NO158439B - DEVICE BY A SECURITY BODY. - Google Patents

Description

The invention relates to a device for a fuse, preferably an electric arming fuse, which in an ammunition unit is designed to hold a moving part in an untriggered position, e.g. a member of a timing mechanism, such as a rotor, a sector body or a similar member, in relation to a fixed part, e.g. the trunk of the security body.

It is previously known to supply an ammunition unit

with different types of safety devices to achieve safe handling and release of the ammunition unit. In addition to conventional interrupters that are triggered in the cannon barrel when fired, special arming fuses can also be used that are triggered at a predetermined distance from the muzzle of the cannon barrel, so that the initiation of the ammunition unit is prevented in the vicinity of the cannon barrel. Such armor protection is necessary to protect the gun crew and own troops in the vicinity. It is also previously known to trigger such armature fuses electrically, which, however, makes the fuse arrangement as a whole sensitive to sources of disturbance, particularly sources of electrical disturbance.

It is desirable to be able to trip the armature fuse electrically and still maintain a high degree of reliability. A high degree of reliability is a requirement when handling highly effective, sharp ammunition units, such as grenades, projectiles or the like.

The main purpose of the invention is to provide

a special safety device that solves the problem mentioned above.

What mainly characterizes the safety device according to the invention is that it comprises a completely insertable part in a corresponding recess, preferably in the movable part, which in its completely inserted position in the recess is out of engagement with the relevant part of the fixed and movable parts and thereby allowing exposure of the movable part in relation to the fixed part, and that the insertable part is designed to, by its insertion into the recess, provide either such a deformation in the material surrounding the recess, or such a deformation or locking of one or more additional safety devices arranged in the ammunition unit, that the said safety devices are prevented from carrying out their release sequence when the safety device or safety devices are affected by their respective their release factors in a non-predetermined time sequence in relation to the first-mentioned safety device's release factor, the recess for the insertable part being located next to a recess for a further safety device, and that the deformation during said insertion occurs in the goods located between the recesses, respectively the said deformation or locking of the additional securing means occurs through cooperation between the insertable part and a part of the securing means located in the latter recess.

In further embodiments of the invention, the insertable part has the form of a pin insertable into the corresponding recess which deforms the material between the recesses arranged in connection with each other. The aforementioned two recesses can thereby be mutually parallel or form an angle with each other. The pin that can be inserted into the corresponding recess can, when inserted, also cooperate with and deform a body belonging to the additional securing means, so that the said body is prevented from leaving or moving in its corresponding recess. The aforementioned body can thereby form part of an interrupter (running safety ring), an acceleration safety device, a rotation safety device or another type of safety device.

Despite its relatively simple structure

in the corresponding recess insertable part, a very reliable security arrangement can be achieved even in the event that initiation is desired with the help of electronics. The new safety device can easily be incorporated into a current ammunition unit together with the other safety devices included in it.

The invention shall be described in more detail below

in connection with preferred embodiments with reference to the drawings, where fig. 1 shows a vertical section of an electric armature igniter which is arranged in connection

with an acceleration fuse and a fixed part and a movable part in a fuse housing, the armature igniter as well as the acceleration fuse being shown in their initial positions, fig. 2 shows a vertical section of the securing means in fig. 1, but in a position in which the electric armature detonator has been triggered, fig. 3 shows a horizontal section of parts which are part of the securing devices in fig. 1 and 2, fig. 4 shows a cross-section of an ammunition unit comprising both a rotation fuse and a rotor included in a fuse, fig. 5 shows a vertical section of parts of an electric armature fuse together with a fuse which is arranged in a movable part in the form of a sector body and a part fixed in relation to the sector body, fig. 6 shows a horizontal section of the securing means according to fig. 5, fig. 7 shows a vertical section of a safety device in a normal functional position, fig. 8 shows a vertical section of the barrel safety ring according to fig. 7, but during a barreling phase, and fig. 9 shows a vertical section of the fuse according to fig. 7 and 8

in a locked functional position in which the movable sector body that comprises the safety device is locked to a fixed part.

That in fig. The security arrangement shown in 1 comprises a fixed part 1 and a movable part 2. The fixed part can e.g. consist of the stem or housing of the fuse arrangement, and the movable part may consist of the rotor or sector body or any other rotatable part of the fuse arrangement. An electric armature detonator 3 is arranged in a corresponding depression or recess 4 in the fixed part. The arming igniter comprises a gunpowder or propellant charge 3a, an ignition charge 3b and electrical circuits 3c. As an electric armature igniter is in and of itself well known, the various parts of such an igniter shall not be described in detail here. It should only be noted that for a particular activation of the electrical circuits 3c, the ignition charge 3b is initiated, after which the driving charge 3a is also initiated. The armature igniter also includes a locking part 5 in the form of a bolt or pin. The locking pin is arranged in the fixed part 1 in a recess 6 which is connected to the tooth recess 4. The recess 6 is in this case made as a continuous bore between the lower surface la of the fixed part 1 and the tooth recess 4. The cross-sectional area of the recess or bore 6 is concentric with, but smaller than, the corresponding area of the recess 4.

