KR900003581Y1 - Impact fuse for any direction of impact - Google Patents

Abstract

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Description

Omni-directional impact sensitive triggers for warhead fuses

1 is a cross-sectional view of the power generation state of the omnidirectional shock-sensitive trigger according to the present invention.

2 is a cross-sectional view showing the shock response and the triggering operation of the device of the present invention,

Figure 2a is an operating state when the axial impact

2b is an operating state diagram when the radial impact occurs.

* Explanation of symbols for main parts of the drawings

10: main body 11: axial guide hole

17: radial guide groove 18: cap

20: submerged assembly 21: axial impact sensitive inertial body

22a: conical projection 23: sinking insertion tube

23b: sinking lock 24: retracting spring

25: sinking 25b: locking slope

26: sinking spring 27: sinking locking ball

30: radial impact sensitive inertia 31: conical groove

The present invention relates to a mechanical shock-sensing trigger device used for fuses of various warheads, in particular, a warhead that is sure to operate even if it is impacted at any angle when the bullet falls to a target, and the structure is simple and reliable. The present invention relates to an omnidirectional impact sensitive trigger device for fuses.

The mechanical impact sensitive percussion device used in fuses of conventional warheads is designed to move axially only by the axial deceleration, and the impact angle is low (less than 10 ^o ). The axial component was so minute that the desired movement (trigger) could not be made sufficiently, resulting in a large incidence of missiles.

In addition, when the bomb hits the target, it is shocked at a very small angle so that a device that can do the desired movement is conceived, but its internal structure is very complicated and lacks reliability, so it cannot be widely applied. There was a problem that was difficult to do.

Therefore, the present invention has been devised to solve these problems, and the wedge principle allows the sinking assembly to carry out forward movement (triggering) against axial shock as well as any angle shock and radial shock. It is to provide an omnidirectional impact-sensitive trigger for warhead fuses.

Another object of the present invention is to ensure the function of the fuse by speeding up the movement speed of the sinking assembly as the first movement, and the sinking is strongly secondary movement by the sinking spring according to the first movement. In addition, its internal structure is simple and reliable, so it can be widely applied, and in particular, it is intended to provide an omnidirectional impact sensitive trigger device for warhead fuses that can be used for high-quality warheads.

Hereinafter, the omnidirectional shock-sensitive percussion device for warhead fuse according to the present invention will be described in detail according to an embodiment shown in the accompanying drawings.

FIG. 1 shows an embodiment of the omnidirectional impact sensitive trigger device according to the present invention, and shows an impact sensitive and pre-powered state.

The forward impact sensitive percussion apparatus according to the present invention, as shown, is composed of a device body 10, the submerged assembly 20 and the radial impact sensitive inertial body 30.

The main body 10 has a single lateral guide hole 11 for guiding the immersion assembly 20 in an axial direction, and has a radial direction in which a radial impact sensitive inertial body 30 is inserted into an upper end thereof. A guide groove 17 is formed, and the radial guide groove 17 is closed by a cap 18 which is screwed on the upper end of the main body 10.

The axial guide hole (11) is a large diameter portion 12 of the upper end in communication with the radial guide groove (7) and a small diameter portion (13) of the lower end opening at the lower end of the main body (10) and these units. It consists of an intermediate portion 14 formed between the small diameter portion 12, 13, the stop step 15 is formed between the large diameter portion 12 and the intermediate portion 14, the intermediate portion 14 and the small diameter portion Between the 13, the spring latch step 16 for retaining the retreat assembly is formed.

On the bottom of the main body 10, a locking ball scattering prevention ring 19 surrounding the small diameter portion 13 is integrally formed.

The submerged assembly 20 has an enlarged head 22 having a conical projection 22a at its upper surface, a submerged insertion hole 23a, and a submerged insertion tube 23 having a lowered submerged locking hole 23b. And an axial shock sensitive inertial body 21 inserted into the axial guide hole 11 of the main body 10 and installed upwardly elastically with the spring assembly 24 for retaining the retracting body, and the sinking insertion of the inertial body 21. It is composed of a sinking 25 inserted into the pipe 23 and installed in the sinking spring 26 downwardly, and a sinking locking ball 27 inserted into the sinking locking hole 23b to lock the sinking 25.

The enlarged head 22 is axially guided in the large-diameter portion 12 of the axial guide hole 11 of the main body 10, the bottom of which is inserted into the sinking assembly retracting spring 24 A spring engaging groove 22b for retreating and maintaining the sinking assembly and a stopping jaw 22c that is caught by the stop step 16 are formed.

The immersion assembly retreat maintenance spring 24 is elastically installed between the spring engaging jaw 16 of the main body 10 and the spring engaging groove 22b to constantly support the axial shock sensitive inertial body 21 at all times. Will be done.

The sinking 25 has a ball 25a and a locking inclined surface 25b formed at the distal end thereof, and in the initial assembly state, the sinking spring 26 is inserted into the sinking insertion hole 23a as shown in FIG. The locking inclined surface 25b is hung on the sinking locking ball 27 inserted into the locking hole 23b so as not to be assembled, and the sinking locking ball 27 is formed in the axial guide hole 11 of the main body 10. The small diameter portion 13 is to be locked by the inner peripheral surface of the cum 25 without being pushed out.

