RU2667168C1 - Method of correcting trajectory of extended range base bleed projectile and head electromechanical fuze with brake device - Google Patents

Abstract

FIELD: weapons and ammunition.SUBSTANCE: invention relates to ammunition, in particular to methods for correcting the range of scattering of high-explosive fragmentation extended range projectiles. By the method, the firing time of the fuze brake device is calculated. Enter this time value into the fuze calculating device. Measure the burning time of solid fuel in base bleed of the projectile from the moment the projectile leaves the gun barrel and until the burning process ends. In the calculated time of activation of the fuze brake device, a correction is made taking into account the measured burning time of the solid fuel of the gas generator. At the same time, the combustion of fuel in the gas generator is stopped by the explosion of a piece of explosive, installed in the zone of burning of solid fuel, with a mass that does not lead to detonation of the explosive of the projectile when it is blasted. Under the action of the shock wave from the explosion of the checker, the remains of the unburned solid fuel are ejected from the cavity of the gas generator. At the end of the solid fuel combustion process, the moment of fixation by the acoustic device installed in the head fuze, the acoustic pulse accompanying the explosion of the checker with the explosive, is taken.EFFECT: increasing the hit precision.1 cl, 2 dwg

Description

The invention relates to defense technology and can be used in various high-explosive fragmentation munitions designed to hit targets with fragments and high-explosive action.

The creation of ammunition for long-range shooting is one of the main tasks in the design of modern artillery weapons. At the same time, modernization of all elements of the shot, including the shape of the projectile, is carried out in order to reduce air resistance to its movement. A separate direction was received by the installation of devices in the projectile, providing a decrease in the degree of discharge of air in the bottom of the projectile. In such shells, bottom gas generators are installed.

For example, in a long-range high-explosive fragmentation projectile of the Alagez type (see Wikipedia), a gas generator (solid fuel charge) operates in the initial part of the projectile movement for about 20 seconds. The use of such a scheme for creating backpressure in a projectile can increase the firing range by more than 10%.

At the same time, the use of additional devices in shells leads to a deterioration in the accuracy of firing at long distances. To compensate for this, it is proposed to carry out the correction of the projectile movement using braking devices installed in the projectile head fuse.

For shells with a bottom gas generator, it is necessary to additionally take into account the operating time of this generator.

Such a technical solution is given in the author’s work (Scientific and Technical Collection of the State Research Center of the Russian Federation FSUE TsNIIHM named after D. I. Mendeleev "Ammunition", 2016, No. 2, pp. 64-70). In this technical solution, the operating time of the gas generator is determined as the time of the presence of high temperature in the combustion zone of solid fuel in the gas generator. This temperature is measured using a thermocouple, and information is transmitted to the head fuse via conductors passing through the explosive charge. Such a transmission scheme is complicated due to the difficulties of sealing the explosive in the shell of the shell in the presence of any objects (conductors), and, in addition, it has low accuracy, since in the zone of the shell after burning solid fuel for a long time, the temperature remains high, which makes it difficult to accurately measure time.

In the invention, there are no such drawbacks.

The proposed technical solution is illustrated by figures.

FIG. 1. The bottom of the shell with a gas generator: 1 - shell shell, 2 - explosive shell, 3 - explosive bomb, 4 - insulating insert, 5 - tracer, 6 - thermal insulation, 7 - solid fuel charge, 8 - charge body, 9 - nozzle. FIG. 2. An oscillogram of recording the response of an acoustic device installed in a head fuse during the combustion of solid fuel and the explosion of an explosive bomb.

A positive effect is achieved by the fact that in the charge of solid fuel, from the side pressed to the bottom of the projectile, an explosive bomb, such as tetryl, is installed. A checker is many times smaller than a solid fuel charge. For example, a solid fuel charge at a density less than the density of explosive material weighs about one kilogram, and a checker weighs no more than five grams. The burning of solid fuel begins at the moment the projectile leaves the bore, under the action of a high temperature of the blow-out gas of the shot, and is further supported by the burning of the combustible substance of the tracer, which, as a rule, is installed in the central part of the charge of solid fuel. In FIG. 1 schematically shows the location of the elements of the bottom gas generator. From the influence of the combustion temperature of these substances at the main stage of the gas generator operation, the explosive bomb (item 3 in FIG. 1) is protected by solid fuel itself (item 7 in FIG. 1). In addition, between the tracer (pos. 5 in Fig. 1) and checker 3, a thermally insulating insert (pos. 4 in Fig. 1) is installed. The combustion of the solid fuel of the gas generator proceeds from the free surface to the bottom of the projectile, i.e. towards a piece of explosive material. Gases generated during the combustion of solid fuel are ejected through the hole (nozzle pos. 9 in Fig. 1) in the bottom of the projectile.

At the moment of approach of the combustion zone of the solid fuel of the gas generator to the checker, the latter explodes under the influence of the high temperature of the combustion of the fuel (more than 1000 ° C). For example, for a tetrile block, the temperature of the onset of detonation is approximately 230 ° C. In the case of a block explosion, under the influence of a shock wave, the remains of unburned solid fuel are ejected from the cavity of the gas generator, and its operation stops.

The shock wave that occurred at the time of the explosion of the checker creates elastic vibrations in the body metal, which, according to the laws of acoustics, propagate in the shell of the shell in all directions, including in the direction of its head part, in which a head electromechanical fuse is installed using a threaded connection. Using an acoustic receiver mounted in the fuse, for example, using a PZ19 piezoceramic, these acoustic vibrations are recorded. An electronic device, also installed in the fuse, records the time from the moment the projectile takes off from the gun’s barrel until the moment of the appearance of an acoustic impulse from the explosion of a bomb of explosive material. This period of time is taken as the operating time of the gas generator. Based on the measurement of this actual operating time of the gas generator, the computing device of the head electromechanical fuse introduces an amendment during the start of operation of the braking devices of the fuse. If the measured operating time of the gas generator is less than the calculated, then the calculated value increases, and vice versa.

In FIG. Figure 2 shows the process of recording acoustic signals using an oscilloscope connected to an acoustic device of an electromechanical head fuse screwed into the shell of an Alagez-type projectile when burning a solid fuel charge and exploding a tetramil bomb weighing two grams. From the above data it is seen that the impulse from the explosion of the checkers is clearly detected against the background of noise from the burning of solid fuel. After the explosion of the checkers, the combustion process ceased, and the noise level decreased significantly. The experimental data show the technical feasibility of implementing the claimed technical solution.

The above information about the claimed invention, characterized in an independent claim, indicates the possibility of its implementation using the described in the application and known means and methods. Therefore, the claimed method meets the condition of industrial applicability.

Claims (1)

A method for correcting the trajectory of a long-range artillery shell with a bottom gas generator and a lead electromechanical fuse with a braking device, which consists in calculating the firing time of the braking device of the fuse, introducing this time value into the computing device of the fuse, measuring the burning time of solid fuel in the bottom gas generator of the projectile from the moment of exit shell from the barrel of the gun and before the end of the combustion process, at the calculated time of switching on the braking device of the fuse the taste, taking into account the measured burning time of the solid fuel of the gas generator, characterized in that the combustion of fuel in the gas generator is stopped by detonating the explosive drafts installed in the zone of burning of solid fuel with a mass that does not detonate the explosive of the projectile when it is detonated under the action of an explosion shock wave checkers, the remains of unburned solid fuel are thrown out of the cavity of the gas generator, at the time the solid fuel combustion process ends, the moment of fixation by the acoustic device is taken, installed in the head fuse, the acoustic impulse accompanying the explosion of the bomb with the explosive.

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