The movable part 2 is provided with a corresponding recess 7 which lies opposite and is aligned with recesses 6 in the fixed part, and the outer end 5a of the locking pin 5 enters the recess 7. The locking pin 5 is somewhat pointed at its outer end 5a. In the position shown in fig. 1, the locking pin is designed to lock the movable part 2

to the fixed part 1. The corresponding recess 7 does not go completely through the movable part, and the bottom of the recess is somewhat sloping.

A so-called acceleration fuse 8 is also arranged between the fixed and movable parts 1 and 2. This acceleration fuse comprises a sliding body 9 in a recess 10

in the moving part. The acceleration protection is suspended in a suspension device 11 in the form of a foil or the like which is arranged to yield to a certain acceleration, so that the sliding body can be moved in the recess 10. The body is connected to a locking part 12 which extends into a corresponding recess 13 in the permanent part. The locking part 12 and the sliding body 9 are connected by means of

a bolt or screw 14 which is provided with a head 14a which engages with the sliding body's lower surface 9a, and with an external thread 14b which is screwed into a corresponding internal thread in the locking part 12. In the initial position shown in fig. 1, the locking part 12 is located in its recess 13, and the parts 1 and 2 are locked to each other via this securing device. When the sliding body 9 is subjected to an acceleration of a certain magnitude, the foil or the like gives way and the body 9 is moved, which means that the locking part 12 is pulled out of its recess 13 so that the parts 1 and 2 are released.

Fig. 2 shows the case in which the arming igniter has been triggered or released, which means that the locking pin 5 has been pushed down into the corresponding recess 7. It is then important that the entire locking pin 5 has been pushed down into the recess 7, so that the parts 1 and 2 really are released.

As shown in fig. 2, the depth of the recess 7 is equal to Hl

and the pin's height is H2. The depth Hl exceeds the height H2

by 10-20%. The pin 5 is pushed down into the recess by means of a relatively large force under the action of the driving charge 3a. After the pin 5 has been pushed down into the recess 7, it must be held in place in a specific position in the recess. The inner diameter of the recess 7 is therefore somewhat smaller than the outer diameter of the locking pin 5.

In the aforementioned embodiment, it is assumed that the release or release of the two safety devices 3 and 8 must be carried out in a specific order. More specifically, the ion fuse 8 must be released before the armature igniter 3. If this is not the case, the locking pin 5 causes

a residual deformation of the material between the recesses 7 and 10 when it is pushed down into the recess 7. This residual deformation 15 reduces the inner diameter of the recess 10 under the body 9, so that a sliding movement is prevented when the body is subjected to the predetermined acceleration force. This means that the locking part 12 is not released or released even if a release factor is present. However, if the order is correct, i.e. if the acceleration fuse is triggered first and then the arming fuse, the locking between the two parts 1 and 2 is released.

As shown in fig. 1 and 2, the recesses are 7 and

10 arranged next to each other, so that their longitudinal axes 4a and 7b are essentially parallel to each other.

It is obvious that the aforementioned recesses could also have

other directions in relation to each other, so that their axes are not parallel to each other in the plane of the paper as in fig. 2, or in a plane normal to the paper plane.

In fig. 3, the distance between the recesses is indicated

by". The deformation 15 of the material between the recesses has been caused by the locking pin 5 whose outer diameter exceeds the recess 7's inner diameter to a certain extent, preferably by approx. 0.1 mm. The rotor and locking pin can be formed from steel, brass or another suitable doctor ring.

The locking pin 5 can also cooperate with a rotation lock.

A rotation safety device 17 is shown in fig. 4 in connection with an ammunition unit and comprises a leaf spring 17a which divides the circular casing 16 of the ammunition unit into two segments. The outer ends 17a' and 17a'<1> of the leaf spring 17a are supported in corresponding recesses 16a and 16b in the casing 16. The central part of the leaf spring is provided with a body or mass 18 with a part 18a that extends into a recess 19 which is formed on the side of the movable part 2', in this case a rotor part. Under the action of a centrifugal force of a predetermined value, the body 18, as a result of the ammunition unit's rotation Rp, is subjected to a force F so that the leaf spring 17a is bent and the part 18a is moved out of its recess 19. The rotor part is then free to move in a certain direction by means of a drive device (not shown), for example as shown by arrow P. The rotation safety must normally be triggered or released before the reinforcement safety 5'. If, however, the armature fuse 5' is released before the rotation fuse, the locking pin 5' engages with the aforementioned part 18a of the body 18, which means that the rotor part 2' is locked to the casing 16 via the rotation fuse even if the special release factor is present. The electric armature igniter in fig. 4 is essentially of the same type as the reinforcing teeth shown in fig. 1 and 2. In fig. 4, the locking pin 5' has been pushed into the corresponding recess and has come into engagement with the part 18a.

