RU2351878C2 - Hollow charge - Google Patents

Abstract

FIELD: blasting.

SUBSTANCE: hollow charge comprises body in the form of open shell, explosive placed inside and cladding applied on body open part with relief on surface inverted outside, made of bulges or indents in the form of strips that shape polygons. Claddings are made of different shape in the form of plates, cones, segments, hemispheres with certain ratio between weight of explosive and weight of used cladding.

EFFECT: volume of punch shaped channel is increased without increase of explosive weight and charge caliber, instability of charge action is reduced.

19 cl, 4 tbl, 5 dwg, 6 ex

Description

The invention relates to the field of pulsed action on various condensed matter, namely impact by shock, and can be used to create high pressures on the surfaces of solid and porous bodies, for example, in cumulative perforators during the second opening of formations in production wells, for loading surfaces of volumes filled liquid or multiphase heterogeneous media, creating holes and craters in solid materials, explosive cutting of metals, compaction of solid and porous media, pressing I powder materials, hardening metal cutting, construction and drilling tools, as well as the destruction of material objects.

Known cumulative charge containing a housing with a cumulative recess, the forming surface of which is made with a variable diameter, decreasing from the base to the top of the recess, explosive and cumulative lining, while forming the surface of the cumulative recess of the body is made in the form of a series of cylindrical grooves, and in the particular case forming the surface of the cumulative recess of the housing is made in the form of a series of grooves, which are truncated cones, the vertices of which are directed to the base of the recess (RU 2217686 [1]). The disadvantages of the known cumulative charge are its relatively low efficiency and wide spread of penetration results: for example, in a concrete target with an explosive mass of 20-30 g the channel volume is 30-40 cm ³ , the spread of its geometric parameters (inlet diameter and depth) is about fifteen%.

Known cumulative charge, which contains a metal casing filled with explosive, an intermediate detonator mounted on the end wall of the casing, and a cumulative recess located on the opposite side of the casing with a lining made in the form of a set of ring sections facing its apex towards the detonator (GB N 2271831 [2]). The disadvantages of the known cumulative charge are the relatively low efficiency and instability of the charge.

The closest to the claimed in its technical essence and the achieved result is a cumulative charge, which contains a metal casing filled with explosives, on the front wall of which an intermediate detonator is installed, and on the opposite side of the casing is a cumulative recess with embossed facing facing its apex towards the detonator . The recess lining is made in the form of a set of annular sections, the transverse profile of each of which has the shape of a semi-oval. The invention allows to increase the penetration ability of the jet with almost complete absence of pestle (RU 2193152 [3]).

The disadvantages of the known cumulative charge, as described above, are its relatively low efficiency, which consists in the fact that when it is blown up in the processed medium, a small volume channel or a hole of a small diameter relative to the charge gauge is formed, as well as the instability of its operation.

The inventive cumulative charge is aimed at increasing the volume of the formed channel or the diameter of the punched hole without increasing the mass of the explosive and the caliber of the charge, as well as reducing instability of the charge.

The specified result is achieved in that the cumulative charge contains a body in the form of an open shell, an explosive placed inside it and a lining located in the open part of the body with a relief on the outward facing surface made of protrusions or indentations in the form of strips forming polygons.

The indicated result is also achieved by the fact that at least three disjoint strips are made on the facing surface of the cladding, while the ratio of the distance between the centers of any of the said adjacent strips to the average thickness of the cladding between them differs by no more than 20% from the same indicator for other neighboring stripes. Moreover, all disjoint stripes indicated here must be either protruding or recessed.

The indicated result is also achieved by the fact that the strips are made with a rectangular or trapezoidal cross section.

The indicated result is also achieved by the fact that the strips are made with a semi-oval or sinusoidal cross-section.

The indicated result is also achieved by the fact that the surface of the lining facing the explosive is made with a relief that partially or completely duplicates the relief on the facing surface facing outward.

The specified result is also achieved by the fact that the lining is made of copper or its alloys.

The specified result is also achieved by the fact that the lining is made with a mass of from 80 to 120% of the mass of explosives placed in the housing.

The specified result is also achieved by the fact that the lining is made in the form of a body of revolution.

