CH635671A5 - Self-destruction device for spinning projectiles - Google Patents

Description

The invention relates to self-dismantling, in which the blocking part and the release direction for a swirl bullet can be made immovable in accordance with the preamble of the application part. On the other hand, the priorities and thus e.g. the overall focus

Devices of this type are known, the task of which the two parts are in a position in which the centrifuge is to trigger the automatic disassembly of a counteracting force to cause the two parts in the opposite direction into one position, if this has not achieved its goal to release the release part. The final

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The position of the overall center of gravity of both parts results e.g. from the displacement of the trigger part, which is exposed to the action of the spring, which tends to move it from its original position against the action of the centrifugal force and which finally succeeds when the centrifugal force e.g. 5 has become small enough. The trigger part can now reach a second position in which e.g. the center of gravity resulting from the whole comes to lie in such a way that it can bring about the desired pivoting effect into the release position. So there is e.g. no condition in which e.g. io connect two parts by engagement and thus prevent self-disassembly of the device according to the invention, and e.g. also no condition in which the engagement and the parts can be released. Rather, the blocking part and the release part can be brought into a different position by pushing their centers of gravity back onto the other side of the imaginary line.

The self-dismantling device according to the invention can therefore be blocked for a certain time during the storage and the rotary movement of the swirl bullet after it has been fired, but can be released after the centrifugal force has dropped below a certain size. The common pin is preferably positively connected to the housing. It is also offset with respect to the axis of rotation of the swirl bullet. Through the interaction of the cam 25 and the stop surface, a form-fitting unit that can be pivoted as a whole can be formed.

Due to the embodiment according to claim 2, the blocking part and the release part can be arranged one above the other in a particularly advantageous manner and can be pivoted about the common axis 30.

The firing pin can be displaced in the direction of the axis of rotation of the projectile, the flange of which can be blocked by the blocking part if the same, e.g. is in its blocking position, i.e. for example, both when the projectile is being stored and when it is rotating after being fired.

The firing pin can become free if e.g. the projectile no longer rotates at a sufficiently high speed and the reduction in the centrifugal force can pivot the release part and then the blocking part until the latter can move away from the flange of the firing pin.

The invention is explained with reference to an embodiment shown in the drawings.

It shows: 45

1 is a plan view of the self-dismantling device according to the invention in its position during storage,

2 shows a section of the self-dismantling device along the line X'-X of FIG. 1,

3 shows a plan view which is reduced in comparison with FIGS. 1 and 2 and looks at the self-dismantling device at the beginning and during the trajectory of a swirl bullet carrying the device,

Fig. 4 is a plan view of the self-dismantling device according to Fig. 3 in a transition position in which the speed of rotation of the swirl bullet has decreased sufficiently and

5 is a plan view of the self-dismantling device according to FIG. 3 in its self-dismantling position.

The device arranged in a floor (not shown) is located in a housing 10 which carries a fixed pivot pin 12 which is eccentric with respect to an axis of rotation 0 of the floor.

A first bow-shaped part 14 is pivotally mounted on the pivot pin 12. This bracket has two legs 15 and 17 and is arranged with the end of its leg 15 on the pivot 65 pin 12.

In the normal position, i.e. H. when the projectile is stored or when it rotates on its external ballistic trajectory at normal speed, the bracket 14 extends around the axis of rotation 0 of the projectile, and the structure of this bracket is chosen so that its center of gravity Gl, when its middle part 16 on one side of a line connecting axis 0 and axis 12, here line X'-X, comes to rest, is on the other side of this line and is nevertheless close enough to this line.

The middle part 16, which connects the legs 15 and 17 of the bracket 14 to one another, is circular on the inside and is designed such that it engages under a flange 18 of a firing pin 20 which serves to trigger the projectile to self-disassemble. The firing pin 20 is able to move under the pressure of a prestressed coil spring 22 (FIG. 2) along the axis of the projectile, but it is held immovably when the projectile is fired by the bow 14 reaching under its flange 18, in order to prevent it from prematurely To prevent self-decomposition.

