RU219559U1 - ARMORED PANEL - Google Patents

Abstract

The utility model relates to body armor and can be used to protect people and equipment from being hit by bullets, shrapnel or other objects. The technical result is the creation of an armored panel of protection class Br5 and Br6 in accordance with GOST R 50744-95, GOST 34286-2017 and GOST R 50963-96. The technical result is achieved by the fact that the armored panel contains a shell made of high-modulus aramid fabric such as Kevlar, Dynema, TSVM-J, ceramic tiles and a base - pressed ultra-high molecular weight polyethylene Dynema, a composite of several layers of fabric TSVM-DZh, Tvaron, Kevlar or aluminum alloy AMgb , while the ceramic tiles are made of a diamond-silicon carbide composite material obtained as a result of the Turing diffusion-reaction process with the formation of three times periodic surfaces of minimum energy. The surface density of the armored panels is 32.0 kg/m ² (protection class Br5) and 60.0 kg/m ² (protection class Br6).

Description

The utility model relates to body armor and can be used to protect people and equipment from being hit by bullets, shrapnel or other objects.

Known means of protection against increased penetration bullets GSh (ind. 7N13) and armor-piercing incendiary bullets B-32 (ind. 7-BZ-3) contain various types of ceramics made of corundum, silicon carbide, boron carbide or glass ceramics. Such protection means are either heavy, as, for example, using corundum tiles, or very expensive, as, for example, using hot-pressed boron carbide tiles (RF patent 2130159, MKI F41H 1/02, publ. 10.05.1999). Existing protections containing tiles made of corundum, silicon carbide, boron carbide or glass-ceramic do not provide the required protection class or are very heavy.

Close in technical essence to the claimed utility model is a bulletproof armored panel (RF patent for utility model No. 51191, IPC F41H 1/02, publ. material, and a layered base made of pressed ultra-high molecular weight polyethylene Dynema or a composite of several layers of TSVM-J or Kevlar fabric. The disadvantage of the technical solution is the low protection class, in particular, when exposed to a heat-strengthened steel core (bullets) weighing more than 9 g at flight speeds of more than 820 m/s.

It is also possible to single out 2 patents for the armored panel (RF patent for utility model No. 80935, IPC F41H 1/02, published on 10/15/2008 and RF patent for utility model No. 97508, IPC F41H 1/02, published on 01.10.2009), which contain a protective layer, ceramic tiles and a base made of Dynema ultra-high molecular weight polyethylene or a composite of several layers of TSVM-J or Kevlar fabric. Ceramic tiles are sintered silicon carbide (RF patent for utility model No. 80935) and self-bonded silicon carbide; a corrugated surface is artificially applied on the back surface of the tiles for a tighter connection of ceramics with the substrate (RF patent for utility model No. 97508). The disadvantage of the known technical solutions is the low protection class of the armored panels, which is mainly associated with the low protective properties of silicon carbide, in particular, low elastic modulus (350 GPa and 320 GPa) and sound speed (10800 m/s and 10500 m/s).

The closest prototype patent is a patent for a protective panel (RF patent for utility model No. 110831, IPC F41H 5/04, publ. 20.07.2011). The design of the protective panel is close to the design of previous armor panels, however, reaction-sintered boron carbide with higher values was used as ceramic tiles: modulus of elasticity (430 GPa); speed of sound (11200 m/s). The disadvantage of this protective panel is the low protection class associated with the low properties of reaction-sintered boron carbide.

The objective of the utility model is to create a new armored panel, including ceramic tiles made of diamond-silicon carbide composite material, providing the highest possible protective properties corresponding to the protection class Br5 and Brb according to GOST R 50744-95, GOST 34286-2017 and GOST R 50963-96.

The technical result is the creation of an armored panel of protection class Br5 and Br6 in accordance with GOST R 50744-95, GOST 34286-2017 and GOST R 50963-96.

The technical result is achieved by the fact that the armored panel contains a shell made of high-modulus aramid fabric such as Kevlar, Dynema, TSVM-J, ceramic tiles and a base - pressed ultra-high molecular weight polyethylene Dynema, a composite of several layers of fabric TSVM-DZh, Tvaron, Kevlar or aluminum alloy AMgb , while ceramic tiles are made of a diamond-silicon carbide composite material obtained as a result of the Turing diffusion-reaction process with the formation of three times periodic surfaces of minimum energy.

