RU107212U1 - SANDWICH PANEL - Google Patents

Abstract

 1. A sandwich panel comprising an armor-protecting composition consisting of layers successively placed in the direction of the damaging effect, a layer of steel, a layer of which the main component is ceramic, with a thickness of at least 20 mm, made of separate ceramic elements obtained by sintering, for example, aluminum oxide, boron carbide, silicon carbide, silicon nitride or other inorganic compounds connected by a highly elastic binder, mainly polyurethane or rubber, and a substrate layer of steel or aluminum nium alloy, characterized in that the steel layer in the armor-proof composition is made of plates of various sizes and shapes of any flat figures laid at least in two rows with offset relative to each other, plates made of a thickness of 2.0-8.0 mm have an area of 4.0-64.0 mm2, hardness of not less than 360 HB, surface roughness of not more than Ra 0.8, the base of the ceramic layer is made of ceramic elements of various sizes and shapes of any three-dimensional figures, while the figures are laid in at least two series, and figures of elements of smaller sizes are placed in the depressions formed by figures of larger elements, the surface layers of the sandwich panel are made of metal sheets or one metal sheet, and the second is made of glass-magnesium sheet, faced with a decorative coating on the front side, and the insulating layers are made either as a single layer of mineral wool or alternating layers of mineral wool and polyurethane foam. ! 2. The sandwich panel according to claim 1, characterized in that the steel plates in the armor-protecting composition in each row are stacked tightly to each other

Description

The utility model relates to the construction of sandwich type panels and is used in modern industrial, military and civil engineering, namely for the manufacture of external walling, fire walls, heat-insulating structures of buildings and structures requiring armor protection.

Sandwich panels used in military construction, stationary, pre-fabricated facilities with the requirement of armor protection, must have high thermal insulation properties with a minimum thickness of the panel, high strength and sound insulation, fire resistance and a high degree of protection of equipment and manpower from destruction of small arms, including sniper weapons.

Known devices for the protection of stationary and vehicles (RU 2196952) The device includes curtains of steel mesh type netting or shell, placed at an angle to the protected object, while it is equipped with an armored part made in the form of three layers adjacent to each other without a gap, the outer layer is made of high strength steel with high hardness and has a thickness equal to the caliber of the bullet, the second layer is made of highly hard porous ceramic, the pores of which are filled with a chemically active substance with oxidizing substances properties, and has a thickness equal to 10 ... 15 caliber bullets, the third layer is made of plastic material, a thickness of 0.5 ... 1.0 caliber bullet. In addition, to protect objects in vehicles, curtains made of steel nets are placed in several tiers on the outer or inner side of the side of the vehicle and have a cell clearance of not more than 0.5 caliber bullets.

The disadvantages of this device in relation to the conditions of protection of stationary pre-fabricated objects are: low degree of protection of the object from the effects of small arms bullets in caliber from 5.45 to 12.7 mm.

A technical solution is known (RU 68674, option 1) aimed at providing the same degree of protection of an object from the effects of small arms bullets and cumulative grenades of hand grenade launchers but is simpler to manufacture. According to this technical solution, multilayer armor protection includes a layer of high-strength armor steel sequentially placed in the direction of the damaging effect, a layer whose main component is ceramic, and a substrate layer. A layer of high-strength armor steel is 2 ... 8 mm thick. In this case, steel is selected that has a hardness of at least 363 HB, which corresponds to a print diameter of not more than 3.2 mm (test with a steel ball with a diameter of 10 mm at a load of 3000 kgf and exposure at a load of 10 sec) or at least 39 HRc (test with a diamond cone at a load of 150 kg, scale C). The layer, the main component of which is ceramics, is made of a thickness of at least 10 mm from individual ceramic elements connected by a highly elastic binder, which is predominantly polyurethane or rubber. Ceramic elements are, for example, cylindrical or spherical in shape, and are made by sintering, for example, alumina, boron carbide, silicon carbide, silicon nitride or other inorganic compounds. The substrate layer is made of a material whose ductility is higher than that of the first layer. It can also be steel, while the substrate layer has a thickness of 2 ... 10 mm. The production of a substrate layer of aluminum alloy with a thickness of 4 ... 20 mm leads to better results. For more reliable trapping of fragments of armor protection and ammunition after the substrate layer, it may be necessary to additionally secure several layers (mainly from 4 to 30 layers) of aramid fabric based on fibers of the type Twaron, Kevlar, Rusar, Texar or the like. For the same purpose, at least one screen of high modulus polyethylene can be further fixed after the substrate layer. This technical solution was made as a prototype.

