RU2066041C1 - Method of and device for protection of object - Google Patents

Abstract

FIELD: protection of transport. SUBSTANCE: ball-shaped protection members are placed in space formed by two separated armored plates. Protection members are installed for movement in direction of most dangerous zone. For implementation of this method construction is used with separated armored plates and ball-shaped protection members arranged in interplate space. Protection structure is divided into sections with interplate spaces of adjacent sections communicating with each other. EFFECT: enhanced reliability of protection. 13 cl, 7 dwg

Description

 The invention relates to means for protecting objects, mainly vehicles, from means of destruction.

A known method of protecting a vehicle, in which in the volume between two spaced armored plates placed protective elements of spherical shape [1]
The disadvantage of this method is the increased consumption of materials due to the fact that the equally protected zones have a constant mass.

 The invention addresses this drawback.

 To do this, the ball-shaped protective elements placed in the volume between two spaced apart armor plates are moved in the direction of the most dangerous zone of destruction. Protective elements can be fixed by filling the volume between them with a hardening fusible carrier or by applying a magnetic field, or compression. Protective elements can additionally be scattered around the object in a given direction.

 The protective structure for implementing the method, comprising spaced armor plates and spherical-shaped protective elements placed in the inter-sheet volume, is divided into sections, wherein the inter-sheet volumes of adjacent sections are interconnected. Protective elements can be made hollow with the filling of the internal cavity with flame or explosive, or combustible substances, or compressed gas. Protective elements can be equipped with a built-in nozzle and are made of composite metal shell and ceramic core. Protective elements can also be made in the form of an elastic shell with segments of solid material fixed to it. Protective elements can also be made in the form of an elastic shell with segments of solid material fixed to it. Protective elements can also be made of perforated shell and porous filler. Protective elements can also be made magnetic. In any embodiment, protective elements between adjacent sections are installed shut-off valves or pinch.

 The protective structure is equipped with a device for spreading the protective elements, connected by a pipeline to the inter-sheet volume, while a container with a liquid is installed on the pipeline to fill the protective elements, for example, fuel.

 The protective structure can be equipped with elastic elements, such as bellows, for connecting spaced armor plates to each other in order to provide the possibility of changing the inter-sheet volume when protective elements are placed in it.

 The drawings schematically illustrate a method of protection and a protective structure for its implementation.

 In FIG. 1 shows the protection of the attack aircraft, in FIG. 2 ship protection, in FIG. 3 protection of the tank turret, in FIG. 4 embodiments of protective elements, in FIG. 5 armor construction using bellows; FIG. 6 - one of the methods for moving and fixing the protective elements in the tank tower, as well as the placement of connecting pipelines, in FIG. 7 node 1 in FIG. 6.

 The protective structure contains spaced armor plates 1 and 2 and the protective elements 3 of spherical shape placed in the inter-sheet volume and are divided into sections. Between adjacent sections, shut-off valves 4 or clamps are installed 5. Armor plates 1 and 2 can be interconnected by bellows 6. Structurally, the protective elements 3 can be made (Fig. 4): solid (a), hollow (b), with filling of the internal cavity flame-extinguishing or explosive, or combustible substances, or compressed gas, equipped with a built-in nozzle (c), composed of a metal shell and a ceramic core (g), in the form of an elastic shell with segments of solid material fixed on it (e) and of a perforated shell and pori of filler (e). When performing protective elements 3 (their parts) of ferromagnetic materials, elements 3 can be made magnetic. The design is equipped with connecting pipelines 7, laid between sections or sections and a device 8 for scattering protective elements 3. In the latter case, a container 9 with liquid is installed on the pipeline 7 to fill the protective elements 3.

Consider the work of the protective structure on the example of attack aircraft protection. The spaced armor plates 1 and 2, preferably made of thin titanium sheets, form a tray covering the cockpit in front, bottom and rear. Protective elements 3 can freely roll over the tray. During horizontal flight (r ₁ r ₁ ) they occupy the position in accordance with FIG. 1 and establish protection against damage from below. When diving (r ₂ -r ₂ ), the protective elements 3 roll into the front of the tray and protect the pilot from oncoming damage from below. When cabling (r ₃ r ₃ ) protective elements 3 are placed behind the cockpit. If in this position to fix them by closing the shut-off valve 4 or in another way, for example by applying a magnetic field, then when going into horizontal flight, the protective elements 3 will remain behind the back. This situation corresponds to aerial combat, when the most dangerous direction is hidden behind. In a critical situation, the protective elements 3 can be thrown by means of the device 8 towards the enemy attacking from behind. If you use protective elements 3 with a built-in nozzle, then using the tank 9, you can get a ball-rocket for some time. Since the nozzle by its mass shifts the center of gravity of the elements 3 downward, in free flight the latter is oriented by the nozzle downward, and the jet of burning fuel supports it, preventing it from falling. Thus, the protective elements 3 thrown towards the enemy hang in the air, forming a fencing zone. With the appropriate composition of the fuel, the protective elements 3 can also perform the functions of IR traps. Protective elements 3 made in the form of elastic shells can increase their volume with a change in external pressure, increasing the density of the protective fence. Protective elements 3 made of a perforated shell and a porous filler, after saturation with combustible components, can serve as incendiary means.