Fig. 5 and 6 illustrate the connection between the electric armature detonator according to fig. 1 and 2 and an interrupter or safety fuse 20 in the form of an axial fuse. The axial protection comprises a body 20a and a holding spring 21 and is arranged in a corresponding recess 22 in a movable sector part 2<11>. The body 20a comprises a head 20b, and the spring 21 is arranged between a ring 23 which is fixed in relation to the sector part, and the lower surface of the head. Under the action of an acceleration force caused by the firing of the ammunition unit from the barrel, the body 20a moves in the longitudinal direction of the recess 22 against the action of the spring 21, and as soon as the acceleration is finished the body is moved back to its starting position by means of the spring 21. In the displaced position caused by the acceleration, a part 20c protrudes from the recess 22

and the ring 23. The protruding part 20c is then placed in a corresponding hole 24 in a part 25 which is fixed in relation to the sector part. Both the mentioned part 20c and the hole 24 are shaped like a truncated cone. This means that the axial fuse temporarily prevents the sector part 2'<1> from moving in relation to the fixed part 25. Normally the reinforcement fuse 5<*>' must be triggered or released after the axial fuse 20. If this does not happen, i.e. if the reinforcement fuse: is triggered before the axial securing, the material between the recesses 7'' and 22 is deformed in the same way as in the previously mentioned designs. The deformation is shown at 15'. In principle, the deformation occurs when the body 20a assumes its initial position, or when the body assumes the position under the acceleration action. In the former case, the body is forced by the aforementioned deformation 15' to move in the longitudinal direction, so that the part 20c enters the recess 24. As the deformation is maintained, the body 20a cannot be pushed back by means of its spring, but is maintained in the position shown in fig. 5, which means that the sector part 2'' has been definitively locked to the part 25. When the electric armature igniter is initiated in the barrel, ie.

when the body has been subjected to the acceleration force and has moved to the position shown in fig. 5, the body 20a is also prevented from moving back to its starting position by means of the deformation 15'.

In fig. 7, 8 and 9 show the operation of the run protection

more detailed. In fig. 7, the body 20a assumes its starting position under the action of the spring 21, and in this position the part 20c is out of the fixed part 25. During the barrel barrel phase shown in fig. 8, the body during the acceleration effect has been pressed down against the spring 21 to its second position in which the part 20c extends down into the recess 24 of the fixed part 25. Fig. 9 shows a position in which the sector part 2'' has been locked to the fixed part 25. This locking is then improved by means of the sloping side surfaces of the part

20c and the recess 24. It is obvious that the inclined surfaces can be varied, and for example the surfaces can be formed in the form of a truncated pyramid instead of a truncated cone.

Claims (6)

1. Device by a fuse (3), preferably an electric arming fuse, as in an ammunition unit (16) is designed to retain a movable part (2) in an untriggered position, e.g. a member of a timing mechanism, such as a rotor, a sector body or a similar member, in relation to a fixed part (1), e.g. the stem of the securing device, CHARACTERIZED BY the fact that it comprises a fully insertable part (5) in a corresponding recess (7), preferably in the movable part (2), which in its fully inserted position in the recess is out of engagement with the relevant part of the fixed and moving parts and thereby allows exposure of the moving part in relation to the fixed part, and that the insertable part (5) is designed to, by its insertion into the recess (7), provide either such a deformation (15) in the material that surrounds the recess, or such a deformation or locking of one or more additional safety devices (8; 17; 19) arranged in the ammunition unit, that the person concerned of the said safety devices is prevented from carrying out their respective triggering procedures when the safety device or safety devices are affected by their respective their triggering factors in a non-predetermined time sequence in relation to the first-mentioned safety device's triggering factor, the recess (7) for the insertable part (5; 5') being located next to a recess (10; 19) for a further safety device (8; 17) ), and that the deformation (15) during said insertion occurs in the goods situated between the recesses (7; 10), respectively the said deformation or locking of the further securing means (17) occurs through cooperation between the insertable part (5') and a part (18a) of the safety device (17) located in the last-mentioned recess (19). 2. Device according to claim 1, CHARACTERIZED IN THAT the recess (7) for the insertable part (5) is located next to the adjacent recess (10) for the further securing means (8), so that the center line (4a) of the insertable part recess (7) is parallel to the center line (7b) of the adjacent recess (10). 3. Device according to claim 1 or 2, CHARACTERIZED IN THAT the said deformation (15) is co-operable with a further securing means (8) in the form of an acceleration-sensing body (9), so that the body is prevented from performing a longitudinal displacement movement or return to their starting position if the aforementioned, not predetermined time sequence exists. 4. Device according to claim 1, CHARACTERIZED IN THAT the recess for the insertable part extends at an angle, preferably at a right angle, with a recess for a device included in a rotation protection (17). 5. Device according to claim 4, CHARACTERIZED IN THAT the device consists of a body unit (18) which is anchored in a leaf spring (17a) and which with a part (18a) projects into the device's recess (19), and that the insertable part is co-operable with the said part (18a). 6. Device according to claim 3, CHARACTERIZED IN THAT the aforementioned, insertable part (5'') upon locking the acceleration-sensing body (20a) in a position affected by the acceleration causes the acceleration-sensing body (20a) to lock the movable part (2''.) to a further, fixed part (25) with a part (20c) having the shape of an inclined surface, a truncated cone or similar shape.