NO124894B - - Google Patents

Description

Impact teeth or vibrator teeth.

The present invention relates to an impact detonator or vibration detonator, in particular for hand grenades and rifle grenades, as well as mines, in which an electric current which is provided by means of a battery after a delay time is used for ignition.

Hand grenade delay detonators are known, such as after a period of 4.5 seconds the detonation for the explosives begins. Mechanical impact detonators are also known which bring the hand grenade to detonation on impact, whereby these are, however, very complicated, as they consist of many parts.

The task which forms the basis of the invention is to provide an impact: respectively vibration teeth of the above-mentioned type, which has few moving parts and an absolute safety against unwanted release.

This is achieved according to the invention by

that the gas pressure developed by a gas-rich igniter displaces the battery and brings a contact member connected to one battery pole out of a rest position to a resting position in relation to another contact member in the lighter, where one of the contact members is resiliently mounted in such a way that in the case of shaking, makes a movement whereby electrical contact is provided with the other contact member. Thereby, according to a further feature of the invention, the spring-mounted contact member is designed as a metal ring, which is suspended in at least three points by means of radially arranged springs.

An appropriate further feature of the invention is that the contact on one of the battery's poles in the rest position for the igniter is short-circuited with the housing over an electrically conductive ring disc. This is appropriate because neither by one

in

unwanted impact of the battery it should; an ignition of the explosive charge is triggered. An unwanted impact could, cf. e.g. occur by outflow of potash without prior ignition of the gas-rich batch having taken place.

A further advantageous design of the invention consists in that a pole part on one pole of the battery is located in the metal ring's bore and is isolated from this by means of an insulating ring which has the same outer diameter as the diameter in the metal ring's bore.

Another design for the invention

is that the spring-mounted contact member is designed as a swivel contact while the other contact member consists of a contact cup,

in

in which the swing contact is suspended on an axial spring in relation to the battery pole. Hereby, it is appropriate that the swing contact in the rest position is short-circuited with the housing over a yielding, electrically conductive ring disc against which the swing contact is pressed by the spring.

By means of these moves it was achieved

an impact or vibration detonator that has few parts and can be used for hand grenades, rifle grenades and mines.

The invention is explained in more detail in the following with reference to examples of the embodiment that has been produced

in the drawing, which shows:

Fig. 1 a section through a detonator for hand grenades,

fig. 2 a partial view of fig. 1 in secured position,

fig. 3 cross-section of the igniter along the line III-III in fig. 2,

fig. 4 a section of fig. 1 in an unsecured position,

fig. 5 a section through another embodiment of the igniter in a secured position and

fig. 6 a section through the embodiment according to fig. 5 in an unsecured position.

As can be seen from fig. 1, in the same way as with ordinary hand grenades, when the hoop 1 is released, a striking mechanism 2 is released, which ignites a fuze cap 3. The fuze cap 3 ignites a delay charge 4 which has a firing time of 2-3 seconds.

In contrast to the known design, with the help of this delay set 4, a gas-rich igniter set 5> is ignited, which has the task of conducting kalilut from a container 6 to an activatable battery 7 such as e.g. emits 1.5 volts or IA, whereby this is activated and the battery is simultaneously pushed forward by a few millimeters. At the bottom of the battery 7 there is a plus pole 8 which is designed corresponding to fig. 2 and has a shoulder 9, which in rest position is short-circuited over a disk 10.

Due to the axial forward movement of the battery 7 upon activation, the short circuit is canceled and the positive coil 8 comes with its shoulder 9 out of contact with the disc 10. The pole part 11 belonging to the positive coil 8 is in the rest position for the battery 7 surrounded by an insulating ring 12 in a contact disc 14 suspended by means of three springs 13 (fig. 3), whereby this disc is fixed in its position and at the same time is separated from the plus coil 8 of the battery 7. The contact disc 14 is placed in an annular bearing 15 which is connected to the detonator plus coil not shown.

