RU2373489C1 - Training laboratory to investigate processes of explosion - Google Patents

Abstract

FIELD: blasting jobs.

SUBSTANCE: invention relates to laboratory equipment used in training in theory of explosives, explosion effects and experimental methods of physics of explosion. Proposed laboratory comprises blasting chamber 1 accommodating mount 2 to place thereon or suspend thereto an explosive charge, electric pulse source arranged outside the chamber and electric cable 11 to connect aforesaid source with charge. Aforesaid charge is made from liquid explosive substance 4 representing a mix of liquid oxidiser and combustible filled in metal or non-metal shell 3. It comprises also spark discharger 5 or exploding conductor dipped into liquid explosive 4. Discharger 5 is connected, via high-voltage cable 11, with electric pulse source.

EFFECT: higher safety of experiments.

21 cl, 15 dwg

Description

The invention relates to laboratory equipment used in the study of courses in the theory of explosives (BB), the effects of an explosion, experimental methods of explosion physics.

Known laboratory facilities include laboratory charges of solid explosives equipped with shells, cumulative recesses, etc., an electric detonator capsule (ED), a current source, such as a blasting machine and a conductor connecting the ED with a current source. The explosive charge and ED are usually placed in an armored camera.

The main problems are associated with difficulties in organizing the storage and transportation of explosives and ED, especially in educational institutions. In addition, the use of standard bridge EDs, for example ED No. 8, creates the risk of spontaneous explosions from interference and current leaks, and, if the bridge breaks and, as a result, the bridge ED turns into a spark with an arbitrary spark gap, also spontaneous explosions from static electricity.

The present invention addresses these drawbacks. The technical solution consists in the fact that the solid explosive of the charge is replaced by a liquid explosive, which is a mixture of liquid oxidizing agent and fuel, the detonator capsule is eliminated and replaced by a high-voltage spark gap, and a high-voltage pulse generator is introduced into the laboratory setup.

The technical result is the reduction of financial and organizational costs during the educational process, improving the safety of experiments, eliminating the possibility of unauthorized use of explosives.

Fig.1 is a diagram of a laboratory setup, Fig.2-14 - options for the performance of the charge and spark gap, Fig.15 is a diagram of an optical survey with backlight.

A diagram of the laboratory setup is presented in figure 1. The installation includes an explosive chamber 1, a tripod 2 placed therein for mounting or suspending a charge, a test charge, complete consisting of a shell 3 filled with a liquid explosive mixture (ZhVS) 4 and a spark high-voltage spark gap 5, and a high-voltage pulse generator 6, consisting from a high-voltage rectifier 7, a kilovoltmeter 8, a high-voltage capacitor 9, a discharge key 10. The generator is located outside the chamber and connected to the spark gap by a high-voltage cable 11. The part of the cable located in the chamber is protected from olkov housing 12.

The camera’s additional equipment may include steel screens 13, which protect the camera from fragments, a tripod 14 for installing armor plate 15 in case of demonstration of armor-piercing charges, an optical window 16 with bulletproof glass for high-speed photography of the explosion process, a vacuum pump 17 with a vacuum shutter 18 for pumping air out of the chamber before the explosion.

As a bit key 10 can be used trigatron (monograph "Physics of fast processes", trans. Edited by N.A. Zlatin. "Mir", 1971, vol. I, p.139). When conducting a high-frequency shooting of the explosion process with the SFR-2M camera, a high-voltage pulse is supplied to the ignition trigger electrode directly from the instrument panel.

Recording instrumentation varies depending on the type of explosion action displayed.

Various embodiments of the charge and spark gap are shown in Fig.2-14. The shell can be made of non-conductive material (plastic, glass, cellulose, nitrocellulose (Fig.2-12), and metal (Fig.13, 14). In the first case, the arrester can be made in the form of a separate assembly, inserted into the shell, in the latter case the last option is used. The shell of the charge has the form of a body of revolution or sphere, while the axis of the pair of spark electrodes is either perpendicular to the axis of the body of revolution anywhere along the length of the charge, or the axis of the spark electrodes coincides with the axis of the body of revolution. ervom case the arrangement of electrodes at the bottom of the shell creates the possibility of varying the mass of charge HPLM.

