JP6634264B2 - EFP warhead - Google Patents

Description

  The present invention relates to an EFP warhead.

  2. Description of the Related Art Conventionally, there has been known an EFP (Explosively Formed Penetrator) warhead including a shell containing explosives and a liner disposed at an opening of the shell. The liner is ejected forward from the opening while deforming to a pointed shape by the explosive energy of the explosive.

  Patent Literature 1 proposes a method in which a grid-like metal tube for accommodating an explosive is disposed in front of a liner so that a mode in which the liner is deformed into a pointed shape and a mode in which the liner is fragmented can be switched. In this method, if the explosive is exploded to remove the grid metal tube, the liner is deformed to a pointed shape, and if the grid metal is left without explosive explosion, the liner is fragmented.

JP 2007-225215 A

  However, the technique of Patent Document 1 has a problem that the structure of the EFP warhead is complicated because the grid-like metal tube is disposed in front of the liner.

  The present invention has been made in view of the above-described problems, and has as its object to provide an EFP warhead capable of breaking a liner into pieces with a simple structure.

  An EFP warhead according to a first aspect includes a shell, a rear explosive, a liner, and a forward explosive. The shell has an opening. The rear explosive is contained in a shell. The liner is located in the opening of the shell. The forward explosive is located opposite the rear explosive with respect to the liner. The forward explosive is remote from the center of the liner when the liner is viewed from the front.

  According to the EFP warhead according to the first aspect, the liner can be fragmented with a simple structure. Further, since the front explosive is separated from the center of the liner, even when the liner is deformed into a pointed shape without being fragmented, it is possible to suppress the front explosive from interfering with the liner.

  An EFP warhead according to a second aspect is related to the first aspect, and includes an initiating section for initiating a rear explosive after a predetermined time has elapsed from the initiating of the front explosive.

  According to the EFP warhead according to the second aspect, the flying angle of the liner can be adjusted with high accuracy.

  An EFP warhead according to a third aspect is according to the first or second aspect, wherein the forward explosive is adjacent to the outer periphery of the liner.

  According to the EFP warhead according to the third aspect, the outer peripheral portion of the liner can be effectively deformed by the detonation wave or the blast of the forward explosive, and the forward explosive can be further prevented from interfering with the liner.

  An EFP warhead according to a fourth aspect is directed to the third aspect, wherein at least a portion of the front explosive faces the outer surface of the liner.

  According to the EFP warhead according to the fourth aspect, the outer peripheral portion of the liner can be more effectively deformed by the detonation wave or the blast of the forward explosive.

  An EFP warhead according to a fifth aspect relates to the third or fourth aspect, wherein the front explosive is disposed along the outer periphery of the liner.

  According to the EFP warhead according to the fifth aspect, the entire outer peripheral portion of the liner can be uniformly deformed by the detonation wave or the blast of the forward explosive, so that the liner can be scattered uniformly.

  An EFP warhead according to a sixth aspect is related to any of the third to fifth aspects, wherein the front explosive is formed in an annular shape.

  According to the EFP warhead according to the sixth aspect, since the front explosives are continuously arranged, the entire outer peripheral portion of the liner can be more uniformly deformed as compared to the case where the explosives are intermittently arranged. As a result, the liner can be scattered more uniformly.

  According to the present invention, it is possible to provide an EFP warhead capable of breaking a liner into pieces with a simple structure.

Sectional view showing the overall configuration of an EFP warhead Side view for explaining the positional relationship of the main configuration of the EFP warhead Front view for explaining the positional relationship of the main components of the EFP warhead Schematic diagram for explaining the flight stable mode Schematic diagram for explaining the fragmentation mode Diagram for explaining the flying angle control method Diagram for explaining the flying angle control method Graph showing relationship between detonation delay time of rear explosive and scattering angle Schematic diagram for explaining an example of use of an EFP warhead Schematic diagram for explaining an example of use of an EFP warhead

(Configuration of EFP warhead 1)
The configuration of the EFP warhead 1 will be described with reference to the drawings. FIG. 1 is a cross-sectional view showing the entire configuration of the EFP warhead 1. FIG. 2 is a side view for explaining the positional relationship of the main components of the EFP warhead 1. FIG. 3 is a front view for explaining the positional relationship of the main components of the EFP warhead 1. In the following description, “front” and “rear” are terms based on the injection direction of the liner 4. “Front” is the injection direction of the liner 4 and “rear” is the opposite of the front.

