This subject matter relates to ballistic armor and, particularly, to such armor, which is adapted for use as an exterior armor for military vehicles
There is known ballistic armor of a kind having a basic, main armor and an additional, auxiliary armor panel in the form of a perforated or slit plate, normally made of steel or other ballistic material, installed at a stand-off distance from the main armor, designed to effectively break an incoming projectile or at least to divert it from its incident trajectory and thus substantially reduce its residual penetration capability through the basic armor.
Examples of armor using at least partially perforated plates are disclosed in U.S. Pat. Nos. 5,014,593, 5,221,807, EP 1,128,154, US2006/0213360 and US2005/0257677.
There are also known armor plates having a layer of cylindrical ceramic pellets with voids therebetween, and IL 115397 discloses the use of one such plate in a multilayer armor panel.
U.S. Pat. No. 6,408,734 discloses the use of an armor plate of the kind disclosed in IL 115397, and suggests filling replacing some of the pellets with elements having protrusions entering voids between adjacent pellets, these elements being made of the same ceramic material as the pellets.
U.S. Pat. No. 6,575,075 discloses an armor plate similar to that disclosed in IL 115397 made a layer of ceramic pellets, each having a channel oriented perpendicularly to the plate's front surface, to reduce the weight of the armor plate.
In accordance with one aspect of the present subject matter, there is provided an armor plate for use in the ballistic protection of a structure against projectiles incoming from an expected threat direction. The plate has an outer face facing the threat direction and comprises a layer of first pellets made of ballistic material of a high density S1 and of a characteristic diameter DP, and second pellets which have a low density section with a central axis transverse to the outer face of the plate. The low density section at least partially extends along the central axis and has a density S2 which is in the range 0≦S2<<S1. The second pellets have an outer characteristic diameter DOUT substantially equal to the diameter Dp and the low density section has an inner characteristic diameter DIN, DIN<DOUT. Each second pellet is surrounded only by the first pellets.
In the present application, the term ‘characteristic diameter’ of a pellet or its part refers to a cross-section of the pellet taken perpendicular to its central axis, and means
The term “ballistic material” means a hard material capable of resistance to penetration by a projectile.
The low density section in each of the second pellets may be formed at any location thereof, and it may for example be in the form of hole or channel in the second pellet. In the latter case, the second pellets may have hollow bodies, with a hole at least partially extending along its central axis. In particular, the hole may be a through going hole. In this case, the density of the low density region will be zero.
The plate is intended for use in the ballistic protection of a structure at least against projectiles having a caliber DC, and the characteristic diameter DIN may be about DC, particularly not greater than DC, and still more particularly, smaller than DC.
The first and second pellets may be of any shape that allows the pellets to be closely packed in the ballistic. In particular, the second pellets may have the same external shape as the first pellets, which shape may for example be cylindrical or hexagonal, allowing closest packaging of the pellets.
The second pellets may have a length/height smaller or equal to that of the first pellets.
The first pellets comprise a front and a rear end, and one or each of these ends may for example be convexly curved or planar.
The central axis of the low density section may be perpendicular to the outer face of the plate or inclined with respect thereto.
The first and second pellets in the layer preferably have a regular arrangement of parallel rows. At least a part of these rows are combined rows each comprising the first and the second pellets. Each of the combined rows may have adjacent thereto at least one uniform row comprising only the first pellets.
The plate may comprise a binder matrix enveloping the first and second pellets and holding them in the desired arrangement.
The first pellets may be made of any appropriate ballistic material such as for example ceramics, and the second pellets may be made of ballistic material of a lower density than that of the first pellets, e.g. of a metal such as ballistic aluminum alloy or the like, or of non-ballistic material, for example non-ballistic metal or plastic. In this context, the term “non-ballistic material” means a material uncapable of resistance to penetration by a projectile.
The weight of each second pellet preferably does not exceed, and in particular is lower than, that of each first pellet. The weight difference between the first and second pellets may be due to any one of the following features of the pellets or a combination of any of them:
In consequence with the above weight difference between the first and second pellets, the weight of the plate of the present subject matter is essentially lower that that of a conventional perforated plate which is not made of pellets but is rather in the form of a solid, metal, plate, e.g. made of steel, having the same thickness and the same arrangement and geometry of holes, and the difference in the weights of the former and the latter plates may be up to 50%, more particularly up to 40%, and still more particularly up to 35%. The weight of the plate is of a great importance since it is meant to be carried by a vehicle and, therefore, a plate having a lower weight is preferred to a plate of greater weight which provides the same ballistic protection.