 The dispersion of the protective elements 3 can be made fundamentally in any direction from the protected object, both mobile and stationary.

Consider the work of the protective structure on the example of the protection of the ship. When the specific gravity of the material of the protective elements 3 is less than unity, the supply of the latter from one cavity of the ship to another can be carried out using their ascent. In FIG. 2 on the left is an option, protective elements 3 are fed from the double bottom to the interdeck. If at the same time block the inter-deck volume with the shut-off valve 4 ¹ , the elements 3 fill the inter-side volume. On the right is an option to return the elements 3 to their original position, for which water is pumped out from the volume between sheets 1 and 2. With the shut-off valve 4 closed, ³ elements 3 are concentrated in the double-sided volume; when open, they slide into the double bottom volume. Depending on the expected direction of the attack, the protective elements 3 can be concentrated in the direction of the most dangerous zone of destruction. Preferred designs of protective elements 3 for the ship 4 ^b and 4 ^d .

 Consider the work of a protective structure using tank protection as an example.

 It is advisable to divide the tank tower into five zones (roof, side, front and rear). The tank tower is additionally equipped with transverse pneumatic (hydro) jumpers 10, an elastic shell 11 placed in the inter-sheet volume from the side of, for example, the internal armor plate 2, and an electromagnet 12. Armor plates 1 and 2 can be equipped with holes 13 to keep the protective elements 3.

 Depending on the degree of the expected danger, the protective elements 3 are moved in the direction of the most dangerous zone of destruction, for example, by a radar or laser pulse, the sensors of which are placed in each zone.

 According to one of the methods of moving and fixing the protective elements in standby mode, it is advisable to place the latter in the roof by using jumpers 10. The electromagnet 12 can be turned off (as a rule, it is turned on for a few seconds to lift the elements 3 to the top of the tower). When blowing off the jumpers 10, the protective elements 3 by gravity move to the corresponding lower zone of the tower.

 The protective elements located in the lower zones of the tower can be crimped by an elastic shell 11, for which gas or liquid is injected under the latter. In the first embodiment (Fig. 7), pressure is applied under the casing 11 after the elements 3 have filled the entire volume between the armor plates 1 and 2 (position of the casing 11 "a"). According to the second variant, the shell 11 is first moved to position “b”, then the elements 3 are gravity-fed to the remaining gap and then squeezed by their shell 11. Thus, it becomes possible to differentiate reservations with a constant thickness of armor plates 1 and 2. When conducting combat operations using conventional means of destruction, it is advisable to supply air from the supercharger under the sheath 11, if there is a threat of using nuclear weapons, consumable liquids (fuel, oil, water), which allows, along with the filling of elements 3, into which enter light elements, organize effective protection against neutron radiation.

 Since the protective elements 3 are moved in the direction of a possible strike, they create a restoring moment relative to the center of gravity of the tower (machine) when it is struck by a projectile (rocket), which reduces the likelihood of the tower falling off the track or overturning the whole machine.

With regard to the protection of the tank turret, it is advisable to use protective elements 3 structures 4 ^a , 4 ^b and 4 ^g .

 By moving the elements 3 on the march from side to side or along the longitudinal axis of the machine, its patency can be increased to a certain extent. When transporting a vehicle, the elements 3 can be transported separately, which makes it more air transportable. YYY2 YYY4 YYY6

Claims (13)

 1. A method of protecting an object, mainly a vehicle, in which ball-shaped protective elements are placed in the volume formed by two spaced-apart armor plates, characterized in that the protective elements are moved in the direction of the most dangerous zone of destruction.  2. The method according to p. 1, characterized in that the closed elements are fixed by filling the volume between them with a hardening fusible carrier, or by applying a magnetic field, or compression.  3. The method according to p. 1, characterized in that the protective elements are additionally scattered around the object in a given direction.  4. A protective structure containing spaced armor plates and spherical-shaped protective elements placed in the inter-sheet volume, characterized in that it is divided into sections, the inter-sheet volumes of adjacent sections being communicated with each other.  5. The design according to p. 4, characterized in that the protective elements are hollow with the filling of the internal cavity with flame-retardant, or explosive, or combustible substances, or compressed gas.  6. The construction according to p. 5, characterized in that the protective elements are equipped with a built-in nozzle.  7. The protective structure according to claim 4, characterized in that the protective elements are made of composite metal shell and ceramic core.  8. The protective structure according to claim 4, characterized in that the protective elements are made in the form of an elastic shell with spherical segments mounted on it made of solid material.  9. The construction according to p. 4, characterized in that the protective elements are made of perforated shell and porous filler.  10. The construction according to p. 4, characterized in that the protective elements are made of magnet.  11. Design according to any one of paragraphs.4-10, characterized in that between the adjacent sections installed shut-off valves or pinch.  12. The construction according to p. 4, characterized in that it is equipped with a device for scattering of protective elements connected by a pipeline to the inter-sheet volume, while a container with a liquid is installed on the pipeline to fill the protective elements, for example, fuel.  13. The design according to p. 13, characterized in that the spaced armor plates are interconnected by elastic elements, such as bellows, to enable the change in the inter-sheet volume when placing protective elements in it.

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