Figure 2 shows the charge intended for the study of detonation fronts and methods for controlling them. The horizontal charge is provided with an end transparent wall 19 and a neck 20 for filling the ZhVS. The spark electrodes 21 are movable, for example, using threads relative to the sheath 3, which provides a shift of the initiation point. Figure 3 presents the charge for demonstration and study of spherical shock waves in the air. The shell 3 charge must be made with a minimum wall thickness to exclude the influence of its fragments on the pressure sensors. In the future, it is possible to manufacture a shell from nanomaterial. For reliable fixation of the spark electrodes in the shell, they can be equipped with flanges 22.

Figure 4 presents the charge for contact loading of the metal plate 23. Spark electrodes are mounted in the cover 24 with the possibility of movement relative to it, which provides a shift of the initiation point along the height of the charge. Figure 5 shows a charge designed to study the propelling ability of the explosive. The determined value is the speed of the metal plate 25. In this circuit, the charge consists of two different compositions of the liquid-fuel mixture, and, as a rule, composition 26, which is in contact with the spark electrodes, has a higher sensitivity.

Figure 6-9 shows various designs of cumulative charges. For more reliable mounting of the electrodes, the shell can be equipped with annular protrusions - external 27 (Fig.6) or internal 28 (Fig.7). The shell 3 can be made in the form of a truncated cone (Fig.8). Figure 9 shows the cumulative charge with a height-adjustable location of the non-conductive lens 29. Figure 10 shows the charge to demonstrate the gas-cumulative effect. 11 shows a charge to demonstrate the process of expansion of the layer of finished striking elements 30.

On Fig shows an example of a demonstration charge explosive wiring. An explosive block with spark initiation is shown for diluting detonation at three points with a leading exit to the midpoint.

Owing to the use of liquid-metal firefighters, the problem of filling bent channels with explosives, which in the case of solid explosives can be very difficult, is easily solved.

Of considerable interest are the demonstration experiments with elongated charges of the liquid-filled metal components placed in glass tubes and flexible tubes made of polyethylene and other materials. These experiments are aimed at demonstrating the effect of models of elongated clearance charges on a plasticine layer simulating soil, the effects of linear charges of separation of panels, charges of emergency opening of volumes, etc.

In the case of charges with metal shells, spark electrodes are placed in insulators 22. Various versions of the arresters are shown in FIGS. 13, 14. FIG. 13 shows a design for a standard fragmentation cylinder according to patent RU 2025646 with detonation input through a screw bottom channel 32. Insulator thickening in the region where the electrodes are located, it provides more stable conditions for the initiation of an explosion. On Fig shows the execution of the arrester in the presence of the so-called "loading" charge 33 for the fragmentation shell of a given crushing 34 with an adjustable depth of immersion of the electrodes in the housing.

As the GHF, for example, mixtures of tetranitromethane with nitromethane, tetranitromethane with nitrobenzene can be used. The characteristics of these mixtures are given in the monograph "Explosion Physics", ed. L.P. Orlenko, ed. 3rd, in 2 volumes, vol. I, p. 413, table 10.9. Extensive experience has been accumulated in the spark initiation of liquid-alcohol-based compounds of tetranitromethane-diesel fuel with a volume ratio of 80:20. The detonation velocity at this ratio is 7320 m / s, the critical diameter is less than 0.5 mm (see V.A. Odintsov. On the existence of a low detonation velocity in a mixture of tetranitromethane - diesel fuel. Journal of Applied Chemistry. T.XXXIV, ANSSR publishing house, 1961, p. 1092). To facilitate operations and reduce leakage of the mixture into the gaps, the mixture was thickened with polymethyl methacrylate in separate experiments.

The pilot plant for two years was used in the educational process of MSTU (then MVTU) them. N.E.Bauman. With its help, laboratory work was carried out on courses in the theory of explosives and experimental methods of explosion physics. The capacitance was 1 μF, the operating voltage was 10 kV, the charging resistance was 1 MΩ, the gap between the electrodes was 1 ± 0.05 mm, and the length of the discharge cable was 500 mm.

