RU2462681C1 - Active armor of staroverov (versions) - Google Patents

Abstract

FIELD: weapons and ammunition.

SUBSTANCE: according to the first version, the active armor comprises in each cell several flat shaped cumulative charges separated by damping partitions and oriented outward. Plane of cumulative charges jet is oriented across the most likely trajectory of reaching of destruction means and makes an angle of 30-90 degrees with the trajectory. Under the cumulative charges a shock absorber with slits is placed. Under the shock absorber a layer of explosive is located, which is connected to cumulative charges through the said slits. According to the second version, between a layer of explosive and the main armor there is the channel panel, which has channels for transmission of cumulative jets. In the channels of the channel panel there are cumulative charges, each of which is connected to a layer of explosive through the slit. The charges which are nearer to the direction of the most probable arrival of weapons are directed frontwards and can penetrate cell wall. The middle charges are aimed at nearer ones and can cause their ignition. Long distance charges are aimed at a plate of explosive connected to the front and/or side parts of the near charge (charges).

EFFECT: improved protection of armored vehicle.

13 cl, 13 dwg

Description

The invention relates to means of active protection of armored objects and is intended to protect them from cumulative, tandem cumulative shells and ATGMs, from uranium and tungsten rods, from shells with plastic explosives.

Known active protection means in the form of cells placed on the armor containing explosives and a metal plate, see Russian patent No. 2079091. However, they protect only from single cumulative shells and grenades.

To protect against rods, it is necessary to violate their integrity or at least shape and orientation. And to protect against tandem shells, it is necessary to cause premature forced non-optimal undermining of the rear charge in it. Non-optimal detonation of a cumulative charge - this is not an explosion at the rear exactly along the longitudinal axis of the charge, but an explosion of its explosive from the front and / or side of its cumulative funnel. In this case, the combustion front propagates so that the cumulative jet either does not form at all, or will be weakened by tens of times, have a blurry structure, a spontaneous direction and a much lower speed, usually not exceeding the speed of propagation of a shock wave.

To obtain these phenomena, active armor contains in each cell several flat shaped-charge charges separated by shock-absorbing baffles and oriented outward, the plane of the jet of which is oriented across the most probable approach path for the destruction of weapons and makes up an angle of 30-90 degrees with this trajectory (optimally 60), and under cumulative charges are located shock absorbing pad with slots, and under it is a layer of explosives, which is connected to these charges through the above-mentioned slots. Above there may be an armored cover with slots or several separate armored strips to protect against bullets and fragments. Rain protection slots can be covered with easily penetrable material, such as rubber. Other options are possible - the armored cover is made monolithic or has weakening grooves opposite the flat charges, but in this case it will be necessary to increase the power of the flat charges. For better quenching of the jet of the first tandem cumulative charge, the cell may have not one, but two armored covers located with a gap.

Flat shaped charges can be placed in the cell perpendicular to the main armor, as in Fig. 1, and can be tilted back (hereinafter: “forward” - from the armored object, “back” - to the armored object, “near” - located closer to means of defeat, “distant” - vice versa).

The channel panel can also be used in conjunction with conventional, non-cumulative active protection.

This is the simplest embodiment of the invention. But the cells of such armor should be the length (hereinafter - in the direction of the most likely arrival of weapons) in the entire length of the inclined section of the armor. And even so, they do not protect the tank well from shells arriving at an angle of 10-15 degrees to the longitudinal axis of the tank.

To increase the reliability of protection and minimize the area of the triggered cells, it is necessary to reduce the size of the cells and provide for a controlled limited transmission of the front of combustion of the explosive to one or two cells closer to the direction of arrival of the weapons. And, in addition, provide for the cessation of further transfer of fire, so that the hit of a projectile in one cell does not cause uncontrolled operation of all closer cells.

For this, a channel panel is located between the explosive interlayer and the main armor, which has channels for transmitting cumulative jets, in the channels of which cumulative charges are connected to the interlayer through openings, and the charges closest to the direction of the most probable arrival of weapons are oriented forward and are able to penetrate the cell wall, medium charges are directed to the near ones and can cause them to ignite, and long-range charges are directed to the explosive plate connected to the front and / or side sections of the near charge (charges). The latter is done in order to cause suboptimal detonation of nearby charges and thereby stop the transfer of fire to other cells. That is, cause at the right time to block the near charges. Proceeding from this, the near charges transferring fire to the next cell can be called “piercing”, and the distant charges that block the work of neighbors can be called “blocking”. In this case, the cell walls opposite the proximal charges, to facilitate its penetration, can have a weakening, for example, through-hole drilling of a small diameter.