  The EFP warhead 1 includes a shell 2, a rear explosive 3, a liner 4, a front explosive 5, and a detonating section 6.

  The shell 2 is formed in a cylindrical shape with a bottom (that is, a cup shape). The shell 2 contains a rear explosive 3. The shell 2 is made of a metal member (aluminum and steel) or a resin member.

  The shell 2 has a side wall 21 and a bottom 22. The side wall 21 is formed in a cylindrical shape. In the present embodiment, the side wall 21 is formed in a cylindrical shape centered on the shaft 2b. The side wall 21 has an opening 2a that opens forward. The side wall 21 surrounds the side of the rear explosive 3. The bottom 22 is attached to the rear end of the side wall 21. The bottom part 22 is formed in a plate shape. In the present embodiment, since the side wall 21 is cylindrical, the bottom 22 is formed in a disk shape. The bottom 22 covers the rear of the rear explosive 3.

  The rear explosive 3 is stored in the shell 2. The rear explosive 3 is arranged behind the liner 4. The rear explosive 3 is made of a substance that burns while detonating. As the rear explosive 3, for example, a well-known explosive can be used.

  The liner 4 is disposed in the opening 2 a of the shell 2. The liner 4 is a concave plate member (concave lenticular member) formed in a concave shape toward the rear. In the present embodiment, since the side wall 21 is cylindrical, the liner 4 is formed in a concave disk shape. The liner 4 is made of a material that can be deformed into a pointed shape and that can be fragmented. As such a material, a metal material such as copper, nickel, iron, and tantalum can be used, but is not limited thereto.

  In the present embodiment, the outer peripheral portion of the liner 4 is fixed to the front end of the side wall portion 21 of the shell 2 by the annular bracket 4a, but the liner 4 only needs to be arranged in front of the rear explosive 3, The outer peripheral portion of 4 may not be fixed to the side wall portion 21. Although the liner 4 closes the opening 2a, a gap may be provided between the liner 4 and the side wall 21.

  The front explosive 5 is disposed on the opposite side of the rear explosive 3 with respect to the liner 4. As shown in FIG. 2, in this embodiment, the front explosive 5 is arranged in front of the liner 4. The front explosive 5 faces the outer surface 4 b of the liner 4. The outer edge of the front explosive 5 coincides with the outer edge of the liner 4. However, the front explosive 5 may be arranged outside the liner 4 in the radial direction perpendicular to the axis 2b. That is, the front explosive 5 does not have to overlap the liner 4 in the axial direction parallel to the axis 2b.

  As shown in FIG. 3, the front explosive 5 is separated from the center 4c of the liner 4 in a front view of the liner 4 (that is, in a plan view of the outer surface 4b). That is, the front explosive 5 is separated from the center 4c of the liner 4 in the radial direction as shown in FIG. The center 4c of the liner 4 is the intersection of the axis 2b of the shell 2 and the outer surface 4b of the liner 4.

  The front explosive 5 is preferably adjacent to the outer periphery of the liner 4. The front explosive 5 is preferably arranged along the outer periphery of the liner 4. In the present embodiment, the front explosives 5 are arranged in an annular shape as shown in FIG. The front explosive 5 is housed in an annular hollow holder 5a.

  The front explosive 5 is made of a substance that burns while detonating. As the front explosive 5, for example, a well-known explosive can be used.

