RU2595033C1 - Method for determining ammunition fugacity characteristics - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: method of determining characteristics of fugacity of ammunition includes generation of air blast wave (ABW) by means of explosion of ammunition, detecting change in geometrical characteristics of a witness object, subject to action of ABW, and subsequent determination of fugacity characteristics. Witness-object used is a horizontal platform having a layer of deformable material with given mechanical properties. Result of exposure to ABW with subsequent determination of fugacity characteristics is measured by means of video recording and/or by change of penetration characteristics of witness material. Witness material used is deformable material with elastic properties, liquid highly viscous material or irreversibly deformable material. Layer of deformable witness material can be performed in form of an elastic membrane or in form of multiple elastic elements of limited width crossing in centre of platform.

EFFECT: invention increases accuracy of determining shock-wave characteristics of surface explosions.

6 cl, 6 dwg

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, i.e. shock-wave characteristics of the explosion of ammunition at a certain height from the ground.

A known method for determining the explosive explosiveness (EX) according to GOST 4546-81, based on the recording of changes in the geometric characteristics of the witness object exposed to the explosion / 1 /.

In accordance with paragraph 1 of GOST 4546-81 ("Determination of high explosiveness in a lead bomb") a sample of explosives weighing 10.00 ± 0.01 g and a density of 1.00 ± 0.03 g / cm ^{3 is} placed in the channel of the lead bomb together with detonator capsule (CD) or electric detonator (ED). The free space of the canal bomb bombarded with quartz sand without compaction to the level of the upper cut of the canal. The bomb is mounted on a solid base and undermine the charge.

The explosiveness in this method is determined by the difference in the volume of the bomb channel:

ΔV = Vк-Vн,

where Vн is the initial volume of the bomb channel, cm ³ ;

Vк is the volume of the bomb channel after the explosion, cm ³ .

The disadvantages of the method include the following:

1) The method determines only the direct contact action of the charge explosion on the witness object, while with regard to ammunition, one of the damaging factors is the remote action due to the air shock wave (HFW). Those. The method does not actually determine the characteristics of the IWL.

2) The method does not take into account the additional effect of the explosion of CD or ED, the charge mass of which is comparable with the mass of the test explosive.

3) The method does not take into account the energy loss of the explosion during the instant ejection of stemming from the channel of the bomb (uncompressed (!) Quartz sand) and the subsequent free high-speed outflow from the channel of the products of the explosion.

The closest to the proposed invention in terms of technical nature and the achieved result is the method / 2 /, also based on fixing changes in the geometric characteristics of the witness object exposed to the water waves, allowing you to determine the intensity and speed of the waves from a high-speed object flying near the sea surface.

The essence of the method is as follows. An object flying at a supersonic speed without changing the height above the sea surface generates an airborne water wave in the surrounding space. The impact of a shock wave formed by a span over the sea surface of the object causes a decrease in the height of the waves of the ripples of the sea surface, i.e. the formation of radar contrast. The pressure wave impulse acts on the ripples of the sea surface regardless of the angle of incidence, thus changing its local profile with the formation of a trace (surface anomaly) of a certain width, propagating either perpendicularly or along the trajectory of the object. After detecting the track by the radar method, the range to the front of the track and bearings to the front of the track are determined, the width of the track is measured by the radar gating method in range. The course of the object is determined by the spatial orientation of the track. At a known speed of the radar carrier, the length of the electromagnetic wave radiated by the radar, and the slip angle when the sea surface is irradiated with the radar, the speed of the object is calculated using fairly simple mathematical relationships using the parameters obtained.

Then, based on the approximate speed of the object (speed of the wake front) and other classification features, the object is classified and selected from the database of the intensity and speed of the object’s shock wave.

In the description of the prototype method / 2 / it is specifically noted that "the method requires the presence of" portraits "(a database of classification features) of known supersonic low-flying objects: tables with data on the values of the intensities of shock waves, velocities of shock waves and distances from the axis of motion of the object to boundaries of the track formed by the shock wave. Objects that have the same glider, engine and speed will correspond to the same “portrait.” The input data for the “portrait” are various classification features of the object, including the speed of the object. The output of the "portrait" is the intensity and speed of the shock wave of the object. "

The disadvantages of the described method include the following:

1) The need for expensive radar equipment.

