NO174175B - Device for projectiles - Google Patents

Abstract

A device for projectiles for translating an axial movement of a transmission element (11) in the firing direction (P) of the projectile into a rotary movement for the actuation of means (2, 28, 35) for initiating or arming the priming system of the projectile. The transmission element is provided with at least one helicoidal portion (12) engaging, during said axial movement of the transmission element, with a guide means (18, 19) which urges the transmission element into performing said rotary movement. <IMAGE>

Description

The present invention relates to a device for projectiles to convert an axial movement in the projectile's firing direction of a transfer element into a turning movement for influencing organs for initiating or securing the projectile's ignition system. Such a device is described in GB-Å-6725990 which forms the basis for claim 1's preamble.

In the event that the device according to the invention is used to secure a projectile's ignition system, it fills a need as a unit fuse for projectiles that do not rotate or rotate at a relatively low speed, such as bomb launchers, tank and artillery ammunition, rockets and bombs.

In the event that the device according to the invention is used to initiate a projectile's ignition system, it forms part of a system for, for example, time-delayed closure of an electrical contact in an ignition system for direct initiation of a secondary explosive, such as EFI or laser igniters.

It is known in ignition systems for projectiles to convert motions of a certain direction and magnitude into motions of a different direction or magnitude to effect different types of functions. Examples of such devices can be found e.g. in SE-B-431124 which relates to a detonator fuse for rotating projectiles, and GB-A-672590 which relates to a safety and launch transfer device for self-propelled projectiles.

If the projectile does not rotate, any rotational force cannot be utilized, which is why one is referred to exclusively axial forces to achieve the various functions. This limits the construction possibilities, complicates the motion transmission devices and/or makes them less reliable or more space-consuming.

The purpose of the present invention is to provide a device of the nature mentioned at the outset which partly causes the conversion of the axial movement into a turning movement in a simple and safe way, partly takes up little space and partly can be built into existing ignition systems without major structural changes. This purpose is achieved by the device according to the invention having the distinctive features specified in the distinguishing part of the patent claims.

The invention will be described in more detail below with reference to the drawing.

Fig. 1 and 2 are a side view or a view from above of a blasting cap fuse comprising the device according to the invention,

fig. 3 and 4 show side views partly in section along the line A—A in fig. 2, as fig. 3 shows the device according to the invention in a secured state, and

fig. 4 shows the device according to the invention in an unsecured state,

fig. 5 and 6 show views along the line B—B in fig. 1, but essentially only movable elements are included, since fig. 5 shows the device according to the invention in a secured position and fig. 6 shows the device according to the invention in an unsecured state,

fig. 7 and 8 are both side views partly in section along the line C—C in fig. 2, as fig. 7 shows the device according to the invention in a secured position and fig. 8 shows the device according to the invention in an unsecured position.

Only one embodiment of several possible ones is shown in the drawings, namely that which relates to use in a time-delayed fuse mechanism in a warhead fuse for non-rotating or slowly rotating projectiles, such as grenade launcher ammunition, anti-submarine grenades, mines, rockets and bombs.

Projectile rotation is thus not utilized as an energy source to effect operation of the safety mechanism, but this operation is achieved in the embodiment shown instead by utilizing the projectile's acceleration.

The turning movement achieved by the device according to the invention is braked by a brake mechanism consisting of a gear change and an armature mechanism in order to achieve a time delay of an arming sequence. The time delay is responsible for the safety of handling and shooting with the ammunition until a point in the projectile trajectory where securing (arming) of the ignition system can take place without danger to the person carrying out the shooting.

An essential condition for the security level of the detonator fuse is that the force that drives the system to arming must not be stored before the time of use, which condition is fulfilled by the described device.

A blasting cap fuse comprising the device according to the invention consists of an essentially circular-cylindrical body 1 composed of several disk-shaped units which is fixed in a known manner between a fuze and a charge in the front part of a projectile, e.g. a grenade, which is intended to be fired in the direction of the arrow P in fig. 1 from the mouth of a fire tube in a launching device. The body 1 includes all the details to keep the device in a secured state and prevent the aforementioned charge from being activated by the igniter and to arm the device and allow the charge to be activated by a flame or projecting tip ejected from the igniter.

