in the method-analogue.

In order to avoid reflection of the water waves from various obstacles and the superposition of reflected waves on the positive phase of the passing water waves, here the tests are carried out when undermining above the hard surface of the measuring platform.

The method consists in placing on a hard surface of the measuring platform in radial directions and at specified distances from a given detonation point at the measuring points of the pressure sensors, installing the test object on the surface of the measuring platform, detonating it at a given point and recording the characteristics of the passing IWB in half-space. After placing pressure sensors on the hard surface of the test site, the test object is first shot in the form of a fragment or a reduced model of ammunition from a ballistic installation, it is detonated at a given point, and the characteristics of the passing ASW generated when an object is detonated that has its own speed and distribution at the time of undermining in half space.

The installation of a similar test object in the form of a fragment or a reduced model of ammunition on the surface of the site is then carried out so that the point of undermining its charge coincides with the given point, and its axis of symmetry coincides with the flight path, the characteristics of the passing ASW resulting from the detonations are compared, the coefficients are determined, characterizing the influence of the test object’s own speed on the change in its explosiveness characteristics. Then, under the same conditions, a full-scale model of the tested ammunition is undermined by recording the same characteristics, etc. with subsequent processing of the results using the methods of similarity theory.

This method is also not without some drawbacks.

1) In view of the small height of the test object’s detonation over a rigid platform with a high probability of pressure sensors, a seismic shock wave will be perceived along with the ASW.

2) The method does not take into account possible disturbances from a low-flying test object above the measuring platform when recording the characteristics of an air shock wave. Those. there is no free field for the propagation of water waves at the time of undermining. The above disadvantages of the method reduce the accuracy of the measurements and complicate the processing of their results.

3) The complexity of undermining a moving test object at a given point on the measuring platform (the point of intersection of the measuring rays).

4) Lack of registration of the characteristics of the HVW at the height of the blasting.

The technical task of the invention is to increase the accuracy and expand the range of application of the analogue method, by making it possible to determine the shock-wave characteristics of a surface explosion, the source of which is located at a certain height from the ground.

The solution to this problem is achieved by the fact that in the known method for determining the characteristics of the explosive ordnance of the munition, including placing on the surface of the measuring platform on the measuring rays, in predetermined directions and at given distances from the point of detonation of pressure sensors, installing the test ammunition at a given point with subsequent detonation or undermining at a given point during the movement with registration of the characteristics of the passing shock air wave at the measuring points, in accordance with the invention chku undermining positioned above the surface of the measurement platform at a predetermined height and wherein the further adjusted several sensors on detonation height, and if necessary munition displacement is carried out in the vertical direction.

It is advisable to install additional sensors at the height of detonation on a measuring beam parallel to one of the ground ones.

Also, additional sensors can be positioned linearly at different heights on an inclined beam, the projection of which coincides with the ground.

As additional sensors, it is preferable to use sensors with a low drag coefficient (streamlined), the so-called "pencil type".

The vertical movement of the test ammunition can be carried out by means of a mortar launch.

When testing high-explosive ordnance tests of modern ammunition, it is often necessary to experimentally determine the shock-wave characteristics of an explosion, the source of which is located at a certain height from the ground. An air shock wave forming above the ground is reflected from the underlying surface with the formation of a shock wave extending upward from the earth and a Mach wave sliding along the earth's surface. Therefore, the use of only surface sensors to determine the characteristics of an IHF from an aboveground explosion often gives biased results. For an objective assessment of the performance indicators of the tested product under such conditions, in addition to the usual measurements of shock-wave parameters on the surface of the measuring platform, it is necessary to register the dependences of the overpressure on time at a certain height from the ground. This is feasible, as mentioned in the distinguishing features of the proposed technical solution, either by placing additional pressure sensors at the height of the blasting, or linearly at different heights, starting from the height of the blasting. In this case, the location of the sensors either on the same level on a direct measuring beam parallel to one of the ground or on an inclined beam, the projection of which coincides with the ground, will allow you to evaluate and compare the characteristics and the possible impact of the water waves propagating in the direction of the measuring beam, as on ground objects , and those located at a certain height from the earth's surface.

At the same time, overhead sensors with a low coefficient of aerodynamic drag (streamlined) located on the measuring beam will have a minimal effect on the front of the IWB both when it reaches the sensor and then moves in space.

Moving, if necessary, the tested ammunition vertically (for example, using a mortar launch), it will be possible to precisely link the detonation points to the epicenter, to which the used sensors are geodesically tied, which will significantly increase the accuracy of processing the obtained measurement results.

The invention is illustrated by drawings.

In FIG. Figures 1 and 2 show the schemes for conducting tests to determine the characteristics of a high explosive ordnance with different locations of additional elevated sensors.

In FIG. 3 - sample recording signals (voltage U - time t) from the primary pressure transducers installed at the charge level.

In FIG. 4 ... 6 - a comparison of experimental and theoretical results of measurements of the maximum overpressure in the explosion of a charge at various heights.

The proposed method for determining the characteristics of high explosive ordnance is as follows (Fig. 1, 2). The required number of surface (ground) pressure sensors 3 are placed on the surface of the measuring platform 1 on the measuring beams 2 in predetermined directions and at specified distances from the epicenter O ′ O. On the measuring beam 4, located at the height of the detonation point, high-altitude (elevated) sensors 5. FIG. 1 shows the placement of additional sensors 5 at the height of detonation on a measuring beam parallel to one of the ground, in FIG. 2 - inclined, the projection of which coincides with the ground.