The specified result is also achieved by the fact that the lining is made in the form of a spherical segment with a solution angle of 141 ° ± 5 °.

The specified result is also achieved by the fact that the lining is made in the form of a cone.

The indicated result is also achieved by the fact that the cladding is made in the form of a straight circular cone, disjoint strips of relief are made in the form of circles, and the stripes intersecting them are made along the generatrices of the cone.

The specified result is also achieved by the fact that the cone is made with a solution angle of 47 ° ± 2 °.

The indicated result is also achieved by the fact that the cone is made with a solution angle of 73 ° ± 3 °.

The specified result is also achieved by the fact that the cone is made with a solution angle of 104 ° ± 4 °.

The specified result is also achieved by the fact that the cone is made with a solution angle of 135 ° ± 5 °.

The specified result is also achieved by the fact that the cone is made with a solution angle of 156 ° ± 6 °.

The execution of a cumulative charge in the form of a charge containing an enclosure from an open shell, an explosive placed inside it and a lining located in the open part of the housing with a relief on the surface facing outward, made of protrusions or indentations in the form of strips forming polygons, can increase the volume of the formed channel or the diameter of the punched hole without increasing the mass of the explosive and the caliber of the charge, and also reduce the instability of the charge. The cladding made with the proposed relief plays the role of a kind of spatial modulator in the path of the high-pressure wave front that occurs at the time of the explosion. As a result, standing waves are formed on the cladding, which reduce spontaneous vibrations, reduce energy dissipation and, ultimately, significantly increase the breakdown ability of a charge.

In theoretical and experimental studies, it was found that with explosive throwing of a relief cladding, chaotic instability and the associated energy dissipation of the explosion are reduced. It was also found that if you create a steady wave growth with a given length, you can not only eliminate the instability, but also obtain the cumulation of the energy and momentum of the cladding in accordance with the specified system of bands and its acceleration by reducing the mass of the front convex fronts of the cladding. Analysis of the dispersion equation showed that the wavelengths - critical, resonant, etc. - are proportional to the average thickness of the corresponding sections of the cladding.

In this regard, it is advisable to carry out at least three disjoint strips on the facing surface of the facing, while the ratio of the distance between the centers of any of the mentioned adjacent strips to the average thickness of the facing between them should differ by no more than 20% from the same indicator for other neighboring strips . The wavelength is specified by either protruding or recessed bands.

The creation of waves due to the relief must be coordinated with the solution of the problem of optimizing throwing of the cladding by an explosion for different optimization criteria. Moreover, in various cases, the creation of strips with a diverse cross section and the execution of different shapes of the front surface of the cladding are required.

Therefore, in special cases of implementation, it is advisable to perform embossed stripes with rectangular, trapezoidal, semi-oval or sinusoidal cross sections.

The execution of the surface of the cladding facing the explosive, with a relief that partially or completely duplicates the relief on the outward facing surface, makes it possible to provide the desired distribution of the thickness of the cladding, which helps to increase the efficiency of the charge.

It is most expedient to perform the lining of copper or its alloys, because of the relatively inexpensive metals, copper has the highest density, which increases the volume of the formed channel or the diameter of the punched hole in steel and other barriers.

It was found that the implementation of the cladding with a mass of 80 to 120% of the mass of the explosive placed in the housing provides an additional increase in penetration due to the fact that, as follows from the solution of model problems, the efficiency of throwing the cladding is closest to 1.

In the most general form, the cladding can be a plate of arbitrary shape (for example, a polygon or an oval with uneven edges, etc.), but the most appropriate is to make the cladding in the form of a body of revolution, for example, a round plate, a spherical segment, part of the ellipsoid of revolution, and t .d. For a body of revolution, the task of obtaining a uniformly deformable cumulative impactor is significantly simplified, while the impulse of the impactor increases.

As the solution to the problem of focusing a spherical segment shows, the greatest momentum is provided at a solution angle of 141 °.

In the case of facing in the form of a straight circular cone, it is advisable to form a relief in such a way that the stripes that do not intersect among themselves pass along the circles, and the stripes intersecting them along the generatrices of the cone.

