RU149123U1 - EXPLOSION FOR CARTRIDGE BATTLE ELEMENT - Google Patents

Abstract

1. A fuse for a cluster warhead containing a housing, a safety system and a percussion mechanism, characterized in that the inertial sleeve of the percussion mechanism has an external annular groove, and in the housing at the level of the annular groove there is a radial groove into which a V-shaped elastic pin is inserted having external bends at the ends, placed in the annular groove of the inertial sleeve of the percussion mechanism and holding the pin in the groove of the body. 2. The fuse according to claim 1, characterized in that the check is made of a spring wire, while the depth and width of the groove in the inertial sleeve of the percussion mechanism and the height of the groove in the body correspond to the thickness of the check, and the width of the groove is equal to the distance between the ends of the bends of the check in the reduced state. . The fuse according to claim 1, characterized in that the groove for the checks in the case is formed by two opposing touching deaf rectangular cavities, the bottom planes of which overlap each other by the thickness of the checks.

Description

The utility model relates to mechanical fuses for military action of cluster elements and can be used mainly in non-rotating ammunition (missiles, air bombs).

Known fuse for cluster cumulative-fragmentation warheads (BE), for example, according to the patent US 4.488.488 F42B 25/02, 12/18/84, in which cocking is carried out by unscrewing the firing pin with an aerodynamic stabilizer in the form of cloth tape, and safety in official use it is provided with a cylindrical check and a V-shaped bracket from the spring tape removed during assembly of the BE. The advantage of this solution is the simplicity of the design. But in this fuse, the safety clip is removed before assembling the cluster munition (CB), while accidentally unscrewing the firing pin and cocking the fuse (the “human factor” is not excluded), which reduces the safety of the KB assembly. In addition, it is necessary to rotate the BE for cocking it, and the long-range cocking time is short, which can lead to BE triggering in the air when they collide at the moment of ejection from the design bureau, and thereby reduce the efficiency, and in some cases, the security of the system.

Known bottom mechanical fuse for BE according to patent RU 2358235, F42C 1/04, 10.23.2007 (adopted as a prototype). Its safety in official handling of the first stage of protection is provided by two screws that are removed during assembly of the design bureau. The first screw is unscrewed after assembling the fuse with the BE, and the second - after connecting the BE group to the bundle before being installed in the KB case through the side technological holes in the BE case. This operation is relatively laborious and not reliable. So, for example, if it is impossible to unscrew (jam) the screw in one of the fuses, it is necessary for safety to re-screw the already removed screws, disassemble the bundle, remove the BE with the damaged screw, and then reassemble the bundle.

The problem solved by this technical proposal is to simplify the design of the fuse and reduce the complexity of the assembly KB.

The technical result is ensured due to the fact that an inertial groove is made in the inertial sleeve of the fuse of the fuse, and a radial groove is inserted in the housing at the level of the groove in the hole, into which a V-shaped elastic pin is inserted with external bends at the ends. These bends are placed in the annular groove of the inertial sleeve and hold the pin in the groove of the housing, and the percussion mechanism from axial movement. The check is made of spring wire, while the depth and width of the groove in the inertial sleeve and the height of the groove in the housing correspond to the thickness of the check, and the width of the groove is equal to the distance between the ends of the bends of the checks in the reduced state. The groove for checks in the housing for technological reasons can be formed by two opposing touching deaf rectangular cavities, the bottom planes of which overlap each other by the thickness of the checks.

The use of an elastic V-shaped check with bends at the ends makes it possible to reduce the laboriousness of manufacturing a fuse (using one simple-to-make check instead of two screws, no need to cut the threads in the case, assembly of the fuse is simplified), and assembly of the design bureau is simplified (check using the technological hook reliably pulled out with one movement of the hand). At the same time, the check ensures safe handling of the fuse and BE. So, for example, a check made of spring wire with a diameter of 0.6 mm with bends of the ends of 1 mm is able to keep the shock mechanism from being pulled out with an axial force of more than 60 kg. With a sufficiently small effort to reduce the bends at the ends of the checks of 0.2-0.3 kg (during assembly), the pulling force of the checks is 4-7 kg, which eliminates its spontaneous loss when exposed to various mechanical loads in circulation and does not cause difficulties for pulling out checks with equipment KB.