To trigger the self-dismantling, it is sufficient if the bracket 14 swivels sufficiently quickly around the pivot pin 12 to detach the flange 18 from its position.

A second bow-shaped part 24 is mounted on the pivot pin 12. This bracket 24 is also supported at the end of one of its legs on the pivot pin 12.

The second bracket 24 is arranged essentially above the first bracket 14, it is pivoted from the same side and its center of gravity G 2 is on the same side of the line X'- during the storage of the projectile or during rotation at normal speed. X as the center of gravity G1 of the bracket 14. In this way, the central part of the two brackets 14 and 24 should be brought closer to the axis of rotation of the projectile by the centrifugal force.

The second bracket 24 is loaded by a helical spring 26 which, however, is intended to remove the middle part of the bracket 24 from the axis of rotation 0 of the projectile by initially opposing the centrifugal force acting on this bracket 24. The helical spring 26 is supported at one end on the housing 10 of the device and at the other end on a cam 28 of the bracket 24.

The second bracket 24 has a stop surface 30, which can come to rest on a cam 32 projecting from the first bracket 14, which lies in the swivel path of the stop surface, and has a sufficient height (FIG. 2). The second bracket 24 can thus, when it is pivoted under the action of the coil spring 26, abut against the cam 32 of the first bracket 14, on which it remains and takes it along with the further pivoting.

The stirrups 14 and 24 are locked during the storage of the projectile in such a way that their centers of gravity G 1 and G 2 are on one side of the line X'-X mentioned, that is to say laterally, in such a way that the centrifugal force when the projectile is fired causes the stirrups 14 and 24 brings closer to the axis of rotation 0 of the projectile, the first bracket 14 blocking any displacement of the firing pin 20 before the projectile is fired and subsequently blocking the first bracket 14 even better on account of this centrifugal force.

Fig. 1 shows the self-dismantling device in its state during storage, whereby it is rendered ineffective by a bolt 34, which consists of a lamella 38 or the like wedged between a recess 36 of the housing 10 and a notch 38 or the like formed on the back of the brackets consists; the brackets 14 and 24 are thus held in a position in which they have no effect on the initiation of the self-dismantling. The firing pin 20 is immovably held by its flange 18 and the position of the centers of gravity of the two brackets 14 and 24, which lie above the line X'-X in Fig. 1. The latch 34 holds in particular the

635 671 4

second bracket 24 in this position, against the return force of FIG. 1, the center of gravity G1 still remaining above the line acting on it helical spring 26. X'-X, is the total of the

The functioning of the device is explained with reference to FIG. 3, two brackets 14 and 24 (which are explained by touching the surfaces to 5. 30 and the cam 32)

Fig. 3 shows the state of the device when the point 5 with existing contact below the line X'-X.

shot has been fired and is running at normal speed. Thus, the two brackets 14 and 24 behave as soon as the speed turns. Contact between them is made like a form-fitting

The centrifugal force swivels the second bracket 24 by a whole, and the centrifugal force moves both of them in a directional pivot pin 12 in such a way that it tends to move in the direction of rotation, thereby pulling the bracket 14 away from its position towards the projectile approach. Since the bracket 24 is launched under the flange 18 of the firing pin 20 when it is fired, until it was wedged in accordance with the condition during storage that the bracket 14 is completely released and the firing pin is released.

has its center of gravity G2 on the upper side of the line mentioned. This is shown in Fig. 5, it shows the phase of

X'-X is located with respect to the middle part of the bracket 24, self-disassembly.

his locking is released by the bolt 34 and he pushes the two brackets are first positively by the then against the wall of the housing 10 of the device or 15 effect of the centrifugal force on their resulting against the firing pin 20; the latch 34 is moved completely freely center of gravity. Then the swiveling of the first one and, under the action of the centrifugal force, also places the shift of its center of gravity G1 on sewand, as can be seen in FIG. 3, and remains there. the lower side of the line X'-X with it, causing the bracket

The centrifugal force holds the bracket 14 under the flange 14 so that it is free even when the two

18 of the firing pin 20, since its center of gravity G1 is no longer positively connected at the start of 20 parts, for example also lies on the upper side of the line X'-X. the case shown in Fig. 5, when the bracket 24 against the

As long as the projectile rotates fast enough, the housing of the device remains bumped before the bracket 14

3, the movement of the complete retraction from the flange 18

Firing pin cannot come loose. of the firing pin 20 has completed.

