RU43061U1 - SIMULATOR FOR TRAINING ARTILLERY CALCULATIONS - Google Patents

Abstract

1. A simulator for training artillery calculations, containing an electronic computer, a simulator of a launch object, a simulator of a launch device, spatial sensors, installation sensors of a simulator of a launch object, a switch and an acoustic system, characterized in that a second electronic computer, a simulator, is additionally introduced into it a laser rangefinder and a visual environment simulator, the first electronic computer connected to a laser target simulator a range finder, the second electronic computer is connected to a simulator of a launching object and a simulator of visual environment, while the first and second electronic computers are interconnected. 2. The simulator for training artillery calculations according to claim 1, characterized in that the first electronic computer is connected to the position sensors through the switch. A simulator for training artillery calculations according to claim 1, characterized in that the second electronic computer is connected to a simulator of a launch device and sensors for installing a simulator of a launch object through a switch. The simulator for training artillery calculations according to claim 1, characterized in that the first and second electronic computers are interconnected by a local information exchange network. The simulator for training artillery calculations according to claim 1, characterized in that the first electronic computer is connected to the speaker system.

Description

The utility model relates to devices of defense equipment and can be used to develop skills in artillery calculations, in particular, to develop skills in using high-precision artillery shell "Krasnopol".

A known simulator, including a launch container containing a sight connected to an electronic computer (computer), a missile launch control unit, as well as a simulator of the operational situation, made in the form of a dome, inside which there is a remote control on the screen, for example, a flying airplane or helicopter, and background (see http://www.eads.net/eads/en/index.htm, Dome Trainer for Missile Systems and Guns, Domier GmbH).

However, the well-known simulator is functionally designed to develop skills in the use of man-portable air defense systems (MANPADS), anti-tank guided missiles (ATGMs) and rocket launchers, but does not have an acoustic system and does not allow you to train artillery systems.

The closest in technical essence and the achieved result to the claimed utility model is a simulator containing a computer, a launch container simulator with a launcher block installed on it and a first spatial position sensor, as well as an indicator, an acoustic system and a second spatial position sensor, a launcher simulator installation sensor container in the normal position, two AND elements, 6I element, two keys and a switch. The indicated units and blocks of the simulator have appropriate connections between themselves to ensure its operability and completeness of the technical solution (see utility model certificate No. 23493, F 41 G 3/26, 2002).

When using this simulator, the instructor using a computer sets the operational situation on the indicator screen corresponding to the curriculum and monitors the learner's performance of the task, for example, the defeat of a helicopter flying low against the terrain, and with the help of a simulated computer aiming system on the indicator screen of the launch container simulator and the launcher unit the student imitates the launch of a rocket, while perceiving, through the headphones of the speaker system, the corresponding Leica Geosystems simulated environment background sound.

Although such a simulator can be used both in a classroom and in conditions close to field conditions, it does not take into account the peculiarities of artillery calculations.

The authors were faced with the task of creating a training tool, devoid of the disadvantages of known devices and allowing to prepare artillery calculations.

To solve this problem, a second computer, a laser target range finder simulator and a visual environment simulator are additionally introduced into a well-known simulator containing a computer, a launch object simulator, a launch device simulator, spatial position sensors, installation sensors of a launch object simulator, a switch and an acoustic system.

Moreover, the first computer is connected to a simulator of a laser target designator-range finder, the second computer is connected to a simulator of a launching object and a simulator of visual environment, while the first and second computers are interconnected.

The first computer is connected to the position sensors through the switch.

The second computer is connected to the simulator of the starting device and the sensors of the installation of the simulator of the starting object through the switch.

The first and second computers are interconnected by a local information exchange network.

The first computer is connected to the speaker system.

The claimed simulator for training artillery calculations has a set of essential features not known from the prior art for devices of this purpose, which allows us to conclude that the criterion of "novelty" for the utility model is met.

The essence of the utility model is illustrated using the drawing, which presents a structural diagram of the simulator.

The simulator for training artillery calculations contains the first computer 1, simulator 2 of the launch object, simulator 3 of the launch device, sensors 4 of spatial position, sensors 5 of the installation of the simulator 2 of the launch object, switches 6, speaker system 7, the second computer 8, simulator 9 of the laser target designator-range finder , a simulator 10 of the visual environment, consisting of a projector 11 and a screen 12.

Moreover, the first computer 1 with a simulator 9 of the laser target designator-range finder, the first and second computers 1 and 8 are interconnected, the second computer 8 is connected to the simulator 2 of the launch facility and the simulator 10 of the visual environment.

In this case, the computer 1 is connected to the sensors 4 of the spatial position through the switch 6, and the computer 8 is connected to the simulator 3 of the starting device and the sensors 5 of the installation of the simulator 2 of the launch object through the switch 6. The computers 1 and the computer 8 are interconnected by a local information exchange network. In addition, the computer 1 is connected to the speaker system 7.

The functioning of the simulator is ensured by the use of the following main units and blocks.

Each of computers 1 and 8 is a personal electronic computer consisting of a system unit, a monitor, and a keyboard (see, for example, the operation manual on the RAMEK RAMK RAMK 431248.013 RE, ZAO RAMEK-VS, 1997).

Simulator 2 of the launch object is made in the form of a base mounted on the table, on which sensors 5 are installed for installing the simulator 2 of the launch object, a fragment of the shell of the projectile (launch object), simulator 3 of the launch device and switch 6. A fragment of the shell of the shell structurally includes sensors 5 of the simulator 2 launch facilities.

The speaker system 7 is made in the form of a sound dynamic system - multimedia speakers from SVEN (see www.sven.ru) connected to the computer system unit 1.

