RU2242704C1 - Small-sized impact fuse - Google Patents

Abstract

FIELD: fuses, in particular, fuses used in ammunition of various types, for example, grenades, mines of mortar shots and other ammunition.

SUBSTANCE: the impact fuse has a firing mechanism, cocking system, pricking detonating cap, beam detonating cap, detonator and a transfer charge that is made stepped with a tapered transition between the steps, the step that is smaller in diameter is directed towards the pricking detonating cap, and that of a larger diameter - towards the detonator and has a variable density growing from the end face with a smaller surface towards the end face with a larger surface. Cross-pieces are provided between the pricking detonating cap and the transfer charge, they are made for prevention of detonation of the transfer charge at an improper operation of the pricking detonating cap and/or of the beam detonating cap and for provision of transmission of the detonating momentum from the pricking detonating cap at its proper operation.

EFFECT: enhanced sensitivity and reliability of transmission of the detonating momentum at an impact with a light obstacle at low speeds, and safety in use.

5 cl, 5 dwg

Description

The invention relates to fuses, and in particular to fuses used in various types of ammunition, for example, in grenades of grenade launcher rounds, mortar rounds and other ammunition.

Known fuse according to patent No. 2125706, RF, 6 IPC F 42 C 1/06, adopted as a prototype. This fuse includes a percussion mechanism, an ignition mechanism, a long cocking mechanism, a detonator capsule, a self-liquidation mechanism, a detonator and a spherical inertial body mounted in a cavity made in the bottom of the fuse body and having a bottom conical section and a cylindrical section. The detonation pulse is transmitted directly from the detonator capsule to the detonator. However, such a fuse, possessing only an inertial action and not having a reaction one, cannot provide high sensitivity when the munition meets light obstacles, such as, for example, water, snow, a swamp at relatively low speeds (30-50 m / s), which ultimately leads to its failure. An increase in the reaction action of the fuse is associated, however, with a decrease in its operational safety, since there is a possibility of unauthorized operation of the detonator of the fuse due to the proximity of the latter from the percussion mechanism.

The problem to which this invention is directed, is to create a shock fuse that would provide not only high sensitivity and reliable transmission of a detonation pulse when meeting a light obstacle at low speeds, but also safety in operation.

This is achieved by the fact that a small-sized shock fuse includes a percussion mechanism, a cocking system, a detonator capsule, a detonator beam capsule, a detonator, and a transfer charge, which is made stepwise with a conical transition between the steps, the smaller diameter being directed towards the head capsule - detonator, and the larger - towards the detonator, and has a variable density, increasing from the end with a smaller surface to the end with a larger surface. There are jumpers between the detonator capsule detonator and the transfer charge and between the detonator radiation capsule and the detonator, which are designed to prevent detonation of the transfer charge during an emergency operation of the detonator detonator capsule and / or the detonator radiation capsule (in the uninvolved position) and ensure detonation transfer pulse from the detonator capsule during normal operation (in cocked position).

The variable density of the transfer charge can vary in the range from 1.2 g / cm ³ to 1.7 g / cm ³ .

The thickness of the jumper between the detonator cap and the transfer charge is determined, on the one hand, by the need to prevent detonation of the transfer charge during abnormal operation of the cap detonator capsule, and on the other hand, by the possibility of transmitting the detonation pulse from the cap detonator capsule to the transfer charge (in the cocked position) . Depending on the design of the fuse, the thickness of such a jumper may be in the range from 0.2 to 0.4 times the diameter of the smaller stage of the transfer charge.

The thickness of the jumper between the detonator beam and the transfer charge is determined by the need to prevent the detonation of the transfer charge during abnormal operation of the beam detonator capsule and can be in the range from 0.8 to 1.2 of the diameter of the detonator beam capsule.

The introduction of the transfer charge into the fuse allows you to increase the distance between the prism detonator capsule and the detonator and thereby ensure greater fuse safety in operation. Performing a step-shaped transfer charge with a conical transition between the steps, in which the smaller step is directed towards the detonator capsule, increases the distance between the transfer charge and the detonator cap and the transfer charge and the radiation detonator capsule, thereby increasing safety fuse in operation, and the implementation of the transfer charge of variable density, increasing from the end face with a smaller surface to the end face with a larger surface, increases n transmission pulse detonation reliability because the smaller the density of the explosive, the more reliable initiation. In addition, a gradual increase in the explosive density of the transfer charge, together with a gradual transition from a smaller to a larger diameter, increases the reliability of the transmission of the detonation pulse to the detonator.

Jumpers (end and side) between the transfer charge and the detonator capsule and between the transfer charge and the detonator beam prevent the fuse from triggering in an emergency. As the end jumper, a portion of the metal sleeve between the transfer charge and the detonator cap is used, and its thickness is selected from the calculation, on the one hand, to ensure the safety of the fuse during an emergency operation of the cap detonator cap, and on the other hand, based on transfer of the detonation pulse from the detonator capsule to the transfer charge (in the charged state). As a side jumper, a portion of the same sleeve between the transfer charge and the beam detonator capsule can be used. The thickness of this jumper is selected on the basis of ensuring the operational safety of the fuse during abnormal operation of the beam detonator capsule.

Figure 1 shows a longitudinal section of a fuse; figure 2 is a section aa in figure 1; figure 3 is a section bB in figure 1; figure 4 - section bb in figure 2; figure 5 is a cross section GG in figure 4.