The disadvantages of this device in relation to the conditions of protection of stationary pre-fabricated objects are: low degree of protection of the object from the effects of small arms bullets in caliber from 5.45 to 12.7 mm. In addition, this multilayer composition does not have high thermal insulation properties and sound insulation.

Currently, sandwich-type laminated panels used for prefabricated stationary objects are produced with a central layer made of polystyrene foam (polystyrene foam) or mineral wool. Such a layer of insulation is placed between the outer and inner cladding made of aluminum or steel profiled sheets. (RU 2156340).

The objective of this utility model is to create a sandwich panel design that allows the construction of military and industrial facilities, ensuring the safety and security of equipment and people, and ensuring a comfortable stay in these objects.

In the process of solving this problem, a technical result is achieved consisting in increasing the resistance to damage from small arms, including sniper, heat and sound insulation.

The specified technical result is achieved by a sandwich panel comprising an armor-protecting composition consisting of layers successively placed in the direction of the damaging effect, a layer of steel, a layer whose main component is ceramic, at least 20 mm thick made of separate ceramic elements obtained sintering, for example, aluminum oxide, boron carbide, silicon carbide, silicon nitride or other inorganic compounds connected by a highly elastic binder, mainly polyurethane or rubber, and the substrate layer of steel or aluminum alloy wherein the steel layer, in the armor-proof composition, is made of plates of various sizes and shapes of any flat figures laid at least in two rows with mixing relative to each other plates made of thickness 2 , 0-8.0 mm, have an area of 4.0-64.0 mm ² , hardness of not less than 360 HB, surface roughness of not more than R _a 0.8, the base of the ceramic layer is made of ceramic elements of various sizes and the shape of any three-dimensional figures while the figures are stacked in at least two rows, and fi ur elements of smaller sizes are placed in depressions formed by figures of larger elements, the surface layers of the sandwich panel are made of metal sheets or one metal sheet, and the second is made of glass-magnesium sheet coated on the front with a decorative coating, and the heat-insulating layers are made either as a single layer from mineral wool or alternating layers of mineral wool and polyurethane foam. In addition, steel plates in the armor-proof composition in each row are stacked tightly to each other, plates and rows with plates are connected to each other by a highly elastic binder, mainly polyurethane or rubber, from 4 to 30 layers of aramid fabric based on the substrate are additionally fixed fibers of the type Twaron, Kevlar, Rusar, Texar or a similar material, elements of the figure of a larger volume of the ceramic layer, have a size in the range of 0.5-1.0 layer thickness, while elements of smaller volumetric figures are located on the side of the pores burning effect, the substrate layer of the armor-protective composition is made of steel and has a thickness of 1.5-5.0 mm, the substrate layer of the armor-protective composition is made of aluminum alloy and has a thickness of 5.0-10.0 mm, the metal sheets are coated with an anti-corrosion coating, primer and polymer coating, the glass-magnesium sheet consists of magnesium chloride, magnesium oxide, perlite, crushed stone, fiberglass and fire-resistant adhesive, with the following volume% ratios:

magnesium chloride - 35%,

magnesium oxide - 45%,

crushed stone - 10%,

perlite - 8%,

fiberglass - 1%,

glue-1%, the decorative coating of the glass-magnesium sheet consists of consists of a polymer film on a paper basis.

In contrast to the prototype in the proposed solution, the steel layer, in the armor-proof composition, is made of plates of various sizes and shapes of any flat figures laid at least in two rows with mixing plates relative to each other, plates made of thickness 2.0-8.0 mm, have an area of 4.0-64.0 mm ² , hardness of not less than 360 HB, surface roughness of not more than R _a 0.8. It was experimentally established that when a bullet penetrates a small arms containing a carbide core, a steel barrier, in the form of a separate sheet, a change in the trajectory of the core practically does not occur, the speed decreases. It is proposed to perform this layer from individual plates laid in several rows. In this case, the obstacle will not be rigid, it is almost impossible to break through a separate plate, when the core moves, the trajectory changes. A further change in the trajectory of the core occurs in the ceramic layer. The layer is made of ceramic elements having high compressive strength. This allows them to withstand high pressures arising from a collision with the core. Smaller sizes practically do not collapse when they meet the core, so the core changes the direction of motion and loses speed. Shards of broken ceramic elements are trapped in the substrate layer and the layers of aramid fabric. The execution of ceramic elements of various sizes and shapes of any three-dimensional figures and placed in several layers, as well as the placement of figures of smaller elements in the depressions formed by the figures of elements of a larger size, practically eliminate the penetration of a sandwich panel from a boom weapon with bullets equipped with hard alloy cores. The execution of the surface layers of the sandwich panel from metal sheets or one metal sheet, and the second from a glass-magnesium sheet lined with decorative coating on the front side, and heat-insulating layers in the form of one layer of mineral wool or alternating layers of mineral wool and polyurethane foam allow you to maintain comfortable conditions when you are people indoors and create the necessary temperature conditions indoors and soundproofing.

