DE2804630C1 - Hollow charge resistant secondary armour for armoured fighting vehicle - Google Patents

Abstract

The armoured fighting vehicle secondary armour has cells (4,5) filled with a friable porous material with a density of least one gram per cubic centimetre. The cells are positioned between two armour panels. The infill material can be foamed glass or furnace slag.

Description

The invention relates to an armor element according to the preamble of claim 1.

Armored vehicles have been used to protect vehicles for ages Steel plates made of high-strength, tough steel (armored steel) used under the greatest possible inclination to Weft direction are attached, because that the The steel thickness to be penetrated increases and that Difficulty penetrating the bullet tip into the armor becomes.  

Modern armor mostly consists of several, parallel to each other the steel plates arranged at an angle to the shot direction (Bulkhead construction) with an air gap. Some of them individual steel plates (carrier plates) with bulkhead armor thin sheets (buckling plates) that are covered by the through impact generated detached and be transverse to the shot direction be accelerated. Also known is explosives in the Armor to accelerate the steel plates to reach diagonally to the direction of fire (active armor).

Furthermore, it is known to armor glass, ceramic or Rock slabs, possibly in combination with steel or Light metal plates to use. The mineral materials show a crater together when a hollow charge beam breaks through membrane; collapsed after the initial formation of the crater the wall material and thereby disturbs or destroys subsequent ones Hollow charge particles.

All these known arrangements have in common that the protective effect against shaped charge is brought about by the use of solid, specifically heavy materials with densities above 2 g / cm ³ . Bulkhead armor, armor with buckling plates and with active, explosive-accelerated plates only have an increased protective effect with oblique shot, whereas with vertical bombardment only the protective effect of an approximately equally heavy, solid plate made of the same materials is given.

It was already in the armor element of the beginning suggested type, closed on all sides, with a liquid or filled with a viscous mass Hollow body in tight packing between the armor plates to add the protective effect against shaped charges increase.

The invention is based on the task, the schil overcome disadvantages of known arrangements and a Armor element of the aforementioned type to create the comparatively low weight an increased protection against vertical and oblique shaped charges.

It turned out that this task with the in the characterizing part of claim 1 paint an armor element in surprisingly simple, technically advanced way can be solved. Some special, advantageous embodiments of the invention refer to claims 2 to 4.

The armor element according to the invention is distinguished above all from an element with the same protective effect by its comparatively low weight, namely due to the use of specifically light materials with densities less than 1 g / cm ³ as filler material; e.g. B. has perlite, an expanded natural glass granulate with a bulk density of only 0.13 g / cm ³ . Nevertheless, as explained in more detail below, increased protection against shaped charges is achieved even in comparison to much heavier armor elements.

Further advantages and possible uses of the Invention go further from the following description Details as well as from the attached pictures.  

Show it:

Fig. 1 in a perspective view, a simplified schematic representation one embodiment of the invention armor element with a raised armor plate,

Fig. 2 is a perspective view of another embodiment of the invention and

Fig. 3 in the diagram comparative experiments on pearlite columns to demonstrate the effect used according to the invention.

According to the embodiment according to FIG. 1, the armor element according to the invention consists of two parallel armor plates 1 , 2 , between which a honeycomb structure 3 of z. B. 2-5 mm thick steel sheet is inserted. The upper armor plate 2 is shown raised to increase clarity. After filling the chambers 4 formed by the structure 3 with a brittle, porous material of low specific weight, for. B. with pearlite, the armor plate 2 is firmly attached and welded to the structure 3 .

In the embodiment of the invention according to FIG. 2, the chambers 5 that are essential to the invention for the insulated introduction of the described, light material by perpendicular to each other in orderly, at the connection points firmly connected webs 6 forms ge.

The design and cross-section of the chambers 4 , 5 is variable within wide limits, so that a shape that is particularly easy to manufacture can be selected. It is only important that the chambers 4 , 5 are not too large, so that the walls condense the filling material to a sufficient extent.

In an experiment to detect the effect of insulated mineral materials, as used according to the invention, the mineral was arranged and insulated between two 10 mm thick armor plates 1 , 2 ; the filler was perlite. The arrangement was bombarded with a shaped charge. With this arrangement, the shaped charge penetrated only about 145 mm behind the steel arranged according to the armor element designed according to the invention. In contrast, the same load penetrated in the same experimental setup - but without filling with perlite - 205 mm steel. The pearlite fill reduced the penetration of the shaped charge in this example by 60 mm steel, that is by around 30%, and even with vertical bombardment of the armor, in which most modern armor elements show no increased protective effect.