A small-sized shock fuse is mounted on a grenade or mortar shot as part of a grenade or mine and other ammunition and consists of a striking mechanism, a cocking system with igniter and centrifugal safety mechanisms, a self-destruction mechanism and a fire chain.

The percussion mechanism is designed to transfer the reaction force of the obstacle to the detonator type detonator capsule, which ensures firing of the fuse chain, and consists of cover 1, rivet 2, cap 3, spring ring 4, two plates 5, supported by a tip 6, preloaded by spring 7, caps 8 and 9, assembled in the liner 10.

The ignition mechanism triggers the long-range cocking mechanism and the self-destruction mechanism and consists of an igniter capsule 11, a spring 12, a sting 13, fixed by punching in the sleeve 14.

The long-cocking mechanism ensures that the fuse is cocked at a predetermined distance from the muzzle section of the grenade launcher and consists of a sleeve 15, a spring 16, a pyrotechnic press fitting 17 and a stopper 18 resting on it, holding the flap 19 with the spring 20 from moving to the firing position. In the shutter 19 is placed detonator capsule 21, which is offset from the tip 6.

The self-destruction mechanism is designed to eliminate the grenade after a predetermined time from the moment of the shot (in case of failure by impact) and consists of a sleeve 14, with a slow-burning composition 22 and an ignition composition 23 pressed into it along the annular track, a detonator beam 24, fixed by punching in sleeve 14.

The centrifugal safety mechanism consists of a pin 25, a spring 26 and a cap 27 located in the sleeve 14.

The firing chain consists of an on-board detonator capsule 21, a transfer charge 28 placed in the sleeve 14 and a detonator 29 fixed with a nut 30.

The mechanisms are placed in the housing 31 on the gaskets 32 and are tightened through the cap 33 with a nut 34.

The caps 3 and 9, as well as the spring ring 4 in the transport position are kept from moving due to the springs 35 and 7.

The transfer charge 28 has a stepped shape with a conical transition 36 from part 37 with a smaller end surface to part 38 with a larger end surface. A jumper 39 is provided between the detonator cap and the transfer charge, and a jumper 40 between the detonator capsule and the transfer charge.

The fuse works as follows. When fired, the igniter capsule 11 under the action of inertia from linear acceleration of the grenade, overcoming the resistance of the spring 12, compresses the latter and impinges on the tip 13. The beam from the fire of the igniter capsule through the groove in the sleeve 14 ignites the pyrotechnic press fitting 17 and the igniter composition 23 of the self-destruction unit. Under the action of inertia from linear acceleration, the caps 3 and 9 and the spring ring 4 overcoming the resistance of the spring 35 and (through the plate 5) the springs 7 lower. The spring ring 4 is opened and locks the cap 3 in the lower position.

In flight, the pin 25 compresses the spring 26 under the action of centrifugal force and disengages from the flap 19. Under the action of the spring 7, the cap 1 with cap 3 through plates 5, cap 9 and spring ring 4 rise up. After combustion of the pyrotechnic press fitting 17 in the sleeve 15, the stopper 18 lowers under the action of the spring 16 and releases the shutter 19, which, under the action of the spring 20, moves to the combat position.

When meeting an obstacle:

a) during the reaction, the cap 1, moving down through the spring ring 4, the caps 3 and 9 and the plate 5 transfers the force of the obstruction to the sting 6, which, overcoming the resistance of the spring 7, pricks the detonator capsule 21. The detonator 21 triggering causes a sequential detonation of the transfer charge 28 and detonator 29,

b) when the inertial action of the liner 10 under the action of inertia forces moves up and transfers the force through the plate 5 to the spring-loaded tip 6, which, dropping down, pricks the detonating capsule detonator 21. The operation of the detonator capsule 21 causes a sequential detonation of the transfer charge 28 and the detonator 29.

In the event that the fuse in the fuse mechanism does not meet when it encounters an obstacle after a predetermined time from the moment of the shot, the composition 22 burns out, from which the radiation detonator capsule 24 is ignited, the operation of which initiates the detonator detonator capsule 21, which leads to the sequential functioning of the transfer charge 28 and detonator 29.

Claims (5)

1. Impact fuse, including a percussion mechanism, a cocking system, a detonator capsule detonator and a detonator, characterized in that it contains a detonator beam capsule and a transfer charge, which is made stepwise with a conical transition between the steps, with a smaller diameter directed towards the head detonator capsule, and the larger one toward the detonator, and has a variable density increasing from the end face with a smaller surface to the end face with a larger surface, while between the detonating capsule detonator and the exact charge between the beam detonator capsule and the transfer charge, there are jumpers made to prevent detonation of the transfer charge during abnormal operation of the detonator cap and / or beam detonator capsule and to ensure the transfer of the detonation pulse from the cap detonator capsule during its normal operation. 2. Impact fuse according to claim 1, characterized in that the density of the transfer charge is in the range from 1.2 to 1.7 g / cm ³ . 3. An impact fuse according to any one of claims 1 and 2, characterized in that the thickness of the end metal bridge between the detonator capsule and the transfer charge is in the range from 0.2 to 0.4 times the diameter of the smaller stage of the transfer charge. 4. Impact fuse according to any one of claims 1 and 2, characterized in that the thickness of the side metal bridge between the transfer charge and the detonator beam capsule is in the range from 0.8 to 1.2 times the diameter of the beam detonator capsule. 5. Impact fuse according to claim 3, characterized in that the thickness of the side metal bridge between the transfer charge and the detonator beam capsule is in the range from 0.8 to 1.2 times the diameter of the beam detonator capsule.

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