RU162948U1 - COMPOSITION ARMOR BARRIER - Google Patents

Abstract

The utility model relates to composite armor protective materials used in various fields of technology, in particular, when creating structures for protecting against impacts of various striking means (for example, small arms), as well as protecting mechanisms and devices of various types of objects. A composite armored barrier consisting of many complex ceramic elements 3 made of silicon carbide, silicon nitride, alumina, etc., fixed in a regular planar honeycomb structure made of metal tape 2, fiberglass, Kevlar or plastic, and ceramic elements 3 are made in the form of octahedrons, forming a deflecting-crushing screen 1 with a multi-row arrangement of adjacent to each other side surfaces of ceramic elements 3.

Description

The utility model relates to composite armor protective materials used in various fields of technology, in particular, when creating structures for protecting against impacts of various striking means (for example, small arms), as well as protecting mechanisms and devices of various types of objects.

Known armor for ballistic protection from damaging elements, consisting of the main and auxiliary plates, between which there is a honeycomb structure, which can be in the form of a regular matrix, foam or elastomer, performing an absorbent function. The main plate of the armor is made of metal, the auxiliary is made of various types of synthesized ceramics: aluminum oxide, boron carbide, etc. - and has a regular relief made in the form of blind holes. The connection of the main plate, the honeycomb matrix and the auxiliary plate is carried out using glue (US patent No. 5221807, publ. 06/22/1993).

One of the main disadvantages of the armored element is unreliable protection due to the fact that the hit of an attacking element, especially a sub-caliber bullet, in the joint between the plates leads to the intensive destruction of their end surfaces in the impact zone. This destruction is enhanced by the influence of edge effects. In the end result, the gap at the junction between the plates increases and, as a result, the bullet pierces through the layers of the armored element.

Known lightweight composite armor, consisting of a solid flat metal matrix unit having in the front layer many open cells of a given shape and size. In each of these cells are ceramic elements made of aluminum oxide or silicon carbide. These elements serve to absorb the kinetic energy of the ballistic projectile acting on the armor when they are destroyed. In the gaps between the ceramic elements and the edges of the cells of the matrix block is a liquid ceramic solution (cement), which secures the elements in the matrix (US patent No. 5686689, publ. 11.11.1997).

The disadvantages of this technical solution include, first of all, the fact that a bullet falling directly into the joint of ceramic elements leads to penetration of the structure even in the presence of a ceramic solution in the junction with between sections. In addition, the connection of the sections to eliminate gaps in the joints between the sections overloads the structure as a whole.

The closest technical solution that can be taken as a prototype is ballistic armor, consisting of many complex ceramic elements having a cylindrical part and two spherical or flat surfaces at the ends. These ceramic elements, made of silicon carbide, silicon nitride, alumina, etc., are fixed in a regular planar honeycomb structure made of metal tape, fiberglass, Kevlar or plastic. The spaces between the ceramic elements are filled with synthetic foam. On the back side of the structure is a support layer of synthetic material such as Kevlar, which absorbs fragments of ceramic elements and shell fragments (patent EP No. 1363101, class F41H 5/04, publ. 19.11.2003).

The main disadvantage of ballistic armor is that the penetration of a sub-caliber bullet end-to-end between ceramic elements leads to intensive destruction of their end surfaces in the impact zone. This destruction is also enhanced by the influence of edge effects. In the end result, the gap between the plates increases, and the bullet pierces through the layers of the armored element.

The objective of the proposed utility model is the reliable protection of the protected object from the effects of small arms bullets.

This goal is achieved by the fact that in a composite armored barrier consisting of many complex ceramic elements fixed in a regular planar honeycomb structure made of metal tape, fiberglass, Kevlar or plastic, the ceramic elements are made in the form of octahedrons, forming a deflecting-crushing screen with a multi-row the location adjacent to each other by the side surfaces of ceramic elements.

The gaps between the ceramic elements are filled with polymer glue. On the back side of the structure is a supporting layer of synthetic material such as Kevlar, which absorbs fragments of ceramic elements and shell fragments.

The bevels of the side surfaces of each pair of ceramic elements are made in mutually opposite directions, while the length of each bevel is chosen such that when the ceramic elements are joined with opposite bevel directions, front and back gaps are formed with a depth of 0.2 ... 0.4 and a width of 0.04 ... 0.15 of the thickness of ceramic elements. The total length on the joined ceramic elements formed on the extension of the bevel line is at least 0.7 of the thickness of the ceramic elements.

Common essential features of the known device and the claimed technical solution is the presence of an armored barrier containing a series of alternating armored layers, one of which is made in the form of a ceramic deflecting-crushing screen.

A general view of the proposed utility model is presented in accordance with FIG. 1, in FIG. 2 shows the structure of a composite armored barrier and in FIG. 3 - ceramic element.

