RU2807626C1 - Explosion simulator (variants) - Google Patents

Abstract

FIELD: military training.

SUBSTANCE: invention relates to means of teaching and training military personnel in simulated combat conditions. The explosion simulator contains a body made of injury-proof, easily destructible material, a filler located in the body and an explosive tube in which a pyrotechnic explosive charge is placed. The burst tube is located in the filler mass. A pyrotechnic whistling tubular element is attached to the body, on its outer side. One hole in the tube of the pyrotechnic whistling tubular element is connected to the atmosphere. Another hole of the pyrotechnic whistling tubular element is connected to the hole of the burst tube, the lower end of which is made blind in the form of a flask. The burst tube and the tube of the pyrotechnic whistling tubular element are connected by a bushing, fixed in the neck of the housing, located between them. The bushing is made with a thread and a belt located above the thread. The neck is made with a flange on which the belt rests. The thread of the bushing is screwed into the thread of the flange that closes the neck of the body on top. An explosion simulator without filler is also proposed, the burst tube of which is located in the air space of the housing.

EFFECT: imitating properties of the simulator are increased, creating training conditions close to combat ones.

2 cl, 2 dwg

Description

An explosion simulator is a means of teaching and training military personnel in simulated combat conditions. The simulator is a means of warning participants in combat reconstructions about the need to take security measures and search for shelters. The simulator can also be used to create reconstructions of military operations in order to obtain a believable effect of military operations and images of these actions in spectacular and entertaining conditions.

The tasks solved by explosive ammunition simulators are the need to more fully simulate the approach (arrival) and explosion of artillery or mortar ammunition, which would make it possible to most fully simulate an artillery strike and the explosion of ammunition in the process of training military personnel, subject to the exclusion of injuries and wounds.

A training grenade is known, containing a body, a device for destroying the body, including a firecracker with a delay mechanism, an initiation mechanism with a grating type igniter, through which a cord is passed, the end of which is brought out and attached to the ring, a striking element, in which, according to the utility model , the delay mechanism in the form of a pyrotechnic composition is made integral with the firecracker and is located in its upper part, while the initiation mechanism is a U-shaped strip with an igniter applied to the inner surface of the upper part in the form of a layer of pyrotechnic composition, and the sides of the strip are fixed to the side surface of the upper part of the firecracker body, and a piece of cord free from the ring is passed through the upper part of the strip, while the fruits of legumes or grain crops are used as a damaging element. In such a training grenade, the body, U-shaped strips of the initiation mechanism, as well as the initiation mechanism can be made of cardboard or fabric (RU 58687 U1, 11/27/2006).

A throwing device is known for simulating combat operations, containing a body of the throwing device, a barrel articulated with it for placing a projectile in it, and the body of the throwing device contains a top cover with sealing rings and other elements, an inertial-type initiating device, an igniter with a pyrotechnic moderator, a firing pin, wherein the main body, the body of the initiating device and the head fairing are made of safety material. The throwing projectile is an simulator of an underbarrel grenade. The main body, the body of the initiating device and the head fairing can be made of polyurethane foam, extruded polystyrene foam or other foamed polymer having a closed-cell structure with a density of 40 to 120 kg/m ³ . The projectile contains a light-noise element, a smoke element and conditionally destructive elements (RU 81793 U1, 03/27/2009).

A throwing device is known for simulating combat operations, related to the field of pyrotechnics for obtaining fireworks effects, for simulating explosions during theatrical and entertainment events, for simulating the effect of a shot from a grenade launcher and simulating the effect of a smoke screen. A throwing device for simulating combat operations consists of a body made of non-flammable material, the inner wall of which has the shape of a truncated cone designed to accommodate a throwing projectile. A projectile for simulating combat operations contains a body made of a non-traumatic material, an igniter with a pyrotechnic igniter-retarder, and a protective film, under which there is an expelling pyrotechnic mixture. The protective film is made of injury-proof, flammable material and is designed to protect the expelling pyrotechnic mixture from spillage and moisture from entering it. The lower part of the projectile body, like the inner wall of the projectile body, has the shape of a truncated cone. Additionally, the body of the projectile may contain stiffening ribs for more reliable fixation and stabilization of the passage of the projectile inside the barrel, reducing friction of the projectile in the projectile. Achieving a greater flight range (up to 200 meters), using an additional pyrotechnic mixture as an energy source, ensuring stability of the launch of a projectile from a throwing device, simplifying the design of the throwing device and the projectile (RU 2670316 C1, 10/22/2018).

