NO133683B - - Google Patents

Description

The invention relates to a detonator fuse for projectile igniters, with a fuse chain consisting of several fuse elements for the detonator released in succession after firing in a predetermined manner, which are arranged in a rotor which can be turned by spring force from the fuse position to the arming position, with a fuse link consisting of two inertia bolts which, due to mutual dependence are displaceable under the action of the axial acceleration, as well as a further securing link which can be triggered by means of the first securing link.

There are very high safety requirements for such blasting cap fuses for projectiles, because despite careful manufacture and assembly, premature detonation of the projectile can occasionally occur, as the blasting cap containing the rotor is triggered by shock, vibrations, spring breakage or other causes.

The task of the invention is therefore to improve the safety of such detonator fuses and to carry out the arrangement of the individual fuse links and their method of operation in such a way that any accidental ignition is prevented. In and of itself, it does not pose any difficulty to provide a detonator fuse with three or more fuse links, however, it is always a problem as well

to place the securing links with the least possible space requirement, because additional space is not available in most cases. Furthermore, when additional safety links are installed, several sources of error may arise which will in turn threaten the intended safety. It is therefore also a task for the invention, taking into account the aforementioned requirements, to provide a detonating capsule fuse with a relatively small space requirement.

For a detonating capsule fuse of the above-mentioned construction, the task according to the invention is solved by the second fuse link consisting of a pin which is arranged on a wing pivotably attached to the housing and which can be triggered by the first fuse link and engages vertically in the end face of the rotor on its axis of rotation, a slot is arranged, and that a further third safety link, designed as a gas pressure safety device, is arranged consisting of a pressure piece guided in a bore in the housing, which rests against a membrane arranged in the bore and supports a locking ball that locks the rotor in its safety position in such way that when the propellant gases impact on a piston arranged with the same axis as the pressure piece, after achieving a predetermined gas pressure, the diaphragm is destroyed and after releasing the locking ball, the rotor is turned by means of its drive spring to the arming position.

The detonator fuse according to the invention is suitable

both for grooved projectiles and for grooveless projectiles, in particular

rocket projectiles and the gas pressure fuse as well as its functional connection with the other fuse links provide maximum safety, because the gas pressure fuse allows for a simple and functionally reliable construction. Particularly appropriate is the use of the gas pressure fuse in a detonator fuse for igniters in rocket projectiles, where another propelling charge is arranged, i.e. a "marching drive". The gas pressure necessary for the decisive release is developed in this case by the combustion of the propelling charge, whereby it is ensured that the ignition system is only armed after the projectile has reached a large safety distance from the launch site, which is particularly advantageous when it has to be launched over own strengths.

The fuse links' functional reliability and their mutual functional dependence are also advantageously favored by the fact that all fuse links: as well as the rotor containing the blasting cap, are arranged in an essentially wedge-shaped housing. In this way, the detonator fuse forms an independent structural part with small external dimensions, whereby the production of the projectile and the associated igniter is also simplified.

According to the invention, the gas pressure fuse consists of a

in a bore in the housing guided pressure piece that rests against a diaphragm arranged in the bore and supports a locking ball which

blocks the rotor's safety position in such a way that when the propellant gases impact on a piston arranged with the same axis as the pressure piece, the diaphragm is destroyed after a predetermined gas pressure is achieved and after the release of the locking ball, the rotor is turned by means of its drive spring to the arming position. This method of construction enables particularly small dimensions, so that this fuse can be placed in the disc-shaped housing without additional space requirements.

A further advantageous design of the invention consists in that all safety links, as well as the detonating capsule containing the rotor, are arranged in a mainly disc-shaped housing which forms an independent structural part. This construction also contributes to enabling a space-saving design, as the wing has an arc-shaped design and is adapted to the essentially circular circumferential surface of the house.

Further details of the invention will appear

of the following description of an embodiment shown on a larger scale in the drawings, as fig. 1 shows a separate view of the blasting cap fuse according to the invention, fig. 2 and 3

shows the reinforcing bolts before and after the launch, and fig. 4 and

5 shows the gas pressure fuse before and after release of the fuse for the rotor carrying the blasting cap (drawn offset).

The one in fig. 1 showed detonator fuse with a fuse chain consisting of fuse links A, B and C, is arranged in an essentially circular disc-shaped housing 1 and thereby forms an independent structural part D which can be inserted in a suitable place in a projectile. In addition, a rotor 3 is rotatably arranged in the housing 1, which carries the explosive capsule 2.

The securing link A forms one of two inertia bolts 4 and

5 consisting firing fuse which is only triggered by means of a

in the P direction of the arrow effective firing acceleration of a specific size and duration. The inertial bolt 5 is displaceably guided parallel to the axis of the projectile in a sleeve 6 fixed in the housing 1

and is kept in its front rest - respectively. safety position by means of a spring 7 arranged in the sleeve, as the bolt with a conical surface 8 formed at its front end rests against a collar 9 formed by indenting the sleeve wall. The inertia bolt 4 is

arranged in a bore 10 in the housing and parallel to the bolt 5. The bolt 4 is supported against a spring 11 arranged in the bore 10 and is held in its securing position by means of a ball 12 which is arranged

in a bore 13 which connects the bore 10 with the sleeve 6. I

the one in fig. 2, the safety position shown grips the ball 12 in a circumferential groove 14 arranged in the bolt 4.

A pin 15 arranged at the front end of the inertia bolt 4 locks in the securing position according to fig. 2 an arc-shaped wing 16 which is adapted to the essentially circular circumferential surface of the housing and by means of a joint eye, 17 and a pin 18 is pivotally supported on the housing 1. The wing 16 is influenced

in the direction of swing by means of a hoop 19 which is clamped in a slot 20 in the housing.

