RU2387968C2 - Method for development of air impact wave (versions) - Google Patents

Abstract

FIELD: testing equipment.

SUBSTANCE: invention is related to testing equipment and may be used for tests of, for instance objects and structures for action of air impact waves (AIW), which are executed at large distances in case of intense explosions. According to the first version, method of AIW development includes arrangement of lengthy explosive substance charge along straight line with length L=VxT, where V is speed of sound in air, T is AIW length, with ES running mass that varies along its length, and explosion of charge at any end. Object of exposure is arranged at the side of charge end with lower running mass, at a specified distance from it. According to the second version several lengthy ES charges are arranged at a specified distance from object of exposure with running mass of ES that varies for each charge. Charges are installed along radiuses of circumference at a specified distance from each other, object of exposure is installed in the centre of circumference, ends of charges with lower running mass are arranged at the side of specified circumference centre, and charges explosion is carried out by serial initiation of charges at any end with a specified time of delay for each subsequent charge explosion relative to explosion of the previous one.

EFFECT: simplified testing of objects for direct exposure to AIW, which is carried out at large distances from intense explosions; reduction of ES charge mass and area of alienable territory by 2 orders.

2 cl, 8 dwg

Description

The invention relates to testing equipment and can be used for testing, for example, objects and structures for exposure to air shock waves (HVW), implemented over long distances with powerful explosions.

When explosive charges (explosives) weighing 100-1000 tons (in TNT equivalent) are detonated at a distance of 1 to 9 km, “long” air weak shock waves (ASW) of up to 2 s duration and amplitude up to 2 kPa are realized, the impact of which on various test objects are of scientific and practical interest.

A known method of simulating high pressure, which consists in creating an IWB by detonating an explosive in a detonation chamber connected to the waveguide through a perforated throttle plate. At the end of the waveguide, a plug of several screens can be located, and the cells of each of the screens are made smaller and smaller in the direction of flow (see US patent No. 3495455, IPC G01M 9/00, publ. 17.02.70).

The disadvantage of this method is the difficulty of reproducing HVA, which is realized when explosive charges of 100-1000 tons are blown up at a distance of more than 1 km, since this would require an impact pipe with a length of about 1 km and the need to eliminate air friction against the pipe wall, which is very problematic.

There is a known method of creating an IWV, implemented when an IWV generator is used containing explosive charges located along straight lines with predetermined intervals between charges, with an initiation system that provides undermining of charges with a given time shift. The generator contains flat charges, each of which is symmetrically fixed inside the metal sleeve along its longitudinal axis of symmetry, perpendicular to the generatrix of the side surface of the sleeve and placed along one of the straight lines of charge arrangement (see RF patent No. 2226259, IPC ⁷ F42D 1/00, F42B 3 / 02, publ. March 27, 04, bull. No. 9).

According to the patent, successively with a given algorithm of time delays, several flat charges placed at a given distance from the target are blown up.

The disadvantage of this method of creating an ASW is the impossibility of reproducing an SUV realized when explosive charges of 100-1000 tons are detonated at a distance of more than 1 km.

As a prototype, a well-known method of creating an IWB was chosen, which consists in undermining in an open space a compact explosive charge of a large mass located at a given distance from the target, followed by measuring the parameters of the IWS at various distances (see M.A.Sadovsky “Mechanical actions of air percussion waves according to experimental research. ”Explosion Physics, collection No. 1, published by the USSR Academy of Sciences, 1952).

The disadvantages of this method are the large consumption of materials and complexity, since the detonation of explosive charges weighing 100-1000 tons requires large explosive costs and, accordingly, the alienation of large territories.

The objective of the proposed solution is to create a simple method of reproduction of the IWS, realized when explosive charges of 100-1000 tons are detonated at a distance of more than 1 km.

Effect: simplification of testing of objects for the direct impact of the IWV, implemented at large distances from powerful explosions; a decrease by 2 orders of mass of the explosive charge and the area of the alienated territory.

The task of the first embodiment is solved by the fact that in the method of creating an air shock wave (IWV), which includes placing the explosive charge at a given distance from the target, the charge detonation, in contrast to the prototype, uses an elongated charge of length L = V × T as the explosive charge , where V is the speed of sound in air, T is the duration of the WWI, with the linear mass of explosives varying along its length, the charge is placed along a straight line, it is detonated from any end, and the object of influence is placed from the side of the charge with a lower linear mass.