Calculations and experiments showed that it is most advisable to form a cone when facing in the form of a straight circular cone so that the flat angle at the apex between the two generatrices of the cone lying in the plane passing through its axis is 47 ° ± 2 °, 73 ° ± 3 °, 104 ° ± 4 °, 135 ° ± 5 ° or 156 ° ± 6 °.

As experiments showed, the maximum penetration parameters (diameter of the inlet, bottom diameter of the channel and depth) and the minimum spread of the explosion results are achieved with the above cladding parameters.

The essence of the claimed cumulative charge is illustrated by examples of its implementation and drawings. Figure 1 presents a cross section of one of the possible options for the implementation of the cumulative charge with the lining in the form of a cone; figure 2 shows an embodiment of the cladding in the form of a flat round plate with three strips that do not intersect each other (top view of the outward facing surface and cross section); figure 3 shows the cross-section of the lining in the form of a flat round plate with a smooth surface facing the explosive, and with relief strips of rectangular cross section on the outward facing surface, semi-oval section and with a relief partially or completely duplicating the relief on the outward facing surface; Figures 4 and 5 show embodiments of the facing in the form of circular cones, while the relief not visible from the outside of the cones is highlighted in a lighter gray tone.

Example 1. The cumulative charge in one embodiment (figure 1) contains a housing 1 of arbitrary shape from a suitable structural material, preferably metal. An initiation hole 2 is made in the bottom of the housing; outside the housing around this hole is a fixture 3 for attaching initiation means, for example, a detonating cord. Explosive 4 and a conical lining 5 are placed inside the casing, on the outward facing surface of which there is a relief of protrusions 6 (their examples are shown in FIG. 3) or recesses in the form of strips that, when crossed, form polygons: triangles, quadrangles, pentagons and hexagons. Creating polygons with more than six angles is not practical.

In the extraction of oil and gas, the cumulative charge is used as follows. Several charges with a detonating cord (in the case of the perforator or without it) are lowered into the well and are installed so that they are facing by facing 5 (see figure 1) towards the side of the well. The detonating cord to the explosive 4 is transmitted initiating impulse, providing an undermining of charges. As a result of undermining the charges, the linings are deformed into cumulative impactors, which form holes in the casing and channels in the reservoir around the well.

When testing perforating charges, shots are fired at a set of steel plates, duralumin columns or a standard combined target: a particularly strong concrete column (imitating cement stone and rock), a steel plate 10 mm thick (casing wall), a water layer of 10-20 mm, steel 6-9 mm plate (perforator body wall) and air gap.

Example 2. For experimental verification of the influence of the ratio of the distance between the centers of adjacent strips of relief to the average thickness of the lining between them, a batch of cumulative charges was made. Each charge contained a steel case with a diameter of 48 mm, a length of 50 mm with a shape similar to that shown in figure 1. Inside the case, 25 g of RDX-based explosive was placed. From the side of the open part of the casing, a cladding made of M1 brand copper was pressed into the explosive. The lining was a hollow straight circular cone with a solution angle of 73 °, a base diameter of 43 mm, a height of 29 mm, and a relief on the surface facing outward. The relief was a thickening in the form of four strips 3 mm wide, made in the form of circles, the planes of which were perpendicular to the axis of the cone, and three strips along the generatrices of the cone. The thickness of the lining between the circumferential strips ranged from 0.6 mm to 0.8 mm, and the thickness of the strips was about 0.85 mm. Facing was made as follows. A round-shaped plate was cut out from the sheet blank, the relief described above was formed by cold pressing on it, then a sector was cut to which it was given a conical shape using a mandrel. The shooting of charges was carried out on a set of plates from St.3 10 mm thick. The distance between the charges and the target was 30 mm. The holes obtained in the target were measured using a caliper. The measurement results are summarized in table 1.