2) Because the determination of the characteristics of the IWL from the object is determined at a great distance (kilometers and tens of kilometers), there is great uncertainty when taking into account the properties of the sea surface (ripples) in the controlled area - wave heights, water temperature (affecting the magnitude of the surface tension coefficient at the interface - atmosphere - surface required to determine the characteristics of the HVW), as well as weather conditions - temperature and humidity, also affecting the characteristics of the HLW.

3) By virtue of the foregoing, there is a great difficulty in the experimental accumulation of a database of classification features of objects.

The technical task of the invention is to reduce the cost and simplify the process of testing ammunition, improving the accuracy of determining the shock-wave characteristics of surface explosions, 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 the generation of high-explosive devices by means of an explosive ordnance, recording changes in the geometric characteristics of the witness object exposed to the high-explosive ordnance, and the subsequent determination of the high-explosive characteristics according to the invention as witnesses use a horizontal platform containing a layer of deformable material with specified mechanical characteristics, and the result of exposure IWVI on it with subsequent determination of the characteristics of high explosiveness is recorded by video recording and / or by changing the penetration characteristics of the witness material.

To cover the witness platform, both reversibly deformable (elastic or highly viscous flowing) materials, for example soft rubber, polyurethane foam, bitumen, and irreversibly deformable, for example, such as wet sand, can be used.

Humidification of an irreversibly deformable material will exclude dusting from exposure to the HVW. For moistening, water can also be used, as well as low viscosity adhesive compositions close to it in viscosity, for example, based on polyisobutylene.

Also, the layer of deformable material can be made in the form of an elastic membrane or in the form of several elastic elements of limited width intersecting in the center of the site.

After the test ammunition is blown up at a given height, the WBM, forming above the ground, reaching the surface of the witness site, has a shock-force effect on it, which will result in a change in the initial geometric characteristics, especially noticeable in the region of the explosion epicenter. Because Since the waterfront is spherical, then the deformation of the surface of the witness platform in the epicenter region will manifest itself in the form of a depression, the maximum depth and diameter of which will be determined both by the site material and directly by the pressure at the front of the water shaft. Video recording of the deformation of the witness platform will allow us to determine the speed of movement of the front of the air defense unit over a fixed time interval of changes in the depth and diameter of the depression, and their maximum values recorded will determine the pressure at the front of the water supply shaft.

When using reversibly deformable materials, elastic or highly viscous, for the witness platform, the process of forming a depression on the surface of the witness platform will be carried out practically without changing the density of the materials, followed by self-healing of the original horizontal surface. In this case, it is advisable to use only video recording to record the results of the exposure to the IWL.

When irreversibly deformable materials, such as wet sand, are used for the witness platform, the process of formation of the depression will be accompanied by compaction maximum in the central region of the depression, while maintaining the deformation changes. Therefore, in addition to video recording, it is advisable to use penetration methods in addition to determining the impact of the IWV. The result of comparing the penetration characteristics of the material before and after exposure to the HVW will allow a more accurate determination of the pressure at the front of the HVW. After performing the necessary measurements, the surface of the site can be leveled and restored to its original state by known technical means.

When using the elastic membrane structure of the witness platform or in the form of several elastic elements of limited width intersecting in the center of the site, the final result of the HLW exposure with subsequent determination of its characteristics will be characterized by recorded video recording of the difference in the height of the membrane (or the intersection point of the elastic elements) before and as a result of exposure Wow.

The invention is illustrated by the following graphic information.

In FIG. 1 ... 3 shows the sequence of tests to determine the characteristics of high explosive ordnance located above the earth's surface on a site containing a layer of irreversibly deformable material of a certain thickness.

In FIG. 4 is a cross-sectional view of a depression obtained on an irreversibly deformable material under the influence of an IHV aboveground explosion.

In FIG. 5 shows a variant of a test site witness with a membrane deformable layer, in FIG. 6. with a deformable material in the form of several elastic elements of limited width intersecting in the center of the site.

The proposed method for determining the characteristics of high explosive ordnance is as follows.

The surface of the horizontal measuring platform 1 is covered with a layer of deformed witness material 2 with predetermined mechanical characteristics, video recorders 3 are used to record the explosion process and its effect on the material of the witness platform 3. The test ammunition 4 is placed at a given height h (O is the point of detonation) in such a way so that the epicenter of the explosion (point O ′) is located in the central region of the site 1 (Fig. 1).

