DE1261428B - Ignition device for a shaped charge projectile - Google Patents

Description

Ignition device for a shaped charge projectile The invention relates to an ignition device for a shaped charge projectile with an impact head for generating of current impulses, an igniter, which is mounted in a rotor, which consists of a Secured position m an ignition position can be rotated, the rotor having a first Contact carries and a second and a third contact attached to the projectile body of which the second contact with one side and the third contact with the other side of the current pulse generator is connected, further one of the both electrodes of the igniter is permanently connected to the second contact, while the other of the two electrodes is permanently connected to the first contact, the in the secured position of the rotor also connected to the second contact is and in the ignition position of the rotor after releasing the second contact with the third contact is connected.

An ignition device of the type described above has already been proposed, which, as will be explained in more detail below, do not guarantee maximum security can.

A contact of the power generator directly with the projectile body in a ground connection to bring is known.

It is the object of the invention to provide such an ignition device create that has a much greater security than the proposed Ignition device.

According to the invention this object is achieved in that the projectile and the rotor are made of electrically conductive material, although the rotor has a plate with approach made of an insulating material, which is supported by a pin is penetrated, which forms the first contact, that the rotor continues to have one has fourth contact, which is formed by a metal lamella that is on a conductive portion of the rotor when the rotor is in the locked position and which is located on the section of the rotor made of insulating material supported when this is in the ignition position, and that the with the as Metal spring formed second contact connected connection of the power generator also has a ground connection in a known manner with the projectile body.

This has the essential advantage that in the secured position the current pulse generator is short-circuited.

In the figures of the drawing is an embodiment of the invention shown schematically. It shows F i g. 1 is a schematic overall view of a Shaped charge projectile with the arrangement of the detonator, F i g. 2 is a view of the detail C in Fig. 1, partly in section, F i g. 3 is a partially sectioned plan view on the ignition device in the safety position, F i g. 4 one of the F i g. 3 corresponding Representation with a different partial section to illustrate the locking of the rotor, F i g. 5 shows a section along line V-V in FIG. 3, fig. 6 a section along the line VI-VI in FIG. 3, fig. 7 one of the F i g. 3 corresponding representation of the device in ignition position, FIG. 8 one of the F i g. 4 corresponding representation of the device also in the ignition position, FIG. 9 shows a section along line IX-IX in FIG. 7, F i g. 10 the element D according to FIG. 5 in an exploded view, FIG. 11 shows a section along line XI-XI in FIG. 9, fig. 12 is an electrical circuit diagram the ignition device according to the invention in the safety position, FIG. 12 a a electrical circuit diagram of the ignition device according to the invention in the ignition position, F i g. 13 shows an electrical circuit diagram of the ignition device that has already been proposed in the secured position and F i g. 13 a is an electrical circuit diagram the already proposed ignition device in the ignition position.

The projectile shown is a missile coming from a power generator 1, an impact head 2, the projectile body 3, the detonator housing 4, a projectile shaft 5 and stabilization surfaces 6 consists.

A current conductor 16 leads the ignition device from the power generator 1 generated current pulses. The igniter has a cylindrical hollow body 24 with a hollow, cylindrical one pointing in the direction of the impact head 2 of the projectile Approach 25. The cylindrical hollow body 24 in turn has a cylindrical one Cavity 26, whose axis X-X (Fig. 6) to the axis Y-Y of the electric detonator or the storey runs vertically. In the rear wall 27 of the cylindrical hollow body 24 a recess 28 is provided, which consists of two different sections Diameter consists. The rear wall 27 is cut out in a certain area, and on a flattened upper side 29 are three insulating pieces 30, 31 and 32, while a fourth associated insulating piece 33 is attached to an adjacent one Section 34 of the rear wall 27 is attached.

A screw passes through one end of the three insulating pieces 30, 31 and 32 35, which is screwed into the side 29. The two lower insulating pieces 30 and 31 each have a notch at their end opposite the fastening end 36 or 37, in which a pin 38 engages, which in turn engages in the rear wall 27 is used. In this way, the two insulating pieces 30 and 31 become non-rotatable held.

On the upper insulating piece 32 three metal lamellae 39 (hereinafter referred to as the fourth contact), 40 (hereinafter referred to as the third contact) and 41 are arranged, of which the fourth contact 39 and the third contact 40 with the upper insulating piece 32 by a Rivet 42 are connected. The lower end of the rivet 42 engages in an opening 43 of the insulating piece 31. The third contact 40 and the metal lamella 41 are connected to one another by a second rivet 44, the lower end of which engages in a recess 45 of the insulating piece 31.

The power line 16 is attached to the upper metal fin 41. The fourth contact 39 is bent downward in this way and thus engages in a cutout 46 of the underlying insulating piece 31 that the free end of the fourth contact 39 lies in a plane below the protruding part of the third contact 40.