The armor barrier includes a deflecting-crushing screen 1, mounted in a regular planar honeycomb structure on a metal or composite substrate 2, using polymer glue, and a deflecting-crushing screen 1 is formed by a multilayer arrangement of adjacent ceramic elements 3 made in the form of an octahedron, adjacent side surfaces 4 to each other and fastened with polymer glue, while the barrier can be fixed in a package rigidly interconnected by screw connection of the barriers, and as substrate 2 used armor layer.

The adjacent side surfaces of the ceramic elements 3 have a gap between each other, which is less than 0.03 of the bullet diameter, the crushing-deflecting screen 1 is closed from the front by an external armor barrier 5. The ceramic elements 3 are bonded to the external armor barrier 5, with the side surface of 4 adjacent adjacent ceramic elements 3, as well as between each other in the layer and at the places where their surfaces adjoin one another using polymer glue, and the outer armor barrier 5 is made of steel 2P (98) 2 mm thick.

The deflecting effect on the front surface of the deflecting-crushing screen 1 is achieved due to the formation of the initial rebound angle by the side surfaces 4 of the ceramic elements 3.

The conditions for core fragmentation are created initially in the area of contact of the bullet with the external armored barrier 5, where zones with one-dimensional compression predominate, and then, with inclined penetration into the subsequent layer of ceramic elements 3, in the region with large shear stresses. Fragmentation of a bullet occurs due to the formation of maximum tangential stresses when a bullet’s core hits at an angle. Moreover, the fracture is discontinuous due to the predominant influence of tensile stresses. Depending on the tasks that an armored obstacle can perform, it can be packaged rigidly interconnected by a screw connection of the same type of armored obstacle, assigned one to another in depth at a predetermined distance, for example, after an armored obstacle an energy-absorbing plate 6 can be installed, made , for example, from an aluminum alloy AMG6-M with a thickness of 8 mm, as well as a rear armor plate 7 made of steel 2P (98) with a thickness of 2 mm.

The action of the armored barrier is as follows: a bullet penetrates the outer armored barrier 5, pierces it and comes into contact with one of several ceramic elements 3, moving a specific ceramic element 3 as much as the layer of polymer adhesive and the strength of the ceramic element allow 3. Steel core of armor-piercing the bullet begins to destroy ceramics and at the same time collapses itself. A broken core continues the destruction of ceramic elements due to its kinetic energy. The inclination of the side surfaces 4 of the ceramic elements 3, directed towards the shelling, ensures the destabilization of the bullet when penetrating the ceramic element 3. The destruction of the entire block is prevented by the flexibility of the layer of ceramic elements 3, both in the direction of the bullet and in the perpendicular direction, due to the movement of adjacent ceramic 3 elements in a layer of polymer glue. Large fragments of ceramic elements 3 are held by an external armored barrier 5, which ensures the preservation of protective properties in the immediate vicinity of the point of impact.

The thickness of the sheet of the external armored barrier 5 less than 1.0 mm is insufficient to hold fragments of a bullet and ceramics when exposed to a large-caliber bullet, and more than 3 mm leads to an unjustified weighting of the structure and an increase in material consumption.

When meeting with the ceramic element 3, the bullet begins to collapse and deviate from the original flight path. At the same time, most of its energy is spent on bringing neighboring ceramic elements 3 into vibrational motion, which in principle resembles the “billiard effect”. The ceramic element 3 is destroyed, absorbs the energy of the shock and sound waves, which prevents the destruction of neighboring ceramic elements 3. As a result, the “weakened”, dilapidated bullet and the resulting fragments are destabilized on the side surfaces of ceramic elements 3 or at their vertices, which is achieved due to the formation of the initial rebound angle formed by the side surfaces 4 of the ceramic element 3, made in the form of an octahedron and delayed by the subsequent armored substrate 2.

With the possible penetration of the striking element through ceramic elements 3 and the armor plate 2, further destruction of the core of the striking element occurs and its fragmentation into individual small fragments that linger inside the armor barrier with further destabilization of the trajectory of the striking element. The armor plate 2 finally extinguishes the kinetic energy of the fragments of the bullet and ceramics, delaying them inside the armor barrier.

When the striking element reaches an energy-absorbing plate 6 made of 8 mm thick AMG6-M material, its kinetic energy is finally extinguished, due to the presence of an elastically deformed effect, the rear armor plate 7, made of 2P (98) steel with a thickness of 2 mm, ensures guaranteed non-penetration of the armor plate barriers.

The bullet weakened in the process of linking in the protection layers is easily captured by the subsequent armor substrate 2. The protective effect here is achieved not by strengthening the armor, but by dissipating the energy of the armor-piercing core in the plane of the outer armor barrier 5 and deviating it from the initial motion path by ceramic elements 3.

The armor substrate 2 can be either single-layer or multi-layer, it can be made of additionally placed layers of AMG6-M 6, steel 2P (98) 7, which makes it possible to more efficiently vary the rigidity and irregularity of the substrate behavior and more effectively inhibit the destroyed bullet and ceramic fragments elements 3 due to delamination upon impact and subsequent deformation of each individual layer with the maximum implementation of their strength properties.

