RU2072096C1 - Ballistic cap of artillery guided missile - Google Patents

Abstract

FIELD: military equipment, artillery guided missiles. SUBSTANCE: ballistic cap of artillery guided missile uses a time fuze secured on the missile top by the destructible member separation device in the form of a conical hollow case with a separation chamber, powder charge and an electric primer. The separation device case has a through side hole, closed with a high-pressure chamber for the electric primer installed for axial motion of the casing of the central insert on and perpendicular to the missile axis, and a powder charge. A dissector in the form of a sleeve with ports communicating with the gas-dynamic channel and perpendicular to the longitudinal axis of the high- pressure chamber is installed between the electric primer and powder charge. An annular groove, communicating with the separation chamber by a square-section through slot, is made in the wall of the high-pressure chamber against the ports. EFFECT: improved design. 2 dwg

Description

 The invention relates to the field of military equipment, in particular to artillery guided missiles with a homing head at the final flight site.

 Known protective cap [1] protects the front end of the projectile from contamination during operation. This protective cap is removed before the shot and solves a particular problem.

 In the new classes of guided artillery shells, in the bow of which an optical homing head with spherical glasses in front is mounted, in addition to the indicated task, it is necessary to ensure the separation of the ballistic cap at the time the control starts.

 An analysis of the state of the development of technology in this area made it possible to identify the closest technical solution to the design of the ballistic shell cap [2], which is the prototype of the proposed solution.

 This ballistic cap contains a remote tube fixed on the top of the projectile with a destructible element, a separation device in the form of a conical hollow body with a separation chamber with a powder charge and an electric igniter.

 The described ballistic cap makes it possible to improve the aerodynamic shape of the projectile (its flight range) and to close the optical homing head from natural and artificially induced interference.

 The proposed design is illustrated in the drawing, where in FIG. 1 shows a general view of a ballistic cap; FIG. 2 partial cut of its wall along AA; in FIG. 3 type B.

 The ballistic cap contains: a remote tube 1, the housing of the separation unit 2, the central insert 3, the shell of the projectile with optics 4, a screw 5, a high pressure chamber 6, a powder charge 7, a cavity of the separation chamber 8, an electric igniter 9, a divider 10, a rectangular groove 11 , an annular groove 12, the windows of the divider 13, connected by a gas-dynamic channel 14, a through side hole 15.

 The operation of the ballistic cap is as follows: when an electrical impulse is supplied from the remote tube 1, an electric igniter 9 is activated, the force of the flame of which is directed to the powder charge 7. Between the electric igniter and the powder charge there is a divider 10, which is made in the form of a glass with thread on the outer surface, and its bottom has four symmetrical windows 13 in the plane perpendicular to the longitudinal axis of the powder charge 7, for the passage of the products of combustion of the electric igniter 9.

 The presence of a gas-dynamic channel 14 and windows 13 in the divider in a plane perpendicular to the longitudinal axis of the charge eliminates the direct impact of the flame force on the end face 7 of the igniter 9, weakening the dynamic effect of the flame force on the charge. Passing through the divider 10, part of the combustion products of the electric igniter 9 flows, bypassing the charge 7, through the windows 13 of the divider, oriented in a rectangular groove 11, into the compartment 8. The annular groove 12 allows the gas to flow into the groove over the entire area of the divider. The bulk of the products of combustion of the electric igniter, leaving the windows 13 of the divider, is evenly distributed along the annular groove 12 in the high-pressure chamber and reliably ignites the powder charge 7.

 The mutual arrangement of the rectangular groove 11, the annular groove 12 in the high-pressure chamber and the windows 13 of the divider provides the same discharge of gases of the electric igniter 9 into the separation chamber for any angular arrangement of the windows 13, which creates a uniform ignition of the powder charge.

 In the case of a partial overlap of the rectangular groove by a powder charge due to overloads during charge control, the combustion products from the high-pressure chamber can flow through the annular groove and the windows of the divider.

 Under the influence of the pressure of the powder gases in the separation chamber, the screws 5 are destroyed, the housing of the separation device moves axially relative to the stationary central insert 3, opening the side hole 15 in the housing.

 Then the moving body captures the insert, drawing it into motion in the axial direction and, under the influence of reactive force, leaves the projectile flight path.

The proposed design ensures reliable functioning of the ballistic cap in the temperature range plus minus 50 ^o C, excluding the splitting of the powder charge.

Claims (1)

 Ballistic cap of an artillery guided projectile containing a distant tube fixed on the top of the projectile with a destructible element, the separation device in the form of a conical hollow body with a separation chamber, a powder charge and an electric igniter, characterized in that a through side hole is made in the separation device body, which is closed with an axial position moving along it the body of the central insert with a perpendicular axis of the projectile to the high-pressure chamber under electric ignition a body and a powder charge, between which a divider is installed in the form of a glass with windows perpendicular to the longitudinal axis of the high-pressure chamber connected by a gas-dynamic channel, while an annular groove is made in the wall of the high-pressure chamber opposite the divider windows, in communication with the separation chamber through a rectangular groove.

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