RU2778491C2 - Method for complex diagnostics of the serviceability of all components of the curtain laying system - Google Patents

Abstract

FIELD: military technology.

SUBSTANCE: invention relates to the field of providing combat training of artillery weapons complexes and is aimed at creating effective maintenance tools, in particular diagnostic tools for curtain laying systems. A method for complex diagnostics of the serviceability of all components of the curtain laying system, using a diagnostic complex including a grenade simulator and a laser rangefinder/target designator radiation simulator, consists in irradiating by the laser rangefinder/target designator of the laser radiation detection sensors of the curtain laying system and subsequent visual monitoring of the presence of threat selection signals by type of laser radiation, crew warning signals, target designation radiation source, automated guidance of launchers and confirmation of the presence of a “START” signal on the selected launcher using a grenade simulator.

EFFECT: possibility of complex diagnostics of curtain laying systems installed at military equipment facilities is achieved.

1 cl, 2 dwg

Description

The invention relates to the field of providing combat training of artillery weapons systems and is aimed at creating effective maintenance tools, in particular diagnostic tools for curtain installation systems.

Curtain systems are designed to protect tanks, infantry fighting vehicles, self-propelled artillery mounts and other military equipment from anti-tank guided missiles and laser-guided munitions, from artillery systems with laser rangefinders, as well as to place a masking smoke screen in a selected direction. Modern automated curtain installation systems include a set of sensors for detecting laser radiation, control units of various designs and operating principles, and a set of unified launchers (PU) for launching smoke grenades [1].

When attacking an object with an installed screening system with artillery ammunition with laser illumination or using a range finder, the sensors of the screening system detect radiation of a certain wavelength range and modulation pattern, as well as determine the direction to the radiation source. The control units provide for the selection of threats by the type of laser radiation, informing the crew, target designation of the radiation source, automated guidance of launchers and shooting grenades (setting the curtain) in the required direction.

Despite the obligatory equipping of all modern tanks, infantry fighting vehicles, self-propelled artillery mounts and other military equipment with curtain installation systems, maintenance tools that provide comprehensive diagnostics of curtain installation systems are not offered. Analogues of the claimed invention have not been identified.

Regular maintenance instructions for the air curtain installation system offer the following diagnostic methods:

- the integrity of the starting circuits of the PU is checked by short circuiting them and checking the integrity of the conductors by measuring the resistance when passing small currents [3]. The method does not provide for checking the circuit with a real starting current and leads to the failure of the PU, if a regular START signal is accidentally given.

- the control unit of some curtain installation systems can be checked using a special control device, but it does not provide diagnostics of laser radiation detection sensors, the operability of the combat vehicle drive control circuits during target designation and control of the required starting currents on the launcher. The main drawback of the device is the lack of versatility - it provides diagnostics of the control system of the SDR of only one, specific type of control unit. However, the device is expensive.

- the serviceability of the sensors for detecting laser radiation and, in part, the functioning of the control system of the curtain installation systems is checked by irradiating the object under test, for example, a tank, with a laser rangefinder of a similar tank [2]. This technique requires special aids and a certain placement of combat vehicles on the ground, is dangerous for the crews of combat vehicles and does not provide verification of the most difficult mode of operation of curtain installation systems, as well as the serviceability of launchers.

The objective of the claimed invention is to create a universal set of comprehensive diagnostics of all known systems for setting curtains installed on military equipment.

The technical result from the use of the claimed invention consists in a comprehensive diagnostics of the health of all components of the system for setting curtains when irradiated by a simulator of a laser range finder / target designator of sensors for detecting laser radiation of a system for setting curtains and subsequent visual monitoring of the presence of signals for selecting threats by the type of laser radiation, warning signals for the crew, target designation of the source radiation, automated guidance (or selection) of launchers and confirmation of the presence of a START signal on the selected launcher using a grenade simulator.

