RU55120U1 - HEAD BLASTER - Google Patents

Abstract

The utility model relates to the field of ammunition, and more specifically to shock fuses that fire when they meet an obstacle. The fuse contains a long-range cocking safety mechanism that holds the transverse gate valve in position when the detonator capsule installed in it is offset from the fire chain, where an actuating detonator is mounted that initiates filling of the munition, while the safety mechanism includes a loaded spring stop, kinematically connected to the gate valve and based on a pyrotechnic checker, which, through distributed pyro-receiving communication channels, communicates with the ignition unit Change. What is new is that the stopper piece is made of puff from slag compositions, and the pressing density of the upper layer is chosen to be higher than the density of the pressing of the lower layer, with which communication channels filled with the pyrotechnic composition directly located at a height of one third of the diameter of the block from the layer boundary are directly connected. and at the bottom end of the checkerboard there is a central recess adequate to the support part of the stopper, the diameter of which is 1 / 3-1 / 2 of the diameter of the checker. The proposed technical solution increased the accuracy of operation of the long-range cocking mechanism of a universal fuse in a narrow range of a flight distance of 30–40 m, and for small-caliber ammunition having a speed of encounter with an obstacle of 30–50 m / s, it was achieved for the first time.

Description

The utility model relates to the field of ammunition, and more specifically, to shock detonators that fire when they meet an obstacle, and can be used for small-caliber shots having a speed of encounter with an obstacle of 30-50 m / s, mainly grenade launchers.

Pyrotechnic fuses are often used to ensure the required long-range firing of fuses, after burning out after a certain time the composition of which the stopper of the fire gate of the fire chain is introduced into the slags of the burnt compound by the action of a spring. In pyrotechnic fuses, both slag (slag mass is 80-95% of the initial mass) and slag-free (slag mass - up to 5%) pyrotechnic compositions are used.

When using non-slag compositions, the diameter of the support part of the stopper rod is almost equal to the diameter of the insert of the pyrotechnic composition, which increases resistance to mechanical overload of operation and firing. To prevent jamming during operation, the details of the movable connection of the safety mechanism are performed with precision accuracy, which limits the serial use of such fuses.

In the designs of fuses with slag compositions of the checkers of the long-range cocking mechanism, the diameter of the supporting part of the movable stopper is 2-4 times smaller than the diameter of the insert of the pyrotechnic composition, on which the safety device rod is mounted. In this case, the problem is to optimize the support part of the stopper so that during operation and firing it does not prematurely penetrate the press-fit and thereby does not remove the protection, and on the other hand, after burning the stopper, it is guaranteed to overcome the resistance of the sintered slag composition.

The prior art in this area is characterized by the fuse according to patent RU 2125706, F 42 C 1/06, 1999, which contains a long-range cocking mechanism, a remote device, a self-liquidation mechanism and an ignition unit for actuating them, as well as an executive detonator, detonator capsule mounted in a transverse slide gate covering the fire chain and an inertial-driven sting.

The long cocking mechanism is a spring loaded rod stopper for positioning the slide gate, supported by a pyrotechnic checker.

The disadvantage of the described shock fuse is the relatively large variation in the response time, which determines the danger when firing from an under-barrel grenade launcher for personnel from early cocking of the fuse or the ineffective damaging effect of the ammunition when it is later loaded, for the location of the target.

The noted drawback is eliminated in the design of the fuse according to the patent US 6318270, F 42 C 15/24, 2000, in which the pyrotechnic block of the long-range cocking mechanism is additionally equipped with a receiver connected by distributed pyro-receiving channels to the ignition unit.

Aerosol combustion products of the powder charge of the ignition unit are accumulated in the receiver to form a powerful initiating pulse of reliable ignition at a given time of the locking block of the long-range cocking mechanism. Time-controlled combustion of the locking checker ensures that the safety mechanism operates in a predetermined time range.

However, due to the high dependence of the burning rate of the pyrotechnic composition of the stopper on pressure, the use of the known design is practically unacceptable in the design of fuses, which, in order to increase sensitivity when meeting with loose barriers, is a cover that is movable relative to the body and which functions as an element of the reactive mechanism (see, for example, patent RU 2242704), when the depressurization of the volume occurs and the pressure drops abruptly.

When the long-range cocking mechanism is installed at the lower limit of the stopper burning time, the munition is triggered far behind the target, which is ineffective, otherwise, when the upper limit of its burning time is fixed, the munition is blown up directly at the firing position, which is unsafe.

The purpose of this utility model is to improve the design of the fuse of universal action regardless of the change in pressure on the flight path of the munition, while ensuring a cocking range in a narrower range.

The required technical result is achieved by the fact that in the known fuse containing the safety mechanism of the long cock, holding the transverse slide gate in the position when the detonator capsule installed in it is displaced relative to the firing chain, where the actuating detonator is mounted, initiating the filling of ammunition, while the safety mechanism includes spring-loaded stopper kinematically connected to the slide gate and supported by a pyrotechnic checker, which the pyro-receiving channels of communication is in communication with the ignition unit, at the suggestion of the authors, the stopper is made of puff from slag compositions, and the density of the pressing of the upper layer is chosen higher than the density of the pressing of the lower layer, to which the communication channels directly filled with the pyrotechnic composition are located at a height from the border the separation of the layers, making up a third of the diameter of the checker, and in its lower there is a central recess adequate to the supporting part of the stopper, the diameter of which is wish to set up 1 / 3-1 / 2 checkers diameter.