The problem of the second embodiment is solved by the fact that in the method of creating an air shock wave (IWV), which includes placing the explosive charge at a given distance from the target, the charge detonation, unlike the prototype, places several charges, as the explosive charges use elongated charges with variable along the length for each charge of the linear mass of explosives, which are installed along the radii of the circle at a predetermined distance from each other, an object of influence is placed in the center of the circle, while the ends of the charges with a smaller linear th mass is placed from the side of the center of the indicated circle, and the detonation of charges is carried out by sequential initiation of charges from any end with a given delay time for undermining each subsequent charge relative to the undermining of the previous one.

The placement according to the first embodiment of an elongated explosive charge of length L = V × T, where V is the speed of sound in air, T is the duration of the IWB, along a straight line at a predetermined distance from the object of impact, undermining the charge allows loading the object of impact of the IWB of the required duration.

The use of an elongated charge with a linear mass of explosives varying along its length, detonating it from any end, placing the object of influence on the side of the charge end with a smaller linear mass at a given distance from it allows us to obtain the required (realized at a distance of 1 to 9 km when explosive charges are detonated mass of 100-1000 tons) the amplitude of the positive phase of the HFW ΔP +, the amplitude of the negative phase of the HFW ΔP-, the waveform of the HFW and the point of pressure transition from the positive phase to the negative phase at the location of the target. For example, computational and experimental estimates show that by blasting an elongated charge of ~ 270 m long and an explosive mass of ~ 9700 kg with a linear explosive mass varying along its length at a distance of ~ 100 m from the end of the charge with a lower linear mass, one can obtain a WBM, which is realized at a distance of ~ 5800 m in the explosion of a charge weighing 1000 tons, i.e. the application of this method according to the first embodiment allows to reduce by 2 orders of magnitude the mass of the explosive charge and, accordingly, the alienated area.

Placement according to the second variant at a given distance from the object of influence of several charges, using elongated charges as charges with a linear mass of explosives that can be changed for each charge, installing them along the radii of a circle at a given distance from each other, placing them in the center of the circle of the object of influence, placing the ends of the charges with a smaller linear mass from the center of the specified circle, the implementation of the undermining of charges by sequential initiation from any end with a given delay time undermining each subsequent charge relative to undermining the previous one allows you to get the required amplitude of the IWB by adding air shock waves at the location of the target. For example, by adding the positive amplitude of the signal from undermining the subsequent charge with the negative amplitude of the signal from undermining the previous one, obtain the given amplitude at a given time. For example, computational and experimental estimates show that using 33 elongated charges ~ 27 m long with a linear mass varying along the length of each charge (total mass of explosive charges ~ 2000 kg) at a distance of ~ 25 m from the end of the charges (at the installation site exposure) it is possible to obtain an IWL that is close to being realized at a distance of ~ 5800 m from the center of the blasted charge with a mass of 1000 tons, i.e. the application of the method according to the second embodiment allows to reduce by 500 times the mass of the explosive charge and, accordingly, the alienated area.

The invention is illustrated by drawings and graphs:

- figure 1 shows a General view of the implementation of the method according to the first embodiment;

- figure 2 shows a General view of the implementation of the method according to the second embodiment;

- figure 3 shows the desired waveform from the WAV;

- figure 4 shows the calculated waveform from the VVV when the charge is blown according to the first variant of the method;

- figure 5 shows the calculated waveform from the VVV when undermining the first charge according to the second variant of the method;

- figure 6 shows the calculated waveform from the IWL with a sequential erosion of the first and second charge according to the second variant of the method;

- figure 7 shows the calculated total waveform from the IWL during the sequential erosion of the first and second charges according to the second variant of the method;

- Fig. 8 shows the calculated total waveform from the HVW with a successive detonation of 33 charges according to the second variant of the method.