This technical solution is illustrated by graphic material, which shows a cross section of a sandwich panel. The overall dimensions of the sandwich panel can be different.

To ensure effective armor protection of objects located indoors (it can be explosives, people and other objects requiring protection) from the damaging effects of ammunition (not shown in the figure), the object is constructed from sandwich panels, which are both an element of the building structure and a shield.

The sandwich panel contains a facing layer made of steel 1, an armor-protecting composition consisting of a layer of 2 metal plates stacked in several layers and connected by a highly elastic binder, layer 3 of ceramic elements of various sizes and the shape of any three-dimensional figures, while the figures are laid at least in two rows, and figures of elements of smaller sizes, are located in the depressions formed by figures of elements of larger size and interconnected by a highly elastic binder, layer 4 of plastic material, layer 5 of ar amide tissue. The necessary temperature regime and sound insulation are provided by layer 6 made in the form of one layer of mineral wool or alternating layers of mineral wool and polyurethane foam and a glass-magnesium sheet consisting of magnesium chloride, magnesium oxide, perlite, crushed stone, fiberglass and fire-resistant adhesive.

Claims (9)

1. A sandwich panel comprising an armor-protecting composition consisting of layers successively placed in the direction of the damaging effect, a layer of steel, a layer of which the main component is ceramic, with a thickness of at least 20 mm, made of separate ceramic elements obtained by sintering, for example, aluminum oxide, boron carbide, silicon carbide, silicon nitride or other inorganic compounds connected by a highly elastic binder, mainly polyurethane or rubber, and a substrate layer of steel or aluminum nium alloy, characterized in that the steel layer in the armor-protective composition is made of plates of various sizes and shapes of any flat figures laid at least in two rows with offset relative to each other, plates made of a thickness of 2.0-8.0 mm have an area of 4.0-64.0 mm ² , hardness of not less than 360 HB, surface roughness of not more than R _a 0.8, the base of the ceramic layer is made of ceramic elements of various sizes and shapes of any three-dimensional figures, while the figures are laid at least in two rows, and figures of elements of smaller sizes are placed in the depressions formed by the figures of larger elements, the surface layers of the sandwich panel are made of metal sheets or one metal sheet, and the second is made of glass-magnesium sheet coated on the front with a decorative coating, and the heat-insulating layers are made either as a single layer of mineral wool or alternating layers of mineral wool and polyurethane foam. 2. The sandwich panel according to claim 1, characterized in that the steel plates in the armor-protecting composition in each row are stacked tightly to each other, the plates and rows with plates are connected to each other by a highly elastic binder, mainly polyurethane or rubber. 3. The sandwich panel according to claim 1, characterized in that from 4 to 30 layers of aramid fabric based on fibers of the type Twaron, Kevlar, Rusar, Texar or the like material are additionally fixed on the substrate layer. 4. The sandwich panel according to claim 1, characterized in that the elements of the figure of a larger volume of the ceramic layer have a size in the range of 0.5-1.0 layer thickness, while the elements of smaller volumetric figures are located on the side of the damaging effect. 5. The sandwich panel according to claim 1, characterized in that the substrate layer of the armor-protecting composition is made of steel and has a thickness of 1.5-5.0 mm. 6. The sandwich panel according to claim 1, characterized in that the substrate layer of the armor-protecting composition is made of aluminum alloy and has a thickness of 5.0-10.0 mm. 7. The sandwich panel according to claim 1, characterized in that the metal sheets are coated with an anti-corrosion coating, a primer and a polymer coating. 8. The sandwich panel according to claim 1, characterized in that the glass-magnesium sheet consists of magnesium chloride, magnesium oxide, perlite, gravel, fiberglass and adhesive, resistant to fire, in the following ratios, vol.%: magnesium chloride 35 magnesium oxide 45 crushed stone 10 perlite 8 fiberglass one glue one 9. The construction sandwich panel according to claim 1, characterized in that the decorative coating of the glass-magnesium sheet consists of a polymer film on a paper basis.