RU2192607C1 - Shellproof and hollow-chargeproof armor plating - Google Patents

Abstract

FIELD: military equipment, specifically, equipment protecting objects against artillery shells. SUBSTANCE: proposed armor plating presents cellular multilayer structure. Outer layer of armor plating is manufactured of high-strength armor steel, its thickness is equal to half-caliber of most efficient antitank guns ( caliber 100 mm ). Width of air clearance behind it equals thickness of outer layer. Third layer is made of same armor steel. Fourth layer comprises porous extra hard nonmetal material filled up with chemically active substance showing oxidation properties. Its thickness is 3-5 times as large as thickness of outer layer. Fifth and seventh layers are made of same steel that is used to manufacture outer layer, air clearance is arranged between them presents sixth layer. Thickness of third, fifth and seventh layers is one-fifth as large as thickness of outer layer and width of sixth layer is twice as large as thickness of fifth layer. Mass of one square meter of such armor plating is smaller approximately by factor of 2.2 than mass of solid armor plating of same thickness but it guarantees its antipiercing properties for both subcaliber shells up to 100 mm and for shaped jets of practically all hollow ammunition. EFFECT: reduced mass and high antipiercing properties of proposed armor plating. 2 cl, 1 dwg

Description

 The invention relates to the field of military affairs and is intended to provide protection for weapons, military equipment and other objects from being hit by artillery shells, including armor-piercing shells, for example, sub-caliber and cumulative ammunition, including mines, shells, grenades, etc.

 Closest to the claimed technical solution is the "Design of the protective wall for an armored vehicle" [1]. The design is designed to protect against armor-piercing shells of cumulative and sub-caliber action. It includes an outer layer made of steel, the second layer is the air gap, the third layer is made in the form of a steel sheet, the thickness of which is less than the first layer. The third layer provides protection against secondary fragments generated during the passage of shells and cumulative jets through the first (outer) layer.

The disadvantages of this design are the following:
firstly, an additional layer of steel, made with an air gap relative to the first, significantly increases the total thickness of the armor and narrows the reserved space;
secondly, this design does not completely neutralize the cumulative stream, but only cuts off the secondary fragments;
thirdly, the mass of a surface unit, as the main indicator of the effectiveness of armor, in such a design has practically no advantage over structures made in the form of a single monolithic layer.

 The technical result of the present invention is to more effectively protect the armored object from the effects of armor-piercing caliber up to 100 mm shells and cumulative anti-tank grenades. Moreover, the mass of a unit surface of the proposed armor at a given level of security of the object is approximately 2 times less than the most advanced standard structures.

 The invention consists in the following.

 The armor, including the outer layer, the second layer is the air gap, the third layer is made of steel sheet, the thickness of which is less than the first layer. Moreover, it is equipped with a fourth layer made of a porous, high-hard non-metallic material, the pores of which are filled with a substance that is chemically active with oxidizing properties, as well as the fifth and seventh layers of steel located with an air gap between them, forming the sixth layer. The outer (first) layer has a thickness equal to half the caliber of the anti-tank gun, the width of the air gap of the second layer is equal to the thickness of the first layer, the thickness of the third, fifth and seventh layers is 5 times less than the thickness of the first layer, the thickness of the fourth is 3 ... 5 times more the thickness of the first layer, the thickness of the air gap of the sixth layer is 2 times greater than the thickness of the fifth layer. The armor is made in the form of a cellular structure with the outer and seventh layers made solid. The armor cell in the longitudinal section has the shape of a square with a side equal to two calibers of the anti-tank gun, and the side surfaces of the cell are made of steel and are connected to each other and to the outer, third, fifth and seventh layers by welding. As a porous, high hard non-metallic material, ceramic, glass or glass is used.

 The materiality of the distinguishing features is substantiated by the following.

 The presence of the fourth layer, made of a porous, high-hard non-metallic material, the pores of which are filled with a substance that is chemically active with oxidizing properties, ensures an intensive consumption of the cumulative jet metal when passing through it due to the mechanical and chemical interaction of the jet with this layer. The main role in jet consumption is played by the chemical reaction of oxidation of the metal of the jet by the filler (combustion of the jet). Porous high-hardness material serves as the skeleton of this layer and provides not only jet braking, but also structural rigidity of the armor. Due to the combined effect of this layer on the cumulative stream, the effectiveness of the armor increases substantially, i.e. its resistance to penetration of a cumulative jet. For example, an element of such a layer with a thickness of 100 mm is equivalent in durability to a layer of steel with a thickness of 200 mm. In general, this leads to a significant (up to 2 times or more) reduction in the mass of a surface unit without increasing its total thickness for a given resistance.