In fig. 3-7 shows a rotor 2 rotatably mounted about a shaft 3, which must be rotated from the one in fig. 3,5 and 7 to the one in fig. 4, 6 and 8 showed the position for a detonator 4 placed centrally in the body 1 to be able to detonate and affect the aforementioned charge in the projectile. The rotor 2 is prevented from turning and is thus held in a secured position by a locking pin 5 which is axially movable between the one in fig. 3 showed the upper position where it is prevented from being displaced axially, and the one in fig. 4 showed the position where it does not prevent the rotation of the rotor 2 depending on whether a blocking element e.g. executed as a ball 6, is led out by engagement with a recess 2a in the periphery of the rotor. The ball 6 is displaced out of this engagement after the locking pin 5, possibly against the effect of a weak spring force, has been released for downward movement by a locking element, e.g. in the form of a ball 7. In the secured state of the device, the ball 7 rests partially in an annular groove 5a on the locking pin 5 and cannot be displaced from this depending on the fact that a locking device, designed as a locking piston 8, prevents this. When e.g. the locking piston 8, when affected by the projectile's acceleration, is displaced downwards from the one in fig. 3 position, so that the upper part 8a of the locking piston 8, with a smaller diameter than the locking piston otherwise, will be directly opposite the ball 7, the ball 7 will be displaced towards the part 8a of the chamfered part of the locking pin 5, which is located between the recess 5a and an upper thickened part of the locking pin, when the locking pin 5 is displaced downwards from the position in fig. 3 to the position in fig. 4. When the locking pin 5 has taken its position in fig. 4 shown lower tilling where it remains, and the acceleration has ceased or decreased, the locking piston 8 will be moved back from its lower position shown with dotted lines to the one in fig. 3 and 4 with solid lines showed the upper position, depending on a pressure spring 10 introduced between the locking piston 8 and a bottom plate 9 on the body 1.

When the rotor 2 is no longer prevented by the ball 6 from turning around the shaft 3, the rotor 2 cannot in any case turn because a further condition must be fulfilled. This condition is that a further locking device which is also dependent on acceleration and which includes the below described device according to the invention must be released.

This device comprises as its essential part a transmission element 11 in the form of a hollow circular cylinder with two helical grooves 12 around the periphery, and two diametrically opposite, substantially hemispherical recesses 13 at the element 11's lower part.

The transfer element 11 is axially displaceable and rotatably placed in a cylindrical space 14 in the body 1. In this position, the working surfaces of the element 11 are protected against blows, impacts and other influences during the device's transport, storage and handling. In its upper secured position as shown in fig. 3, the element 11 is pressed against a fixed part 15 on the body 1 by a compression screw spring 16 which is conical so that adjacent screw threads can be introduced into each other when the spring is compressed and it will thus take up little axial space. The spring 16 rests against the bottom plate 9 and against friction-reducing means 17, possibly consisting of a metal chip which rests against the spring 16, and a Teflon chip located between the metal chip and the lower part of the element 11.

In the transmission element 11 in fig. In the upper position shown in 3, two locking devices in the form of balls 18 and 19 are partially inserted into the recess 13. The balls 18 and 19 are held axially in place by the recess in the walls of the room 14 and radially outwards by the locking piston 8 and a locking piston 20 which is identical to the locking piston 8 and works in the same way as this.

When the transfer element 11 is subjected to a in fig. 3 downward force, caused by the acceleration of the projectile in the direction P of the arrow, the locking pistons (20, 8) are also subjected to a downward force, and both the element 11 and the locking pistons 8, 20 are brought approximately simultaneously to their lower positions which are shown with solid lines when applies to the element 11 and with dotted lines for the pistons 8,20 in fig. 4. The downward axial movement of the locking pistons 8, 20 is a controlled prerequisite for the axial movement of the element 11 to the same position. The controlled condition is constituted by the fact that the balls 18,19 of the locking pistons 8,20 are prevented from leaving their positions in the recesses 13. Depending on the fact that the time constants for the mass of the transfer device 11 and the force of the spring 16 are much lower than the mass of the locking pistons 8 and 20 and the spring 10 forces come, when the projectile's acceleration decreases or ceases to work, the locking pistons to be moved back from the position in fig. 4 to the position in fig. 3 earlier than element 11.

A shaft 22 is inserted into the axial hole of the transmission element 11. The shaft 22 is rotatably supported in the bottom plate 9 and in a top plate 23. The spring 16 and pieces 17 surround the shaft 22. A pin 24 is fixed in a radial hole in the shaft 22 and protrudes with its one end 24a (fig. 7) some distance from the shaft 22 mantle surface. This pin end 24a engages in an axial groove 25 in the axial hole of the element 11. The upper part of the shaft 22 is provided with a toothed wheel 26 which engages with a toothed wheel 27 on a toothed segment 28 (fig. 3,5-8). The tooth segment 28 is provided with a tooth track 29 which via a gear changer 30 drives an armature 31 in a conventional brake system. The armature 31 is given an oscillating movement by the gear changer 30 around a shaft 32 and delays (brakes) the counterclockwise rotation of the segment 28 around the shaft 22 for a predetermined period of time.

