RU2505775C1 - Tank gun stabiliser - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: proposed stabiliser comprises unit of signal processing transducers incorporating amplifier-converter and automatic compensation module, transfer motion speed transducer arranged at tank turret. Automatic compensator comprises 1^st and 2^nd adders, 1^st, 2^nd, 3^rd and 4^th multipliers, 1^st and 2^nd integrators. Transducer unit is connected with 1^st adder input and first inputs of 1^st and 2^nd multipliers. Transfer motion speed transducer output is connected with second inputs of 1^st and 3^rd multipliers and differentiator, output of the latter being connected to second inputs of 2^nd and 4^th multipliers. Outputs of 1^st and 2^nd multipliers are connected to inputs of integrators, outputs of the latter are connected to first inputs of 3^rd and 4^th multipliers. Outputs of 3^rd and 4^th multipliers are connected to end adder first and second inputs. Output of the latter is connected to second input of 1^st adder.

EFFECT: precise electric drive of vertical aiming and stabilisation.

1 dwg

Description

The invention relates to automatic weapons control systems, in particular to stabilizers of tank weapons.

Known stabilizer of tank weapons (Pat. RF №2421679) (adopted as a prototype), containing vertical and horizontal guidance drives, a gun, a control unit and an absolute speed sensor of the gun and a block of sensors and auxiliary devices connected to it, a power amplifier electrically connected to the block the control unit, the control unit is equipped with a signal processing module configured to process feedback signals generated by a power amplifier, an absolute speed sensor, while the vertical navigation drive The unit is made electric, including an electric cylinder, consisting of an electric motor with a rotor position sensor, an electric motor connected to a power amplifier, and a power helical reversible transmission, which is mechanically connected to the motor shaft to enable the gun to rotate.

The disadvantage of the prototype tank armament of the prototype is the relatively low accuracy of stabilization of the vertical guidance (VL) drive, due to two main factors: low efficiency of the helical mechanical transmission and the inertia of the armature of the executive electric motor, which in the stabilization mode creates significant disturbing effects on the stabilization object (gun).

The claimed technical solution is aimed at improving the accuracy of VN drives by introducing into the drive structure a two-channel, automatically tunable scheme for compensating for errors from disturbing tank oscillations in the plane of the gun’s movement.

The drawing shows a functional diagram of the proposed stabilizer tank weapons.

To achieve the technical result provided by the invention, a tank weapon stabilizer comprising an electric horizontal guidance (GN) drive mechanically connected to a turret, a vertical guidance electric drive (EP VN) 4, including an electric motor with a rotor position sensor, electrically connected to a power amplifier, and a mechanical a lift connected to the cannon, a sensor unit (DB) 1, mechanically and electrically connected to the turret and the cannon of the tank, a signal processing unit (BOC), including th amplification-converting device (UPU) 3 and an automatic compensation module (IAC), a portable movement speed sensor (DSPD) 5, located on the tank turret, and an automatic compensation module contains the first 2 and second 13 adders (SU), a differentiator (DIF) 6, the first 7, the second 8, the third 11 and the fourth 12 multipliers (MUs), the first 9 and second 10 integrators (I), while BD1 (a stabilization error meter on the HV channel) is connected to the first input of the first SU 2, and also the first inputs of the first MU 7 and the second MU 8, the output of the DSPD 5 is connected to the second the inputs of the first MU 7 and the third MU 11, as well as with the differential amplifier 6, the output of which is connected to the second inputs of the second MU 8 and the fourth MU 12, the outputs of the first MU 7 and the second MU 8 are connected respectively to the inputs of the integrators 9 and 10, the outputs of which are connected to the first inputs of the third MU 11 and the fourth MU 12, the outputs of which are connected respectively to the first and second inputs of the second SU 13, the output of which is connected to the second input of the first SU 2, the output of which is connected to series-connected UPU 3 and the drive of the VL 4 electric drive.

Consider the operation of the automatic error compensation circuit of the VN electric drive. When the tank moves over rough terrain, a stabilization error occurs, the main reason for which is the disturbing vibrations of the hull and turret of the tank in the plane of movement of the gun. The general principle of error compensation is that a compensation signal is supplied to the drive control loop, which is a function of the disturbing signal that caused the error. The generated compensation signal must coincide in amplitude and phase at the summation point with an error signal without compensation. For a linear system with the exact coincidence of the amplitude and phase, the compensation signal will become control, and the error will be zero. In a real nonlinear system this cannot be achieved completely, but the error can be reduced several times.

Thus, the automatic compensation scheme solves two problems. The first task is to ensure that the compensation signal and the error signal are in phase without compensation. This problem is solved by summing in the right proportion the direct and quadrature signals of the tower speed in the plane of movement of the gun. In the proposed technical solution, the direct signal is a tower oscillation speed signal (DSPD 5 output), and a quadrature signal is obtained by differentiating the tower speed signal (DIF 6). Next, each of the signals is subjected to automatic scaling (self-tuning), passing through blocks 7, 9, 11 (direct channel) and 8, 10, 12 (quadrature channel), followed by their summation in the second SU 13.

Consider the process of automatically adjusting the compensation signal using the direct channel as an example. The channel provides MU 7, which multiplies the error signal from DB 1 and the tower speed signal (DSPD 5 output) and the first And 9 connected in series with it. Due to the fact that the integrator time constant is chosen large enough, the integrator will respond (accumulate the signal) to a constant, or slowly changing component of the signal at its input (i.e., at the output of MU 7). The constant component at the output of the first MU 7 will become equal to zero (equilibrium state) only in the absence (full compensation) in the error signal in phase with the signal of the tower speed component. The third MU 11, the inputs of which respectively receive signals from the first And 9 and the tower speed signal with DSPD 5, is a regulator of the level of the compensation signal for the common mode component.

The channel works similarly in terms of the quadrature component of the tower speed (pos. 8, 10, 12). Its role is to develop such a level of the quadrature component of the compensation signal so that the total signal from the second SU 13, filed in the UPA 3, provides a minimum of drive stabilization errors.

The effectiveness of the proposed technical solution was tested during testing of the electric drive of guidance and stabilization of the tank gun at the test bench of the VNII Signal OJSC, as well as during testing of the drive in the T-72 tank at UKBTM OJSC (test report, October 2011). Tests have shown that the proposed two-channel automatic compensation scheme in the application allows several times to reduce the stabilization error in comparison with the prototype and bring it to the level of promising requirements.

Claims (1)

A tank weapon stabilizer comprising an electric horizontal guidance (GN) drive mechanically connected to a turret, a vertical guidance electric drive (EP VN), including an electric motor with a rotor position sensor, electrically connected to a power amplifier, and a mechanical lift connected to the gun, a sensor unit mechanically and electrically connected to the turret and the cannon of the tank, characterized in that a signal processing unit is included in it, including an amplifying-converting device and an automatic module static compensation, a portable speed sensor located on the tank turret, the automatic compensation module containing the first and second adders, a differentiator, first, second, third and fourth multipliers, first and second integrators, while the sensor unit is connected to the first input of the first adder , as well as the first inputs of the first and second multiplier devices, the output of the portable speed sensor is connected to the second inputs of the first and third multiplier devices, as well as with a torus whose output is connected to the second inputs of the second and fourth multiplier devices, and the outputs of the first and second multiplier devices are connected respectively to the inputs of integrators, the outputs of which are connected to the first inputs of the third and fourth multiplier devices, while the outputs of the third and fourth multiplier devices are connected respectively to the first and second inputs of the second adder, the output of which is connected to the second input of the first adder, while its output is connected to the input amplifier-converting a device whose output is connected to an electric drive vertical guidance.