RU2663421C1 - Non-lethal ammunition - Google Patents

Abstract

FIELD: training; weapons and ammunition.SUBSTANCE: invention relates to training equipment, namely, drill ammunition, which can be used as manual, engineering, artillery ammunition for training and personnel training in conditions close to combat, as well as for paramilitary games. Non-lethal ammunition contains a polymeric body with an internal cavity, in which a bursting charge is disposed, comprising a pyrotechnic composition or an explosive and, optionally, a filler, which is a conditionally damage agents and / or a coloring pigment. At least a portion of the internal cavity of the body is filled with an inert bulk material in a non-compacted form, such as a powder and / or a metal or metal alloy shot.EFFECT: invention provides the maximum correspondence of external and mass-dimensional characteristics to the simulated combat model and at the same time the maximum safe operation for objects at a small distance.8 cl, 2 ex

Description

The invention relates to educational aids, educational, training and practical ammunition, such as hand, engineering, artillery ammunition, which can be used for training and training personnel in conditions close to combat, as well as for paramilitary games - airsoft, paintball . In the appropriate configuration, these ammunition can be used in police operations or as a traumatic means for guarding objects, marking and scaring offenders (people, animals).

Training and development of the necessary skills in handling various types of ammunition within the entire nomenclature is associated with a high risk of personal injury, including death, high ammunition consumption and the high cost of the preparation process. Therefore, in the educational process they use cheaper and safer, compared to military, training (educational, training and practical) ammunition, which are as close as possible to military samples in terms of weight and size characteristics, methods and conditions of their operation. For this purpose, in the manufacture of training ammunition, as a rule, the forming elements of the originals are borrowed to give the simulator the exact shape of a combat sample, and in order to provide the necessary mass, an inert weighted filler is pressed into the case.

To obtain a training cartridge for a grenade launcher, the sleeve from the live cartridge for the grenade launcher is fastened with a destructible link with a grenade simulator when fired (RU 2339901 C2, F42B 8/02, 11/27/2006). To reduce barrel wear during firing, the simulator body is made of polymer (polyamide or aramid). To compensate for the mass of ammunition, ballast in the form of sand, metal powder or shot is introduced into the inert filler formed by the compound. To fix the place of entry into the inert filler, a contrast dye is introduced, which leaves a clear imprint upon the destruction of the polymer shell. In this case, an inert filler (vulcanized compound) at the same time performs a constructive function, fastening together the elements of the device and ballast particles.

A disadvantage of the known simulator is insufficient security. Prior to the moment of collision with a target, a cap with a weighted filler moves with the preservation of a certain kinetic energy necessary for its destruction. When meeting an obstacle and triggering a bursting charge, the weighted compound is destroyed with the formation of parts of different mass and density, which, when flying, can cause harm to nearby objects.

Known for simulating an engineering mine device used for military or police exercises, comprising a housing made of hard plastic with holes filled with pressed powder sound pyrotechnic composition (whistling sand QuS). The filling hole is closed by a screw cap, when pressed, a sharp sound and smoke are reproduced (CN 2079736 U, F42B 8/28, 06/26/1991).

The disadvantage of this device is the external and overall mismatch of the simulator with military samples, and the inability to use different means of initiation. Therefore, this pyrotechnic tool cannot be useful for developing skills in handling combat engineering mines in conditions close to combat.

Known simulator of explosive ordnance, providing imitation of the detonation of mines. The munition contains a housing made of seamless cast from a biodegradable polymer material or a mixture based on such material, and an explosive placed in the housing, which is used as gunpowder or gas, an initiating agent and a color filler (RU 105984 U1, F42B 8/00, 27.06. 2011).

Thus, upon receipt of ammunition of this type, one of the two tasks is usually solved: either mass-dimensional resemblance to the original ammunition, or safety in terms of impact on surrounding objects. The fulfillment of both conditions within the framework of a single non-lethal munition was not considered.

The invention is aimed at solving this problem.

The technical result is to ensure maximum compliance with the external, mass-sized and operational characteristics of the non-lethal ammunition with a simulated combat analogue, and at the same time maximize the safe operation for objects at a short distance from it.

Non-lethal ammunition with explosive charge, contains a polymer case with an internal cavity in which the explosive charge is located and, optionally, a filler, which is a conventionally damaging elements and / or coloring pigment. At least part of the free volume of the internal cavity of the housing is filled with metal powder and / or metal shot. The housing is configured to install initiation means on it.

