RU2578904C1 - Dynamic protection - Google Patents

Abstract

FIELD: military equipment.

SUBSTANCE: invention relates to military equipment, particularly to design of armor protection, designed to counteract to cumulative ammunition. Dynamic protection includes a housing in which there are two parallel metal plates, detonators, uniformly located in the gap between the metal plates, sensors for determining coordinates of penetrating cumulative jet, fixed on inner surfaces of plates. In the gap between metal plates there are vessels filled with fluid, inside the vessels there are rigidly fixed detonators, made in the form of controlled electrical dischargers, power electrodes of which are connected by wires to the output of electric energy storage unit, and igniter electrodes are electrically connected to the generator output of ignitor pulses, whose input is electrically connected to sensors for determination of coordinates of cumulative jet.

EFFECT: higher reliability of dynamic protection.

1 cl, 1 dwg

Description

The invention relates to military equipment, in particular to the design of armor protection, designed to counter cumulative ammunition.

Known dynamic protection (RU 2284004, F41H 5/007, 09/20/2006) for counteracting cumulative ammunition, containing a housing in which there are blocks consisting of metal plates, between which an explosive charge is placed. Each block is equipped with a detonator located in the center of the explosive charge layer and sensors for fixing the spatial angle of the approach of the cumulative jet to the plate surface at the point of contact of the cumulative jet with the plate fixed to the surfaces of the plates adjacent to the explosive charge at a distance of 2-5 mm each from friend. To increase the level of protection of armored vehicles from the action of cumulative munitions, sensors and a detonator were introduced into the dynamic defense design, with the help of which it is possible to initiate explosive substances from neighboring blocks located in the wake of the projection of the cumulative jet onto the protected surface of the armor, to more effectively influence the tail elements of the introduced cumulative jet .

The disadvantage of this dynamic protection is the need to use an explosive charge, the detonation of which can be initiated by falling into the dynamic defense of a non-cumulative projectile, which leads to insufficiently high reliability of its operation.

Known dynamic protection (RU 2284003, F41H 5/007, 09/20/2006), selected as a prototype and containing a housing, an explosive charge placed between two metal plates, detonators uniformly located in the explosive layer at distances of 0.4b and 0 4a, where a and b are the geometrical parameters of the plate, and sensors for determining the coordinates of the penetrating cumulative jet, fixed at distances of 2-5 mm from each other on the surfaces of the plates adjacent to the explosive charge. The level of protection of armored vehicles from the action of cumulative ammunition is ensured by providing control of the trajectory movement of the dynamic protection plate at the stage of dispersal, which is achieved by the initiation of detonators.

Due to the probability of detonation of an explosive charge when a non-cumulative projectile gets into the dynamic defense, the prototype is characterized by low reliability.

The authors were faced with the task of increasing the reliability of the dynamic protection through the use of shock waves arising from an electric discharge in a liquid.

The technical result is achieved in that in a dynamic protection containing a housing in which there are two parallel metal plates, detonators uniformly located in the gap between the metal plates, sensors for determining the coordinates of the penetrating cumulative jet mounted on the inner surfaces of the plates, in the gap between the metal plates vessels filled with liquid; inside the vessels, detonators made in the form of controlled electric arresters are rigidly fixed; ektrody are connected by wires to the output of the electric power storage unit, and the ignition electrodes are electrically connected to the output set fire pulse generator having an input electrically connected to the sensors determine the coordinates of the cumulative jets.

Dynamic protection is shown in the figure.

The dynamic protection includes a housing 1, in which two parallel metal plates 2 are located. In the gap between the metal plates 2, detonators 3 are evenly arranged, made in the form of controlled electric dischargers, for example, trigatrons (Technique of high pulsed currents and magnetic fields. Edited by BC Komelkova M.: Atomizdat, 1970.S. 194).

The detonators 3 contain power electrodes 4 and ignition electrodes 5. The power electrodes 4 are connected by wires to the output 6 of an electric energy storage device 7, for example, a capacitor bank. The ignition electrodes are connected by wires to the output 8 of the ignition pulse generator 9 (Stefanov KS High Voltage Technique. L .: Energia, 1967. P. 217-229), the input 10 of which is electrically connected to the sensors 11 for determining the coordinates of the cumulative jet. The sensors 11 are rigidly fixed on the inner surfaces of the plates 2. In the gap between the metal plates 2 there are vessels 12 filled with liquid. Inside the vessels 12, detonators 3 are rigidly fixed.

The operation of the device is as follows.

When a cumulative projectile hits the housing 1, a cumulative jet is formed. At the moment of contact of the cumulative jet with the upper plate 1, the angle of approach of the cumulative jet to the dynamic protection plate 2 is calculated using sensors 11 that determine the coordinates of the penetrating cumulative jet. Also, using sensors 11, signals are generated that enter the input 10 of the generator of ignition pulses 9 and start it. The ignition pulses from the output 8 of the ignition pulse generator 9 are fed to the ignition electrodes 5, which initiate the breakdown of the gap between the power electrodes 4, as a result of which a spark discharge arises in this gap, which is accompanied by the appearance of shock waves propagating in the liquid filling the vessels 12 (Technique of high Stresses, edited by G.S. Kuchinsky, St. Petersburg: Energoatomizdat, 2003. P. 173). These shock waves, coming into contact with a cumulative jet, cause maximum damage to it. As you can see, the use of shock waves that occur during a spark discharge in a liquid, instead of explosives, can improve the reliability of dynamic protection.

Claims (1)

Dynamic protection comprising a housing in which there are two parallel metal plates, detonators evenly located in the gap between the metal plates, sensors for determining the coordinates of the penetrating cumulative jet, mounted on the inner surfaces of the plates, characterized in that in the gap between the metal plates there are vessels filled liquid inside the vessels detonators are rigidly fixed, made in the form of controlled electrical arresters, the power electrodes of which are connected They are connected by wires with the output of an electric energy storage device, and the ignition electrodes are electrically connected to the output of the ignition pulse generator, the input of which is electrically connected to the sensors for determining the coordinates of the cumulative jet.