RU35002U1 - Armored vehicle body and reactive protective device for the body - Google Patents

Description

Armored vehicle body and reactive safety device for

The invention relates to the field of armored structures, in particular to armored hulls of vehicles and reactive protective devices for hulls, and can be used to protect ground armored vehicles.

The body of an armored vehicle with reactive armor is known, containing a roof, sides, lower and upper frontal plates rigidly interconnected, the last of which is equipped with reactive armor packages, the upper frontal sheet being made with a curved trailing edge, and the upper part of the lower frontal sheet is elongated by the amount of bending of the upper frontal sheet, while the sides, lower and upper frontal sheets are interconnected to form a niche along the perimeter of the straight part of the upper frontal sheet, and the niche is equipped with an amplifier for the upper forehead of the sheet, including a transverse armored insert and a package of passive protection plates, on top of which with reactive armor packets are mounted with a gap, which are mounted on a common armored katana base, used as the lower sheets of reactive armor packets and made in the form of a cellular frame, each cell of which is used in as a combat cavity with a laid charge and equipped with an armored protective cover (see RF patent No. 2111442, CL. F41H 7/04, publ. 05/20/1998).

The disadvantages of the known body are quite high weight, which leads to a decrease in maneuverability and speed characteristics, insufficient reliability from cumulative shells and their repeated

IPC7: F41H7 / 04

corps. about the impact when falling into one place of the hull, the impossibility of repair by the crew in the field. Known reactive protective device for the housing, containing a shock absorbing damper with protective charges, stacked in combat cavities, closed on top with shockproof covers (See RF patent No. 2111442, CL. F41H 7/04, publ. 05.20.1998). A disadvantage of the known protective device is inadequate protection against cumulative shells, the impossibility of repair by crew silts in the field. The objective of the utility model related to the hull of an armored vehicle is to reduce the weight of the hull, increase the effectiveness of protection by resisting the repeated cumulative effects of shells. The objective of the utility model related to the reactive protective device for the hull is to increase the effectiveness of protection by reducing the power of the cumulative jet, the implementation of the repair by the crew in the field. The specified task relating to the body of the armored car is achieved by the fact that the body of the armored car containing multilayer armor plates and reactive protective device, according to the utility model, further comprises honeycomb panels located between the armor plates, each of which has a through connection with adjacent cells, when this, one of the honeycomb panels is filled with dispersed heat-resistant filler, while the other honeycomb panels are connected to means for supplying non-combustible cooling gas, while made of reinforced polymer composite materials. To ensure the inclusion of means for supplying non-combustible refrigerant gas at the moment of cumulative impact on the housing, the roof sheets can be equipped with thermal sensors.

The polymer composite material of the armor plates can be reinforced with synthetic fiber material, which allows to obtain the best damping properties and high impact strength of the material of the armor sheets.

To increase the protective properties, aramid fibers can be used as synthetic fibrous material.

The armor plates may additionally contain glass and / or carbon and / or basalt and / or boron fibers, which makes it possible to reduce the cost of the design and convey special physicomechanical characteristics to the materials of the armor sheets.

The housing may further comprise at least one armor plate of a metal alloy, which allows to increase the protective properties and simplify the manufacturing technology.

To reduce weight and increase collapse resistance, titanium or aluminum can be used as the material of honeycomb panels.

Cellular panels may additionally contain reinforcing elements made of VZh-6 alloy, which makes it possible to increase the thermal resistance and shape stability of the case under cumulative effects, as well as to increase the rigidity of the case.

For thermal protection and cushioning of the housing, corundum and / or silicon oxide and / or alumina and / or wood ash can be used as a dispersed filler.

As an inert cooling gas, CO: and / or non-combustible freon can be used, which makes it possible to reduce the temperature in cells, prevent the spread of hot gases, and also reduce the thermal degradation of armor plates made of polymer composite materials.