In order to prevent abnormal ignition of the explosive strip from the occurrence of medium charges or from the non-optimal triggering of long-range charges, pads made of shock-absorbing material may be present in open areas of this strip. The strip itself (jumper) is needed in order to block both neighbors with one long-range charge.

The average charges are needed in order to rapidly transfer fire to the near end of the cell and to another cell.

For this, the near and middle charges in the channel panel are connected to the explosive layer by their rear parts, and the distant charges are connected to it by the front-side parts, again in order to cause suboptimal detonation of the long charges and thereby prevent unnecessary blocking.

Of great importance is the rate of transfer of fire from the point of impact of the projectile to the near end of the cell and to the near end of another (others), closer to the cell. For this, the medium and long charges in the channel panel are super-cumulative (i.e., with a cylindrical or tapering cavity). The speed of the cumulative jet of such charges reaches 150 km / s.

In order for the cumulative jet, which accelerates the transfer of fire, not to damage the charge into which it will fall, the near and far charges have an armored washer in the back with one central or several inclined holes converging to the center.

For the transfer of fire from one cell to another, the near and far charges in the channel panel, if there are two, are located from the side edges of the cell at a distance ^of _{1/4 of the} transverse step of the cells or the near charges of one cell are located opposite to the distant charges of another cell (cells), and if there are four long-range charges, then they are arranged in pairs and in each pair are directed to different nearby charges, and the charges in the pair are connected by the explosive section so that they work together.

In the latter case, the explosive strip between the near charges may not be needed.

However, in the case where there is a plate, the burning time of the plate from the place of the long-range jet to any of the nearest charges is less than from one near charge to the average charge directed to another near charge, and less than from the far charge to any average charge. This is necessary so that the non-optimal operation of one short-range charge does not lead through the interlayer and one of the middle charges to the optimal response of the other short-range charge.

When active armor is triggered, cumulative jets are the first to fly out. Then takes off an armored cover or armored strip. And then the channel panel flies out of the cell. But the speed of its approach is small, since the number of explosives in super-cumulative charges under it is small. To increase the approach speed, the channel panel contains additional channels open to the main armor, filled with explosives and connected to the interlayer and / or to medium charges through the hole.

However, the feasibility of this and the amount of additional explosives should be determined experimentally, since when the tandem charge hits, the panel should not take off too quickly - it must effectively extinguish the second stream, if it does form.

Cells are best done in a mostly rectangular shape. Such cells can be grouped in various ways. Two options are most optimal - the cells are arranged in rows or with a shift by half a step in the transverse direction (the step is a periodically repeating size, in this case it is equal to the cell width plus the thickness of one partition).

The first option is most suitable for side armor provided that it is defeated horizontally in front at an angle of no more than 30 degrees to the longitudinal axis of the tank. In this case, the planes of the flat cumulative jets should be approximately vertical. When a projectile hits, two cells fire - punched and closer, see Fig. 7, hatched. This option is suitable for combat in open areas.

However, for combat in urban conditions, when there is a high probability of a cumulative grenade strike perpendicular to the side, it is more expedient to direct the plane of the jets parallel to the longitudinal axis of the tank, that is, approximately horizontally.

So that depending on the conditions of the future battle, it was possible to change the orientation of the active armor charges, the cells on the side armor are square in shape and have an easily removable armor cover, and the active armor elements are placed in the cells with the possibility of extraction. In this case, the armored covers can be fastened with thermoplastic glue or Wood's alloy and are removed with light heating. Flat charges and the channel panel are removed and inserted in a different orientation. Then again, with light heating, the armored cover is installed in place in the desired orientation. The orientation of the channel panel should be such that the punched panel and the lower one below it work.

For frontal armor, the location of the cells in transverse rows with a shift of half a step is optimal (see Fig.6). In this case, three cells are triggered - punched and two closer ones (shaded). This provides effective protection against all types of damage in the front in the sector determined by the proportions of the cell. With a cell aspect ratio of 2: 3 in the longitudinal direction, the protection sector will be 9.5 degrees to the right and left, and for square cells - 14 degrees.

Another option is the arrangement of the cells in longitudinal rows with a shift of half a step. In this case, the protection sector expands, but the protection itself becomes weaker - with some unsuccessful hits, only half of one cell works effectively. In this case, four cells should work.

