RU2522740C2 - Method of determining characteristics of fougasseness (versions) - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: group of inventions relates to the field of testing ammunition. When testing the shot of test object is made in the form of a fragment or a miniature model of ammunition from the ballistic installation, its charge is exploded in the given point, the characteristics of the passing air shock wave are recorded, formed when blasting of the test object having at the time of blasting the own speed, and their distribution in the half-space. Using the method of similarity and the obtained coefficients, the characteristics of fougasseness of real ammunition are determined, having the own speed, and their distribution in an infinite space. According to the second embodiment, after placement on the rigid surface of measuring platform of pressure sensors the shot of ammunition from the ballistic installation is made, its charge is exploded in the given point, and the characteristics of the passing air shock wave are recorded, formed when blasting the ammunition. Using the method of similarity, the characteristics of fougasseness of the ammunition are determined, having the own speed, and their distribution in an infinite space.

EFFECT: possibility of experimental determination of the characteristics of fougasseness close to the absolute values when blasting the ammunition having the own flight speed is provided.

2 cl, 1 dwg

Description

The invention relates to a testing technique. The primary area of use is tests for determining the explosive characteristics (amplitude of overpressure and specific impulse of the positive phase of the passing air shock wave (IWV)) during the explosion of ammunition charges, which have their own flight speed, which from certain values has a significant effect on their striking ability.

A known method for determining the characteristics of the explosiveness of stationary explosive charges by undermining them in air at a certain distance from the bounding surface (soil). The characteristics of the air-blast guns are recorded in various directions and at a specified distance from the point of explosion of pressure sensors, the sensitive elements of which can be installed either flush with the surface or at a certain distance from the surface (B.E. Gelfand, M.V. Silnikov. " High-explosive effects of explosions. St. Petersburg, Polygon, 2002).

This method does not allow determining the characteristics of the explosive ordnance of ammunition (BP), which have their own flight speed, in absolute values, since when they are detonated with a sufficiently large number of explosives, secondary WWIs are formed, which, when reflected from the ground surface during propagation, are superimposed on the main signal. Therefore, in this case, the determination of the explosive charge characteristics of the explosive charge of a BP from the recorded dependences AP (t) is carried out in relative values when compared with the explosive charge characteristics obtained by undermining the explosive charge with widely known characteristics under the same conditions.

A known method for determining the characteristics of high explosive charges described in the paper "Small explosive test for estimating the detonation energy of explosives" presented at the 35th international conference "Energetic Materials. Stmcture and Properties", June 29-July 2, 2004, Karlsruhe, Federal Republic of Germany, (http://ict.fraunhofer.de) On a steel plate, a fixed test object (OI) is installed and blown up at a given point in the form of a hemispherical explosive charge. To record the characteristics of a passing IWV and their distribution in half-space, pressure sensors located in radial directions and at a given distance from the point of detonation are used, the sensitive elements of which are located flush with the surface of the measuring field (IP). The method is selected as a prototype.

This method does not allow to determine the characteristics of the explosiveness of a PSU having its own flight speed, since stationary explosive-free explosive charges are detonated.

The invention is directed to creating a method for determining the characteristics of high explosiveness in the event of a PSU detonation in air having its own flight speed. EFFECT: possibility of experimental determination of explosive characteristics close to absolute values when undermining a power supply having its own flight speed.

The problem is solved by implementing a method for determining the characteristics of high explosiveness, which includes, according to the first embodiment, placement on a rigid surface of an IP in radial directions and at specified distances from a given point of detonation at measuring points of pressure sensors, installation of a test object (OI) on the surface of an IP, its undermining a given point, the registration of the characteristics of the passing IWV and their distribution in half-space, in which, unlike the prototype, after placing sensors on a hard surface, the pressure First, they shoot an OI in the form of a fragment or a reduced BP model from a ballistic installation, undermine the charge of a fragment or a reduced BP model at a given point, and record the characteristics of the passing HEW generated by undermining an OI having its own speed at the time of undermining and their distribution in half-space.

The installation of a similar OI in the form of a fragment or a reduced BP model on the surface of the IS after that is done so that the point of undermining its charge coincides with the given point, and its axis of symmetry coincides with the flight path of the OI, the characteristics of the passing ASW resulting from the undermining are compared, the coefficients are determined, characterizing the influence of the intrinsic velocity of an optical element on a change in its high-explosiveness characteristics. Then, a full-scale model of the test PSU is installed on the surface of the IS so that the point of undermining its charge coincides with the specified point of detonation, and its axis of symmetry coincides with the flight path of the OI, a full-scale model of the PSU is undermined with the characteristics of the passing ASW at the measuring points and their distribution in half space . Based on certain coefficients characterizing the influence of the intrinsic velocity of the OI on the change in its explosiveness characteristics, the explosiveness characteristics of a full-scale BP model having doubled mass and intrinsic velocity at the time of detonation are obtained, and their distribution in unlimited space. Then, using the similarity method and the obtained characteristics, they determine the explosiveness characteristics of a real PSU having its own speed and their distribution in unlimited space.

