RU2074385C1 - Electroprimer bush - Google Patents

Abstract

FIELD: means for rocket engine solid-propellant ignition. SUBSTANCE: electroprimer bush has casing 1 accommodating ignition charge 9, central current lead-in 10 insulated from casing 1 by bush 11, and two disk electrodes 2,3 with initiating compound 6 and filament bridge 7 between them; the upper disk electrode is connected to the casing. To provide safety in use of the device, bush 11 accommodated current-conducting sleeve 13, whose base adjoins lower disk electrode 3. Sleeve 13 accommodates contactor 14 for axial movement to central current lead-in. The contacting surfaces of central current lead-in and contactor 14 are provided with permanent magnets 17, 18, whose like poles face each other. Central current lead-in 10 and contactor 14 may be made of diamagnetic material; contactor 14 may be made in the form of a cylinder. EFFECT: enhanced reliability. 3 cl, 2 dwg

Description

 The invention relates to the field of technical means used in rocket technology for igniting a solid propellant charge of a rocket engine.

There are various designs of electrocapsule bushings containing a housing, electrodes placed in the housing with an incandescent bridge, initiating and igniter compositions, as well as current conductors [1, 2]
A disadvantage of the known electrocapsule bushings (ECB) is that they do not have protection against stray electric currents arising in the rocket launch circuit under the influence of atmospheric electric fields and lightning discharges. As a result of this, self-propelled missiles from launchers often take place, which is unsafe for the population, as well as buildings and structures.

The closest in technical essence to the claimed object is an electrocapsule sleeve containing a housing, an ignition charge placed in the housing, a central current lead isolated from the housing by a sleeve and two disk electrodes with an initiating composition and an incandescent bridge between them, while the upper disk electrode is connected to the housing, and lower to the central current lead [3]
The known design of the electrocapsule sleeve does not have protection against stray currents arising in the rocket launch system under the influence of atmospheric electricity, as well as from the possibility of the sleeve operating at angles less than critical. As a result, the security of using anti-hail missile systems is reduced and the possibility of their use in ethnic conflicts is not ruled out.

 The aim of the present invention is to ensure the safety of the use of missiles due to the design solutions of ECV, providing protection against stray currents in the missile launch system, as well as the operation of ECV at angles higher than critical.

 This goal is achieved by the fact that in the well-known electrocapsule sleeve containing the housing, a igniter charge is placed in the housing, a central current lead isolated from the housing by the sleeve and two disk electrodes with an initiating composition and an incandescent bridge between them, while the upper disk electrode is connected to the housing, inside bushings placed a conductive cup adjacent the base to the lower disk electrode, while inside the cup placed contact closure with the possibility of free movement along axis to the central current lead, while the contacting surfaces of the central current lead and contact closure are equipped with permanent magnets facing each other with the same poles.

 In the electrocapsule sleeve, the central current lead and the contact closure are made of diamagnetic material, for example aluminum, or its alloys, while the contact closure is made in the form of a cylinder.

 In FIG. 1 shows a general view of EQ: in FIG. 2 fragment of the central current lead.

 The ECV contains a housing 1, inside of which disk electrodes 2 and 3 are placed, isolated from each other by a gasket 4. An opening 5 is provided in the upper disk 2. An initiating part 6 is placed between the disk electrodes 2 and 3, inside of which there is an incandescent bridge 7 connected to the disk electrodes 2 and 3. Above the disk electrode 2 in the housing 1 is placed a cap 8 with an ignition composition 9. A central current lead 10 is insulated along the axis of the housing 1, insulated from the housing 1 by the sleeve 11. In the cavity 12 of the sleeve 11 there is a conductive cup 13, adjacent connecting the base to the lower disk electrode 3, while the cup 13 is not in contact with the central current lead 10. The contact closure 14, made in the form of a cylinder, is freely movable along its axis inside the cup 13. The central current lead 10 and the contact closure 14 are made of diamagnetic material, for example aluminum, or its alloys. The end surfaces of the central current lead 10 and the contactor 14 (Fig. 2) facing each other contain recesses 15 and 16 in which the permanent magnets 17 and 18 are pressed in. The magnets 17 and 18 are facing each other with the same poles.

 A current lead 20 is insulated to the central current lead 10 using a nut 19, insulated from the housing 1 by a gasket 21, and a second current lead 22 is attached to the housing 1, which is fixed when the ECV is screwed into the threaded channel of the rocket engine (not shown). Depending on the conditions of assembly, the beaker 13 can be made as a single element with a disk electrode 3 (Fig. 1), or it can be made as a separate part (Fig. 2) and pressed against the disk electrode 3.

 The characteristics of the permanent magnets 17 and 18 are selected in such a way that, at angles of inclination of the axis “0-0” of the ECV to the horizontal plane exceeding the critical angle α (Fig. 2), the contact closure 14 closes the incandescent bridge under its own weight, overcoming the repulsive force of the magnets 7 with a central current lead 10.

 ECV works as follows.

 To start the ECV to the conductors 20 and 22, an electric current voltage is applied. If the angle of inclination of the axis of the ECV (0-0) to the horizontal plane exceeds the angle a, then contact closure 14, having overcome the force of the magnetic field, will close the electric circuit. In this case, the initiating composition 6 will ignite, and then the igniting composition 9, which ensures the operation of the ECV. If the angle of inclination of the axis "0-0" to the horizontal plane is less than the critical angle a, then the magnetic field will lead contact contactor 14 from the central current lead 10 and the electrical circuit will be open. In this case, the ECV will not work despite the presence of voltage on the conductors 20 and 22.

 The proposed electrocapsule sleeve provides the necessary safety for the use of anti-hail rockets. This eliminates the self-propelled rockets from launchers under the influence of atmospheric electricity.

 The electro-capsule sleeve can also be used in multiple launch rocket systems in order to prevent unauthorized missile escapes from launchers on combat duty.

Claims (3)

 1. An electrocapsule sleeve comprising a housing, an ignition charge placed in the housing, a central current lead isolated from the housing by the sleeve, and two disk electrodes with an initiating composition and an incandescent bridge between them, wherein the upper disk electrode is connected to the housing, characterized in that inside the sleeve a conductive cup is placed adjacent the base to the lower disk electrode, while a contact closure is placed inside the cup with the possibility of free movement along the axis to the central current y, wherein the contacting surface of the central current lead and the contact contactor provided with permanent magnets facing each other with the same poles.  2. The sleeve according to claim 1, characterized in that the central current lead and the contact closure are made of diamagnetic material, for example aluminum.  3. The sleeve according to claim 1, characterized in that the contact closure is made in the form of a cylinder.

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