There is a known saber that simulates shell explosions, the body of which contains a fuse, a smoke composition, a transition composition and a diaphragm (https://yandex.ru/images/search?pos=7&img_url=http%3A%2F%2Fsurvival.com.ua%2Fsov% 2Fart6%2Fs021.jpg&text=simulator%20explosion&lr=213&rpt=simage&source=serp. 02/28/2023).

To simulate explosions of grenades and mines, plastic grenade simulators are also known, which contain a thin plastic body with a firecracker installed in it. These simulators are used in various military games to create noise effects (http://www.kalibr603.ru/shop/UID_1346.html. 02/28/2023).

A simulator of explosive ammunition is known, containing a housing with an explosive placed in it and/or a means of initiating such a substance, and the housing is made of a seamless, solid cast material from a biodegradable polymer material, or from a mixture based on such a material. The body material additionally includes color filler. The body material additionally includes weight filler. A simulator is a simulator of a grenade or mine, or a projectile, or a non-sheathed explosive device, or an improvised explosive device. Gunpowder or gas was used as an explosive (RU 105984 U1, 06/27/2011 - prototype).

The common features of the simulator disclosed in the prototype and the simulator presented in this description are that both simulators belong to explosion simulators, and each of them contains a body made of injury-proof easily destructible material, a filler located in the body, in the array of which there is a pyrotechnic or bursting charge.

The explosion simulator disclosed in the prototype does not fully simulate the explosion of a flying projectile, the approach of which is accompanied by a whistle, warning of the need to seek shelter from fragments flying to the sides.

The technical result of this group of inventions is to increase the imitating properties of the simulator.

The technical result was obtained by the first version of an explosion simulator, containing a body made of injury-proof, easily destructible material, a filler located in the body, in the array of which there is a pyrotechnic explosive charge, and the explosive charge is placed in a burst tube, which is located in the filler array, while on the body, with its on the outer side, a pyrotechnic whistling tubular element is fixed, one hole of the tubular element tube is connected to the atmosphere, the other hole of the tubular element is connected to the hole of the burst tube, the lower end of which is made blind in the form of a flask.

The burst tube of the first option and the tube of the whistling element are connected by a sleeve located between them, fixed in the neck of the body, while the sleeve is made with a thread and a belt located above it, the neck is made with a flange on which the belt rests, and the thread of the sleeve is screwed into the thread of the flange that closes top of the body neck.

The technical result was obtained by the second version of the explosion simulator, which contains a housing made of injury-proof, easily destructible material, a pyrotechnic explosive charge located in the housing, characterized in that the explosive charge is placed in a bursting tube, on the housing, on its outer side, a pyrotechnic whistling tubular element is fixed, one hole The tube of the tubular element is connected to the atmosphere, the other hole of the tubular element is connected to the hole of the burst tube, the lower end of which is made blind in the form of a flask, while the burst tube of the simulator is located in the air space of the housing.

The burst tube of the second option and the tube of the whistling element are connected by a bushing located between them, fixed in the neck of the body, while the bushing is made with a thread and a belt located above it, the neck is made with a flange on which the belt rests, and the thread of the sleeve is screwed into the thread of the flange closing top of the body neck.

Figure 1 shows the first version of the explosion simulator in a longitudinal section.

Figure 2 shows the second version of the explosion simulator in a longitudinal section.

This description presents examples of two options for an explosion simulator - examples of two independent solutions.

The first version of the explosion simulator contains a pyrotechnic whistling element 1 made in the form of an open top tube with a pyrotechnic composition inside, while the element 1 is fixed to the simulator body 2 from its outer side. The housing contains a pyrotechnic explosive charge 3, which is closed in the cavity of the lower tube 10 and located in the central part of the filler array 4. The filler is located in the housing 2 as shown in Fig.1. As filler 4, a signal pigment or smoke composition, or conditionally “damaging fragmentation elements”, for example, safety peas or elements that produce an acoustic effect, can be used.

The pyrotechnic whistling element 1 includes a tube 5, which is tightly fitted onto a sleeve 6, the belt 7 of which rests on a flange 8 made at the end of the neck 9 of the housing 2 of the simulator. The lower part of the sleeve 6 is pressed onto the upper end of the second tube 10, which is located in the simulator body. The pyrotechnic charge 3 is located in the lower part of the second burst tube 10.