For such a response, the cells are arranged in longitudinal rows with a half-step shift, and the channel panel contains three punch cumulative charges directed to the middle of the near wall of the cell and to the lower quarter of the side walls, contains three block cumulative charges located in the middle of the far wall and in the upper quarter of the side walls and aimed at an intermediate explosive charge located in the center of the cell and connected by explosive sections with three intermediate cumulative charges directed to the front side plates slime three perforating charges, and has a mean cumulative charges towards perforating charges. That is, such a channel panel is similar to a six-pointed star: three blocking jets converge in the center, again split into three and cause suboptimal detonation of three breakdown charges, blocking the transfer of fire to other cells. In this case, one blocking charge is able to block all three breakthroughs. And the number of average charges should be at least three.

Due to the insufficient effectiveness of this option, graphic materials on it are not given.

This active armor protects the entire surface of the inclined armor well, with the exception of the near edges - these are the bottom ten cm of the tower and the front edge of the frontal and side armor. If hit in these places, the ammunition is almost out of the area of action of the flat cumulative jets. Therefore, to protect these areas, additional active armor cells should be placed. To place them, the leading edges of the inclined main armor have forward-upward or forward-downward visors made of armor equipped with active armor directed forward-down or forward-up, respectively.

Figure 1 shows a stepped cross section of active armor along the channels of the channel panel. On the main armor 1 there are partitions 2, which are the walls of the cells. In the cell are six flat cumulative charges 3, separated by shock-absorbing partitions 4. Under the charges there is a shock-absorbing pad 5 with six slots. And under the gasket there is a layer 6 of explosives, under which there can be a channel panel 7, in the channels of which there are two near cumulative charges 8, eight medium super-cumulative charges 9 and two distant super-cumulative charges 10. The latter are directed to a plate of explosives 11 connecting the front side edges of near charges. The plate is protected from false alarms with shock absorbing pads 12.

On top of the cell is closed from bullets with an armored cover 13 with six slots. And the slots are closed from the rain by hermetic strips 14.

Figure 2 shows a bottom view of the channel panel 7. It can be obtained by casting from metal, and in this case, the channels in it can have a semicircular shape, see figure 3.

Figure 4 shows in cross section a super-cumulative charge. These can be charges 8, 9, or 10. It consists of a cylindrical block of explosives 15 having a cavity 16 tapering in the direction of the explosion with or without a lining. To form the combustion front, there is a central shock-absorbing insert 17 and a shock-absorbing washer 18 with a central hole. At the rear end for primary ignition of the charge there is a layer of explosive 19. In the near and far charges, which themselves are exposed to cumulative jets, there should also be a metal washer 20 with several inclined holes converging to the center.

Figure 5 shows in cross section additional channels 21 in the channel panel 7, filled with explosives.

Figure 6 shows the arrangement of the cells in transverse rows with shifts of half a step. This arrangement is optimal for frontal armor. The arrow shows the hit of the projectile, the triggered cells are shaded.

7 shows the arrangement of cells in orthogonal rows. This arrangement is optimal for side armor when fired from the front sector.

In Figs. 8, 9, 10, the steps of triggering a cell when a uranium rod 22 enters are shown.

In Fig. 11, the operation of two cells when a tandem shell 23 hits is shown.

12, 13, front 24, 25, 26 and side 27, 28 visors with active armor are shown.

Active armor works like this: when a striking munition hits, an explosive explodes in one of the flat cumulative charges 3. The combustion front through the slots in the gasket 5 is transferred to the interlayer 6 and to the remaining flat charges.

If there was a channel panel 7 in the cell, then combustion through the holes in it is transmitted to the middle charges 9, the near charges 8 and to the front-side part of the long charges, causing the latter to be non-optimal self-liquidating. Middle charges accelerate (at a speed of 150 km / s) transfer combustion to nearby charges 8, they pierce the cell wall and transfer combustion one (when the cells are arranged in orthogonal rows) or two (when the cells are arranged with a shift by a half step in the transverse direction) closer located cells, causing them to trigger.

Formed flat cumulative jets (Fig.8) with sufficient power cut the rod 22 into several parts and cause a violation of their orientation (Fig.9). Then, the armored covers 13 fly off the cells and the channel panels 7 fly out, causing further disturbance of the orientation of the rod parts. As a result, not a longitudinally flying solid rod gets into the main armor, but several fragments that randomly fly it, which are not able to penetrate the main armor.

