FI80785C - PANSARGENOMBORRANDE PROJECT. - Google Patents

Description

1 80785

This invention relates to a new type of armor-piercing projectile comprising a tip which operates according to a hollow charge principle and thus is a hollow charge intended to penetrate an extremely thick conventional armor and in addition an active armor and a dynamic armor.

The hollow inserts receive their special function as a direct result of their structure. As a result, all the cavity charges:: end up in a cavity surrounded by metal at the front, which continues ··; the moon forward and which causes a centralized, permeable jet when the charge explodes, and which, as long as the jet is kept centered, is capable of penetrating very thick and hard armor. Indeed, making a hole in the paint, i.e. penetrating the paint, is the primary effect of the cavity charge, followed by a secondary effect, namely that the explosive charge enters the paint with a permeable jet and causes pressure, fire, shrapnel and / or toxicity.

Hollow cartridges are suitable for firing from cannon cannons, compared to simple weapons such as swords, whether they can be used in different types of anti-tank missiles. Thanks to their good performance in the interior of armored * ’* · paints, they have long posed a serious threat to armored vehicles. As a result, there has been a race for many years between the development of new armor and the improvement of hollow inserts.

Different trends have been tried in an attempt to develop an armor that can withstand the attacks of today’s hollow cartridges. The simplest and most obvious method of reinforcing the armor plate is to make it thicker, but it follows that the armored vehicle becomes so heavy that it is tactically unusable. Other tried and tested methods include active and dynamic armor designed to cut off a continuous passing jet, by means of an armor interleaved like a fish bog, or by placing lightly armored cassettes along the outer surface of the armored vehicle, each of which contains an explosive charge which explodes when a penetrating jet hits it, thus reducing the power of said jet. Another variant that provides additional protection against hollow cartridges is: a composite armor consisting of several layers of very hard material such as different types of ceramics. However, the combination pan-Sari is extremely expensive.

The development of an armor plate for armored vehicles thus continues, while the size of weapons piercing the armor is limited by the caliber of their firearm. The latter is a particular problem when it comes to producing more powerful ammunition for older, cannons.

;;; It is an object of the present invention to provide, within predetermined 'caliber limits, a hollow-charge type armor-permeable: *: projectile which has a substantially better permeability to conventional, dynamic and composite armor.

This is possible due to the fact that the tip of the projectile has two complete cavity cartridges which, when the projectile is fired, •: fly as a unit during most of their trajectory, then differ from each other at a predetermined distance from the target, and thus continue their journey at somewhat different speeds along a more or less congruent trajectory, then striking the finish line at such a time that the first charge has time to detonate the protective charge in the active armor, if any, before the next second charge arrives at the finish line so that the piercing jet from said second charge can operate without interference goal in a limited area than the first bet.

3 80785

In order to operate in accordance with the principle outlined above, both said cavity cartridges must have their own ignition system with associated igniters. The detonation of both charges at the required distance from the target can be initiated by all types of delay igniters that operate in a capacitive manner, according to the double shell principle, or by some other type of delay sensor. It is also possible to use an impact igniter equipped with an antenna-type sensor, although this would prove to be a rough solution in this context.

In order to ensure that the two cavities follow each other for most of their flight and then differ, after a predetermined period of time, they must be consecutive and interconnected in such a way that they can be separated by a small separation charge. The hollow inserts can be connected to each other, for example, with a cutting stick, a seam that can be folded open, or a forced fit in which the strength of the material is precisely dimensioned.

If a small separating charge, e.g. a powder charge, is placed between the two hollow charges, this charge causes a change in the speed of said hollow charges. The anterior cavity cartridge gets a little more speed and the posterior cavity slows down a bit.

: In order to meet the above requirements, in view of the fact that: both cavity cartridges must pierce the paint, it is necessary that the separation time of the cavity cartridges be precisely determined in relation to the firing distance. The present invention ensures the separation time by making the ignition of the separation charge dependent on an electronic timer mounted relative to the firing distance.

Time igniters of this type are very reliable and reach completely acceptable values in this context.

Since the various securing devices for both the cavity charge and the separation charge are of the conventional type, they will not be discussed in detail here 4 80785. Generally speaking, setting the electronic time igniter, which determines the moment of separation between the cavity cartridges, is the only action that needs to be taken before each shot.

In practice, it should be sufficient to design a projectile according to the present invention, i. so that said two cartridges are located in succession, but in principle the invention comprises more than two cartridges which work together and reach the target in succession, operating in the same, very limited area.

The present invention is defined by the claims and will be explained in more detail here in connection with one of its preferred embodiments.

Figure 1 of the drawing '' is a longitudinal sectional view of the primary general structure of a projectile according to the invention.

Figure 2 shows the same projectile after its two cavity charges have been separated.

Figure 3 ’shows the relationship between the hit points of the following different inputs:.

The projectile 1 shown in Figure 1 is stabilized with fins and is intended to be fired so that it rotates, with the cannon of an armored car. However, only the stern of the projectile with the outwardly pivoting guide fins 2 and the guide ring 3 for co-operation with the cannon barrel refers to this. The structure of the other parts can be said to be fully standardized, whether it is a projectile projectile, a projectile intended for use in a recoilless cannon or a projectile, or whether it is the front of a missile or other rocket-propelled projectile, except the engine and possible control device.