The specified task relating to a reactive protective device for the housing is achieved by the fact that in the reactive protective device for the housing containing a shock absorbing damper with a protective charge,

according to a utility model, the shock absorbing damper is made of polyurethane in the form of the outer and inner layers, while the inner layer is reinforced with fibrous filler, and the protective charges are made in the form of containers filled with secondary explosive, with throwing plates, and are located in the outer layer in two levels several rows in each level, and in each row the containers are located relative to each other with a gap not less than the length of the container, and each subsequent row of containers is shifted by the amount of clearance tnositelno previous row of containers, wherein the containers of the upper level are positioned above gaps of the lower level and at a distance from the outer surface of the damper is not less than 0.5 of the container height, wherein the polyurethane in the outer layer along the contour of the containers formed perforation.

The location of the containers of the upper level at a distance from the outer surface of at least 0.5 of the height of the container is caused by the need for additional protection of the container itself from bullet and fragmentation; if you do not comply with the specified size, the effectiveness of the protection decreases.

The displacement of the containers relative to each other allows you to prevent the destruction of neighboring containers in the event of failure of one of them in the event of a projectile hit and, as a result, maintain reactive protection as a whole.

Throwing plates can be made of various metal outer and inner layers fixed to each other, which reduces the effect of the cumulative jet.

Throwing plates can be made conical, with the top of the cone facing the body, which allows you to break the cumulative stream (projectile) and reduce its effect on the body.

The outer layer of the throwing plate can be made of material with a hardness of at least 60-63 HRC, which allows crushing part of the projectile and the core of the cumulative jet.

For the formation of the greatest number of crushing particles and their uniform concentration and ejection, the outer layer of the throwing plate can be perforated.

The inner layer of the throwing plate can be made of stainless steel for the greatest ductility and uniform transfer of energy of the secondary explosive to the crushing particles.

For the best damping and technological properties, cold cure polyurethane and / or cold cure elastomers can be used as polyurethane.

For local ejection of a throwing plate, obstacles to the destruction of neighboring containers and preservation of reactive protection in general, perforation along the contour of containers was performed in polyurethane.

Aramid fibers can be used as a fibrous filler, which increases the resistance of reactive protection and the body to high-speed shock loads.

Figure 1 shows a layered diagram of an element of armor with armor plates, honeycomb panels and a reactive protective device;

figure 2 - damper device with a reactive protective device;

Fig. 3 - damping device with a reactive protective device, section AA;

in FIG. 4 - cell honeycomb panels with through holes.

The body of the armored vehicle contains armor plates 1,2,3, cellular

panels 4 with filler and cells 5 and honeycomb panels 6 with cells 7,

reactive protective device 8 located on the outer armored

carbon materials), layer 11 from heat-resistant fabric (fabric withstanding temperatures up to 400 °, decorative finishing layer 12.

Reactive protective device 8 contains a shock absorbing damper made in the form of the outer 13 and inner layers 14, protective charges in the form of containers 15 of the first level and containers 16 of the second level of height h and length B with a secondary explosive 17 and throwing plates 18 with external 19 and internal 20 layers made conical and facing the top of the cone to the body of the armored car. The outer layer 19 of the throwing plate is made with perforation in the form of unfinished slots 21. The perforation 22 is made in polyurethane along the contour of the containers 15, 16.

In combat collisions, the armored vehicle is protected as follows:

When bullet and pointed fragmentation hits the armored wall of the car at an angle of 90 ° +/- 25 °, due to the physicomechanical and rheological properties of polyurethane, they penetrate to a shallow depth and stop. If the projectile hits tangentially or flat, it partially penetrates into the polyurethane, and then discards. At the same time, polyurethane works as an elastic damper and a highly astringent for high-velocity shells.