The increase in protective properties is achieved through the use of ceramic tiles made of composite material diamond-silicon carbide, which has high physical and mechanical characteristics, such as the modulus of elasticity and sound speed, which provide effective dissipation (dissipation) of impact energy.

Composite material diamond-silicon carbide (named "Ideal") is obtained under technological conditions that promote the synthesis of silicon carbide as a result of the diffusion-reaction Turing process and the formation of three times periodic surfaces of minimum energy. As a result of the impregnation of blanks from diamond particles with liquid silicon, a practically pore-free material is obtained, consisting of more than 80 vol.% diamond and up to 20 vol.% silicon carbide. The choice of diamond to create a composite material with properties that allow it to be used as an armor material is due to the fact that diamond exhibits the highest level of mechanical properties.

As a base (support layer), pressed ultra-high-modulus Dynema polyethylene or a composite of several layers of TSVM-J or Kevlar fabric is used. Urethane adhesive is used as an adhesive to connect the shell, ceramic tiles and base to each other.

The scheme of the utility model (figure 1) is a cross section of the armored panel, where 1 is a shell, 2 is a ceramic tile made of a diamond-silicon carbide composite material, 3 is a base.

At the National Research Center "Kurchatov Institute" - the Central Research Institute of KM "Prometheus" various designs of armored panels were implemented and tested, including the claimed utility model. The claimed utility model showed the highest protective properties, this is due to the fact that, unlike the prototype patent, the diamond-silicon carbide ceramic composite material has the best mechanical properties, in particular the modulus of elasticity and the speed of sound (table 1), which are the main indicators of armor materials.

The most effective operation of the armored panel is to localize all the energy of the shock wave in ceramic tiles and dampen this energy to a minimum level.

The device works as follows: at the moment of impact of a bullet (fragment), compression waves propagate from the point of contact along the surface deep into the armored panel and into the bullet (fragment). Compression shock waves are eventually reflected as tension waves from the back surface of the ceramic. During the impact of a bullet (fragment) in ceramics, two types of stresses arise: interlayer tension and shear stress, causing the destruction of ceramics.

Breaking the ceramic allows the energy to dissipate faster, which helps break up the bullet and stop it inside the armor.

If the interface between the base and the ceramic tiles is not strong enough to withstand the high impact of tensile waves, delamination of the armor panel will occur.

The shell serves to protect against flying fragments of ceramic tiles and fragments of a bullet.

The developed design of the armored panel has high protective properties, namely, it corresponds to the protection class Br5 according to GOST R 50744-95, GOST 34286-2017 and GOST R 50963-96 (Dragunov SVD rifle, increased penetration bullet PP (ind. 7N13), caliber 7.62 mm and a speed of 815-845 m / s and armor-piercing incendiary bullet B-32 (ind. 7-BZ-3) caliber 7.62 mm and a speed of 795-825 m / s) and protection class Brb according to GOST R 50744-95 , GOST 34286-2017 and GOST R 50963-96 (OSV-96 large-caliber sniper rifle, B-32 armor-piercing incendiary bullet (ind. 57-B3-542) of 12.7 mm caliber and speed of 810-850 m/s). The surface density of the armored panels is 32.0 kg/m ² (protection class Br5) and 60.0 kg/m ² (protection class Br6).

Claims (11)

1. Armored panel containing a shell made of high-modulus aramid fabric, ceramic tiles and a base, characterized in that ceramic tiles are made of diamond-silicon carbide composite material. 2. The armored panel according to claim 1, characterized in that a diamond-silicon carbide composite material is used, obtained as a result of the Turing diffusion-reaction process with the formation of three times periodic surfaces of minimum energy. 3. Armored panel according to claim 1, characterized in that the diamond-silicon carbide composite material contains at least 80 vol.% of diamond particles. 4. Armored panel according to claim 1, characterized in that the shell is made of Kevlar. 5. Armored panel according to claim 1, characterized in that the shell is made of Dynema. 6. Armored panel according to claim 1, characterized in that the shell is made of TSVM-J. 7. Armored panel according to claim 1, characterized in that the base is made of pressed Dynema ultra-high molecular weight polyethylene. 8. Armored panel according to claim 1, characterized in that the base is made of a composite of several layers of TSVM-J fabric. 9. Armored panel according to claim 1, characterized in that the base is made of a composite of several layers of Twaron fabric. 10. Armored panel according to claim 1, characterized in that the base is made of a composite of several layers of Kevlar fabric. 11. Armored panel according to claim 1, characterized in that the base is made of aluminum alloy AMgb.