Distinctive features increased the accuracy of the mechanism

long-range cocking of a universal fuse in a narrower time range, which, in particular, for under-barrel grenades, provided detonation at an optimal distance of 30-40 m.

The implementation of the puff checker provides the ability to control its burning time and to adapt the combustion process to the changing pressure inside the fuse.

When using slag compositions, the coke residue after the combustion of the pyrotechnic block performs the bearing functions of the structural element with the calculated resistance to the elastic forces of the compressed spring of the stopper, which provides the specified time required for the stopper to break through the arched coke formation and exit it from the transverse gate carrying the detonator capsule.

The pyrotechnic composition with a lower bulk density of the press-in ensures the intensification of its ignition.

Placing the pyro-receiving communication channels with the ignition unit on the periphery of the locking checker increased the reliability of initiation of ignition of the lower layer by narrowly directed forces, which upon reaching the interface of the layers provide ignition of the upper layer at the end and its uniform combustion in volume.

Filling the communication channels with a pyrotechnic composition identical to the composition of the lower layer of the checker block activates its ignition and provides comprehensive (independent loops) stable layer-by-layer check burning in the calculated mode. This ensures duplication of ignition of the locking checkers.

The location of the communication channels relative to the interface of the layers at a height of 1/3 of the diameter of the stopper ensures that the flame exits to the interface and ignites the upper layer of the checker before the lower layer burns in the radial direction. This ensures the preservation of the bearing capacity of the coke residue and the resistance of the spring supplying the stopper for a predetermined long-cocking time.

The central recess in the lower end of the checkerboard, adequate to the supporting part of the stopper, is designed to freely move the slag residue of the burnt pyrotechnic composition under the action of the spring from top to bottom, as a result of which the stopper, penetrating into the coke, is guaranteed to lower and release the gate valve at the estimated time.

The calculated support area of the stopper rod is limited by the range of correlation with the cross-sectional area of the checker due to unpleasant conditions: load bearing strength and the possibility of introducing the rod into the volume of slag residue during sequential layer-by-layer combustion of the compositions.

When the ratio of these areas is less than 1/3 of the rod under axial dynamic loads, it can infiltrate the charge and premature cocking occurs when a free slide gate moves the detonator capsule under the firing pin. Therefore, the fuse can occur when fired in the barrel, which is unacceptable.

When the ratio of these areas is more than 1/2, there may be cases when the force of the feed spring of the rod is not enough to move it inside the slag residue of the retainer piece, which will lead to failure of the munition.

The use of pyrotechnic compositions coking during combustion makes it possible to obtain, after combustion of the checkers, a cellular structure of slag residue that is uniform in volume (85-90%) with calculated load-bearing characteristics and structural strength of the layers. This made it possible to exclude an intermediate precision support element in a limited volume of the safety device, the design and functioning of which were simplified.

Therefore, each essential feature is necessary, and their combination is sufficient to achieve a novelty of quality that is not inherent in the signs of disunity, that is, the technical task is solved not by the sum of the effects, but by a new super-effect on the sum of the attributes.

The essence of the utility model is illustrated in the drawing, which shows:

figure 1 - the proposed head fuse in the context;

figure 2 is the same when fired;

figure 3 is the same on the path,

figure 4 is a longitudinal section of the ignition unit.

In the housing 1 of the head fuse of shock, closed by a cover 2, mounted with the possibility of relative longitudinal movement, a beam detonator capsule 4 and firing pin 5, loaded with a spring 6, are strengthened coaxially to the fire transfer channel 3.

The cover 2 is kinematically connected by means of the spring 7 of the pressure cap 8, on which the annular spring 9 is mounted in the upper position of the two-position stop of the cover 2.

The cap 8 is installed in the profile (on-off) groove 10 of the cover 2 with the possibility of longitudinal movement in the annular gap 11 between the housing 1 and the central sleeve 12, while the stop 13 interacts with leaf springs 14 laid on the sleeve 12, relying on the striker 5.

Under the axial striker 5, blocking the channel 3, a transverse slide gate valve 16 equipped with a drive spring 15 is installed, which carries a firing primer-igniter 17, which in its initial position is offset from the axis of the fuse (fire chain), where it is held by the vertical locking rod 18 of the long-range cocking mechanism 19.

The long-cocking mechanism 19 contains a puff pyrotechnic checker made of two press-ons 20 and 21 coking, slag-forming during combustion of the compositions, respectively: the lower, having a lower bulk density, and the upper with a higher bulk density of the pyrotechnic composition.

The lower press-fitting 20 is equipped with radial distribution channels pyro-receiving channels 22 distributed with the initiating mechanism (ignition unit), and at the lower end there is a central recess 23, which is adequate to the supporting part of the rod 18.