4 shows the self-dismantling device in a superposition. The self-dismantling is thus obtained from the interaction stage when the speed of rotation of the projectile is released from various causes.

has decreased so far that that acting on the bracket 24

Force of the return spring 26 is greater than the centrifugal force. First, the bracket 24 is pivoted under which this bracket 24 is located and from the axis of rotation of the projectile, interaction of the return forces of the helical spring 26

moved away. 30 and the centrifugal force on this, once its center of gravity G

Since the bolt 34 at the start of the projectile has shifted its blocking position to the other side of the line X'-X (FIG. 1). Then left sition, the bracket 24 begins to enlarge considerably against the cam 32 of the part 14.

Distance between the middle part of the bracket 24 and the hitting, namely when there is no longer any contradiction in the shape of the projectile 0 of the projectile when the center of gravity of both brackets results from the center-connected parts.

fugal force decreases. 35 is located below the line X'-X. Finally the temple begins

To the extent that the bracket 24 pivots, 24 approaches the rapid release of the bracket 14 with a certain one

its center of gravity G 2 of the line X'-X and finally comes out of its position under the flange of the firing pin 20

Lich on the other side, which suddenly an acceleration of the increasing impact speed against the cam 32 of the Bü-

Movement of the bracket 24 entails hitting the gel 14 due to the fact.

that the centrifugal force is now the effect of the return spring 26 40 from the moment when the resultant supports the centrifugal force acting on the middle part of the bracket 24 from the axis of rotation of the bracket 24 through the different

To move 0 of the projectile away. Practice the focus G 2 from its initial position into one

The stop surface 30 of the bracket 24 now comes with the new position on the line X'-X is canceled, the force of the

Cam 32 of the bracket 14 in contact. Since the stop surface helical spring 26 to the predominant force, and after

30 of the bracket 24 and the cams 32 of the bracket 14 so arranged 45 shift from G 2 to the lower side of the line X'-X below

It is net that the contact between these two parts supports the centrifugal force acting on the bracket 24

a moment comes in which the position of the pulling force of the coil spring 26 so that the bracket 24 is now closed

Center of gravity G 2 is excited sufficiently below the line in X'-X in an accelerated movement.

C.

2 sheets of drawings

Claims (6)