Table 1 №№ Sequence numbers of strips from the top to the edge of the cladding The distance between the centers of the strips, mm The average thickness of the lining between the strips, mm The ratio of the specified distance to the specified thickness Channel Options diameter mm depth mm Region No. 1 1-2 7.0 0.60 11.7 20.1 52 2-3 9.0 0.70 12.9 3-4 12.0 0.80 15.0 Region Number 2 1-2 8.0 0.72 11.1 17.6 64 2-3 9.0 0.76 11.8 3-4 11.0 0.78 14.1 Region Number 3 1-2 7.5 0.70 10.7 18.2 62 2-3 9.3 0.75 12,4 3-4 11,2 0.80 14.0 Region Number 4 1-2 8.0 0.75 10.7 17.3 71 2-3 9.2 0.77 11.9 3-4 10.8 0.80 13.5 Region Number 5 1-2 9.0 0.60 15.0 19.2 56 2-3 9,4 0.70 13,4 3-4 9.6 0.80 12.0 Region Number 6 1-2 8.5 0.72 11.8 18.5 one hundred 2-3 9.5 0.78 12,2 3-4 10.0 0.80 12.5 Region Number 7 1-2 8.8 0.65 13.5 20,2 86 2-3 9.5 0.75 12.7 3-4 9.7 0.83 12.1 Region Number 8 1-2 8.6 0.70 12.3 19.0 95 2-3 9.3 0.75 12,4 3-4 10.1 0.82 12.6

Example 3. To determine the optimal ratio of the mass of the lining and the mass of the explosive was made a batch of cumulative charges. Each charge contained a steel case with a diameter of 48 mm, a length of 57 mm with the shape shown in figure 1. From 15 g to 40 g of RDX-based explosive was placed inside the enclosure. The lining was made of M1 copper in the form of a straight circular cone with a 47 ° opening angle, a base diameter of 43 mm, a height of 49 mm, and a relief on the surface facing outward. The relief was a thickening in the form of six strips 2.5 mm wide, made in the form of circles, the planes of which were perpendicular to the axis of the cone, and six strips along the generatrices of the cone. The thickness of the lining between the circumferential strips ranged from 0.6 mm to 0.8 mm, and the thickness of the strips was about 0.85 mm. Shooting experiments were also carried out as described in example 1, their results are summarized in table 2.

table 2 №№ Explosive mass, g Facing weight, g The ratio of the mass of the lining to the mass of the explosive,% Channel Options diameter mm depth mm one fifteen 25 167 14.6 61 2 17 25 147 15,2 65 3 19 25 132 14,4 94 four 21 25 119 15,2 130 5 23 25 109 14.6 150 6 25 25 one hundred 15.7 134 7 28 25 89 16,0 125 8 31 25 81 15.6 126 9 34 25 74 15.0 90 10 37 25 68 14.5 85 eleven 40 25 63 14.2 75

Example 4. An experimental batch of charges was made as described in example 1, with the same amount of explosive 28 g. Facings were made in the form of straight circular cones with different angles of mortar, but with the same base diameters (with the same caliber of charge). The relief on the surface facing outward consisted of disjoint strips made in the form of circles, and strips intersecting them, running along the generatrices of the cone. The experimental results are shown in table 3.

Table 3 №№ The angle of the cone, deg Channel Options diameter mm depth mm one 40 ° 12,2 132 2 43 ° 13.5 110 3 47 ° 15.1 140 four 55 ° 14.5 95 5 72 ° 15.8 122 6 74 ° 16.3 114 7 80 ° 14.5 95 8 90 ° 15.9 82 9 102 ° 17.5 one hundred 10 104 ° 17.0 110 eleven 106 ° 17,2 one hundred 12 115 ° 15.6 84 13 120 ° 15.1 92 fourteen 125 ° 14.5 95 fifteen 132 ° 19.2 84 16 135 ° 20,0 82 17 138 ° 20,2 75 eighteen 144 ° 15,2 85 19 148 ° 14.7 94 twenty 152 ° 17.1 104 21 155 ° 17.7 one hundred 22 158 ° 18,4 95 23 161 ° 18.0 95 24 170 ° 25.6 thirty 25 178 ° (almost flat plate) 31,4 twenty

Example 5. In the charge with the housing described in example 1, a cladding made of a copper sheet in the form of a spherical segment was pressed. On the facing surface facing outward, a relief was made in the form of recessed stripes forming hexagons. The mass of the explosive placed in the case was 22 g, the cladding caliber was 43 mm. The charges were fired at the following combined target: a concrete column of мм110 mm, covered with sand outside, a steel plate 10 mm thick, a water layer of 17 mm, a steel plate of 5 mm and an air gap of 10 mm. The diameter of the hole in the steel plate and the depth of the channel in the concrete column were measured using a caliper; a thickness of 10 mm was added to the obtained depth. The experimental results for facings with different angles of solution of the spherical segment are shown in table 4.