Thus, the projectile 1 consists of a front cavity cartridge 4 and a rear cavity cartridge 5. The two cartridges are non-permanently connected to each other along the edge 7 by means of insertion pins 6 inserted.

I; 5,80785

Since the projectile according to Fig. 1 has to rotate, it would be convenient if the joint along the edge 7 was made with interlocking teeth and notches in each part, in order to avoid the need to dimension the cutting pins 6 so that they could withstand torsion in the center line of the projectile.

The front cartridge 4 comprises an explosive charge 8 delimited at the front by a metal partition 9, the special shape of which generates a transmission jet when the charge explodes. On the sides, the explosive charge 8 is surrounded by a shell 10 which terminates in front at the tip cone 11, which gives the projectile its aerodynamic shape. The tip cone 11 includes an electronic timer 12. This timer can be set to suit various long firing distances and is connected to an igniter 13 which in turn ignites a separating charge 14 which may be, for example, black powder. Said separating cartridge and its igniter are located in the rear part 15 of the cartridge 4, which also includes the ignition system 16 of the cooling cartridge 8, and the associated securing device and outwardly pivoting fins 17.

· - ·. As long as the cartridges 4 and 5 are connected, the rear part 15 of the first cartridge 4 is inserted into the cavity 18 in which the explosive cartridge 20 of the second cartridge 5 terminates at the front with a metal partition 19. The outer shell of the cartridge 5 terminates at the rear of the above-mentioned fins. system 22 and the associated fuse are also located there.

The structure of the independent ignition systems 16 and 22 is not included in the present invention and will therefore not be discussed in detail here. Said ignition systems can be excited by a double wall principle, a capacitive principle, or some other type of sensor.

The forward charge of the projectile 1 is not shown in Figure 1. Before firing this projectile towards the armored target, the time igniter 12 is set according to the firing distance. The projectile is in the state of Figure 1 as it exits the tube, and travels almost its entire trajectory in this same state. By setting the timer 6 80785 12 at a distance from the extreme, e.g. 200 m, the timer 12 activates the igniter 13, which in turn ignites the separator cartridge 14. The gases formed when the separator cartridge burns increase the pressure in the cavity 16 until the sticks 6 break and the cartridges 4 and 5 differ. Exactly at this time, the speed of the front cartridge 4 accelerates slightly and the speed of the rear cartridge 5 slows down slightly. However, they do not deviate from their direction to the finish.

Once the separation has taken place, the - - state shown in Fig. 2 is reached. From the cartridge 4, which now advances towards the target at a slightly higher speed than the device before separation, the fins 17 are now turned out to stabilize the rest of its flight, while the cartridge 5, which continues its journey at a slightly slower speed, is independently stabilized.

• The setting of the time igniter 12 is critical in that the separation of the cartridges 4 and 5 must take place so early that the cartridge 4 has time to detonate the protective cartridges in the active armor, if any, before the cartridge 5 reaches the target. Since the velocities of the charges 4 and 5 are slightly different at the rest of the runway, minor changes take place at this end of the runway, which requires that the explosion must not occur too early. Figure 3 addresses this problem. It can be seen from Figure 3 that it can be calculated that the cartridge 4 hits point 24, which is slightly. . ·. above target 23, while cartridge 5 hits point 25, ____: which is slightly below said target. However, theoretical calculations have shown that if all known significant variables are considered in this context, variations greater than a few centimeters are not expected even at the longest firing distances. These slight variations still allow the penetration jet of charge 5 to take advantage of the hole made by the penetration jet of charge 4.

It can be seen from Figure 1 that the start-up cartridges 8 and 20 are slightly different in shape. This is due to the previously mentioned possibility to optimize the stakes so that they have a slightly different effect on the finish.

Il 7 80785 As a result, the hollow cartridge portions of both charges can be shaped so that both are jet-forming or projectile-forming. Alternatively, they may be shaped so that one cartridge (main cartridge) forms a jet, while the other cartridge (guide cartridge) forms a projectile or a combination of projectile and jet.

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Claims (3)

An armor-breaking projectile (1) comprising at least two successively arranged RSV loads (4, 5) interconnected with their own fuse and ignition functions (16, 22) and a split charge (14) with its own ignition function (13) for separation of the RSV charges from each other while the project line is in a path towards the meter, characterized in that the partition charge (14) and its ignition function (13) are designed so that the partition charge (14), regardless of the shot width of the meter, is always triggered at a pre-adjustable distance. from the meter and thereby the front RSV charge gives a smaller plus velocity and the rear a smaller minus speed without affecting the direction of the two RSV charges (4, 5) to the meter. Armor-breaking projectile according to claim 1, characterized in that the ignition function (13) of the partial charge (14) is adjustable with respect to the flight time of the projectile towards the target and is an electronic timing tube (12). Armor-breaking projectile according to claim 1 or 2, characterized in that the partial charge (14) consists of a gun charge arranged in the hollow which is made up of the metal for the rear of the two RSV charges (5) required for the rear (18) while the solvable connection between the two RSV projections (4, 5) is one or more shear readings (6) which fail when the pressure in the hollow from the combustion gases formed during the combustion charge is too high.