A bore 21, which is arranged in the housing 1 and across

of the longitudinal axis of the projectile and the housing, serves to accommodate the rotor 3 which carries the detonating capsule 2. In the armed position, the detonating capsule can be ignited in a known manner by electrical contacts or by means of an ignition piston through a recess 22 in the end wall of the housing. In the secured position, the rotor is turned about its longitudinal axis, so that the blasting cap does not lie in the area of the recess 22. In this position, the rotor 3 is secured by means of two independently-operating links B and C. One of these consists of a pin 23 arranged on the inner side of the wing 16 which engages in a slot 24 arranged on the end side of the rotor and more precisely eccentric in relation to the axis of rotation of the rotor. On

on the other end of the rotor is a worm wheel 25

which engages with a worm screw 26 stored in the housing. The operation of the worm screw consists of a tensioned spiral spring 27 which is arranged in a spring capsule 28 attached to the end wall of the housing.

The fuse link C is the one in fig. 4 and 5 showed gas pressure protection. For a better overview, the arrangement of the gas pressure fuse C in fig-.. 1 is shown offset by 180°. In a bore 29 arranged perpendicular to the longitudinal axis of the rotor 3 in the housing 1, there is a membrane 30 which rests against a shoulder and is held in place by means of

a bushing 31 which, with its outer end, is finished flush with the surface of the housing and is attached to the housing by means of suitable means (e.g. core punch). In a similar way, a ? is arranged in the bushing 31. t two-part pressure piece 32 secured against falling out, which pressure piece is influenced by means of a coil spring 33 in the direction of separation and rests against the membrane. The pressure piece 32 under-supports a locking ball 34 which locks the rotor 3 in a secured position.

At a suitable place in the projectile, e.g. in projectile

the bottom 35 is in one with the same axis as the bore 29 an-

arranged bore 36 displaceably supported a piston 37 provided with a sealing ring and secured by means of a spring ring 38 from slipping out. Fig. 4 shows the assembly position of the piston 37, where a push rod 37a arranged on the piston extends to .immediately in front of the impact piece 32....;The operation of the described blasting cap fuse ;is as follows: Before firing, the inertia bolts 4 and 5 are 1 in the position shown in Fig. 2. In this case, the device is in a known manner as follows that only an acceleration force P with a specific magnitude and duration is able to produce the triggered position in Fig. 3, because the movement of the bolt 4 can only take place when the bolt 5 has reached its (in the figure) lower position and the persistent acceleration force also causes the movement of the bolt 4 to the position shown in Fig. 3, after the locking ball 12 has been pushed out of the circumferential groove 14. In this position, a hoop spring 4a fixed in the wall of the housing has engaged in front of a shoulder on the bolt 4, whereby this is maintained. When the bolt 4 is moved, the wing 16 is released, which swings outwards under the action of the hoop spring 19 acting on it. (In the case of grooved projectiles, the hoop spring 19 is omitted; the swinging movement of the wing is in this case caused by the centrifugal force). *

After achieving a determined and effective gas pressure on the piston 37 in the gas pressure fuse - produced either by the firing propellant charge or with the help of a marching propellant charge - the shock rod 37a hits the shock piece 32, thereby bursting the membrane 30 and due to the compression spring 33 a gap 32a is created between the two pressure piece parts (fig. 5). In this space, the locking ball 34 - due to the turning force acting on the rotor 3 by means of the spiral spring 27 over the worm drive 25, 26 - can escape, so that the rotor is turned to its armed position.

The fuse links A, B and C are assigned to the rotor 3 to be secured, in such a way that it can only be turned to the armed position when the fuses have been triggered in the described temporal sequence. Should, for example, the gas pressure fuse C for one reason or another is triggered before the other safety links, the force of the spiral spring 27 can certainly turn the rotor part of its turning angle of approx.

15°, but continued rotation is nevertheless prevented by the pin 23 arranged on the wing 16. By the force of the spiral spring 27, the

the pin 23 stuck in the rotor's slot - 2± blocks this -. An ignition of the explosive cap present in the rotor is thus not possible. The security of the clamping can be further increased if the slits

24: walls and the pin have a corresponding undercut design.

Claims (2)

1. Explosive cap fuse for projectile igniters with a fuse chain consisting of several fuse elements that are released one after the other after firing in a predetermined manner for the detonator r which is arranged in a rotor which can be rotated by spring force from the fuse position to the arming position, with a fuse link CA) consisting of end of ta inertial bolts 3om due to mutual dependence are displaceable under the effect of the axial acceleration, as well as a further safety link (Bi which can be triggered with the help of the first safety link"characterized by the fact that the second safety link fB) consists of a pin (2=3}). which is arranged on a wing (16) pivotably attached to the housing and which can be released by the first safety link (A) and engage in a slot (24-) arranged in the end surface of the rotor (3) perpendicular to its axis of rotation, and that a-further-, designed as a gas pressure safety third safety link (C) is arranged consisting of a pressure piece (32) guided in a bore (29)- in the housing (1) which rests against a membrane (30) arranged in the bore- and supports a locking ball (34) which locks the rotor (5) in its safety position in such a way that upon the impact of the propellant charge gases on a piston (37) arranged with the same axis as the pressure piece, after a predetermined gas pressure is achieved, the diaphragm broken and after release of barrier the ball, the rotor is turned with the help of its drive spring (27> tit othering position. 2. Detonator fuse according to claim 1, characterized in that all fuse links, as well as the detonator (2f containing rotor (3) are arranged, in a mainly disk-shaped housing (1) which forms an independent structural part (D). 3-. Explosive capsule fuse according to claims I and 2, characterized in that the wing (16) has an arc-shaped design and is adapted to the essentially circular circumferential surface of the housing (1).