Table 4 №№ The angle of the spherical segment, deg Penetration Parameters diameter mm depth mm one 120 ° 18.2 179 2 130 ° 18.6 172 3 137 ° 20,0 294 four 139 ° 21.5 260 5 141 ° 22.6 242 6 143 ° 23,2 224 7 145 ° 22.0 250 8 160 ° 20,2 150 9 170 ° 19.6 155 10 180 ° (hemisphere) 17.6 192

Example 6. To determine the shape and volume of the channel obtained in the target, the charge was shot at a metal column (duralumin bar ⌀70 mm). The charge consisted of the body shown in FIG. 1, an RDX-based explosive with a mass of 28 g, a conical lining with a 46 ° opening angle, with a relief on the outward facing surface shown in FIG. 4; the distance from the charge to the target was 25 mm. After the actuation of the charge in the duralumin column, a channel was obtained in a shape close to a truncated cone, with an input diameter of 22.5 mm, a depth of 236 mm, and a channel bottom diameter of about 5.8 mm; the channel volume was about 44 cm ³ . In the combined target described in example 4, the same charge created a hole in a steel plate with a diameter of 17.8 mm, a channel in a concrete column with a depth of 410 mm and a bottom diameter of 10 mm; the volume of the channel was over 60 cm ³ .

Claims (19)

1. A cumulative charge containing a body in the form of an open shell, an explosive placed inside it and a lining located in the open part of the body with a relief on the outward facing surface made of strips of protrusions or indentations forming polygons. 2. The cumulative charge according to claim 1, characterized in that at least three protruding non-intersecting strips are made on the facing surface of the cladding, while the ratio of the distance between the centers of any said adjacent strips to the average thickness of the cladding between them differs by no more than 20% of the same indicator for other neighboring bands. 3. The cumulative charge according to claim 1, characterized in that at least three recessed deep non-intersecting strips are made on the facing surface facing outward, while the ratio of the distance between the centers of any of the said adjacent strips to the average thickness of the facing between them differs by no more than 20% of the same indicator for other neighboring bands. 4. The cumulative charge according to claim 1, characterized in that the strip is made with a rectangular cross-section. 5. The cumulative charge according to claim 1, characterized in that the strip is made with a trapezoidal cross section. 6. The cumulative charge according to claim 1, characterized in that the strip is made with a semi-oval cross-section. 7. The cumulative charge according to claim 1, characterized in that the strip is made with a sinusoidal cross section. 8. The cumulative charge according to claim 1, characterized in that the relief facing the explosive surface of the lining is made, partially or completely duplicating the relief on its outward facing surface. 9. The cumulative charge according to claim 1, characterized in that the lining is made of copper or its alloys. 10. The cumulative charge according to claim 1, characterized in that the lining is made with a mass of from 80 to 120% by weight of the explosive placed in the housing. 11. The cumulative charge according to claim 1, characterized in that the lining is made in the form of a body of revolution. 12. The cumulative charge according to claim 1, characterized in that the lining is made in the form of a spherical segment with a solution angle of 141 ° ± 5 °. 13. The cumulative charge according to claim 1, characterized in that the lining is made in the form of a cone. 14. The cumulative charge according to item 13, characterized in that the lining is made in the form of a straight circular cone, the strips of relief that do not intersect with each other are made in the form of circles, and the strips intersecting them are made in the form of the cone. 15. The cumulative charge according to 14, characterized in that the cone is made with a solution angle of 47 ° ± 2 °. 16. The cumulative charge according to 14, characterized in that the cone is made with a solution angle of 73 ° ± 3 °. 17. The cumulative charge according to 14, characterized in that the cone is made with a solution angle of 104 ° ± 4 °. 18. The cumulative charge according to 14, characterized in that the cone is made with a solution angle of 135 ° ± 5 °. 19. The cumulative charge according to 14, characterized in that the cone is made with a solution angle of 156 ° ± 6 °.

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