In the prior art, metal powder and shot is added to a plastic thermosetting material to weight and inertia the light polymer mass of the filler. A distinctive feature of the invention is the use of metal particles without a polymer matrix in the form of binders (rubber, compounds, etc.) or other substances that perform the function of the medium. The absence of a dense binding medium reduces the impact energy when the munition is triggered due to the absorption and dissipation by unbound particles of the bursting charge response energy. Thus, metal powder and shot on the one hand perform the function of ballast to adjust the required mass, and on the other hand, metal particles in an unbound (free) state simultaneously ensure safety when munition is fired for objects at a short distance, simulating the effect of projectile firing.

Metal particles are an inert material with respect to filler materials and with respect to objects surrounding the munition. In addition, metal particles are heat-absorbing material that does not support and does not cause combustion. Hot gaseous products that occur when a bursting charge is triggered are freely filtered through heavy heat-absorbing particles and cool when passing through a granular medium. As a result, metal particles extinguish the burning products of a bursting charge. A sharp decrease in the temperature of gaseous products, respectively, leads to a decrease in their pressure, and, consequently, in the rate of dispersion of particles, providing a small radius of hazardous exposure. Thus, the specified technical result will be achieved regardless of the size of the particles, as well as the type of metal or composition of the alloy from which they are made.

Depending on the task or the type of simulated ammunition, the use of a metal powder, shot or mixture thereof may be preferred. The choice of a particular metal or alloy of particles is also determined by the task, as well as technological capabilities. Examples of metal powder can be copper, lead, steel or brass powder, and steel shot can be an example of a metal fraction. At the same time, it is clear to a specialist in the art that these examples are given only to illustrate the materials used, but the possibility of using other metals and alloys is not limited by them, since the ongoing physical and chemical processes are based on the use of the properties of metals, as such.

An explosive charge is a small (compared to the volume of the case) amount of pyrotechnic composition or explosive located inside the ammunition. Initiation of the charge leads to a sharp formation of gaseous products, which, expanding, destroy the polymer body and discharge its contents - metal particles and filler (conditionally damaging atraumatic elements and / or pigment) to a predetermined (small) distance.

As the pyrotechnic composition, any pyrotechnic mixture capable of providing the necessary action can be used. Most preferred are compositions based on potassium perchlorate or asphalt powder with metal fuel, for example aluminum powder (PAM-4, PAP-1).

As the explosive, you can use any known substances, sensitive to the pulse means of initiation and capable of rapid chemical transformation with the formation of gaseous products. It is allowed to use both individual substances and mixed ones.

The amount of pyrotechnic composition or explosive may vary depending on the tasks and materials used. The mass (energy) of the bursting charge should be sufficient to destroy the polymer body and release metal particles and filler. In this case, all kinetic energy transferred from the breaking charge to the particles must be dissipated, allowing the particles to fly apart without having a penetrating (traumatic) effect.

To undermine the explosive charge can be used as a means of initiation, in particular, provided for the completion of a specific munition, as well as used in pyrotechnic devices.

For the manufacture of an atraumatic case, any thermosets, thermoplastic polymeric materials, for example, polyethylene, polypropylene, polyvinyl chloride, polyurethane foam, etc. can be used. When the ammunition is triggered, the polymer case collapses to form particles that do not have high kinetic energy, sharp edges and corners that can cause significant harm to anything. The use of polymer allows you to perform a hull of any kind and complexity to achieve external compliance as close as possible to a military model.

Atraumatic particles used in imitation pyrotechnic devices, for example rubber, rubber balls or polymer granules, are used as conditionally damaging elements. Elements can be made of porous material, for example, foam rubber or dense rubber.

Thus, the invention cannot be limited to the type of specific ammunition, because its implementation can correspond to any munition with a bursting charge, for example, manual, engineering, artillery, during the implementation of which the specified technical result will be achieved, namely:

- providing mass and overall characteristics and operational parameters close to the original, as well as external similarity;

- safety when triggered for objects at a short distance;

- the possibility of separate transportation to the place of use of structural elements: body, explosive charge, means of initiation, metal powder (shot), filler.

Examples of carrying out the invention.