The explosion of the tested ammunition 4 at point O, located at a given height h (Fig. 2), generates a spherical IWL, the front of which 5 propagates in space, in particular in the direction to the witness platform, which is shot by several video recorders 3 with visualization of optical heterogeneity, caused by various air densities at the front of the airborne forces and in the surrounding area. This type of survey will make it possible to determine the propagation velocity of water waves based on its results. The site with a layer of witness material 2 and registrars 3 have a common geodetic reference. As additional reference points can be used, for example, the corners of the site. To obtain more accurate results, the survey is conducted from mutually perpendicular angles.

As a result of the action of the HVW, a part of the surface of the witness material 2 is deformed with the formation of a depression 6 (Fig. 3), which is a spherical segment whose diameter D and height H (depth) depend both directly on the pressure at the front of the HVL and on the mechanical characteristics of the material .

If there is a database of experimental data obtained previously when testing model charges with various given mass of explosives and the height of the detonation point, which in the case of aboveground explosions is much simpler than for the objects of the prototype method (above the sea surface), based on the results of video recording of the geometric characteristics of surface deformation witness material is determined by the pressure at the front of the waterjet.

When using an irreversibly deformable material, for example, wet sand, as a witness object, the surface density of the material in the zone of exposure to the HEM (zone A in Fig. 4) at a certain layer thickness δ will be higher than for the material in the "initial" state (zone B in Fig. 4). If there is a database of penetration (or compression) characteristics of the material, the pressure at the front of the HVW is additionally determined by the difference in the penetration characteristics of the material in zones A and B.

In the case of a layer of deformable witness material 1 in the form of an elastic membrane 2 (Fig. 5a), the latter is located at a certain height h ′ relative to the earth's surface. Under the influence of the IWS, the membrane 2 is deformed in such a way that its center "drops" to a height h ′ ′ (Fig. 5b).

A similar effect will be observed during the execution of the deformed witness material 2 in the form of several elastic elements of limited width intersecting in the center of the site (Fig. 6a). Here, the central element of the site is made in the form of a flat figure 7 of a given area. When the IWB acts on the central element 7, the elastic elements undergo tensile deformation, and the element 7 "lowers" to a height h ′ ′ (Fig. 6b).

The pressure at the front of the WBM is determined by the height difference Δh = h′-h ″ recorded by the DVRs 3, using the corresponding database of previously obtained experimental data.

Thus, the proposed method for determining the characteristics of high explosive ordnance does not require expensive radar equipment for its use, it is simpler and more accurate due to the simplification of the set of experimental data bases obtained when testing model charges with different given explosive mass and height of the detonation point for various deformable witness materials.

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 on the surface of test sites.

Information sources

1. GOST 4546-81 Explosives. Methods for determining the explosiveness. - M.: IPK Standards Publishing House, 1998.

2. Patent RU 2466424. A method for determining the speed of a supersonic low-flying object along a track on a sea surface when approaching to meet an object. 07/19/2011 (prototype).

Claims (6)

1. A method for determining the characteristics of the explosive ordnance of an ammunition, including generating an air shock wave (ASW) through an explosion of ammunition, recording changes in the geometric characteristics of a witness object exposed to an ASW, and then determining the explosive characteristics from them, characterized in that the witness object is used a horizontal platform containing a layer of deformable material with predetermined mechanical characteristics, and the result of the action of the HVA on it with the subsequent determination of the characteristics high explosive characteristics are recorded by video recording and / or by changing the penetration characteristics of the witness material. 2. The method according to p. 1, characterized in that as a witness material use a reversibly deformable material with elastic characteristics, for example soft rubber, polyurethane foam, etc. 3. The method according to p. 1, characterized in that as a witness material using a reversibly deformable flowing highly viscous material, such as bitumen. 4. The method according to p. 1, characterized in that as a witness material use an irreversibly deformable material, for example wet sand. 5. The method according to p. 1, characterized in that the layer of deformable witness material is made in the form of an elastic membrane. 6. The method according to p. 1, characterized in that the deformable witness material is made in the form of several elastic elements of limited width intersecting in the center of the site.

Images