The maintainability of a composite armored barrier is increased due to the fact that the replacement of damaged elements is carried out in blocks using a standard tool, including the replacement of ceramic elements 3.

Such a technical solution allows, when a bullet enters an armored obstacle in a deflecting-crushing shield zone, to destabilize and destroy it. The substrate receives minor damage without through penetration. To ensure the necessary equal strength protective properties of the armored barrier, first of all, when a bullet enters the gaps between the armored elements, the end surfaces of the ceramic shaped elements are made of a complex profile, the most important of which is that the side part of this profile is made with a bevel of a certain length and bevels of each pair of elements from ceramics are made in mutually opposite directions. When joining ceramic elements, frontal and rear gaps are formed that are offset from each other. Resistance to the effects of sub-caliber bullets of small arms when a bullet enters the frontal gap is achieved due to the fact that the bullet is destabilized when it comes into contact with the side surfaces of ceramic elements. The bullet deviates from the original direction of movement, begins to unfold, the process of its destruction is amplified. An insignificant part of the bullet reaches the substrate of the armored barrier, approximately 0.2 ... 0.3 of its initial length. In the event that a bullet enters the frontal clearance zone, at first a gradual, but intense, destruction occurs with a loss of stability. Next, the bullet loses its stability and unfolds. When interacting with the substrate, its intense braking occurs. The substrate receives minor local damage without through penetration. The design of the armored barrier is such that the joints between adjacent armored elements are not a weak link, but rather become useful from the point of view of the implementation of the processes of destabilizing the movement of the bullet, turning and enhancing its destruction when introduced into the protective layers. The slope angle of the end surfaces of ceramic elements is selected from the conditions for the implementation of the rebound of the sub-caliber bullet and the non-penetration of armor protection.

The depth and width of the front and back gaps formed during the joining of neighboring ceramic elements depend on the length of the bevels of the side surfaces of the octahedron with mutually opposite directions. In this case, the total length of the contacting surfaces of the ceramic elements should be at least 0.7 of the thickness of the ceramic elements. If these ratios are not maintained, the protective and operational properties of the armor protection are reduced.

At the same time, the width of the gap should be deliberately smaller than the midship of the sub-caliber bullet, so that the bullet does not penetrate freely into the structure and, therefore, break through the armor protection. In addition, the width of the gaps in the joints should not be less than the magnitude of the thermal gaps between the ceramic elements in order to maintain the structural strength of the armor protection in operation at temperature extremes. The selected gap width of 0.04 ... 0.15 of the thickness of the ceramic elements meets the specified requirements.

Thus, the claimed technical solution provides reliable protection of the protected object from the effects of sub-caliber bullets of small arms due to the profile of the end surfaces of ceramic elements and their docking with each other.

On the back of the structure, there may be a supporting layer of aramid material such as Kevlar, which absorbs fragments of ceramic elements and fragments of the projectile.

The blocking properties of the armored barrier are ensured by the organization of an oblique strike when the striking element meets the outer surface of the deflecting-crushing screen made of contacting ceramic octahedrons and subsequent destruction in the deflecting-crushing screen, armor plate and energy-absorbing barriers with complete damping of their speed in the barrier layers.

This constructive solution and the optimal characteristics of ceramics were obtained on the basis of a large number of experiments. The proposed ceramic armored barrier improves the efficiency of the ceramic material, which destabilizes the bullet and absorbs the energy of the bullet core due to a combination of properties typical only for reaction-bound materials, such as high microhardness, almost zero porosity, and internal microstresses.

The industrial applicability of the claimed armored barriers is confirmed by experimental tests, which showed that the use of the proposed armored barriers ensures no damage when firing 12.7 mm with B-32 armor-piercing bullets at a firing range of 100 m.

The technical result of the proposed solution is to increase the protective properties of the armored barrier to the effects of sub-caliber bullets of rifle systems by destabilizing the movement of the bullet by changing the profile of the joint of the end surfaces of ceramic elements and the proposed docking between them.

The technical result obtained when using the utility model is expressed in ensuring the protection of the object from the hit of several armor-piercing bullets of B-32 caliber 7.62 mm SVD, flying at speeds up to 840 m / s, with a distance between hits in the object of at least 100 mm, which corresponds to class 6A GOST R 50744-95, GOST R 50963-96.

Thus, the proposed composite armored barrier allows to provide high protective properties of objects from armor-piercing bullets of small arms, including large-caliber ones, by increasing the resistance, survivability and maintainability of multilayer armored barriers with ceramic materials.

Claims (1)

Composite armored barrier, consisting of many complex ceramic elements fixed in a regular planar honeycomb structure made of metal tape, fiberglass, Kevlar or plastic, characterized in that the ceramic elements are made in the form of octahedrons, forming a deflecting-crushing screen with a multi-row arrangement of adjoining each other to each other by the side surfaces of ceramic elements.

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