Operating voltage is established experimentally. At a voltage of 9 kV, the probability of initiation was 1.0, at a voltage of 8 kV - 0.9. With a further decrease, the probability rapidly decreased and at 7 kV was 0.3. Subsequently, all explosions were carried out at a voltage of 10 kV. In total, more than four hundred detonations were carried out at the installation. Not a single failure was recorded.

Also, experiments were conducted on the initiation of mixtures of nitric acid - dichloroethane 60:40 and nitrogen tetroxide - gasoline (70:30, 80:20). A lower sensitivity of these ZHVS is noted.

Along with the spark initiation of the LAB, initiation using exploding wires or fouls can be used. In the experiments, copper wire and foil 0.05 mm thick were used. The use of this scheme is associated with higher labor costs.

The weight of the liquid-propellant charge varied from 2 to 50 g. The explosions at the first stage were carried out mainly in glass test tubes, and later, in plastic containers, to eliminate the harmful effects of glass dust on the respiratory organs and pollution of laboratory premises.

The installation allows you to easily change the configuration of the charge by changing the shape of the shell or its bottom, as well as changing the position of the initiation point in the explosive charge to demonstrate how to control the explosion.

The explosive charge is made immediately before the experiment from available chemical reagents, which removes the problems of metering, storage and transportation. Eliminates the need to build a bunded storage facility in the school with an alarm and security system.

Safety during laboratory work is significantly increased, since the use of an electric detonator, the most dangerous element of explosive assemblies, is excluded.

It should be noted that for small laboratory charges, the dimensions of detonator capsules are commensurate with the sizes of charges, which will lead to a deviation from the required symmetry, for example, when initiating spherical charges. The spark initiation of the LHF is free from this drawback.

The following is a brief list of the main topics of educational laboratory work carried out at the facility, indicating the measurement methods and the necessary additional equipment:

1. Management of the fronts of the detonation wave. Registration is carried out by an SFR camera in a slot scan mode.

2. The formation and propagation of shock waves in air, water and other media. Registration is carried out by the SFR camera in the mode of slit and single-frame shooting, as well as using piezoelectric and piezoresistive pressure sensors.

3. The contact action of the explosive charge on a thick plate with measurement of the speed of the spall plate using target frames and an electronic decade counter.

4. Determination of the propelling ability of explosives by the method of contact throwing of plates, including meniscus lining, with the measurement of their speed.

5. Determination of thicknesses of homogeneous and multilayer barriers pierced by cumulative charges.

6. Measurement of the backward action of cumulative charges.

7. The effect of gas-cumulative charges.

8. The effect of fragmentation charges, determined by the shield target environment.

9. The effect of explosive wiring and detonation logic elements.

In the case of optical photography with explosive illumination, the charge of the internal air-conditioning device can also be used for the latter. The corresponding circuit is shown in Fig. 7 (includes a charge of the ZhVS backlight 35, exploding wires 36, tube 37, and an electron-optical camera 38).

The front of the air shock wave during the entire time of its propagation through the pipe emits a bright glow that provides illumination of the process in transmitted light. If necessary, the front illumination can also be realized with the help of the charges of the ZhVS.

The use in laboratory work of a liquid-cooled liquid-containing liquid initiating device has another useful aspect. With the appropriate selection of the composition, the explosion products are almost transparent, and the exclusion of the detonator capsule removes the problem of screening the explosion with opaque lead azide decomposition products. This will allow, for example, using optical shooting to demonstrate the process of destruction of the fragmentation shell, the process of formation of the impact nucleus, etc.

The structure of the installation can also include a magnetic pulse thrower powered by the same generator 6. In this case, the installation becomes complex and will allow for a wide range of laboratory work in the physics of explosion and shock.

A description of the magnetic-pulse throwing device is given in the article by K.V. Tatmyshevsky, S. A. Kozlov “Magnetic-pulse throwing devices as means of destruction in active protection systems of objects of special importance”, “Special Technique”, 2005, No. 5.

Literature

1. The effect of weapons and ammunition: a training manual / I.F. Kobylkin, S.V. Ladov, V.A. Odintsov, V.N.Okhitin. Publishing House of MVTU im. N.E.Bauman, 2005.