When cumulative shells hit, penetration through polyurethane to the nearest reactive protection container 15 occurs, detonation of the container explosive occurs, and the propelling plate 18 moves towards the cumulative jet and parts of the projectile, while the inner layer 20 (of stainless steel) of the propelling plate 18 changes its the shape, crushing the outer layer 19 (from alloy with HRC 60-63) of the throwing plate into fragments 18. The fragments of the outer layer 19 and the inner layer 20 of the throwing plate 18 partially disperse the cumulative jet and the shell body shells, as well as, change their trajectory. Further advancement of the cumulative jet and splinters

meets the resistance of the aramid fiber-reinforced polyurethane inner layer 14 of the reactive protection and the outer armor plate 3 of the machine body made of polymer composite materials, where the trajectory also changes, the momentum of the force and energy of the cumulative jet is reduced. After passing through these layers 3, 14, part of the cumulative stream and fragments fall into the honeycomb panels 4 with a through connection of the cells and covered with dispersed (corundum and / or silicon oxide and / or alumina, and / or wood ash) heat-resistant filler, where the cumulative stream is dispersed , partial decrease in temperature and momentum of fragments. Further, the cumulative jet and fragments meet the resistance of the second armor plate 2 of polymer composite materials, which works similarly to the first armor sheet 3. When the cumulative jet passes through the first and second armor plates 3, 2, the thermal sensors 9 give a signal to the control device to turn on the supply means cooling non-combustible gas into the second row of honeycomb panels 6, where the main cooling of the cumulative jet and the extinction of the remaining energy of the weakened fragments about the third (last) armored Article 1, practically without its destruction.

In case of bullet and fragmentation hits, shock loads are absorbed and damped, the path of the projectile changes to a depth of not more than 40 - 50 mm of the outer armor plate 3 due to the implementation of this layer of impact-resistant isophthalic polyesters reinforced with aramid materials.

The sensors are molded in layers of armor plates of 5-7 pcs per 1 dm2, the switching temperature is from 60 ° C.

Flushing honeycomb panels with non-combustible chladone or CCB. Combustion products are removed through special openings in cells equipped with valves.

The utility model formula.

1. The body of the armored vehicle, containing multilayer armor plates and a reactive protective device, characterized in that it further comprises honeycomb panels located between the armor plates, each of which has a through connection with adjacent cells, while one of the honeycomb panels is filled with dispersed filler, and others honeycomb panels are connected to means for supplying non-combustible cooling gas, while the armor plates are made of reinforced polymer composite materials.

2. The hull under item 1, characterized in that the armor plates are equipped with thermal sensors.

3. The housing according to any one of paragraphs 1-2, characterized in that the polymer composite material of the armor plates is reinforced with synthetic fiber material.

4. The housing according to claim 3, characterized in that aramid fibers are used as a synthetic fibrous material

5. The housing according to any one of paragraphs 1-4, characterized in that the armor plates further comprise glass and / or carbon and / or basalt and / or boron fibers.

6. The housing according to any one of paragraphs 1-5, characterized in that it further comprises at least one armor plate of a metal alloy.

7. The housing according to any one of paragraphs 1-6, characterized in that titanium or aluminum is used as the material of the honeycomb panels.

8. The housing according to any one of paragraphs 1-7, characterized in that the honeycomb panels further comprise reinforcing elements of VZh-6 alloy.

9. The housing according to any one of paragraphs 1-8, characterized in that corundum and / or silicon oxide and / or alumina and / or wood ash are used in the dispersion filler class.

10. The housing according to any one of paragraphs 1-9, characterized in that as an inert cooling gas using CCh and / or non-combustible freon.

11. A reactive protective device for the housing containing a shock absorbing damper with a protective charge, characterized in that the shock absorbing damper is made of polyurethane in the form of the outer and inner layers, while the inner layer is reinforced with fibrous filler, and the protective charges are made in the form of containers filled with secondary explosive substance, with throwing plates, and are located in the outer layer in two levels, several rows in each level, and in each row the containers are located relative to each other with a gap rum is not less than the length of the container, and each subsequent row of containers is offset by the amount of the gap relative to the containers of the previous row, while the upper level containers are located above the lower level gaps and at a distance from the outer surface of the damper at least 0.5 container heights, while in polyurethane according to the contour of the containers is perforated.

12. The reactive protective device according to claim 11, characterized in that the throwing plates are made of various metal outer and inner layers fixed to each other.

