SE512080C2 - Improving effect of multiple charge armour piercing (RSV) munition upon or after armour penetration - Google Patents

Abstract

Two explosion jets (18, 19) are generated by two different explosive charges (11, 12) and are made to collide with each other as the munition penetrates the armour. An Independent claim is also included for the multiple charge armour-piercing munition (10).

Description

When the last formed RSV beam collides during or after passage of the cover with beam parts from the first formed beam, such as slugs, tail fragments or other parts at a lower speed than the tip of the last formed RSV beam, the material is dispersed from the two rays. The dispersed material has an increased effect according to one or more of the following principles.

- Generation of a radial scattering of splinters from colliding fragments, which increases the conventional splintering effect inside a protected space, both by increasing the number of splinters and by splitting them out in other directions than normal, ie from inside the shield .

- If the collision is allowed to take place inside the (armor) protection, the conventional hole diameter is significantly increased due to the radial force component caused by the collision. This results in an increased amount of secondary splinters and thereby a better effect. This phenomenon is particularly accentuated if the collision occurs near the inside of the cover, ie at the end of the penetration process. The conventional effect in the form of splinters increases if the hole diameter increases. i - Combustion, alloying and other exothermic reactions are enhanced by various mechanisms. The spread of material provides better oxygen supply and larger reaction surfaces. Furthermore, the supply of energy that occurs during the collision may be sufficient to initiate reactions.

The reactions have an effect inside the fired spaces in the form of an increase in temperature, pressure, hot splinters and smoke, etc.

There are several possibilities for causing two RSV beams to collide during or after penetration of the cover.

According to an advantageous embodiment, a control device is arranged to initiate the second RSV charge in dependence on the initiation of the first RSV charge to cause the RSV beams of the RSV charges to collide.

According to another advantageous embodiment, the geometric distances between incoming RSV charges are dimensioned so that the faster part of the second beam reaches the slower part of the first beam during or after penetration of the cover. According to other advantageous embodiments, the RSV charges have different geometric shapes and / or different explosive technical properties through the use of different explosive sleeves, initiation principles and the like.

Examples follow below of parameters that can be changed to change properties of an RSV charge, including mass / velocity of RSV jet and slug: - RSV cone (liner) angle, - RSV cone material thickness, - RSV cone density, - Use of explosives with different detonation pressures, - Larger or smaller amount of explosive in the charge and the distribution of the explosive in relation to parts of the cone / linem and the point of initiation - the choice of density and to some extent thickness of the charge, - initiation principle (center initiation / peripheral) Preferably, the included charges are of the beam-forming type or projectile-forming type.

The ignition order of the RSV charges can either be that the front of two RSV charges is ignited first or that the rear one is ignited first. In the latter case, according to one embodiment, the beam of the front RSV charge can also be stored in a more or less empty section area in the beam of the rear RSV charge. In this latter embodiment, parts other than the tip and tail of the RSV charges can be made to initially participate in the collision between two beams.

The invention will be described in more detail below with reference to the accompanying drawings, where Figure 1 schematically shows the activation of a tandem type multi-RSV charge at five times for illustration of the collision process and Figure 2 schematically shows a multi-RSV charge with control device. The multi-RSV charge 10 shown in Figure 1 comprises a first and a second RSV charge 11 and 12, respectively. The first RSV charge 11 comprises an explosive kit 13 with an associated liner 14 and the second RSV charge 12 comprises an explosive kit 15 with liner 16. The center axes of the RSV charges coincide in a common center line 17. Some detonators are not shown but are assumed to be included according to some conventional solution.

Both RSV charges can be of the projectile-forming type (RSV IV) or of the beam-forming type (RSV III). It is also possible that one RSV charge is of the projectile-forming type and the other of the beam-forming type.

The activation process is now described below.

At time T1, the multi-RSV charge is on its way to its target, but none of the multi-RSV charge RSV charges 11, 12 have yet been ignited.

At time T2, the front charge 11 detonates. An RSV beam 18 is generated. At time T3, the beam 18 has moved a bit forward in the path.

At time T4, the rear charge 12 lights up and an RSV beam 19 is generated. The charges follow essentially the same path towards the target.

At time TS, the RSV beam 19 of the rear charge has caught up with the front RSV beam 18 and a collision occurs between the faster parts of the rear RSV beam and the rear parts of the front RSV beam, such as slug, tail and other slow moving parts. The RSV beams 18, 19 penetrate or have at this time T5 penetrated a protection (not shown), for example the armor protection on a tank. Arrows 20 indicate that large radial forces are occurring.

A process has been described above in which the front RSV charge is ignited before the rear one. In the event that instead the rear RSV charge is ignited first, care must be taken that in some known manner the rear first ignited charge is allowed to pass in whole or in part through the front charge. This is not part of the invention and is therefore not described in more detail. For examples of such charges, see SE B 8205973-4.