  The detonating section 6 detonates the rear explosive 3 and the front explosive 5. The detonating unit 6 includes a rear detonating device 6a, a plurality of front detonating devices 6b, and a detonation control unit 6c. The rear detonator 6a detonates the rear explosive 3 in response to a detonation command (such as energization) from the detonation control unit 6c. Each of the plurality of front detonating devices 6b detonates the front explosive 5 in response to a detonation command (such as energization) from the detonation control unit 6c. The plurality of front detonators 6b are arranged in a circumferential direction about the axis 2b of the shell 2. The plurality of front detonators 6b are preferably arranged symmetrically about the axis 2b of the shell 2.

  The detonation control unit 6c detonates the rear explosive 3 by outputting a detonation command to the rear detonation device 6a. The detonation control unit 6c detonates the front explosive 5 by outputting a detonation command to the plurality of front detonating devices 6b.

  In the present embodiment, the detonation control unit 6c outputs a detonation command only to the rear detonation device 6a in a mode in which the liner 4 is ejected while deforming the liner 4 into a pointed shape (hereinafter, referred to as “flying stable mode”). Detonate rear explosive 3 only. On the other hand, in the mode in which the liner 4 is injected while being fragmented (hereinafter, referred to as “fragmentation mode”), the detonation control unit 6c detonates the rear detonation device 6a after outputting a detonation command to a plurality of front detonation devices 6b. By outputting the command, the front explosive 5 is detonated before the rear explosive 3. At this time, the detonation control unit 6c can adjust the flying angle of the liner 4 by changing the detonation delay time of the rear explosive 3. The adjustment of the flying angle will be described later.

(Flight stable mode)
Next, a flight stabilization mode in which the liner 4 is deformed into a pointed shape will be described. FIG. 4 is a schematic diagram for explaining the flight stable mode.

  In the flight stabilization mode, a detonation command is output only to the rear detonator 6a, and only the rear explosive 3 is detonated. Therefore, the detonation wave generated by the rear explosive 3 propagates to the indented liner 4 in its original shape, so that the liner 4 has a velocity vector that is generally directed toward the axis 2b. As a result, the liner 4 is injected forward while being transformed into a pointed shaped bullet 41.

(Sharding mode)
Next, a fragmentation mode for fragmenting the liner 4 will be described. FIG. 5 is a schematic diagram for explaining the fragmentation mode.

  In the fragmentation mode, the front explosive 5 is detonated before the rear explosive 3 by outputting a detonation command to the plurality of front detonators 6b and then outputting a detonation command to the rear detonation device 6a. Therefore, after the outer peripheral portion of the liner 4 is deformed so as to be depressed rearward by the detonation wave or the blast of the front explosive 5, the detonation wave by the rear explosive 3 propagates to the deformed liner 4, so that the entire liner 4 is provided. , A velocity vector directed outward is generated. As a result, the liner 4 is ejected at a predetermined flying angle ω while expanding and spreading as a whole into a plurality of fragments 42. The flying angle ω is an angle formed by the direction in which the outermost fragment of the fragments 42 is ejected and the axis 2b.

  Here, FIGS. 6 and 7 are diagrams for explaining a method of controlling the scattering angle ω in the fragmentation mode.

  In FIG. 6, it is assumed that the rear explosive 3 is detonated when a time T1 second has elapsed since the front explosive 5 was detonated. When a time T1 second elapses from the detonation of the front explosive 5, the outer peripheral portion of the liner 4 is depressed rearward due to the detonation wave or blast of the front explosive 5. Then, when the detonation wave of the rear explosive 3 propagates to the deformed liner 4, the liner 4 is emitted as a plurality of fragments 42 at the scattering angle ω1.

  In FIG. 7, it is assumed that the rear explosive 3 is detonated when a time T2 (> T1) seconds has elapsed since the front explosive 5 was detonated. After a lapse of time T2 seconds from the detonation of the front explosive 5, the outer peripheral portion of the liner 4 is greatly recessed rearward due to the detonation wave or blast of the front explosive 5. When the detonation wave of the rear explosive 3 propagates to the greatly deformed liner 4, the liner 4 is emitted as a plurality of fragments 42 at a scattering angle ω2 (> ω1).