The vertical stem 18 is pressed by a spring 24 to the upper press fitting 21 and has a bearing area of 1 / 3-2 / 3 of the cross section of the press fitting 20, that is, the locking block as a whole.

A feature of the implementation of the proposed long-range cocking mechanism 19 is the placement of communication channels 22 adjacent directly to the lower press-in 20, having a common pyrotechnic filling, at a height from the interface of the press-fits 20-21, comparable to the third diameter of the stopper formed by them.

The ignition unit (Fig. 4) of the inertial action contains a coaxially mounted fixed tip 25 and a spring-loaded igniter capsule 26, which commutes with the pyrotechnic charge 20-21 of the long-range cocking mechanism 19 and the slowly burning powder composition 27 of the ring track 28 of the insert 29, which serve as the mechanism self-destruction, communicating with the executive detonator capsule 4.

The fuse operates as follows.

When fired, the igniter capsule 26 of the ignition unit (Fig. 4), by the action of inertia from the linear acceleration of the ammunition, moves downward, where it touches the sting 25. The force of the flame from the igniter capsule ignites the pyrocomposition in the channels 22, which communicate with the press-fit 20 of the locking block of the mechanism 19 cocking, and powder composition 26 of the ring track 28 self-destruction mechanism.

Under the action of inertia from the linear acceleration of the munition, the pressure cap 8 settles in the groove 11, compressing the spring 7, the leaf spring 14. The leaf springs 14 push themselves in front of them with an emphasis 13, spring deflecting, bending in the center, and move the firing pin 5 downward, compressing the spring 6.

When moving down the cap 8, an annular spring 9 is released, which, when opened, moves along the groove 10 of the cover 2 to the lower stable position, where it is fixed to the spacer between the cover 2 and the cap 8 in the lower position.

On the flight, when the axial loads disappear, under the action of the elastic forces of the springs 6 and 14, by means of the striker 5, the cover 2 moves upward relative to the housing 1 - the shock mechanism is cocked and ready to meet the obstacle.

During this time, the press-in 20 intensively burns up with ascending distributed along the periphery torches formed during the combustion of the pyrotechnic filling of the channels 22. Then, when the fire exits to the interface of the press-fit 20-21, the latter is uniformly ignited and stably burns at the end, insensitive to the pressure drop that occurs

inside the fuse with the cover open 2.

During the combustion of the slag compositions of the pressings 20 and 21, a supporting coke residue frame is formed, which counteracts the spring 24 and keeps the rod 18 in kinematic engagement with the shutter 16.

At the estimated time, when the press fitting 21 dies, the spring 24 overcomes the resistance of the frame (caked coke) from the slag residue of the pyrotechnic stopper and introduces the rod 18 into the inside, which is lowered. In this case, the transverse flap 16 is released, which is moved by the spring 15 to the leftmost (according to the drawing) position, bringing the detonator capsule 17 under the firing pin 5.

The fuse is ready for action at a distance of flight of ammunition in a narrow predetermined range of 30-40 m, optimal for effective destruction of the target and the safety of personnel in close combat.

When meeting the obstacle, cap 2, compressing the springs 7, 14 and 6, reactively moves down and dynamically pushes the hammer 5, which impinges the detonator capsule 17. The detonator capsule 17 triggering detonates the actuator detonator capsule 4, which initiates the filling of the munition. In this case, the cover 2 performs the functions of a sensitive reaction element, the mechanical movement of which occurs when it encounters non-rigid obstacles, such as snow cover, water surface, swamp, etc.

In the case when the ammunition does not meet the target on the trajectory or does not work when it encounters an obstacle, after a predetermined burning time of the powder composition 27 in the ring track 28, the force of flame of the self-destruction device enters the fire chain and initiates the radiation detonator capsule 4, as a result of which the ammunition is undermined.

Thus, a multifunctional, time-stable action of a small-sized head-mounted fuse suitable for use in various artillery ammunition, mines and grenades is carried out.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the utility model does not explicitly follow for a fuse specialist, showed that it is not known, and taking into account the possibility of industrial serial production of a head fuse, it can be concluded that the patentability criteria are met.

Claims (2)

1. A fuse comprising a long-range safety mechanism holding the transverse slide gate in position when the detonator capsule mounted therein is displaced relative to the fire chain, where an actuating detonator is mounted that initiates filling of the munition, while the safety mechanism includes a spring-loaded stopper kinematically connected to with a slide gate and resting on a pyrotechnic checker, which, through distributed pyro-receiving communication channels, communicates with the node in flame, characterized in that the stopper piece is made of puff of slag compositions, and the density of the pressing of the upper layer is selected more than the density of the pressing of the lower layer, which is directly connected to the communication channels filled with the pyrotechnic composition, located at a height from the interface of the layers, which is one third of the diameter of the checker , in the lower end of which there is a central recess adequate to the supporting part of the stopper. 2. The fuse according to claim 1, characterized in that the diameter of the supporting part of the stopper is 1 / 3-1 / 2 of the diameter of the checker.