The specified technical result is achieved by using a diagnostic kit for a curtain installation system, including a grenade simulator and a laser rangefinder/target designator radiation simulator. The kit provides diagnostics of the serviceability of the starting circuits of the PU, the operability of the sensors for detecting laser radiation and the control units of the SPZ in all operating modes.

The grenade simulator (Fig. 1) consists of a body 2, a bottom flange 3, a top cover 1, an indicator LED 5, an electronic circuit 4 and fastening elements. The outer dimensions, the shape of the hull 2 and the bottom flange 3 completely repeat the dimensions and shape of the standard smoke grenade. The top cover 1 ensures the convenience of loading and unloading the launcher when using the simulator, as well as mounting the indicator and protecting it from damage. The electronic circuit 4 ensures the control of the PU charge by the control unit of the air curtain installation system, the rated current in the PU circuit when the START signal is given, the glow of the indicator LED 5 after the START signal is received for a long time.

The radiation simulator of the laser rangefinder/target designator (Fig. 2) consists of a housing 11, which contains a laser emitter 6, an indicator LED 7 for turning on the simulator emitter, toggle switches for powering on 8 and selecting an operating mode 9, a single pulse start button 10, an electronic circuit. A power cable is attached to the body of the simulator for connection to the on-board power supply network of the tested object. The simulator of the laser rangefinder/target designator, depending on the selected mode of operation, generates a single pulse or a continuous sequence of pulses of laser radiation. A single pulse imitates the illumination of the sensors of the curtain setting system with a range finder, and a sequence of pulses simulates continuous modulated laser radiation from artillery target designators or anti-tank systems. The frequency and shape of laser radiation pulses are determined by the technical requirements for the SDR. Since the laser radiation is outside the visible range, an indicator LED is used to indicate the simulator is on.

The claimed invention works as follows.

The grenade simulator is installed in the tube of the launcher, while providing mechanical control of the serviceability of the retaining ring of the launch tube. The air curtain setting system is switched on in the normal mode of operation. The electrical circuit of the grenade simulator provides control of the charge of the corresponding launcher by the control unit of the air curtain installation system. With the help of a simulator of a laser range finder/target designator, one of the sensors for detecting laser radiation of the system for setting curtains from a selected direction is irradiated. Depending on the selected modes of operation of the radiation simulator and the system for setting curtains, the control unit of the system generates appropriate signals for informing the crew, and also guides or selects the appropriate charged launcher and sends a START signal to the grenade. At the same time, the electric circuit 4 of the grenade simulator loads the control unit of the air curtain installation system with the required starting current and provides an indication of the passage of the START signal by a long glow of the signal LED 5. presence of radiation. At the same time, the radiation parameters are safe for the operating personnel.

Thus, the claimed invention makes it possible, by acting on the initial element of the system for setting curtains (laser radiation sensors) and controlling the presence of the final action of the system (starting fans in the required direction), to diagnose the performance of all known systems for setting curtains, regardless of their device, operation algorithm and composition. .

The use of the present invention has the following advantages:

- provides a comprehensive check of all circuits, blocks and algorithms of the air curtain installation system;

- versatility, provides control of all known and promising systems for setting curtains;

- small, light and safe design, low cost to manufacture and easy to operate.

Sources of information

1. Complex of optical-electronic suppression, Operation manual, JSC "NPO "Elektromashina", 2013

2. Tank T-90S, Operating Instructions, OAO Scientific and Production Corporation Uralvagonzavod.

3. System 902, Technical description and operating instructions.

Claims (1)

A method for comprehensive diagnostics of the health of all components of the air curtain installation system, using a diagnostic complex, including a grenade simulator and a laser range finder / target designator radiation simulator, which consists in irradiating laser radiation detection sensors of the curtain installation system with a laser range finder / target designator simulator and subsequent visual control of the presence of threat selection signals according to the type of laser radiation, crew warning signals, target designation of the radiation source, automated guidance of launchers and confirmation of the presence of the “START” signal on the selected launcher using a grenade simulator.

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