The multi-RSV charge shown in Figure 2 is constructed in the same way as the multi-RSV charge shown in Figure 1, except that a control device 21 is inserted between the two RSV charges.

The control device 21 delays the generation of the last generated by two RSV beams to such an extent that the tip of the later generated RSV beam catches up with the slower parts of the first generated RSV beam in connection with penetration of the cover.

The delay between the ignition of two RSV charges can be achieved in many different ways. Determining are, among other things, geometric and other conditions in the charges and the distance from the charges to a predetermined collision point or a predetermined collision area in the vicinity of which a target to be fought is located.

An example of causing delay is described in the above-mentioned SE B 8205973-4. In this case, the delay of the time it takes for the slug of the relatively large diameter RSV beam to be moved to a predetermined position is determined to initiate the front charge in this case. Other examples of prior art are to utilize the delay that occurs when a shock wave is allowed to travel a certain predetermined distance in the grenade structure or to introduce electronic delay circuits that prevent / delay an initiation of charge two. Such delays can also be provided by pyrotechnic or explosive elements or mechanical devices. Combinations of the above delay modes can also be used.

The invention is not limited to the embodiments described above, but within the scope of the appended claims there are a number of alternative embodiments. Thus, the Multi-RSV charge may include more than two RSV charges. The RSV charges can be ignited in reverse order, ie a rear charge before a front one, etc. Furthermore, the RSV charges can have different calibers, different geometries in general and contain different materials.

Claims (14)

512 080 Patent claims Method of multi-RSV charge (10) for producing increased effect during or after penetration of protection, characterized in that a first RSV beam (18) from a first RSV charge (11) and a second RSV beam (19) from a second RSV charge (12) is caused to collide in connection with penetration of the cover. Method according to one of the preceding claims, characterized in that the geometric distances between incoming RSV charges (11, 12) are dimensioned so that the faster part of the second beam (19) reaches the slower part of the first beam (18). ) in connection with the penetration of the protection. Method according to one of the preceding claims, characterized in that the included RSV charges (11, 12) are given different geometric shapes in order for the faster part of the second beam to reach the slower part of the first beam in connection with penetration of the protection. Method according to one of the preceding claims, characterized in that the included RSV charges (11, 12) are given different explosive properties by using different explosives, initiation principles, etc. in order for the faster part of the second beam to reach the slower part. of the first beam in connection with penetration of the cover. Method according to one of the preceding claims, characterized in that the delay of the activation of the second RSV charge (12) relative to the first RSV charge (13) is controlled so that the faster part of the second beam reaches the slower one. part of the first beam in connection with penetration of the cover. Method according to one of the preceding claims, characterized in that the rear (12) of two RSV charges is ignited before the front (1 1). 512 080 7 Method according to Claim 6, characterized in that the jet (18) of the front RSV charge is stored in a more or less empty section area in the jet (19) of the rear RSV charge. Method according to one of Claims 1 to 5, characterized in that the front (11) of two RSV charges is ignited before the rear (12). A multi-RSV charge (10), comprising at least a first and a second RSV charge (11, 12) arranged to act in substantially the same direction against a penetration protection thereof, the RSV charges comprising an explosive charge (13 and 15) with liner (14 and 16, respectively), and which multi-RSV charge comprises means for detonating the RSV charges, wherein from each charge upon detonation of an RSV charge an RSV beam (18, 19) is formed for action. against the cover, characterized in that the multi-RSV charge (10) comprises means (21) for causing the RSV beams from at least the first and second RSV charges (1 1, 12) to collide in connection with penetration of the cover. Multi-RSV charge according to claim 9, characterized in that the geometric distances between incoming RSV charges (11, 12) are dimensioned such that the faster part of the second beam (19) reaches the slower part of the first beam. (18) during or after penetration of the protection. Multi-RSV charge according to one of Claims 9 to 10, characterized in that the RSV charges (11, 12) have different geometric shapes in order to cause the RSV rays (18, 19) of the RSV charges to collide. Multi-RSV charge according to one of Claims 9 to 11, characterized in that the included RSV charges (11, 12) have different explosive technical properties for causing the RSV beams (18, 19) of the RSV charges to collide. Multi-RSV charge according to any one of claims 9-12, characterized by a control device (21) arranged to initiate the second RSV charge (12) in dependence on the initiation of the first RSV- u, a, svza; ¿I. in charge of the charge (11) to cause the RSV beams (18, 19) of the RSV charges to collide. Multi-RSV charge according to one of Claims 9 to 13, characterized in that the input RSV charges (11, 12) are of the beam-forming type or projectile-forming type. 1995-1 i-zzfFgc