The simulator 9 of the laser target designator-range finder is made in the form of a table-mounted construct similar to a standard laser target designator-range finder (see, for example, the technical description and operating instructions for the laser target designator-range finder LCD-2, Research Institute Polyus, 1995).

The visual environment simulator 10 consists of a projector 11 and a screen 12 (see, for example, the catalog “Display Systems 2004/2005”, CJSC Polymedia).

The simulator works as follows.

The simulator equipment is installed in the classroom at the workplaces of artillery crew members: at the workplace of the battery commander, the first computer 1 and speaker system 7; at the workplace of the range finder (operator of the laser target designator-range finder) - simulator 9 of the laser target designator-range finder and simulator 10 of the visual situation; at the workplace of the senior battery officer - a second computer 8 and at the workplace of the installer - simulator 2 of the launch facility.

A projector 11 and a screen 12 are installed in front of the range finder (the distance between them is determined by their technical characteristics). At the same time, an instructor can also work from the workplace of the battery commander.

The formation of the visual environment and acoustic signals, the calculation of the flight path of the guided projectile, the processing of signals from sensors 4, 5 and the simulator 3 of the launch device, the actions of the students are evaluated by computers 1 and 8 based on mathematical modeling of the functioning of the artillery calculation implemented in computer software.

The instructor or commander of the battery using the first computer 1 sets the training exercise (type of visual environment, weather data, type of projectile, etc.). Corresponding data is supplied via a local information exchange network to a second computer 8, which through a projector 11 forms a predetermined visual environment on the screen 12. In this case, the acoustic system 7 under the control of the computer 1 provides a sound simulation of both noise signals inherent in this type of visual environment, and sound

characteristics of simulated targets. At the same time, computers 1 and 8 record the information received from the switches 6 about the initial position of the sensors 4 spatial position, sensors 5 installation simulator 2 of the launch facility and simulator 3 of the launch device. These and similar data will be further used to control and evaluate the correctness of the completion of the training assignment by artillery calculation.

The battery commander, based on the formed visual environment, selects the target for the shelling and its landmarks. The range finder, having received a task from the battery commander, turns on the simulator 9 of the laser target designator-range finder in the range measurement mode and, operating with the actuators of the sensors 4 of the spatial position of the simulator 9, performs an optical search for the target according to the visual situation on the screen 12. The corresponding information comes from the simulator 9 to the computer 1, where it is compared with previously recorded. Next, the computer 1 generates proportional displacement signals of the visual environment and transmits them via the local information exchange network to the computer 8, which through the projector 11 reproduces this on the screen 12. The range finder, having detected the target and combined with the aiming mark, measures the range and coordinates of the target using the controls (not shown) simulator 9. Based on the rangefinder’s report on the target, the battery commander orders the senior battery officer to calculate the projectile settings. After listening to the report of the latter on the calculation, the battery commander gives the order to set the calculated values on the projectile, and the range finder - to continue tracking the target. The senior battery officer transfers the required installation of the projectile to the installer, which translates the sensors 5 of the installation of the simulator 2 of the launch facility to a predetermined position that the computer 8 is fixed through the switch 6, and reports the readiness to the senior battery officer. The senior battery officer gives the Fire command. Next, the installer, simulating a shot from the gun, presses the "Start" button (not shown) of the simulator 3 of the launch device, thereby recording the moment of the shot, which also enters through computer 6 into computer 8, and the speaker system 7 generates the corresponding sound signal. At the same time as the Fire command of the senior battery officer, the battery commander duplicates it with a rangefinder, who puts simulator 9 into target designation mode. With proper tracking of the target, the range finder holds the reticle in the target’s contour and after a predetermined (set) time, because the coordinates of the target and aiming marks coincided, the computer 1 generates a signal "The target is hit." On a local information exchange network, this signal through computer 8 and projector 11 on screen 12 will form a characteristic image of an explosion on target, computer 1 in acoustic system 7 will show an explosion echo, and an assessment of artillery calculation actions will be displayed on computer monitors 1 and 8.

In case of a miss, the image of the explosion on the screen 12 will be formed outside the target and the battery commander or instructor decides to repeat the training exercise or enter new initial data.

The applicant company has developed working design documentation of the inventive simulator, made a prototype, the performance and advantages of which compared with the well-known ones, including the prototype, are confirmed by repeated demonstrations at scientific and technical conferences held on the basis of the State Unitary Enterprise KBP and OJSC Tulotachmash ”, Where there is interest from the GRAU of the Ministry of Defense of the Russian Federation and foreign customers for the supply of simulators.

Based on the foregoing, it becomes possible to assert that the inventive simulator for preparing artillery calculations satisfies the requirement of "industrial applicability" for a utility model.

Claims (5)

1. A simulator for training artillery calculations, containing an electronic computer, a simulator of a launch object, a simulator of a launch device, spatial sensors, installation sensors of a simulator of a launch object, a switch and an acoustic system, characterized in that a second electronic computer, a simulator, is additionally introduced into it a laser rangefinder and a visual environment simulator, the first electronic computer connected to a laser target simulator a range finder, a second electronic computer is connected to a simulator of a launching object and a simulator of a visual situation, while the first and second electronic computers are interconnected. 2. The simulator for training artillery calculations according to claim 1, characterized in that the first electronic computer is connected to the position sensors through the switch. 3. The simulator for training artillery calculations according to claim 1, characterized in that the second electronic computer is connected to a simulator of the starting device and sensors for installing the simulator of the starting object through the switch. 4. The simulator for training artillery calculations according to claim 1, characterized in that the first and second electronic computers are interconnected by a local information exchange network. 5. The simulator for training artillery calculations according to claim 1, characterized in that the first electronic computer is connected to the speaker system.