RU134628U1 - EXPLOSION PROTECTIVE MECHANISM - Google Patents

Abstract

1. The safety-actuating mechanism of the fuse, characterized in that it contains an engine with an igniter capsule installed therein, a base, a squeezing nut and a cup, while the igniter capsule is set in alignment with the fire force transmission channel to the moderator or detonating device, and the transmission channel is closed by a cup of injection-molded polyformaldehyde for gas obturation of the igniter capsule during its emergency operation. 2. The safety-actuating mechanism of the fuse according to claim 1, characterized in that the cup is stamped from copper foil with a hole in the bottom with a flat circle of the required thickness made of injection-molded polyformaldehyde inserted inside.

Description

FIELD OF TECHNOLOGY.

This utility model relates to the field of military equipment, namely to the safety-actuating mechanisms of rocket and shell fuses.

BACKGROUND OF THE INVENTION

The use of missiles and shells to destroy various targets is directly related to safety in official circulation and to the reliability of their action in all conditions of combat use (during launch and on the flight path until the long-range cocking of the safety-executive mechanism).

The closest analogue (prototype) is the MRV-U fuse for multiple launch rockets (MRV-U fuse. Service manual. Military Publishing House of the USSR Ministry of Defense, 1973. G-33532, S.3-5).

The safety and actuator mechanism of the MRV-U fuse contains an igniter capsule placed in the engine and a cup of cellulose acetate film placed in the compression nut to transfer the force of fire to the detonating device directly or through a moderator. In the case of spontaneous operation for some reason, the igniter capsule, the resulting gases fill the cavity of the compression nut and, cooling significantly during expansion, are not able to burn the cup and, therefore, penetrate the detonating device. After erection, the engine is installed in a combat position, in which the igniter capsule is aligned with the channel of transmission of the fire beam to the detonating device, closed by a cup. When the ammunition fires, a beam of fire from the igniter capsule burns the cup and is transmitted to the detonating device. The cup should burn without the formation of residues (drops) that impede the transmission of the beam.

The disadvantage of this technical solution is the manufacture of a cup of cellulose acetate film, since this does not allow changing the thickness of the jumper between the igniter caps and the detonating device, which may be required when using various capsules, detonators and fuse designs, such as, for example, in the known small-sized shock fuse according to the patent RF on invention No. 2242704, published on December 20, 2004, IPC F42C 1/04.

The composition of this small-sized shock fuse includes a percussion mechanism, a cocking system, a detonator capsule and a detonator, characterized in that it contains a radiation detonator capsule and a transfer charge, which is made stepwise with a conical transition between the steps, and the smaller step is directed to the side detonating detonator capsule, and a large one toward the detonator, and has a variable density increasing from the end with the detonator and the transfer charge and between the beam detonator capsule and eredatochnym charge jumpers are configured to prevent detonation of the transfer charge in the abnormal actuation nakolnogo blasting cap and / or radiation detonator capsule and ensure the transmission of the detonation impulse from nakolnogo blasting cap in its normal actuation.

As a jumper (end and side) between the transfer charge and the detonator capsule and between the transfer charge and the detonator beam, which prevent the fuse from operating in an emergency, a section of the metal sleeve between the transfer charge and the detonator cap can be used In this case, its thickness is selected from the calculation, on the one hand, to ensure the safety of the fuse in case of abnormal operation of the firing detonator capsule, 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.

Thus, it seems that the use of cellulose acetate film as a material for the production of lintels is not advisable.

The task underlying the present utility model is to create a safety-actuator mechanism for the fuse design, free from these drawbacks inherent in the technical solution representing the prior art.

This problem is solved due to the fact that the fuse safety actuator contains an engine with an igniter capsule installed in it, a base, a compression nut and a cup, while the igniter capsule is set in alignment with the channel for transmitting the force of fire to the moderator or a detonating device, and the transmission channel is closed by a cup of injection molded polyformaldehyde for gas obturation of the igniter caps during its emergency operation or by a stamped cup made of copper foul a rod with a hole with an inserted into the bottom of a flat circle desired thickness of the molding polyacetal.

The technical result of the utility model is that the reliability of operation and the manufacturability of the manufacturing of the safety-actuating mechanism is increased, due to the fact that the cup is made of injection-molded polyformaldehyde or stamped from copper foil with a hole in the bottom with a flat circle of the required thickness made of injection-molded polyformaldehyde inserted inside.

DISCLOSURE OF A USEFUL MODEL.

The utility model is illustrated by a description and an example of practical use.

The essence of the utility model is illustrated by the drawing, where figure 1 shows a General view of the safety-actuating mechanism.

The safety-actuating mechanism comprises an engine 2 with an igniter 6 installed in it, a base 4, a compression nut 3 and a cup 5.

The safety-executive mechanism is installed in the fuse housing 1 for transmitting a beam of fire to the detonating device 8 or moderators 7.

IMPLEMENTATION OF A USEFUL MODEL.

The safety-executive mechanism is as follows.

After the ammunition is launched on the trajectory during flight, fuse 1 is cocked, and the engine 2 moves along the base 4 to the position where the igniter 6 is placed opposite the cup 5. When the igniter 6 is activated, the force of fire breaks through the cup 5 and sets the detonator on fire. 8 or retarders 7. The cup 5 burns without the formation of residues that impede the transfer of fire.

During abnormal operation of the igniter capsule 6 (without arming the safety-actuating mechanism), the gas pressure acts on the cup 5, which closes the fire force transmission channel, since the gas pressure in this case is not enough to break through the cup 5 and burn it.

An experimental batch of the safety-executive mechanism of this design with a cup made of injection-molded polyformaldehyde was made at OJSC Kurganpribor NPO. In 2013, laboratory and testing trials were successfully conducted.

Claims (2)

1. The safety-actuating mechanism of the fuse, characterized in that it contains an engine with an igniter capsule installed in it, a base, a squeezing nut and a cup, while the igniter capsule is set in alignment with the fire force transmission channel to the moderator or detonating device, and the transmission channel is closed by a cup made of injection-molded polyformaldehyde for gas obturation of the igniter capsule during its emergency operation. 2. The safety-actuating mechanism of the fuse according to claim 1, characterized in that the cup is stamped from copper foil with a hole in the bottom with a flat circle of the required thickness of molded polyformaldehyde inserted inside.

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