Example 1. The case of the simulator is made of foamed polyurethane foam, the external configuration of which is most consistent with the body of the mine MON-50. It is acceptable to use standard means of initiation and target sensors. Part of the body volume is filled with heavy metal (steel, lead, brass, copper) powder, which, if necessary, can be replaced by a metal fraction or its mixture with powder. Metal powder is placed in the housing along the back wall of the mine in packaged form in plastic bags. On the opposite (front) side of the mine’s hull there are plastic bags with a filler containing conventionally damaging elements and / or coloring pigment. A bursting pyrotechnic charge based on potassium perchlorate and PAM-4 aluminum powder is placed between packages with metal powder and with filler. The overall dimensions of the simulator correspond to the indicated simulated ammunition.

The simulator works like the original - in both hemispheres. When an explosive charge is triggered, the body and easily destroyed packages are destroyed with a spread of conditionally damaging elements, pigment and powders. The spread of pigment, conditionally damaging elements and fragments of the body occurs from the front side of the mine. From the back of the mine’s hemisphere, the scatter of fragments of the hull and equipment elements (metal powder) occurs to a lesser extent, because heavy powder absorbs and dissipates the energy of operation of the explosive charge, inhibiting their expansion.

Safe removal from the simulator of a mine in the back is from 5 m, i.e. much less than the front of the mine. The directional release of conditionally striking marking elements in the frontal projection of the mine occurs up to 15 meters, which is similar to the original ammunition indicator. With the proper use of personal protective equipment, being at a closer distance will also not lead to irreversible loss of health.

Using such a device allows you to develop the skills of mining and mine clearing of terrain and objects, marking targets and participants in the educational and game process.

With an increase in the mass of conventionally damaging elements and an increase in the bursting charge power, a mine can be used as a non-lethal traumatic agent. The use of such ammunition as a protective tool can have a high psychological effect on people and animals violating the restricted area, but without causing serious injuries.

Example 2. Non-lethal ammunition contains a polyethylene case simulating an F-1 hand grenade filled with steel powder and equipped with a low-speed explosive charge based on potassium perchlorate. Also, the body can be filled with steel shot with the addition of lead powder. The use of fractions allows you to achieve full weight and size compliance with the original ammunition and high safety response simulator.

The initiator drives a bursting charge. The products of explosive combustion which destroy the shell of the ammunition and scatter fragments of the shell and equipment (powder, shot).

Similarly, it is assumed the execution of any ammunition from hand, engineering, artillery ammunition with an explosive charge.

The results of tests of modifications that mimic various ammunition confirm the possibility of achieving maximum mass-dimensional similarity with a combat model, as well as its non-invasiveness. The possibility of using full-time (army) means of initiation and target sensors ensures the maximum similarity of the initiation methods, which allows the training process to be carried out in conditions as close as possible to combat conditions, but at the same time significantly reduce the risk of personal injury.

In addition, given the safety of the operation of funds, non-lethal ammunition can be useful as a means of stopping or repelling. For example, when exposed as a warning (deterrence) in front of minefields of lethal action, to protect against accidental ingress of civilians or animals.

The proposal to use metallic heavy inert particles without a binding medium to solve the specified technical problem, i.e. ensure the overall dimensions of the combat sample while ensuring the safety of the means, not found in the prior art. And the specialist in this field of technology it is clear that the fame of the individual components of the invention does not indicate the evidence of its receipt.

Claims (8)

1. Non-lethal ammunition with a bursting charge, comprising a polymer body with an internal cavity in which a bursting charge and optionally a filler are located, which are conventionally damaging elements and / or coloring pigment, characterized in that at least part of the free volume of the internal cavity of the body is filled metal powder or metal fraction in uncompressed form. 2. The ammunition according to claim 1, characterized in that the casing is made with the possibility of installing initiation means on it. 3. The ammunition according to claim 1, characterized in that the powder and shot are made of metal or an alloy of metals. 4. Ammunition according to any one of claims 1 or 3, characterized in that the powder and shot are made of lead, copper, steel or brass. 5. The ammunition according to claim 1, characterized in that the powder, shot and filler are placed in the casing in pre-filled with easily destructible shells, for example, plastic bags. 6. The ammunition according to claim 1, characterized in that the casing is made of polymeric materials, for example polyethylene, polypropylene, polyvinyl chloride, polyurethane foam or thermosetting plastic. 7. The ammunition according to claim 1, characterized in that it contains atraumatic particles, for example rubber or rubber balls or plastic granules, as conditionally damaging elements. 8. The ammunition according to claim 1, characterized in that the explosive charge contains a pyrotechnic composition or explosive.