2. I.F. Kobylkin, V.V. Selivanov, B.C. Soloviev, N.N. Sysoev. Shock and detonation waves. Research Methods. Ed. 2nd, Moscow: Fizmatlit, 2004.

3. Explosion physics, in 2 t / ed. L.P. Orlenko, Moscow: Fizmatlit, 2004.

4. Physics of fast processes. / Ed. N.A. Zlatina. “World”, 1971, vol. I.

Claims (21)

1. An educational laboratory apparatus for studying explosive processes, comprising an explosive chamber, a tripod placed therein for mounting or suspending an explosive charge, an explosive charge, an electric pulse source located outside the chamber, an electric cable connecting the source to the charge, characterized in that the charge is made of a liquid explosive, which is a mixture of a liquid oxidizing agent and fuel, is poured into a metal or nonmetallic shell, equipped with a spark gap or detonates a conductor immersed in a liquid explosive, the spark gap being connected by a high voltage electric cable to an electric pulse source. 2. The installation according to claim 1, characterized in that the liquid explosive substance is a mixture of tetranitromethane-diesel fuel with a volume ratio of 80:20, and this mixture can be thickened with polymethyl methacrylate, as well as a mixture of nitric acid-dichloroethane 60:40 and tetroxide nitrogen gasoline (70:30, 80:20). 3. Installation according to claim 1, characterized in that a trigatron is used as a bit key. 4. Installation according to claim 1, characterized in that it includes a high-speed photo recorder located outside the camera, and the camera is equipped with an optical window. 5. Installation according to claim 1, characterized in that the shell of the charge is made of an electrically conductive material with spark electrodes fixed therein. 6. Installation according to claim 1, characterized in that the axis of the spark electrodes is either perpendicular to the axis of the cylindrical shell, the axis of the electrodes being located anywhere along the length of the charge, or the axis of the spark electrodes coincides with the axis of the cylindrical shell. 7. Installation according to claim 5, characterized in that the shell is provided on the outer or inner side with an annular protrusion in which the spark electrodes are located. 8. Installation according to claim 5, characterized in that the spark electrodes are made with the possibility of their movement along the axis passing through the electrodes, including using a screw pair. 9. Installation according to claim 5, characterized in that the shell of the charge at the end opposite the arrester is equipped with a transparent bottom. 10. Installation according to claim 5, characterized in that the shell of the charge at the end opposite the arrester is equipped with a conical, hemispherical or meniscus cumulative lining. 11. Installation according to claim 10, characterized in that the shell of the cumulative charge is made in the form of a truncated cone. 12. Installation according to claim 10, characterized in that an explosion-proof lens is mounted inside the shell with the ability to move along the axis of the charge. 13. Installation according to claim 5, characterized in that the shell is provided with an axial cavity designed to form a gas-cumulative jet. 14. Installation according to claim 5, characterized in that on the outer surface of the shell of the charge placed a layer of finished damaging elements. 15. The apparatus according to claim 5, characterized in that the charge comprises a detonation wiring unit with cranked or curved channels made therein filled with liquid explosive compositions or a detonation logic unit. 16. Installation according to claim 1, characterized in that the charge is made up of two parts separated by a diaphragm, while the part of the charge in contact with the spark gap is made of a more sensitive explosive. 17. Installation according to claim 1, characterized in that the charge shell is made of metal, and the spark gap is made in the form of a separate assembly with a non-conductive housing (insulator) inserted into the shell. 18. Installation according to claim 1, characterized in that the spark gap electrodes are interconnected by a wire or a strip of foil. 19. Installation according to claim 18, characterized in that it contains a backlight charge for shooting in transmitted light, made of a liquid explosive composition, both charges (main and backlight charge) equipped with exploding wires connected in series, and the backlight charge is placed in pipe mounted along the line of the camera - the main charge. 20. The installation according to claim 1, characterized in that it is made with the following parameter values: capacitor 1 ÷ 1.5 μF, operating voltage 9 ÷ 11 kV, charging resistance 1 ÷ 1.2 MΩ, the gap between the electrodes 1 ± 0.05 mm, the length of the discharge cable is not more than 500 mm. 21. Installation according to claim 1, characterized in that it includes a magnetic pulse thrower powered by a common high-voltage generator.

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