FI79611C - PROCEDURE WITH REGARD TO ITS MANAGEMENT. - Google Patents

Description

1 79611

Hollow charge with a directed explosive effect Halladdning med riktad sprängverkan

The invention relates to a hollow charge having a directed explosive effect comprising a sheath of the actual charge part, an explosive inserted therein, a metal cone fitted at one end of the sheath and an initiator charge fitted at the other end, and an initial charge sheath. precisely concentric with the cartridge shell and that the initial charge is centered concentric with the cartridge shell and the metal cone so that the common axis of symmetry of the cartridge shell and cone and the axis of symmetry of the initial cartridge form one line as closely as practicable; an inert lens, an so-called non-explosive lens, is arranged between the cartridge part and concentrically with said line. pulp lens, preferably hard, homogeneous wood, wood pulp, plastic or gypsum.

Known cavity charges of this type utilize only either a high-velocity but nearly massless tip jet of a metal cone portion having an impact distance of about 3 to 8 times the caliber of the charge, or a long-acting impact cavity of about 300 to 1000 times the caliber of the charge. is based on either the kinetic energy of the partial cones of the metal cone (e.g. Finnish Patent No. 66988) or the kinetic - ::: energy of a relatively low-velocity mass projectile formed from almost the entire mass of the metal cone (e.g. Finnish Patent No. 66085).

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The object of the invention is to develop a long-acting, single-mass projectile cavity charge so that several different metals can be used as lining material for the explosive cavity and that a high-velocity projectile is formed from almost the entire mass of conical metal used as lining.

To achieve this purpose, the hollow charge according to the invention is characterized in that the shape of the mass lens and the shape, size, number and location of the channels are selected so that the lens aligns the firing front of the explosive beginning and propagating in the initial charge so that it propagates almost in the metal cone. planar, and that, viewed from the direction of the projecting object, the shape of the cone of the hollow charge is selected so that the opening angle of the straight-walled cone on the straight portion of the wall is 155 ° to 175 °.

Due to the large opening angle of the cone and the planar fire or detonation front of the explosive, the angle between the vector describing the direction of the detonation wave and the side of the metal cone is as large as it can be in practice to form the cone into a mass projectile.

The variation limits of the cone angle 155 ° to 175 ° are due to e.g. for the following reasons: - when using highly deformable metals, such as copper, a smaller cone angle can be used, - for less deformable, eg low-carbon steel, a larger cone angle must be used, e.g. due to work hardening during molding.

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The following rule applies: The smaller the cone angle, the greater the relative elongation of the formed projectile, i.e., the ratio, the length of the projectile to the diameter of the projectile, increases.

When the ratio is large enough, a cone made of any metal shrinks into a projectile during the shaping step into two parts, i.e., the skirt portion of the projectile shrinks away from the tip portion.

The cone angle is also affected by the explosive used, mainly its rate of fire or detonation: When using an explosive with a high detonation rate, the cone angle must also be increased.

This hollow charge invention is based on the use of an explosive having a detonation velocity of about 7700 to 8000 m / s.

In the cavity charge according to the invention, the angle between the direction vector of the detonation wave and the side of the cone over the entire cone is about half the cone opening angle, i.e. about 75 ° to 90 °, when in corresponding previously known cavity charges (e.g. Finnish patents 66085 and 66988) , in which region most of the cone mass is located is only about 10 ° to 25 °.

In a preferred embodiment of the invention, the cone of the hollow charge is made of metal, preferably copper, brass or low carbon steel.

In another preferred embodiment of the invention, said straight parallel arbitrary normal explosive thickness has a ratio of explosive and conical metal used to the wall thickness of the cone, and up to 16-25: 1, depending on the metal treatment, when the resulting projectile has a mass m ^ 0.90 x metal cone mass M.

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The angle of encounter of the detonation wave with respect to the cone, in addition to the relationship between the thickness of the explosive charge and the wall thickness of the cone, is of great importance for how high the initial velocity of the formed mass projectile reaches, i.e. how much explosive energy is transferred to the flying projectile. The ideal situation arises when an explosive charge operating on the planar front principle is lined with a straight metal circular plate; then the detonation wave encounters the metal plate over its entire area at an angle of 90 °.

The disc can be provided with the highest possible output speed without breaking the disc; however, the plate cannot form an ammunition, a flying projectile with a stable trajectory and characteristics.

The projectile according to the invention formed from almost the entire mass of the cone can be provided with an initial velocity which is about half the detonation velocity of the explosive used, i.e. in practice about 3000 to 4000 m / s.

The hollow charge according to the invention can be spaced and triggered towards a concrete or steel barrier, a blocked mine shaft, an ice hollow or a frangible wall.

The ability of the hollow charge according to the invention to break obstacles is primarily due to the high impact velocity of the projectile, as well as to almost the entire conical metal molded into the projectile and secondarily to the projectile shape, surface hardness, projectile impact area, etc.

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A mass projectile formed by blasting a formed metal cone is ejected at high speed toward an obstacle to which it penetrates at the moment of impact until the projectile-reduced surface pressure or compressive stress in the projectile no longer exceeds the in the vicinity of.

The invention will become more apparent from the following description and the accompanying drawings, in which: Fig. 1 shows a hollow charge according to the invention seen obliquely from above in the direction of the initial charge, Fig. 2 shows a side sectional view of the hollow charge according to Fig. 1 and Fig. 3 explains a planar hollow

According to Figures 1 and 2, the hollow charge A comprises a jacket 2 of the charge part 1, an explosive 3 arranged inside it, a metal cone 4 arranged at one end of the jacket 2 and an initial charge 5 arranged at the other end.