In the upper part of the tube 5 there is a whistling pyrotechnic composition 11. The upper hole of the tube 5 and the whistling pyrotechnic composition 11 are connected to the atmosphere. As an example, the whistling pyrotechnic composition includes, wt.%: potassium perchlorate - 70%, sodium - 25%, iron oxide - 2% and binder - 3%. When composition 11 ignites, a gas is formed in tube 5, which, when compressed in the tube, produces a whistling sound. The body, tubes and bushing of the explosion simulator are made of non-traumatic material, for example, polyethylene.

The second version of the explosion simulator contains all the elements of the first version of the simulator, with the exception of the filler, which is absent in the second version of the simulator. In this case, the cavity of the housing 2 of the explosion simulator remains unfilled, and the burst tube 10 of the simulator is located in the air space of the housing. The design of the second version of the simulator, due to the absence of filler in the body, eliminates the possibility of secondary fragmentation elements, which reduces the risk of injury when using the simulator.

The first version of the explosion simulator works as follows. Many simulators or one explosion simulator are placed at the training ground in advance and activated remotely at an unexpected moment for the participants in the training process. Or explosion simulators can be thrown toward the participants in the training process after the whistling pyrotechnic composition 11 of the whistling element 1 is initiated. To do this, the composition 11 of the whistling element 1 is manually or remotely influenced, as a result of which the composition ignites, gas is formed, and gas vibration occurs when its turbulent outflow at the outlet of tube 5. Hot gas is pushed out of tube 5 and through the open upper hole of this tube a whistling sound is created at the outlet, simulating the flight of a projectile. A whistling sound is produced by the simulator for several seconds, within 1-3 seconds, and then explosive charge 3 is triggered, which simulates the explosion of a combat projectile. After the bursting charge 3 is triggered, the filler 4 is scattered to the sides from the explosion. In this case, the scattering of conventionally “fragmentation-damaging” elements is simulated, or the scattering of a signal pigment or smoke composition (instead of “fragmentation-damaging” elements) which can be used as a filler is simulated.

The second version of the explosion simulator works the same way as the first version of the simulator, with the exception of the scattering of conventionally “damaging fragmentation elements”, since there is no filler in the body of the second version of the simulator. In this case, when the housing ruptures, a pyrotechnic explosion of the housing is created and a gas cloud is formed, which eliminates the possibility of secondary fragmentation elements and reduces the risk of injury when using the simulator.

When simulating multiple explosions in the training area of military units, unit personnel practice methods of sheltering from enemy artillery fire.

The technical result is achieved by the distinctive features of the simulator in conjunction with a pyrotechnic whistling element, and in the first version, when the simulator body ruptures, the filler scatters in different directions, and in the second version of the simulator there is no scattering of the filler. Such executions of simulators significantly expand the capabilities of the training process, and before the simulators explode, a whistling sound imitates the flight of a projectile, warning of danger and the need to seek shelter, which, in comparison with other simulators, increases the simulating properties of the simulator, creating training conditions close to combat conditions.

Claims (2)

1. An explosion simulator containing a body made of injury-proof, easily destructible material, a filler located in the body, in the array of which there is a pyrotechnic explosive charge, characterized in that the pyrotechnic explosive charge is placed in a burst tube, which is located in the filler array, while on the body, with on its outer side, a pyrotechnic whistling tubular element is fixed, one hole of the pyrotechnic whistling tubular element tube is connected to the atmosphere, the other hole of the pyrotechnic whistling tubular element is connected to the hole of the burst tube, the lower end of which is made blind in the form of a flask, while the burst tube and the pyrotechnic whistle tube of the tubular element are connected by a sleeve located between them, fixed in the neck of the body, wherein the sleeve is made with a thread and a belt located above it, the neck is made with a flange on which the belt rests, and the thread of the sleeve is screwed into the thread of the flange that covers the neck of the case from above. 2. An explosion simulator containing a housing made of injury-proof, easily destructible material, a pyrotechnic explosive charge located in the housing, characterized in that the pyrotechnic explosive charge is placed in a bursting tube, while on the housing, on its outer side, a pyrotechnic whistling tubular element is fixed, one hole the tube of the pyrotechnic whistling tubular element is communicated with the atmosphere, the other hole of the pyrotechnic whistling tubular element is connected to the hole of the burst tube, the lower end of which is made blind in the form of a flask, while the burst tube of the simulator is located in the air space of the housing, while the burst tube and the tube of the pyrotechnic whistling tubular The elements are connected by a bushing located between them, fixed in the neck of the body, the bushing is made with a thread and a collar located above it, the neck is made with a flange on which the band rests, and the thread of the bushing is screwed into the thread of the flange that closes the neck of the body on top.