The test ammunition 6 is undermined at point O located at a given height h.

The installation of additional sensors and the placement of the tested ammunition at a given point is carried out using a frame metal structure 7, which provides almost free propagation of the shock wave in the air in the measurement zone.

In the event of a detonation of a fixed charge, it is suspended at a point O above the epicenter O ′ on the cable 8. The sensors are attached to the massive element of the metal structure 9 by means of rigid brackets 10.

If it is necessary to test a moving munition, the mortar launcher 11 is placed at the epicenter of detonation — point O ′ with the vertical orientation of the barrel.

Testing of the proposed method with a fixed explosive charge was carried out at the test site of the Federal Research and Design Institute “Geodesy”.

In particular, the spherical charges of bulk TNT with a density of ~ 940 kg / m ³ at various heights from the ground were studied to determine the high-explosive characteristics. The charges had a mass m from 11.15 to 12.54 kg. The initiation of detonation was carried out at the center of symmetry of the charges. The registration of the shock-wave parameters of an air explosion was carried out simultaneously on the surface of the measuring platform and at the height of the charge. Piezotronics RSV Piezotronics 102V and 137 series pressure sensors were used to record the dependence of overpressure on time. The 102V series sensors were installed in the ground plane, and the "pencil" series 137 sensors (streamlined, with a low drag coefficient) were placed so that their sensitive the elements were at the level of the center of the spherical charge.

A sample of recording signals (voltage U - time t) from pressure transducers installed at the charge level is shown in FIG. 3. Here the first and second pressure peaks are clearly visible, corresponding respectively to the arrivals at the registration point of the shock wave coming from the charge and the shock wave reflected from the ground.

, равных 3,58; 2,84 и 2,00 м/кг^1/3, и различных удалений от заряда и от эпицентра взрыва

приведены в таблицах 1…3. В верхней части таблиц представлены данные измерений на уровне расположения заряда, а в нижней части - данные измерений на поверхности земли.The values of the maximum overpressure of the air shock wave Δp _m obtained as a result of the processing of the oscillograms, referred to the ambient pressure p _o , for reduced blast heights

equal to 3.58; 2.84 and 2.00 m / kg ^1/3 , and various distances from the charge and from the epicenter of the explosion

are given in tables 1 ... 3. The upper part of the tables presents the measurement data at the level of the location of the charge, and the lower part presents the measurement data on the surface of the earth.

For clarity, the results obtained are also presented in graphical interpretation - FIG. 4 ... 6. For comparison, the graphs plot theoretical curves corresponding to the MA formula. Sadovsky / 3 / for an explosion on the ground:

where m is the mass of the charge, kg;

r is the distance from the center of the explosion, m;

and also - in an explosion in a limitless atmosphere - the formula obtained by substituting the above formula instead of the value m of the value m / 2.

It can be seen from the graphical dependences that the values of the maximum overpressure obtained during measurements at the level of charge placement lie quite close to the values Δp _m found by the Sadowski formula for an explosion in an unlimited air environment (the maximum discrepancies between them do not exceed the measurement errors).

The results of measuring Δp _m on the surface of the measuring platform show that the smaller the height of the blasting, the higher the amplitude of the air shock wave. So, in the case of a charge explosion at an altitude of 2 m / kg ^{1/3, the} maximum overpressure at distances from the epicenter of the explosion of more than 3.15 m / kg ^1/3 turns out to be larger than Δp _m calculated by the Sadovsky formula for an explosion on the ground.

The proposed method for determining the characteristics of the high explosive ordnance during testing in the case of using a multi-level analog-digital recording system and transmitting signals for processing with has greater accuracy and reliability in determining the parameters of the IWS compared to the prototype method. As statistics are gathered, its use will accelerate the creation of the most automated systems for collecting and processing information about explosive processes that occur during the testing of ammunition. Such systems will have a number of obvious advantages over current ones based on the use of air shock pressure sensors located only on the surface of test sites.

Information sources

1. Patent RU 2519614, F42B 35/00. The method for determining the high-explosive action of the test object. 04/15/2013.

2. Patent RU 2522740, F42B 35/00. Method for determining the characteristics of high explosiveness (options). 07/17/2012 (prototype).

3. Sadovsky M.A. Selected Works. Geophysics and explosion physics. - M .: Nauka, 1999 .-- 335 p.

Claims (5)

1. The method of determining the characteristics of the explosive ordnance of the munition, including placing on the surface of the measuring platform on the measuring beams, in predetermined directions and at specified distances from the point of detonation, pressure sensors, installing the test ammunition at a given point with subsequent detonation or undermining it at a given point during movement recording the characteristics of the passing shock air wave at the measuring points, characterized in that the point of detonation is placed above the surface of the measuring platform at a given height, while additionally installing several sensors at the height of the blasting, and the movement of ammunition, if necessary, is carried out in the vertical direction. 2. The method according to p. 1, characterized in that the additional sensors at the height of the detonation are mounted on the measuring beam parallel to one of the ground. 3. The method according to p. 1, characterized in that the additional sensors are linearly located at several heights on an inclined beam, the projection of which coincides with the ground. 4. The method according to p. 1, characterized in that as additional sensors are used sensors with a low drag coefficient. 5. The method according to p. 1, characterized in that the test ammunition is moved vertically with a mortar launch.

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