A rotor 47 is accommodated in the cylindrical cavity 26. This engages with a coaxial extension 48 in a blind bore 49 with a slight sliding fit. The bottom of the blind bore 49 runs conically and serves as a bearing for a ball 50 on which the rotor 47 is supported with its extension 48. As a result, the ball 50 is constantly centered and there is little surface contact between the rotor 47 and its support, the space denoted by s between the underside of the rotor and the wall of the cylindrical cavity 26 being very small.

The rotor 47 has another cylindrical one on the opposite side Approach 571, the end face of which has a diametrically extending groove 52, in which engages one end of a coil spring 53 which surrounds the projection 51 and whose the other end is fastened to the cylindrical hollow body 24 by means of a screw 54 is. This spring 53 constantly exerts a torque on the rotor 47.

The rotor 47 is centered with the aid of a plate 55, this one is fastened to the cylindrical hollow body 24 by means of the screws 54 and 56 and is freely penetrated by the cylindrical extension 51 of the rotor 47. The plate 55 has a cutout 57. The screw 56 is also used to attach a metal spring 58 bent upwards (hereinafter referred to as second contact) on the plate 55, the spring end lying above the cutout 57.

The rotor 47 has a blind bore 59 in its transverse direction, the axis ZZ of which (FIG. 4) assumes a slight inclination with respect to the longitudinal axis YY of the cylindrical hollow body 24 in the safety position of the rotor, ie before the projectile is fired. The tapered end 60 of a locking pin 61, which is inserted into the recess 28 of the rear wall 27, engages in this blind bore 59. In addition, the rotor 47 has a comparatively wide cutout 62 which is delimited by two flat surfaces 63 and 64 that are perpendicular to one another. An insulating plate 66 having a shoulder 67 is fastened to the surface 63 by means of a screw 65.

The insulating plate 66 is arranged in such a way that it closes the adjacent opening of a radially extending channel 68 which passes through the rotor 47. A pin 69 (hereinafter referred to as the first contact) is inserted through the projection 67 of the insulating plate 66 and projects beyond the projection 67 and at the same time serves to attach a contact spring 70 , which is in contact with the ignition needle 71 assigned to the ignition charge 72, which has a bore 73 penetrated in the insulating plate 66.

The primer 72 is secured within the channel 68 by a shoulder 74 held. On the front wall 75 of the cylindrical hollow body 24 is one to the Recess 28 coaxially extending bore 76 provided with the channel 68 is aligned when it is in alignment after the rotor 47 has rotated about the axis X-X when firing of the projectile runs in the direction of the Y-axis.

The bullet shaft 5 is immediately next to the ignition device of a locking pin 77 penetrated, which is normally only a short distance away extends from the back of the locking pin 61, so that a loosening of the locking pin is excluded, although a subsequent to the recess 28 in the projectile shaft 5 Space 78 for receiving the locking pin 61 is provided.

The cylindrical hollow body 24 has a serrated, grooved, fluted or a similarly formed collar 79, which the assembly of the ignition device with the projectile body 3 facilitated. The outer circumference of the ribs, teeth or the like. of the collar 79 is slightly larger than the outer diameter of the cylindrical Hollow body 24 and also slightly larger than the inner diameter of the Projectile body 3 subsequent cylindrical part.

In the F i g. 3, 4 and 12 show the safety position of the ignition device according to the invention, in which the circuit leading to the ignition needle 71 is interrupted. The first contact 69 is separated from the third contact 40 by the rotational position of the rotor 47, so that the circuit shown in FIG. 12, the switch symbolized schematically by the first contact 69 and the third contact 40 is open. The third contact 40 is, as already explained, in an electrically conductive connection with the upper metal lamella 41, to which in turn the current conductor 16 of the power generator 1 is attached. Furthermore, as in particular from FIG. 3 can be seen, the fourth contact 39 against the metallically conductive body of the rotor 47, so that the switch symbolized in FIG. 12 by the fourth contact 39 and the rotor 47 is closed. The power generator 1 is thus advantageously short-circuited here. Furthermore, the ignition needle 71 is also connected to ground, namely via the contact spring 70, the first contact 69, the second contact 58, the screw 56 and the cylindrical hollow body 24. This position is in particular shown in FIGS. 3 and 4, which show that the second contact 58 rests against the first contact 69. This state is shown in FIG. 12 symbolically represented in that the switch formed from the first contact 69 and the second contact 58 is closed.