Preparation for testing according to the first option is performed in the following order. On the site 1 (see figure 1) along a straight line place an elongated explosive charge 2 long

L-V × T,

where V is the speed of sound in air, T is the duration of the VVU required for research (see Fig. 3), with the linear mass of explosives varying along its length, and the object of influence 3 is placed on the side of the end of the charge with a smaller linear mass at a given distance from it . The algorithm for changing the linear mass of the explosive along the length of the charge is chosen by calculation and experimentation from the condition of ensuring the required amplitude of the positive phase of the HVA ΔP ⁺ , the required amplitude of the negative phase of the HVA ΔP ^- , the waveform of the HVA and the pressure transition point from the positive phase to the negative phase. Next, charge 2 is blown from either end by an electric detonator 4. So, for example, to implement the method of creating an IWV, shown in Fig. 3, according to the first embodiment, an elongated charge 2 of ~ 270 m long with a linear mass of explosives varying in length for obtaining the required dependency of the WWW. The HLW obtained by undermining the elongated charge 2 is shown in FIG. 4 and shows satisfactory compliance with the desired HLW (see FIG. 3). Impact object 3 is loaded with an air-blast gun similar to that implemented at a distance of 1 to 9 km when explosive charges of 100-1000 tons are blown up. At the same time, as shown by the calculation and experimental estimates, a 2-order less mass of the explosive charge and, correspondingly, the alienated area are needed.

It should be noted that the experimental verification of the method according to the first embodiment on a charge model ~ 27 m long with a linear mass variable along the length (total explosive mass ~ 10 kg) confirmed the operability of the method and good agreement between the experimental and calculated parameters.

Preparation for testing according to the second option is performed in the following order. On site 1 (see figure 2) along the radii of the circle at a predetermined distance from each other, several elongated charges 2 are installed with a linear mass of explosives that varies in length for each charge. The object of influence 3 is placed in the center of the circle. The ends of the charges with a smaller linear mass are placed from the center of the specified circle at a given distance from it. Then carry out the detonation by sequential initiation using electric detonators 4 charges 2 from any ends with a given delay time for undermining each subsequent charge relative to the undermining of the previous one. Appropriate selection of the number of elongated charges 2 with a variable length for each charge of the linear mass of explosives, their placement and the order of detonation allows you to get the necessary IWL at the location of the target 3. So, for example, for the implementation of the method for creating the IWS shown in Fig. 3, according to the second variant, 33 elongated charges 2 with a length of ~ 27 m with a linear mass of explosives varying in length for each charge and the corresponding blasting order were selected using the calculation and experimental method, which occurs at the installation site of object 3, the addition of the IWS to obtain the desired dependence of the IWS. The addition of the IWL from undermining two elongated charges is shown in FIG. 5, 6 and 7, where the total IWW with the required amplitude at a given time is obtained by adding the negative amplitude of the signal from the explosion of the first charge with the positive amplitude of the signal from the explosion of the second charge. The HLW obtained by adding the HLW from the explosions of all 33 elongated charges 2 is shown in Fig. 8 and shows a satisfactory agreement with the desired HLW (see Fig. 3).

It should be noted that the experimental verification of the method according to the second embodiment on 33 charges ~ 13.5 m long with the linear mass varying along the length of each charge confirmed the operability of the method and good agreement between the experimental and calculated parameters. That is, as noted above, the application of the method according to the second embodiment allows to reduce by 500 times the mass of the explosive charge and, accordingly, the alienated area.

Thus, the application of this method allows to reduce by 2 orders of magnitude the mass of the explosive charge and the alienated area. This greatly simplifies the testing of objects for the direct impact of the IWV, implemented at large distances from powerful explosions.

Claims (2)

1. A method of creating an air shock wave (IWV), comprising placing an explosive charge at a predetermined distance from the target, blasting the charge, characterized in that an elongated charge of length is used as the explosive charge
L = V
where V is the speed of sound in air;
T is the duration of the WBW,
with a linear mass of explosives that varies along its length, the charge is placed along a straight line, and the object of influence is installed on the side of the end of the charge with a smaller linear mass. 2. A method of creating an air shock wave (HVW), including placing an explosive charge at a predetermined distance from the target, blasting the charge, characterized in that several charges are placed at a given distance from the target, and elongated charges with varying lengths are used as explosive charges for each charge of the linear mass of explosives, which are set along the radii of the circle at a given distance from each other, an object of influence is placed in the center of the circle, while the ends of the charges with a smaller linear mass schayut from the center of said circle, and undermining charges carried successive initiating charge with a predetermined time delay detonation of each subsequent charge with respect to previous detonation.

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