  As described above, the flying angles of the plurality of fragments 42 can be easily adjusted by changing the detonation delay time T of the rear explosive 3. FIG. 8 is a graph showing the relationship between the detonation delay time T of the rear explosive 3 and the scattering angle ω. FIG. 8 illustrates an example in which the detonation delay time T and the flying angle ω are in a proportional relationship, but the invention is not limited to this.

(Example of using EFP warhead 1)
Next, an example of use of the EFP warhead 1 will be described with reference to the drawings. FIG. 9 is a diagram for explaining the EFP warhead 1 including a warhead. FIG. 10 is a view for explaining the EFP warhead 1 of the warhead release type.

  As shown in FIG. 9A, in the case of the warhead-inclusive type, the EFP warhead 1 is fixed downward, for example, inside a flying object (missile, shell, etc.) 7. As shown in FIG. 9 (b), when the sensor 71 attached to the EFP warhead 1 detects a target during flight, the detonation control unit 6c (see FIG. 1) performs a flight stabilization mode based on the type and position of the target. Or fragmentation mode. When the detonation mode is selected, the detonation control unit 6c sets the scattering angle ω so that the target falls within the range, and determines the detonation delay time T with reference to the graph shown in FIG.

  Then, the detonation control unit 6c detonates the rear explosive 3 when the detonation delay time T elapses from the detonation of the front explosive 5, so that the liner 4 becomes a plurality of fragments 42 as shown in FIG. It is ejected downward at the scattering angle ω. On the other hand, when the flight stabilization mode is selected, the detonation control unit 6c detonates only the rear explosive 3 so that the liner 4 becomes a pointed shaped bullet 41 as shown in FIG. Injected into.

  As shown in FIG. 10A, in the case of the warhead discharge type, the EFP warhead 1 is mounted, for example, downward in a projectile (missile, shell, etc.) 7. As shown in FIG. 10B, the EFP warhead 1 is released from the flying object 7 near the target. As shown in FIG. 10C, the EFP warhead 1 detects a target by the sensor 71 while dropping while being suspended by the parachute 72.

  Then, the detonation control unit 6c selects the flight stable mode or the fragmentation mode based on the type and position of the target. When the fragmentation mode is selected, the detonation control unit 6c sets the scattering angle ω so that the target enters the range, and determines the detonation delay time T with reference to the graph shown in FIG. Then, the detonation control unit 6c detonates the rear explosive 3 when the detonation delay time T elapses from the detonation of the front explosive 5, so that the liner 4 becomes a plurality of fragments 42 as shown in FIG. It is ejected downward at the scattering angle ω. On the other hand, when the flight stabilization mode is selected, the detonation control unit 6c detonates only the rear explosive 3 so that the liner 4 becomes a pointed shaped bullet 41 as shown in FIG. Injected into.

(Characteristic)
(1) The EFP warhead 1 includes a shell 2, a rear explosive 3, a liner 4, and a front explosive 5. The shell 2 has an opening 2a. The rear explosive 3 is stored in the shell 2. The liner 4 is disposed in the opening 2 a of the shell 2. The front explosive 5 is disposed on the opposite side of the rear explosive 3 with respect to the liner 4. The front explosive 5 is apart from the center 4c of the liner 4 when the liner 4 is viewed from the front.

  According to such an EFP warhead 1, the liner 4 can be fragmented with a simple structure. Further, since the front explosive 5 is separated from the center 4c of the liner 4, even when the liner 4 is deformed into a pointed shape without being fragmented, the front explosive 5 is prevented from interfering with the liner 4. it can.

  (2) The detonating section 6 detonates the rear explosive 3 after the explosion delay time T (one example of a predetermined time) elapses from the detonation of the front explosive 5. Therefore, the flying angle ω of the liner 4 can be adjusted with high accuracy.