According to Figures 1 and 2, the initiation charge 5 comprises a jacket 6 of the initiator charge 5, an explosive 7 fitted inside it, a mass lens 8 arranged at one end of the jacket 6 of the initiation charge 5 and an explosive 9 fitted at the other end.

According to Figures 1 and 2, the pulp lens 8 is shaped so that the shape, size, number and location of the channels 10 in the lens 8 are selected so that the detonation wave of the hollow charge A propagates almost planarly after the pulp lens 8 in the actual charge portion 1679611.

The common axis of symmetry of the jacket 6 of the initial charge 5, the mass lens 8 and the detonator 9 forms one line with the common axis of symmetry of the jacket 2 and the cone 4 of the cartridge part 1 as accurately as practicable.

According to Fig. 3, the angle between the directional network D of the detonation wave and the straight side of the metal cone 4 = 2o (/ 2 = 155 ° to 175 ° / 2 (20 (= cone opening angle); in the area of the convex radius r of the cone 4 is 20 (/ 2 </ & <90 °; ts.0f <./ 3 <90 °.

According to Fig. 3, the fire front of the explosive 7 starting from the flash point sp in a ball wave is corrected by an inert mass lens 8 so that the fire front meets the metal cone 4 tip of the hollow charge A cartridge portion 1 after ignition time t1 (tp = 0) and reaches the cone edge portions t2.

Due to the large opening angle 2o <of the cone 4 and the planar correction of the detonation of the explosive 3 facing the cone 4, the time difference dt between the tip part and the skirt part of the cone 4 becomes small.

The time difference dt, the magnitude of which is further influenced by the diameter or caliber of the cavity charge A, is chosen so as to cause the cavity charge A to explode into a mass projectile when the cavity charge A explodes, as shown in I.

By using a large opening angle of 2 <χ and a planarly advancing detonation front, the deformation work required to make a flying, desired? -From of the metal cone of the hollow charge utilizing explosion pressure molding is minimized. 79611 a projectile, a mass projectile that behaves stably during the flight phase, directed in advance to that target.

By minimizing the deformation work, the following advantages can be achieved: (1) the formation of a cone by mass blasting into a mass projectile can be reliably reproduced as a phenomenon, even if there is little manufacturing, raw material, etc. in the cavity charge, its structure. defects, i.e. the probability of mass projectile rupture during the molding phase is low, (2) less malleable metals, such as some brass and steel grades, can be used as the hollow charge cone material, (3) due to the minimization of deformation work, the explosive charge can be relative to the wall thickness of the cone used as the liner.

When the claims of the invention according to Finnish patent No. 66085 state that the ratio of the thickness of the explosive to the thickness of the metal cone at an arbitrary normal is 12: 1, in the structure according to the invention the ratio of explosive thickness S2 to depending on the metal treatment, 16 to 25: 1 when the mass of the resulting projectile m is 0.90 x the mass M of the metal cone (Fig. 3).

The relative increase in the thickness of the explosive relative to the wall thickness of the metal cone means that a significantly higher exit velocity can be obtained for the mass projectile entering the cone 79611 in the cone compared to previous corresponding inventions.

The high flight speed of the projectile gives the hollow charge a better ability than previous previous inventions to break various obstacles and thus provides a considerable improvement e.g. in terms of the efficiencies of the hollow charges used to open blocked or vaulted shafts in mines.

Claims (3)

9,79611 A directional explosive cavity charge (A) comprising a sheath (2) of the actual charge part (1), an explosive (3) embedded therein, a metal cone (4) fitted at one end of the sheath (2) and an initial charge (5) fitted at the other end, and an initial charge (5) a sheath (6), an explosive (7) inserted therein, an explosive (9) fitted to the end of the initial charge (5) so that the detonator (9) of the initial charge (5) is precisely centered in the sheath (6) of the charge (5). and that the initial charge (5) is centered concentric with the shell (2) and the metal cone (4) of the cartridge part (1) so that the common axis of symmetry of the shell (2) and the cone (4) of the cartridge part (1) and the initial cartridge (5) the axis of symmetry forms a single line (/), as closely as practicable, and that an inert lens which is not exploded concentrically with said line (/) is arranged between the detonator (9) of the initial charge (5) and the charge part (1), of p. a pulp lens (8), preferably of hard, homogeneous wood, pulp, plastic or gypsum, characterized in that the shape of the pulp lens (8) and the shape, size, number and location of the channels (10) therein are selected so that the lens (8) ) corrects the fire front of the explosive (7) starting and advancing as a spherical wave in the initiating charge (5) so that it advances almost planar in the actual charge portion (1) containing the metal cone (4) and that the shape of the cone (4) of the hollow charge (A) is selected such that the opening angle (2c? C) of the straight-walled cone on the straight portion of the wall is 155 ° to 175 °. Hollow charge according to Claim 1, characterized in that the cone (4) of the hollow charge (A) is made of metal, preferably copper, brass or low-carbon steel. 10 7961 1 Hollow charge according to Claim 1 or 2, characterized in that the ratio S2 of the thickness s2 of the explosive (3) to the wall thickness s1 of the cone (4) in the straight (/) direction is up to 16 - depending on the explosive (3) and conical metal used 25: 1 when the mass of the resulting projectile m> 0.90 x the mass of the metal cone M. 11 79611