The tooth segment 28 is provided with an open recess 33 and an elongated hole 34. The recess 33 can be moved from the secured position (fig. 5), where it is located at a distance from the central hole in the body 1 to which the detonating capsule 35 fixed in the rotor 2 can be moved to an unsecured position (fig.6), where the recess is directly opposite the center hole. The hole 34 surrounds a driver pin 36 which is attached to the rotor 2.

After the projectile provided with the device according to the invention has been launched and accelerated and the transfer element 11 against the action of the spring 16 has been brought to its lower position (fig. 4) - which is made possible by the balls 18 and 19 being pushed radially outwards of the chamfered upper edges of the recess 13 and the locking pistons 18 and 20 are brought to their in fig. 4 with dotted lines shows positions - the acceleration will decrease so that the spring 16 pushes the transmission element 11 upwards. Immediately before, the locking pistons 8 and 20 are returned to their upper positions and press the balls 18,19 radially outwards. When the transfer element 11 is pressed upwards, the balls 18 and 19, which in the upper position of the element 11 are located in the upper parts of the helical grooves 12, will act as control means for the element 11 which will rotate counterclockwise from the position in fig. 5. The groove 12, which preferably has a rectangular cross-section, has such a strong rise that the element 11 rotates with a high degree of efficiency on the force exerted by the spring 16. The means 17 ensure that the friction between the spring 16 and the element 11 is small.

During its upward movement, the element 11 via its axial groove 25 and the engaging pin end 24a forces the shaft 22 in a clockwise direction, whereby the tooth segment 28 is turned in a clockwise direction from the position in fig. 5 to the position in fig. 6 with the time delay caused by the braking system 30-31.

When the counter-clockwise rotation of the tooth segment 28 has finished, the driver pin 36 has displaced the rotor 2 to that in fig. 6 shown position where the recess 33 exposes the central hole to which the explosive capsule 35 is guided by the rotor.

According to another possible embodiment, a transfer element corresponding to the element 11 can be used to convert a rectilinear axial movement, e.g. caused by the acceleration of a projectile, to a turning movement to close or break an electrical contact in an ignition system for direct initiation of a secondary explosive or to achieve an adjustable time function in order to limit the turning movement, so that the desired time is achieved, e.g. to be used in connection with preset brisance, in so-called clockwork tin tubes.

Claims (7)

1. Device for projectiles to achieve, during the projectile's launch, a turning movement for influencing organs (2,28,35) for initiating or securing the projectile's ignition system, which device has a transfer element (11) which is axially displaceable in a direction opposite to the launch direction of the projectile and then in the launch direction, characterized in that the transfer element (11) is provided with at least one screw-shaped part (12) which, during the transfer element's axial movement in said launch direction, engages with a control device (18,19) which forces the transfer element (11) to perform the aforementioned the turning movement, which guide means (18, 19) is out of engagement with the screw-shaped portion (12) of the transfer member (11) to allow the axial movement of the transfer member in the opposite direction to the launching direction, without the transfer member turning. 2. Device according to claim 1, characterized in that the screw-shaped part is made up of a groove (12) and the control member is made up of at least one ball (18, 19) located in this. 3. Device according to claim 1 or 2, characterized in that the transfer element (11) is spring-actuated (16) in the direction of launch of the projectile. 4. Device according to claim 3, characterized by a screw driver (16) whose one end via friction-reducing means (17) rests against the transmission element (11). 5 . Device according to claim 4, characterized in that the coil spring (16) is conical so that its windings are at least partially inserted into each other when the coil spring is compressed. 6. Device according to one or more of the preceding claims, characterized in that the transmission element (11) before launch is held back in its position in the launch direction by a locking device (8,20) which preferably affects the control device (18,19). 7. Device according to one or more of the preceding claims, characterized in that the transmission element (11) is axially displaceable on a shaft (22), that the transmission element and the shaft are provided with bodies (24, 25) which engage each other and which allow axial movement of the transmission element on the shaft during simultaneous rotation of these and the shaft is connected to the means (2, 28, 35) for initiating or securing the projectile's ignition system.