When a tandem ordnance hits 23, the first-charge jet is weakened by flat cumulative jets from charges 3 and the flying armored cover 13. In this case, the combustion of explosives is transmitted to one or two closer cells, and one of the flat cumulative jets breaks through the wall of the projectile and causes an optimal burst of the second tandem charge. The cumulative stream is practically not formed. If, for some reason, this did not succeed, then the jet of the second charge is weakened by the soaring channel panels 7.

The armored covers work like this: a projectile flying into the lower part of the tank’s tower hits the visor 24, on the front-lower surface of which there is active armor. However, it cannot be cumulative, since the jets will penetrate the thin upper armor of the tank (or it must be strengthened in this place). In this case, the visor 25 will protect from flying horizontally in front of the uranium rod. Moreover, this visor should be located perpendicular to the upper frontal armor, otherwise it will spoil the active armor on it with its jets.

Visor 26 will protect the frontal armor near the leading edge. The visor 27 will protect the front edge of the side armor of the tower from shelling from the front sector, and the visor 28 will protect the front edge of the side armor of the hull.

The use of this armor on new tanks and as a modernization of old ones will make them invulnerable from shelling with all types of ammunition horizontally in the front in the sector of 10-15 degrees from left to right. The effectiveness of ammunition flying at large angles will also be significantly weakened.

Claims (13)

1. Active armor, consisting of cells with an explosive substance, characterized in that it contains in each cell several flat cumulative charges separated by shock absorbing baffles and oriented outward, the plane of the jet of which is oriented across the most probable approach path for the destruction of weapons and makes an angle of 30- 90 °, moreover, under the cumulative charges there is a shock-absorbing pad with slots, and under it there is a layer of explosive, which is connected to the cumulative poisons through said slit. 2. Armor according to claim 1, characterized in that the cell has one or two armored caps located with a gap. 3. Active armor, consisting of cells with an explosive substance, characterized in that between the layer of explosive and the main armor there is a channel panel having channels for transmitting cumulative jets, in the channels of which cumulative charges are connected to the layer of explosive through an opening, and the charges closest to the direction of the most probable arrival of weapons of destruction are oriented forward and are able to penetrate the cell wall, the average charges are directed to the nearest and can cause them to ignite, and distant charges are directed to the explosive plate connected to the front and / or side sections of the near charge (charges). 4. Armor according to claim 3, characterized in that the near and middle charges in the channel panel are connected to the layer of explosive with their rear parts, and the distant charges are connected to it by the front-side parts. 5. Armor according to claim 3, characterized in that the medium and long charges in the channel panel are made with a cylindrical or tapering cavity. 6. Armor according to claim 3, characterized in that the near and far charges have an armor washer in the back with one central or several inclined holes converging to the center. 7. Armor according to claim 3, characterized in that the near and far charges in the channel panel, if there are two of them, are located 1/4 of the transverse step of the cells from the side edges of the cell or the nearby charges of one cell are opposite the long charges of another cell (cells ), and if there are four long-range charges, then they are arranged in pairs and in each pair are directed to different nearby charges, and the charges in the pair are connected by a section of explosive so that they work together. 8. The armor according to claim 3, characterized in that the burning time of the plate from the point of entry of the long-range jet to any of the nearest charges is less than one short-range charge to an average charge directed to another short-range charge and less than the long-range charge to any medium charge. 9. Armor according to claim 3, characterized in that the channel panel contains additional channels open to the main armor, filled with explosive and connected to the interlayer and / or with medium charges through the hole. 10. Armor according to claim 3, characterized in that the cells are arranged in rows or with a shift by half a step in the transverse direction. 11. The armor according to claim 3, characterized in that the cells on the side armor are square in shape and have an easily removable armored cover, and the active armor elements are placed in the cells with the possibility of extraction. 12. The armor according to claim 3, characterized in that the cells are arranged in longitudinal rows with a shift by a half step, and the channel panel contains three breakdown cumulative charges directed to the middle of the near wall of the cell and to the lower quarter of the side walls, contains three blocking cumulative charges located in the middle of the far wall and in the upper quarter of the side walls and aimed at an intermediate explosive charge located in the center of the cell and connected by sections of the explosive with three intermediate cumulative charges directed to the front side plates three perforating charges, and has a mean cumulative charges towards perforating charges. 13. Armor according to claim 3, characterized in that the leading edges of the inclined main armor have forward-upward or forward-downward visors made of armor equipped with active armor directed forward-down or forward-up, respectively.

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