After the activation and advancement of the battery 7, i.e. after the fuse for the igniter has been lifted, compare fig. 4, during vibrations a contact occurs between the contact disk 14 and the contact 9 of the plus coil 8, whereby the current circuit to the detonator is closed. In the rest position for the igniter, the positive coil 8, 9 of the uncharged battery is short-circuited with the housing 16, so that even in the event of an unwanted outflow of potassium hydroxide, an ignition of the detonator cannot occur.

The one in fig. 5 and 6 shown teeth differ from the one described with the help of fig. 2-4 by a different design for the contact-giving joint. The positive coil 8 of the battery 7 has, in this embodiment of the igniter, a threaded attachment 17,

on which a spring 18 is placed. At the other end of the spring, a pin 19 is mounted to a swing contact 20, whereby a mechanical and electrical connection is provided between the positive coil 8 and the swing contact 20. This is short-circuited in the secured position with the housing 16 by means of a short circuit disc 21, whereby the spring 18 also fixes the swing contact in its position.

Due to the axial forward movement of the battery 7 during activation, the short circuit is canceled and the swing contact 20 pushes through the short circuit disc 21 and can now swing freely due to its spring suspension. In the event of an impact or a vibration, a contact occurs between the swing contact 20 and the relative housing 16 insulated contact cup 22, whereby the current circuit to the detonator is closed.

It is also possible to use the igniter according to the invention as a mine igniter, whereby the delay tube 4 is dimensioned for a longer period of time, e.g. six to ten second burn time. The activation of the battery 7 takes place in this case, e.g. when used in a hand grenade, only after impact on it. The battery's 7 standby time after activation amounts to approx. 30 minutes. For a mine opener, it is desirable to extend the standby time to approx. 24 hours, which can be achieved by installing a corresponding battery. If during this time there is an impact against the mine, or a movement, an ignition corresponding to that for impact igniters is initiated.

As an additional safeguard, the battery 7 can be held firmly in the rest position by means of a distance pin, not shown, or a distance disc.

The sensitivity of the igniter to impacts, respectively to mine action, can be affected by a corresponding design for the contact disk 14 (fig. 3) > increasing the mass and dimensioning of the springs 13, as well as the swing contact 20 and the spring

1 18 in the second embodiment.

Claims (6)

1. Impact or vibration detonators, in particular for hand grenades and rifle grenades as well as mines, in which an electric current that is provided by means of a battery after a delay time is used for ignition, characterized in that a gas pressure, which is developed by a gas-rich detonator (5) displaces the battery (7) and brings a contact member (9, 20) connected to one battery pole (8) out of a rest position to a contact position in relation to another contact member (14, 22) in the igniter, where one of the contact members (14 or 20} is resiliently mounted in such a way that it vibrates a movement whereby electrical contact is provided with the other contact means (9 or 22). 2. Ignition according to claim 1, characterized in that the spring-mounted contact member is designed as a metal ring (14), which is suspended in at least three points by means of radially arranged springs (13). 3. Igniter according to claim 1 or 2, characterized in that a shoulder (9) on one of the battery's poles (8) in the rest position for the igniter is short-circuited with the housing (16) over an electrically conductive ring disc (10). 4. Igniter according to one of the claims 1-3) characterized in that a pole part (11) on one pole (8) of the battery is located in the bore of the metal ring (14) and is isolated from this by means of an insulating ring (12) which has the same outer diameter as the diameter in the metal ring (14) bore. 5. Igniter according to claim 1, characterized in that the spring-mounted contact member is designed as a pivoting contact (20) while the other contact member consists of a contact cup (22) in which the pivoting contact (20) is suspended on an axle in relation to the battery pole (8) fitted spring (18). 6. Igniter according to claim 5> characterized in that the pivoting contact (20) in rest position is short-circuited with the housing (16) over a yielding, electrically conductive ring disc (21), against which the pivoting contact (20) is pressed by the spring (18).