The essence of the utility model is illustrated by drawings, which depict:

in FIG. 1 - longitudinal section of the fuse in official circulation;

in FIG. 2 - cross section of the fuse (view of the pin);

in FIG. 3 - view of the check in a free state;

in FIG. 4 - view of the check in a compressed (reduced) position.

In the composition of the KB, the BEs are arranged in such a way that the bottom part with the fuse of one BE is coaxially located in the cavity of the cumulative funnel of the next. The BE chains arranged in a bundle are placed parallel to the KB axis.

In the official position (Fig. 1), the detonator capsule 1 located in the engine 2 is offset relative to the axis of the BE transfer charge and is kept from moving by the inertial sleeve 3 of the impact mechanism, which in turn is held by the bent ends of the V-shaped elastic check 4. the check 4 is placed in the transverse groove of the housing 5, and its bends - in the groove of the inertial sleeve 3 (Fig. 2). The dimensions of the check 4 are made in such a way as to ensure the relations: a≥b, c≥d, where a is the width of the groove under the check, b is the distance between the bends of the check in a compressed state (Fig. 4), c is the height of the groove under the check (Fig. . 1), d is the thickness (wire diameter) of the check. Additionally, in the service position, the engine 2 is blocked, for example, by a hydraulic fuse 6 similarly to the prototype.

After assembling and securing the BE bundle, check 4 is pulled out by hook through the technological holes (the preliminary stage of protection is removed). The inertial sleeve 3 through the belt stabilizer BE (not shown in the figures), mounted on the sleeve 7, is kept from moving by subsequent BEs in the assembled design bureau.

When firing and flying KB, the movement of parts and mechanisms of the fuse does not occur. For a certain period of time before unpacking the design bureau inside it, due to the operation of the gas generator, the necessary gas pressure of a given duration is created and a hydraulic fuse 6 is charged. The first main protection stage is removed. When the BE is emitted from the design bureau under the action of the air flow, a force is created on the aerodynamic stabilizer belt (not shown in the figures) fixed in the shock mechanism sleeve 7, under the influence of which it drops down to the stop with the inertia sleeve 3 shoulder in the nut 8, releasing the engine 2 with the capsule - detonator 1. The second main stage of protection is removed. The engine 2 under the action of the spring 9, overcoming the resistance of the rubber 11 emerging from the hole of the sleeve 10, advances with a given deceleration and becomes the detonator capsule 1 along the axis of the fuse. The fuse is cocked.

When encountering an obstacle, the percussion mechanism in the inertial sleeve 3 under the action of the axial component of the inertial force advances towards the detonator capsule 1, pricks it with a sting 12, causing the fuse to fire. A self-liquidation mechanism can be placed in the cavity of the inertial sleeve 3, which enables the fuse to operate in case of failure of the shock mechanism, similar to the prototype.

The advantages of this fuse are an increased level of its manufacturability and reduced labor intensity of assembly of design bricks.

Claims (3)

1. A fuse for a cluster warhead containing a housing, a safety system and a percussion mechanism, characterized in that the inertial sleeve of the percussion mechanism has an external annular groove, and in the housing at the level of the annular groove there is a radial groove into which a V-shaped elastic pin is inserted having at the ends external limbs placed in the annular groove of the inertial sleeve of the percussion mechanism and holding the pin in the groove of the body. 2. The fuse according to claim 1, characterized in that the check is made of spring wire, while the depth and width of the groove in the inertial sleeve of the percussion mechanism and the height of the groove in the body correspond to the thickness of the check, and the width of the groove is equal to the distance between the ends of the folds of the checks in the reduced state . 3. The fuse according to claim 1, characterized in that the groove for the check in the case is formed by two opposing touching deaf rectangular cavities, the bottom planes of which overlap each other by the thickness of the check.

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