RU12463U1 - STABILIZATION AND GUIDANCE SYSTEM - Google Patents

Abstract

A stabilization and guidance system comprising a control panel, an integrator and an actuator connected in series, characterized in that a fiber-optic angular velocity sensor is introduced into the system, the output of which is connected to the second input of the integrator.

Description

A predictable utility model relates to the field of automatic control systems for objects located on a moving base, and specifically to stabilization and guidance systems in two planes of artillery weapons, for example, infantry fighting infantry fighting vehicles (BMPs).

Known stabilization and guidance system of the weapon block BMN-3 (product 2E52) 1, a block diagram of which is presented in figure 1. The system contains a gyrotachometer 1, an integrator 2 and an actuator 3 connected in series. In addition, the control panel 4 is etched, the output of which is connected to the second input of the integrator 2. By the signals of the gyrotachometer 1, stabilization is performed, and by the signal from the console 5 of equation 4 pointing the weapon block.

The disadvantage of the described system is the significant time that the system is ready for operation, caused by a rather significant time for the gyroscopic devices to reach the operating mode. For gyrotachometer 1, this time is from 1 to 3 minutes for various operating conditions of the system. This readiness time leads to a delay in the start of the stabilization system, which reduces the efficiency of using BMN-3 for its intended purpose.

The proposed utility model is aimed at reducing the time of readiness of the stabilization system and guidance to work.

The essence of the proposed technical solution lies in the fact that the fiber-optic angular velocity sensor, the output of which is connected to the second input of the integrator, is introduced into the stabilization and guidance system containing the control panel, integrator and actuator connected in series.

The application materials are illustrated by drawings, where:

- figure 1 - presents a block diagram of a system of stabilization and guidance of the product 2E52, adopted as a prototype;

- figure 2 - presents a block diagram of the proposed utility model.

Information confirming the possibility of implementing the proposed technical solution to obtain the above technical result, are as follows.

The proposed stabilization and guidance system (Fig. 2) consists of series-connected control panel 1, integrator 2 and actuator 3. In addition, a fiber-optic angular velocity sensor 4 is introduced into the system, the output of which is connected to the second input of integrator 2.

The proposed system works as follows. By the signal of the control panel 1, guidance is carried out, and by the signal of the fiber optic angular velocity sensor 4, stabilization of the control object is carried out. The fiber optic angular velocity sensor 4 has an almost instantaneous operational readiness, as does not have moving mechanical parts. This sensor determines the angular velocity by measuring the deviation of the light beam caused by the influence of the angular velocity when the sensor rotates around an axis perpendicular to the measuring plane. Due to the indicated feature of the sensor, the total readiness time of the stabilization and guidance system is significantly reduced to almost 0.5 - 1 s, thereby increasing the efficiency of using objects equipped with this system.

The proposed technical solution was used in the documentation of the modernized stabilization and guidance system of the weapon block of a promising infantry fighting vehicle, bench tests of the layout of the proposed system showed that the system’s readiness for work was reduced to 1 second.

LITERATURE

1. The stabilizer 2E52. Technical description PB 331 092TO. Archive VNII Signal.

Claims (1)

A stabilization and guidance system comprising a control panel, an integrator and an actuator connected in series, characterized in that a fiber-optic angular velocity sensor is introduced into the system, the output of which is connected to the second input of the integrator.