13. Reactive protective device according to any one of paragraphs 11-12, characterized in that the throwing plates are made conical, with the apex of the cone facing the body.

14. Reactive protective device according to any one of paragraphs 11-13, characterized in that the outer layer of the throwing plate is made of material with a hardness of not less than 60-63 HRC.

15. Reactive protective device according to any one of paragraphs 11-14, characterized in that the outer layer of the throwing plate is perforated.

16. Reactive protective device according to any one of paragraphs 11-15, characterized in that the inner layer of the throwing plate is made of stainless steel.

17. A reactive protective device according to any one of paragraphs 11-16, characterized in that cold cure polyurethane and / or cold cure elastomers are used as polyurethane.

18. Reactive protective device according to any one of paragraphs 11-17, characterized in that aramid fibers are used as the fibrous filler. D HH 1111.1. IIIIE.i. II f№ g, rf-V. rf-%. , f - th.

Claims (18)

1. The body of the armored vehicle containing multilayer armor plates and a reactive protective device, characterized in that it further comprises honeycomb panels located between the armor plates, each of which has a through connection with adjacent cells, while one of the honeycomb panels is filled with dispersed filler, and others honeycomb panels are connected to means for supplying non-combustible cooling gas, while the armor plates are made of reinforced polymer composite materials. 2. The housing according to claim 1, characterized in that the armor plates are equipped with thermal sensors. 3. The housing according to any one of claims 1 to 2, characterized in that the polymer and composite material of the armor plates is reinforced with synthetic fiber material. 4. The housing according to claim 3, characterized in that aramid fibers are used as synthetic fibrous material. 5. The housing according to any one of claims 1 to 4, characterized in that the armor sheets further comprise glass and / or carbon and / or basalt and / or boron fibers. 6. The housing according to any one of claims 1 to 5, characterized in that it further comprises at least one armor plate of a metal alloy. 7. The housing according to any one of claims 1 to 6, characterized in that titanium or aluminum is used as the material of the honeycomb panels. 8. The housing according to any one of claims 1 to 7, characterized in that the honeycomb panels further comprise reinforcing elements of VZh-6 alloy. 9. The housing according to any one of claims 1 to 8, characterized in that corundum and / or silicon oxide and / or alumina and / or wood ash are used as a dispersed filler. 10. A housing according to any one of claims 1 to 9, characterized in that CO ₂ and / or a non-combustible freon are used as an inert cooling gas. 11. A reactive protective device for the housing containing a shock absorbing damper with a protective charge, characterized in that the shock absorbing damper is made of polyurethane in the form of the outer and inner layers, while the inner layer is reinforced with fibrous filler, and the protective charges are made in the form of containers filled with secondary explosive substance with throwing plates, and are located in the outer layer in two levels, several rows in each level, and in each row the containers are located relative to each other with a gap rum, not less than the length of the container, and each subsequent row of containers is offset by the gap with respect to the containers of the previous row, while the upper level containers are located above the lower level gaps and at least 0.5 container height from the outer surface of the damper, while in polyurethane perforation is performed along the contour of the containers. 12. The reactive protective device according to claim 11, characterized in that the throwing plates are made of various metal - external and internal - layers fixed to each other. 13. Reactive protective device according to any one of paragraphs.11 and 12, characterized in that the throwing plates are made conical, with the apex of the cone facing the body. 14. Reactive protective device according to any one of paragraphs.11-13, characterized in that the outer layer of the throwing plate is made of material with a hardness of at least 60-63 HRC. 15. Reactive protective device according to any one of paragraphs.11-14, characterized in that the outer layer of the throwing plate is perforated. 16. Reactive protective device according to any one of paragraphs.11-15, characterized in that the inner layer of the throwing plate is made of stainless steel. 17. Reactive protective device according to any one of paragraphs.11-16, characterized in that as the polyurethane used polyurethane cold-cured and / or elastomers cold-cured. 18. Reactive protective device according to any one of paragraphs.11-17, characterized in that aramid fibers are used as a fibrous filler.