  (3) The front explosive 5 is adjacent to the outer periphery of the liner 4. Therefore, the outer peripheral portion of the liner 4 can be effectively deformed by the detonation wave or the blast of the front explosive 5, and the front explosive 5 can be further prevented from interfering with the liner 4.

  (4) The front explosive 5 faces the outer surface 4b of the liner 4. Therefore, the outer peripheral portion of the liner 4 can be more effectively deformed by the detonation wave or the blast of the forward explosive 5.

  (5) The front explosive 5 is arranged along the outer periphery of the liner 4. Therefore, the entire outer peripheral portion of the liner 4 can be uniformly deformed by the detonation wave or the blast of the front explosive 5, so that the liner 4 can be scattered uniformly.

  (6) The front explosive 5 is formed in an annular shape. Accordingly, since the front explosives 5 are continuously arranged, the outer peripheral portion of the liner 4 can be more uniformly deformed than in the case where the explosives 5 are intermittently arranged. Can be scattered.

(Other embodiments)
In the above embodiment, the side wall 21 of the shell 2 is cylindrical, but may be polygonal. In this case, the bottom 22 may have a shape corresponding to the shape of the side wall 21.

  In the above embodiment, the liner 4 is a concave plate member, but may be a flat plate member. Even in such a case, the liner 4 can be appropriately fragmented by adjusting the position of the forward explosive 5 and the size of the detonation wave or the blast.

  In the above embodiment, the liner 4 is fixed to the shell 2 by the annular bracket 4 a, but may be placed on the rear explosive 3.

  In the above embodiment, the front explosives 5 are arranged continuously in an annular shape, but may be arranged intermittently. In this case, the front explosives 5 are preferably arranged at equal intervals in the circumferential direction around the axis 2b of the shell 2.

  In the above embodiment, the entire front explosive 5 is opposed to the outer surface 4b of the liner 4. However, only a part of the front explosive 5 may be opposed to the outer surface 4b of the liner 4, or the front explosive 5 It does not have to face the outer surface 4b of the liner 4.

  Although not particularly mentioned in the above embodiment, when the detonation control unit 6 selects the flight stable mode, the front explosive 5 may be retracted from the front of the shell 2. Further, when the detonation control unit 6 selects the fragmentation mode, the front explosive 5 may be moved in front of the shell 2. Thereby, it is possible to further suppress the pointed shaped bullet 41 from interfering with the front explosive 5.

  In the above embodiment, the detonation control unit 6c calculates the detonation delay time T based on the detected target position, but the detonation delay time T may be a fixed value (predetermined value).

DESCRIPTION OF SYMBOLS 1 EFP warhead 2 Shell 2a Opening 2b Shaft 3 Rear explosive 4 Liner 4a Annular bracket 4b Outer surface 4c Center 41 Molded bullet 42 Fragment 5 Front explosive 6 Explosive part

Claims (6)

A shell with an opening;
A rear explosive contained in the shell;
A liner disposed in the opening of the shell;
A forward explosive disposed opposite the rear explosive with respect to the liner;
A fragmentation mode in which the rear explosive is detonated after a predetermined time has elapsed from the detonation of the front explosive, and a detonation unit that injects the liner by selecting one of the flight stabilization modes in which only the rear explosive is detonated,
With
The front explosive is separated from a center of the liner in a front view of the liner,
EFP warhead. The detonation unit, based on the type and position of the target, selects one of the flight stable mode and the fragmentation mode,
An EFP warhead according to claim 1. The front explosive is adjacent to an outer periphery of the liner;
An EFP warhead according to claim 1 or 2. At least a portion of the front explosive opposes an outer surface of the liner;
An EFP warhead according to claim 3. The front explosive is disposed along an outer periphery of the liner;
An EFP warhead according to claim 3 or claim 4. The front explosive is formed in an annular shape,
An EFP warhead according to any one of claims 3 to 5.

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