 The thicknesses of the layers are essential. The outer layer, equal to half the caliber of the anti-tank gun, is selected based on the fact that a sub-caliber projectile pierces the thickness of a continuous layer of armor approximately equal to its caliber. Given the thickness of the subsequent layers, the residual energy of the projectile that pierced the outer layer is completely absorbed. The presence of an air gap - the second layer provides fragmentation of the shell core due to the tensile action of the rarefaction wave going to its back. This factor further reduces the penetration of the projectile.

 The thickness of the fourth layer is selected for reasons of guaranteed energy absorption of the cumulative jet in conjunction with other layers. The thickness of the sixth layer - the air gap is sufficient to capture the secondary fragments of the seventh layer.

 The cellular structure of the armor provides an additional effect of the destruction of the cumulative jet due to the influence of reflected waves from the side walls of the cells converging to the jet. Cell sizes provide this effect.

 The invention is illustrated by the drawing, which shows a longitudinal (a) and transverse (b) sections of one armor cell.

 Position 1 denotes the first (outer) layer of armor made of high-strength steel with a thickness equal to 0.5 caliber anti-tank guns; position 2 - air gap (second soy) with a width equal to the thickness of the first layer; position 3 - the third layer of steel with a thickness equal to 0.2 of the thickness of the first layer; position 4 - the fourth layer of a porous high-hard non-metallic material filled with a melt of solid oxidizer with a layer thickness of 3 ... 5 times the first layer; position 5 - the fifth layer of steel with a thickness equal to the thickness of the third layer; position 6 - the air gap (sixth layer) with a width of 2 times the thickness of the third and fifth layers; position 7 - the seventh (back) layer of steel with a thickness equal to the thickness of the third and fifth layers; position 8 - the side walls of the armor cells made of steel with a thickness equal to the third, fifth and seventh layers.

 The outer and back (seventh) layers are solid, and the armor cells located between them are bonded to these layers by welding. The armor cell in longitudinal section has the shape of a square with a side equal to two calibers of the anti-tank gun.

A specific example, confirming the effectiveness of the proposed technical solution, are experiments performed by the inventors. The experiment used a cumulative charge (BB TG-50) with a copper lining of a cumulative recess. The penetration depth of the cumulative jet of this charge was 280 mm. Then, as the fourth layer, porous alumina (Al ₂ O ₃ ) ceramic was used, the pores of which were previously filled with molten sulfur. The result of the impact on the assembly according to the drawing of the invention, in which the thickness of the fourth layer was 100 mm, the penetration of the cumulative jet into the steel was 90 mm. Thus, the option of using high-hard porous ceramics with sulfur can reduce the mass of a unit surface of the armor by more than 2 times without increasing its thickness.

It is known that the armor penetration of, for example, cumulative grenades of hand grenade launchers is 500 ... 600 mm, which is about 2 times the thickness of modern multilayer tank armor. That is, to completely neutralize the effects of cumulative ammunition with modern armor, it should have a mass of one square meter of about 4000 kg. The claimed technical solution for the same security of the object (full protection against cumulative grenades) has a mass of 1 m ^{2 of} armor of about 1300 kg, or about 3 times less. With the thickness of the claimed armor, its specific weight is 2 times less than the standard armor of modern tanks. However, the claimed armor fully protects the object from cumulative ammunition, including tandem action, while standard armor does not provide this.

 The inventive armor is simple in production technology, has non-deficient domestic materials. Its cost will not exceed the cost of modern armor.

Source of information taken into account
1. German patent DE 3226476, 07/14/88. The design of the protective wall for an armored vehicle.

Claims (3)

 1. Bulletproof and anti-cumulative armor, including an outer layer made of steel, the second layer is an air gap, the third layer is made in the form of a steel sheet, the thickness of which is less than the outer layer, characterized in that it is equipped with a fourth layer made of porous, high-hard non-metallic material, the pores of which are filled with a substance chemically active with oxidizing properties, the fifth and seventh layers of steel, located with an air gap between them, forming the sixth layer, while the outer the layer has a thickness equal to half the caliber of the anti-tank gun, the width of the air gap of the second layer is equal to the thickness of the outer layer, the thickness of the third, fifth and seventh layers is 5 times less than the thickness of the outer layer, the thickness of the fourth layer is 3.. . 5 times the thickness of the outer layer, the width of the air gap of the sixth layer is 2 times the thickness of the fifth layer, and the armor is made in the form of a cellular structure with the outer and seventh layers made solid.  2. Bulletproof and anti-cumulative armor according to claim 1, characterized in that the armor cell in the longitudinal section has the shape of a square with a side equal to two calibers of the anti-tank gun, and the side surfaces of the cell are made of steel and connected to each other and to the third, fifth and outer seventh layer welding.  3. Bulletproof and anti-cumulative armor according to claim 1, characterized in that ceramic, glass or glass is used as a porous, high-hard non-metallic material.