The use of the totality of features according to the first option allows us to determine the explosive characteristics close to absolute values for a BP having its own speed and dimensions that exceed the caliber and mass of missile objects that can be dispersed using existing ballistic installations.

The task of the second option is solved by implementing a method for determining the high-explosiveness characteristics, including placing on a rigid surface of the SP in radial directions and at specified distances from a given point in the measuring points of pressure sensors, detonating the ammunition at a given point, recording the characteristics of the passing ASW and their distribution in a half-space in which, in contrast to the prototype, after placing pressure sensors on a hard surface of an IP, they first shoot a BP from a ballistic installations, undermine its charge at a given point, record the characteristics of a passing IWS formed when a PSU is blown, which has its own speed at the time of blasting, and their distribution in half-space, determine the explosiveness characteristics of a BP having doubled mass and own speed at the moment of blasting, and their distribution in unlimited space, then, using the similarity method, determine the characteristics of the explosiveness of a BP having its own speed, and their distribution in unlimited space.

The use of the entire set of features according to the second variant allows determining the explosive characteristics close to absolute values for a PSU having its own speed and dimensions that do not exceed the caliber and mass of missile objects that can be dispersed using existing ballistic installations.

The invention is illustrated by a figure, which shows a diagram of the implementation of the method.

The invention according to the first embodiment is as follows. An IP having a smooth rigid surface is formed. The surface dimensions of the IP are determined as follows. Each PSU is designed to defeat a certain number of targets, for which the HWA's striking ability is most often known, expressed in terms of the amplitude of the overpressure and the specific impulse of the positive phase. For the investigated BP with an explosive charge elongated or concentrated, using well-known formulas for calculating the overpressure amplitude in the front of the IWB, the duration of the positive phase and the specific impulse of the positive phase, determine the radius R of the region of registration of the dependences of the overpressure amplitude corresponding to the distance from the point of blasting, which implements the defeat parameters of the minimally protected of the considered series of targets (see figure). For explosive charges with cylindrical symmetry, it is sufficient to record the dependences of the excess pressure amplitude on time ΔP (t) in the half-plane of the half-space. On the surface of the transmitter from a given point of detonation, the OI in the radial directions trace measuring rays, in the measuring points (IT) at a given distance from the point of detonation, pressure sensors are installed. At the same time, the sensitive elements of the sensors are placed in the IT flush with the surface of the transmitter and oriented vertically upwards. The position of the IT is determined by the polar radius emanating from the point of detonation, and the angle α, counted from the "zero beam".

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, they provide:

- an increase in the radius of the registration area by a distance L ₁

L ₁ = D _uv1 · τ ₊₁ ,

where D _uv1 is the velocity of propagation of the front of the VUV in the extreme IT of the measuring beam, τ ₊₁ is the duration of the positive phase of the VVV in the extreme IT of the measuring beam;

- the location of the point of detonation from the edge of the surface of the IP at a distance L ₂

L ₂ = Du2 · τ ₊₂ ,

where D _uv2 is the velocity of propagation of the front of the IWB at the measuring beam that is closest to the point of detonation of the IT, τ ₊₃ is the duration of the positive phase of the IWS at the point of closure of the measuring beam of the IT.

They shoot an OI in the form of a fragment or a reduced BP model from a ballistic setup (BU), undermine it above the IS at a given intersection point of the measuring rays and record the parameters of the passing IWV in IT. According to the data obtained, the characteristics of the high explosiveness of the OI in the form of a fragment or a reduced BP model, which has its own velocity at the time of undermining, and their distribution in half-space are determined.

To accelerate the explosive charge to speeds above 2000 m / s, barrel-mounted control units are used. However, their capabilities are limited by the available caliber of the trunks, as well as the masses of missile test objects. This leads to the fact that it is not possible to carry out tests with overclocking of full-scale structures of the explosive power supply charges. Therefore, to solve the problem, in addition to the full-scale model of the PSU or its part, reduced models are used that are developed on the basis of geometric similarity and while maintaining the load factor, or fragments of the PSU.

Taking into account the fact that the barrel of the control unit, depending on its type, is spaced from the horizon surface, as a rule, at distances from 0.8 to 1.2 m, SPs are formed in such a way that the flight path of the UI coincides with the zero beam, and the distance from the axis of the munition to the surface of the UI met the requirement

h≤d

where h is the distance from the axis of the ammunition to the surface of the SP, d is the caliber of the OI, i.e. the height h is chosen to be minimal so that the HLW implemented in this case is close in parameters to the HLW resulting from the explosion of an OI on the surface of an SP.

Then, the OI in the form of a fragment or a reduced BP model is installed over the IS so that the projection of its detonation point on the IP surface coincides with the specified detonation point, the intersection point of the measuring rays, and the axis of symmetry of this OI coincides with the flight path of the OI. Undermine and record the parameters of the passing IWV in IT. Based on the experimental data obtained, the explosive characteristics are determined when a stationary OI is blown up in the form of a fragment or a reduced BP model and their distribution in half space.

