RU2664254C1 - Device for emission of pyrotechnical cartridges - Google Patents

Abstract

FIELD: military equipment.SUBSTANCE: invention relates to the field of military equipment and can be used to protect an aircraft from guided missiles. Device for ejecting pyrotechnic cartridges contains a box-shaped box with fastening units for replaceable cassettes and a contact module for triggering pyrotechnic cartridges. Body is mounted in a frame with the possibility of rotation in one plane, and the frame is connected to the fuselage of the aircraft with the possibility of rotation in a plane perpendicular to the plane of rotation of the body. In addition, sensors for corners and frame rotation angles, mechanisms for rotating the body and frame, as well as the control unit are introduced. Outputs of the housing and frame angle sensors are connected to the first and second inputs of the control unit, respectively, the first and second outputs of the control unit are connected to the rotation mechanisms of the housing and the frame, respectively, and the third output is connected to the input of the contact module.EFFECT: increase the effectiveness of protection of the aircraft from guided missiles by turning the ejection device in the direction of the attacking missile and shooting pyrotechnic cartridges.1 cl, 2 dwg

Description

The invention relates to the field of military equipment and can be used to protect the aircraft from guided missiles.

The closest in technical essence to the claimed invention is a passive interference emission device, which contains a box-shaped housing fixed to the aircraft with an electronic pulse shaping module mounted on it for triggering jamming cartridges and attachment units for removable cartridges, an electric pulse transmitting device for triggering jamming cartridges guides of jamming cartridges. An electric pulse transmission device for operating jamming cartridges is made in the form of a set of interchangeable contact modules with contact nodes containing three spring-loaded contacts and providing electromechanical contact with the corresponding jamming cartridge, the number and location of each contact node in a removable contact module corresponds to the number and location of jamming cartridges in a removable cartridge [Patent RU No. 2517549 C1, IPC F41H 1/02, 05.27.2014].

The disadvantage of this device is the low efficiency of protecting the defended aircraft from guided missiles, due to the need to perform maneuver of the defended aircraft to ensure the shooting of pyrotechnic cartridges in the calculated area of space, which entails additional physical load on the pilot and an increase in the errors in determining the time of shooting of pyrotechnic cartridges [Nikolaev A.V., Pashko A.D. Ballistic support for throwing active defense elements under the action of small-sized high-speed objects // Moscow Aviation Institute Bulletin, 2016, Volume 23, No. 3, p. 96-101, Pashko A.D. The possibility of hitting guided missiles by creating a cloud of fragments on their trajectory // Collection of scientific articles based on the materials of the III All-Russian scientific-practical conference "Academic Zhukovsky readings". Voronezh: Air Force Research Center “VVA”, 2016, p. 116-121].

The technical result of the invention is to increase the efficiency of protecting the aircraft from guided missiles by turning the ejection device in the direction of flight of the attacking missile and shooting pyrotechnic cartridges.

The specified technical result is achieved by the fact that in the known device for the discharge of pyrotechnic cartridges containing a box-shaped body with attachment units for removable cartridges and a contact module, the body is mounted in a frame rotatably in the same plane, and the frame is connected to the fuselage of the aircraft with rotational rotation perpendicular to the plane of rotation of the housing, and additionally introduced sensors of the angles of rotation of the housing and frame, the rotation mechanisms of the housing and frame, as well as the control unit, while ode rotation angle sensor body and connected to the first frame and the second input of the control unit respectively, first and second outputs of the control unit are connected to the steering gear housing and the frame, respectively, and the third output is connected to an input pin of the module.

The essence of the invention lies in the fact that the onboard defense complex of the aircraft detects an attacking missile and, based on the parameters of the missile’s movement with onboard computing devices, the time of shooting pyrotechnic cartridges and the angles of rotation of the ejection device of the pyrotechnic cartridges are calculated so that the pyrotechnic cartridge gets into the area of space for hitting the rocket . Data on the firing time and the required angles of rotation of the ejection device are sent to the control unit, which compares them with the actual angular position of the body and frame. The mismatch signal is fed to the rotation mechanisms of the case and frame. After the rotation of the ejection device in the direction of flight of the attacking rocket, the pyrotechnic cartridge is fired.

The invention is illustrated in FIG. 1, where indicated:

1 - box-shaped body;

2 - frame;

3 - housing rotation mechanism;

4 - frame rotation mechanism;

5 - power element of the fuselage;

6 - skin of the fuselage of the aircraft.

The block diagram of the invention is illustrated in FIG. 2, where indicated:

7 - sensor of the angular position of the housing;

8 - sensor of the angular position of the frame;

9 - control unit;

10 - the mechanism of rotation of the housing;

11 - frame rotation mechanism;

12 - pin module.

The rotation mechanisms of the body and frame are designed to rotate the body and frame to the required angles. As a mechanism, for example, a gear motor of the MN-145B type can be used [see, for example, the Handbook of a mechanical constructor. Volume 3 / Anuryev V.I. -M.: Engineering, 2006, p. 659-663, 750].

The purpose of the sensors for the angular position of the body and frame are clear from their name. As a sensor, for example, a potentiometric sensor can be used [see for example, Kazakov I.E., Isaev V.N. Fundamentals of automatic weapons systems. M .: VVIA, 1991, p. 84].

The control unit is designed to compare the actual values of the angular position of the hull and frame with the required values of the angular position coming from the computing devices of the aircraft defense complex, issuing commands to the rotation mechanisms of the hull and frame for turning and to the contact module for shooting pyrotechnic cartridges.

The device operates as follows. The aircraft’s onboard defense system detects an attacking guided missile and, based on the parameters of the missile’s movement, calculates the angle of rotation of the ejection device and the time of the firing of the pyrotechnic cartridge to ensure the firing of the pyrotechnic cartridge in the area of space for hitting the rocket. From the computing devices of the airborne defense complex, signals are proportional to the values of the required rotation angles of the pyrotechnic cartridge ejection device and the firing time to the control unit 9. Next, the required values of the angular position of the device are compared with the real values received from the angular position sensors of the housing 7 and frame 8, and transmission the control signal to the rotation mechanisms of the housing 10 and the frame 11 to work out the error signal. After that, the command is transmitted to the contact module 12 for shooting pyrotechnic cartridges in the calculated area of space.

Claims (1)

A pyrotechnic cartridge ejection device comprising a box-shaped body with attachment units for removable cartridges and a contact module, characterized in that the body is mounted in a frame rotatably in one plane, and the frame is connected to the aircraft fuselage with rotation in a plane perpendicular to the plane of rotation of the body additionally introduced sensors of angles of rotation of the housing and frame, rotation mechanisms of the housing and frame, as well as a control unit, while the outputs of the sensors of angles of rotation of the housing and frame with connected to the first and second input of the control unit, respectively, the first and second outputs of the control unit are connected to the rotation mechanisms of the housing and frame, respectively, and the third output is connected to the input of the contact module.

Images