The immersion assembly retreat maintenance spring 24 is a weaker than the immersion spring 26 as having the elastic force of the degree necessary for the immersion assembly 20 to maintain the retracted state (first degree state) at all times, and the immersion spring 26 Reference numeral 26 denotes a strong elastic force necessary to trigger the sink 25.

The radial impact sensitive inertial body 30 has a conical groove 31 corresponding to the upper conical projection 22a of the axially axially sensitive inertial body 21 of the immersion assembly 20 on the bottom thereof, and has an upper surface. Guide portion 32 is formed in contact with the bottom surface of the cap 18 is inserted into the radial guide groove 17 of the main body 10 so that the conical groove 31 of the bottom surface of the sinking assembly 20 It is maintained in close contact with the conical projection 22a.

The omnidirectional shock-sensing trigger device for warhead fuse according to the present invention configured as described above has a submerged assembly 20 on the outer circumferential surface of the rotor 40 having the submerged hole 41 and the primer 42 in the warhead fuse in the assembled state as shown in FIG. The lower end of the axial shock-sensitive inertial body 21 of () is installed in contact with.

In this state, when the warhead is fired, the rotor 40 is slowly rotated, and when a predetermined time elapses, the sinking hole 41 is positioned in a state consistent with the axial direction of the sinking assembly 20 as indicated by the dashed line in FIG. When the warhead impacts the target, the deceleration is applied to the warhead and triggered by the inertial force of the submerged assembly 20 and the radial shock sensitive inertial body 30 regardless of the impact direction.

That is, when the warhead is impacted in the axial direction (orthogonal to the target) as shown in FIG. 2A, the axial impact sensitive inertial body 21 of the submerged assembly 20 is for maintaining the retreat of the submerged assembly by the axial inertia force. Advance against the spring 24.

When the sinking locking ball 27 exits from the small diameter portion 13 of the axial guide hole 11 of the main body 10 as the sinking assembly 20 is advanced, the sinking locking ball 27 is free and sinked. It is pushed laterally by the locking inclined surface 25b of the sink 25 elastically installed by the spring 26, and the sink 25 is momentarily released and the sink 25 is axially moved by the sink spring 26. Strongly contracted at the lower end of the sinking insertion tube 23 of the impact sensitive inertial body 21, triggering the primer 42 through the sinking hole 41 of the rotor 40, and then ignited, and then through the detonating tube, etc. This is to be exploded.

Here, the sinking 25 is a primary movement speed in which the entire sinking assembly 20 moves in the axial direction by the inertial force, and a secondary movement speed that is generated by the successive sinking spring 26 and is moved in the axial direction. It is triggered by the combined high-speed triggering speed, and it becomes possible to exhibit the function of a fuse reliably.

When the next warhead is impacted to the target in the radial direction (horizontal direction with respect to the target), as shown in FIG. 2B, the axial impact sensitive inertial body 21 and the radially impact sensitive inertial body 30 of the sinking assembly 20 are not included. The radial inertial force is applied to each bar, and the axial impact sensitive inertial body 21 does not move in the axial direction only by its own radial inertial force, but the radial impact sensitive inertial body 30 is applied to the semi-radial inertial force. While moving in the radial direction by pushing the inclined surface of the conical projection 22a of the axial impact-sensitive inertial body 21 by the inclined surface of the conical groove 31 formed on the bottom of the radial-impact inertial body 30 The axial impact sensitive inertial body 21 is axially driven by the axial component force in the conical groove 31 and the conical projection 22a for the motion caused by the radial inertial force of the radial impact sensitive inertial body 30. Exercise It is to be performed the above-described trigger accordingly.

In addition, when the warhead is impacted at an arbitrary angle between the axial direction and the radial direction, the axial component force against the inertial force of the axial impact sensitive inertial body 21 and the inertial force of the radial impact sensitive inertial body 30. The triggering operation of the submerged assembly 20 is performed while the axial shock-sensitive inertial body 21 moves in the axial direction by the combined force of.

As described above, according to the present invention, not only the axial shock of the warhead but also the radial shock can be used for the immersion assembly to perform sufficient axial movement and triggering operation in any direction. In the event of impact, the entire assembly will be fired at a high-speed triggering speed, which is the sum of the first movement speed of the immersion caused by the movement in the axial direction and the second movement speed of the immersion by the immersion spring that is continuously performed during the first movement. It can be used for a wide range of warheads because of its simple structure and high reliability.

Claims (1)

A main body 10 having a single axial guide hole 11 and an upper radial guide groove 17 and covered with a radial guide groove 17 by a cap 18, and an axial direction of the main body 10. Submerged 25 in the submerged insertion tube 23 of the axial impact sensitive inertial body 21 inserted into the guide hole 11 and installed resilient upwardly by the retracting holding spring 24 and having the conical projection 22a at the top. Inserted into the sinking spring 26 and installed downwardly resilient and the sinking locking ball (27) in contact with the locking inclined surface (25b) of the sinking 25 in the sinking locking hole (23b) perforated in the lower end of the sinking insertion tube (23). ) And a radial impact sensitive inertial body 30 having a conical groove 31 inserted in the radial guide groove 17 and having a conical groove 31 corresponding to the conical projection 22a at the bottom thereof. Omni-directional impact-sensing trigger for warhead fuse, characterized in that consisting of.