The ignition device already proposed is for a shaped charge projectile provided with shock head and shock generator, with an igniter mounted in a rotor and an angular rotation from a safety position to an ignition position can perform. This rotor has a first contact piece 51 '. The proposed The device also has a second and a third contact piece 47 'and 56', these contact pieces attached to the projectile body and with one or the other Connection of the power generator are connected. One of the two electrodes, namely 17 ', the ignition device is permanently connected to the second contact piece 47', the other Electrode 18 'permanently connected to the first contact piece 51', the latter in the secured position (Fig. 13) of the rotor with the second contact piece 47 ' and in the ignition position (FIG. 13 a) connected to the third contact piece 56 ' is.

In the secured position of the rotor, the electrodes 17 'and 18' are short-circuited by the contact piece 51 'in the rest position. In the rest position, the electrode 18 ' is switched off from the power generator by the same, first contact piece 51'.

The operation of the ignition device according to the invention is as follows: Before the projectile is inserted into the launcher, the safety pin 77 is removed and the detonator is automatically tensioned at the moment of firing, since the rotor 47, counter to the action of the spring 53, has a persistence that becomes effective when firing executes slight rotary movement, so that the tapered end 60 of the locking pin 61 is freed from the lateral frictional pressure acting on this. As a result of the inertia, the locking pin 61 now comes out of the recess 28 and into the space 78. The locking of the rotor 47 is thus released. The rotor is therefore under the action of the spring 53 in the in the F i g. 7 and 8, in which the channel 68 of the rotor 47 carrying the ignition charge 72 is aligned with the bore 76 in the front wall 75. An electrical switchover takes place, which is shown schematically in FIG. 12 a is shown. During the aforementioned movement of the rotor 47, the fourth contact 39 disengages from the metallic surface of the rotor 47, since this fourth contact 39 is now located in the cutout 62. This electrical state is shown in FIG. 12 a symbolized by the fact that the switch formed from the fourth contact 39 and the rotor 47 is open. As the F i g. 7 and 8 show, one side of the first contact 69 has come to rest against the third contact 40, so that the circuit shown in FIG. 12 a by the contacts 69 and 40 symbolized switch is closed. As a result, the ignition needle 71 is applied to a terminal of the conductor 16 of the power generator 1.

During this rotational movement of the rotor 47, however, the first contact has been made 69 moved out of the contact position with the second contact 58, so that the ground fault line the ignition needle 71 is open.

The above explanations and the circuit diagrams show that the rotor 47 is equipped with a first contact 69, a second contact 58 and a third contact 40 being mounted on the projectile body 3. The third contact 40 is connected to the power line 16 of the power generator 1. The rotor (forming one electrode) is permanently connected to the second contact 58, while the ignition needle 71 (forming the other electrode) is permanently connected to the first contact 69. In the secured position of the rotor 47, the first contact 69 is in contact with the second contact 58 and is therefore connected to ground, and the first contact 69 in the ignition position of the rotor 47 is in contact with the third contact 40 .

As in the proposed ignition device, the rotor 47 and the ignition needle 71 are short-circuited by the first contact 69 in the safety position, and the ignition needle 71 is disconnected from the power generator 1 by the first contact 69. The fourth contact 39 provided in the ignition device according to the invention briefly switches the power generator 1 when the rotor 47 is in the safety position and is opened when the rotor 47 is in the ignition position. In the secured position, the fourth contact 39 rests against the body of the rotor 47 , and in the ignition position the rotor 47 has rotated into a position in which this fourth contact 39 is no longer connected to ground.

Claims (1)

Claim: Ignition device for a shaped charge projectile with an impact head for generating current pulses, a detonator which is mounted in a rotor which can be rotated from a safety position to an ignition position, the rotor carrying a first contact and a second and a third contact on the projectile body are attached, of which the second contact with one side and the third contact with the other side of the current pulse generator are connected, furthermore one of the two electrodes of the igniter is permanently connected to the second contact, while the other of the two electrodes is permanently connected to the first contact is connected, which is also connected to the second contact in the secured position of the rotor and is connected to the third contact in the ignition position of the rotor after releasing the second contact, characterized in that the projectile and the rotor (47 ) consist of electrically conductive material, although the rotor e has a plate with extension (66, 67) made of an insulating material, which is penetrated by a pin (69) which forms the first contact, that the rotor (47) furthermore has a fourth contact (39) is formed, which is supported on a conductive portion of the rotor (47) when the rotor is in the secured position, and which is supported on the insulating material portion of the rotor when it is in the ignition position and that with the formed as a metal spring second contact (58) connected connection of the power generator (1) also has a ground connection in a known manner with the projectile body (3). Documents considered: German Patent No. 1015 349; Belgian Patent No. 568191; French Patent Nos. 1137 814, 1206 026; U.S. Patents Nos. 2,486,362, 2,853,011. Prior Patents Considered: German Patent No. 1154,740.