635 671 2 PATENT CLAIMS and its trajectory at a relatively large distance from 1. Self-dismantling device for swirl projectiles ended with the launch site. Self-disassembling trigger elements, which have a central one, These devices are based on the fact that firing bolts under spring pressure and a blocking part behind a projectile containing the projectiles are fired at a certain rotational speed (their longitudinal axis engaging the flange of the firing bolt, and their longitudinal axis), and that this rotation is that in a cylindrical housing to decrease eccentrically when the projectile can be pivoted at the end of the trajectory with a pin arranged on its longitudinal axis, and a relatively low residual rotational speed arrives, also around an eccentrically arranged pin. These have a pivotable release part caused by the decreasing rotational speed, which In the idle state with a reduction in the forces used to lock the self-dismantling by means of a bolt and to trigger it under the effect io. a spring that opposes the release part to the according to DE-OS 24 05 179 such a self- the centrifugal force, which is known to be reduced due to the small disassembly device, is pivoted with a central projectile swirl which becomes Fe and thus causes the firing pin, which is under block pressure, to cause the firing pin behind a collar of the kierteil to also pivot and the locking part engaging the firing pin, to release that on a cross to the bolt, characterized in that the blocking is arranged longitudinal axis of the floor plate about an eccentric 'part (14) and the trigger part (24) one above the other about a pin arranged to the central axis. A common pin (12) can be pivoted and has a shape that partially encompasses the firing pin (20) if it can be pivoted about an eccentrically arranged pin, the release part being lockable in the idle state by means of a strut, the centers of gravity (Gl, G2) of both parts (14, 24) at rest and is under the action of a spring, which the trigger part stood on that side of an imaginary line (X.) through the longitudinal axis 20 against the centrifugal force acting on it in its verse (0) and the axis of the pin (12) '-X) due to the decreasing projectile swirl, which pivots towards the opening of the partially encompassing shape. This causes the locking part to also lie, whereby the trigger part (24) swivels under the action of the spring and releases the firing pin. (26) can be pivoted to the extent that its center of gravity (G2) In this known device, the trigger part and the belt migrates to the other side of the imaginary line (X'-X), and gel part in flight at a still high swirl speed via two interlocking parts (14), a cam (32) and the hook engaging the trigger, and so on the reed part (24), which interacts with the cam (32), is held in the detachable part. With a decreasing swirl speed and thus a distance from it and on the same radius as this, the centrifugal force acting on the triggering part has a stop surface (30) arranged over the longitudinal axis (0), and then the force of the triggering gradually increases locked position of the release part (24) and blocking part 30 seteil acting spring, which strives to pull the hook of the release (14) the central part (16) of the latter which in the longitudinal axis partly from the hook of the bolt part and thus the bolt ( 0) extending firing pin (20) against longitudinal displacement and thus to release the firing pin. This secures and the cam (32) on the side of the connecting line (X'-X) facing away from the centers of gravity (Eq., Friction between the contact surfaces of the hooks G2) and must be. The magnitude of this friction can, in particular, impact surface (30) on the center of gravity (Eq, G2) as it is initially at rest, e.g. are arranged towards the longer facing side of the connecting line (X'-X). Storage through solidified lubricants or similar 2. Self-dismantling device according to claim 1, thereby chen be quite different. However, this has a great unsi-character that the blocking part (14) and the trigger part are safety-shaped with regard to the determination of the point in time of the self (24) and each result in a disassembly of the projectile at the end. Leg (15) corresponds to a pin (12) fixed to the housing. DE-OS 15 78 460 shows a similar device which has a drilling. with even two latch parts, but without a special release part 3. Self-dismantling device according to claim 2, thereby working. But here, too, the two latch parts, which are characterized in that a flange (18) of the firing pin (20) on the firing pin are opposite one another, are first connected to one another by locking hooks locked in the pretensioned position by the blocking part (14). So here too the must. 45 triggering the device a not exactly definable rest 4. Self-dismantling device according to claim 1, characterized by the friction between the locking hooks being overcome, characterized in that when there is a center of gravity, it is also difficult with this construction to make the point (G2) on the other side of the imaginary line (X'-X) to determine the approach on the trajectory at which the self-dismantling face (30) comes into contact with the cam (32). is triggered. 5. Self-dismantling device according to one of claims 1 50, starting from the self-dismantling device according to FIGS. 4 to 4, characterized in that the spring (26) acting on the triggering part (24) DE-OS 24 05 179 is therefore the object of the invention. which includes the common reasons, by reducing the influence of frictional forces, on the pivot pin (12). the location of the projectile's self-disassembly on the trajectory 6. Self-dismantling device according to claim 1, thereby being able to determine more precisely. This object is characterized according to that the bolt (34) consists of a lamella, 55 invention by the features defined in the characterizing part of claim 1 one end of which in a recess (36) of the housing (10). held detachably and the other end in notches (38) of the advantageous embodiments of the invention. Blocking part (14) and the trigger part (24) engages. stands are described in claims 2 to 6. In the device according to the invention you make the 60 displacement of two pivoted parts, i.e. of Blocking part and the trigger part take advantage of that to prevent self-decomposition by the centrifugal force in one position