Comparison of the characteristics of the high-explosiveness of the OI and their distributions obtained for a stationary OI with its own flight speed. As a result, coefficients are determined that characterize the influence of the intrinsic velocity of the optical radiation on the change in the high-explosiveness characteristics.

A full-scale PSU mock-up is installed on the IP in such a way that its detonation point coincides with the specified detonation point, the intersection point of the measuring rays, and its axis of symmetry coincides with the flight path of the OI. They undermine the charge of a full-scale PSU mockup and register the parameters of the passing IWV in IT and their distribution in half-space. Based on certain coefficients characterizing the influence of the intrinsic velocity of the active element on the change in its explosiveness characteristics, using the similarity method, the explosiveness characteristics of a full-scale BP model having doubled mass and intrinsic velocity at the moment of detonation, and their distribution in unlimited space are determined, and then the explosive characteristics of a full-scale are determined mock BP, having its own speed at the time of undermining, and their distribution in unlimited space.

The invention according to the second embodiment is as follows. Form IP in the same manner as described in the first embodiment.

They shoot an OI in the form of a real PSU from a ballistic installation (BU), detonate it at an SP at a given point of detonation, the point of intersection of the measuring rays, and record the parameters of the passing IWB in IT.

Taking into account the fact that the barrel of the control unit, depending on its type, is spaced from the horizon surface, as a rule, at distances from 0.8 to 1.2 m, the SPs are formed in such a way that the flight path of the PSU coincides with the zero beam and the distance from the axis of the munition to the surface of the SP met the requirement

h≤d

where h is the distance from the axis of the ammunition to the surface of the SP, d is the caliber of the BI, i.e. the height h is chosen to be minimal so that the HLW implemented in this case is close in its parameters to the HLW resulting from the explosion of a PSU on the surface of the SP.

The characteristics of the explosiveness of a PSU having a double mass and its own velocity at the time of blasting, and their distribution in half-space, and then, using the similarity method, determine the characteristics of the explosiveness of a BP having its own velocity at the moment of blasting, and their distribution in unlimited space.

This method was applied in experimental studies and made it possible to determine the explosive characteristics close to absolute values.

This method can be applied to almost all axisymmetric BP forms known today and the explosive materials used in them.

Claims (2)

1. A method for determining the characteristics of a high-explosiveness, including placing on a hard surface of a measuring platform (PI) in radial directions and at specified distances from a given point in the measuring points of pressure sensors, installing a test object (OI) on the surface of the PI, undermining it at a given point, registering the characteristics of the passing air shock wave (HVW) and their distribution in half-space, characterized in that after placing pressure sensors on the hard surface of the IP, they first shoot the OI in the form of of an agent or a reduced model of ammunition (ammunition) from a ballistic installation, undermine its charge at a given point, record the characteristics of a passing IWV, formed when a detonating object having its own speed at the time of detonation, and their distribution in half-space, and installing a similar one in the form of a fragment or after that, a reduced BP model on the surface of the SP is produced so that the point of undermining of its charge coincides with the given point, and its axis of symmetry coincides with the flight path of the OI, the results obtained are compared e of undermining the characteristics of the passing IWB, determine the coefficients characterizing the influence of the intrinsic velocity of the optical element on the change in its high-explosiveness characteristics, then on the surface of the IP, as the optical element, a full-scale model of the test PSU is set so that the point of undermining of its charge coincides with the given point of detonation, and its axis of symmetry with the flight path of the OI, they undermine the full-scale PS model with recording the characteristics of the passing HVW at the measuring points and their distribution in the half-space, on the basis of Using certain coefficients characterizing the influence of the intrinsic velocity of the optical element on the change in its explosiveness characteristics, they obtain the explosiveness characteristics of a full-scale BP model having doubled mass and intrinsic velocity at the moment of detonation, and their distribution in unlimited space, then, using the similarity method and the obtained coefficients, determine the characteristics the explosiveness of a real PSU having its own speed, and their distribution in unlimited space. 2. A method for determining the characteristics of a high-explosiveness, including placing on a hard surface of a measuring platform (PI) in radial directions and at specified distances from a given point in the measuring points of pressure sensors, detonation of ammunition (BP) at a given point, recording the characteristics of a passing air shock wave ) and their distribution in half-space, characterized in that after placing pressure sensors on the hard surface of the IP, they first fire a shot from the ballistic installation, and undermine the point of its charge, the characteristics of the passing IWV formed during the explosion of a power supply unit, having its own speed at the time of detonation, and their distribution in half-space, are determined by the explosive characteristics of a power supply unit having doubled mass and its own speed at the time of detonation, and their distribution in unlimited space, then, using the similarity method, determine the characteristics of the explosiveness of a BP having its own speed, and their distribution in an unlimited space.