The test results are clearly shown in FIG. 3:

Hollow charges with a 60 ° copper Insert cone with a diameter of 40 mm and a wall thickness of 1 mm. The shaped charge jet was axially in on both sides closed with a steel disc (St 50, 10 mm thick) Pipes directed. The length of the cylinders or pipes was 140 mm, their diameter was 60 mm. The  Pipes were placed vertically on deep-drawn sheet metal stacking plates poses. At a distance of 2 calibers from the upper steel plate then the shaped charge ignited. The total breakthrough (cylinder cover + residual breakthrough in the stack) was measured, whereby the inlay caliber of the shaped charge of 40 mm ver was applied.

In comparative experiment 1 - firing distance 6 calibers, without the insertion of an armor element - the total penetration was 5.56 calibers, after inserting the empty steel cylinder (the firing range was 2-5 for each experiment, 2 calibers from the upper steel plate), the total penetration was as still stated 4.75 caliber. The surprising effect of the measure according to the invention, namely the use of insulated, brittle, porous, low-weight material between two armor plates was confirmed by tests 3 and 4, in which in the former case the tube wall was made of steel and in test 4 it was made of comparatively weak light metal. Inadequate insulation of the filling material leads to a considerable reduction in the protective effect, as experiment 5 shows, in which the tube wall consisted of a thin cardboard.

The test series according to FIG. 3 thus helps to understand the effect which is achieved by the measures according to the invention and illustrates which structural features are to be observed.

Brittle, porous materials with a low bulk density, preferably highly porous, mineral substances are suitable as filling material. A high hardness of the material should have a favorable effect. Materials with closed pores, such as perlite, which are expanded natural glass granules with a bulk density of about 0.1 g / cm ³ are advantageous. Due to the implosion of these vacuum glass pores during the impact passage, the energy stored in the internal tensions of the material is released and converted into kinetic energy of the mineral powder.

Another advantage of the armor elements according to the invention is the shock absorbing property due to the filled porous Materials. When using active armor with explosive accelerated armor plates is a problem in the Reduk tion of the strong impact of the active plates on the armor on End of the flight path of the plates. When using the fiction according to knowledge, d. H. when filling porous materials into the cavities of active armor elements and damaging the Filling material, would also have to increase the protective effect, especially against vertical fire, and also a reduction the shock load of the armored vehicle.

In another construction, the gaps were a 5-plate Targeted from armored steel plates filled with pearlite. The goal building consisted of a 13 mm thick steel plate the two outer sides of the armor element and from three 7 mm thick armor plates in the middle. The clear distance between the plates  was 24 mm each. When firing at an angle of The penetration rate of the shaped charge also became 60 ° NATO here reduced by 15% by filling the multi-plate target with pearlite.

Essential for the increased protective effect of the brittle, porous material of low specific weight, which is used according to the present invention, is the all-round inclusion of the material by the inserted from the walls of the structure (honeycomb structure 3 in Fig. 1 and webs 6 in Fig. 2nd ) and chambers formed by the adjacent armor plates 1 , 2 . This allows the filled material to flow back onto the penetrating shaped charge. This favors irregular tearing of the shaped charge jet into particles that are not completely symmetrical and are easy to disrupt.

The boundary walls of the chambers perpendicular to the armor plates 1 , 2 can be relatively thin. Sheet thicknesses of approximately 2 to 8 mm are sufficient.

Claims (4)

1. Armor element, in particular for protection against Hohlla dung, consisting of two or more, spaced armor plates, between which chambers are provided which enclose a mineral material, characterized in that the chambers ( 4 , 5 ) with a brittle , porous material with a density of less than 1 g / cm ^{3 are} filled. 2. armor element according to claim 1, characterized in that foamed mineral material, such as pearlite, foam glass, blast furnace slag or the like is used. 3. armor element according to claim 1 or 2, characterized indicates that the material is closed-pore. 4. armor element according to one of claims 1 to 3, characterized in that the chamber diameter is vertical for the direction of penetration in the order of magnitude of the shaped charge Caliber, d. H. about between 0.5-5 times the caliber the shaped charge against which protection is to be obtained.