In accordance with another aspect of the present subject matter, there is provided an armor system for the ballistic protection of a structure against projectiles incoming from an expected threat direction. The armor system includes a basic, main armor layer and an additional, auxiliary armor layer in the form of an armor plate as described above, mounted in front of the main armor layer, in the threat direction, at a stand-off distance therefrom. Main armor plate in this context is an armor plate mounted closest to the structure to be protected or resident therein. A wall of the structure may be also a main armor plate or part thereof.
In accordance with another aspect of the present subject matter, there is provided a vehicle having at least one region that comprises a plate described above. The region may be in a side wall and/or track of the vehicle and may be free of any other armor.
In order to understand the subject matter and to see how it may be carried out in practice, embodiments will now be described, by way of non-limiting examples only, with reference to the accompanying drawings, in which:
The plate 10 comprises a layer 11 of first, solid pellets 12 and second, hollow pellets 22, wrapped by a wrapping material 13. The plate 10 has an inner face 16, an outer face 18, and it will further be described with reference to an axis A extending along the thickness of the plate between its inner and the outer faces 16 and 18, respectively.
The pellets 12 are made of a high density ballistic armor material, e.g., ceramic, such as for example alumina, silicon carbide, silicone nitride, boron carbide or the like. With reference to
The hollow pellets 22 may be made of a material having a lower density such as aluminum alloy, titanium alloy, other metal alloy or strong plastic material. Each hollow pellet 22 has a body 24 of an outer diameter DOUT and a length L2, a central axis A2 and a through hole 26 extending along the axis A2, of an inner diameter DIN. The outer diameter DOUT is substantially equal to the diameter DP of the pellets 12, and the inner diameter DIN satisfies the condition DIN<DC, where DC is the caliber of those of the projectiles against which the plate 10 is to be effective (as will be explained in more detail below). The thickness T of the hollow pellets 22, which equals the difference between their outer and inner diameters, may be of such that the hollow pellets may be considered thin-walled cylinders. For example, T may be in the range of 0.45-0.55 mm, and more particularly 0.49-0.51 mm. The length L2 of the hollow pellets substantially satisfies the condition L2≦L1.
When arranged in the layer 11 within the wrapping 13, as shown in
In the present example, the solid pellets 12, the hollow pellets 22, and the through holes 26 in the solid pellets 22 are all cylindrical, i.e. have all circular shape in their central cross-section, which is a cross-section taken perpendicular to their central axes. However, the solid and hollow pellets and the through holes in the hollow pellets may have any other appropriate shapes, the same or different, in which case the diameters indicated above will be their characteristic diameters, i.e. the diameters of imaginary circles inscribed therein in their central cross-sections (not shown).
The layer 11 of the solid pellets 12 and the hollow pellets 22 has a regular arrangement of the pellets in N parallel rows R. In the example shown in
Each of the hollow pellets 22 in the rows R2 to RN-1 is surrounded by solid pellets 12 only. In the present example, where the arrangement of the pellets is hexagonal, each hollow pellet 22 has six solid pellets 12 therearound. However, if the arrangement of the pellets was, for example, square (not shown), each hollow pellet would be surrounded by four solid pellets.
The plate 10 described above has a weight W, which substantially satisfies the condition: W≦0.67 WR, where WR is a weight of a reference plate (not shown) in which all the hollow pellets 22 are replaced with the solid pellets 12. In the present example the above ratio yields a weight difference of about 6.8 kg/m2 between the plate 10 and the reference plate. When comparing the plate 10 to a conventional perforated plate made of steel, e.g. a standard steel perforated plate of a thickness about 8 mm and a weight of about 37 kg/m2, having the same or similar arrangement and geometry of holes as that of the plate 10, the weight reduction may be up to 50%.
The number of solid pellets disposed between each adjacent hollow pellets in the armor plate 10 and their arrangement in the rows may differ. Two examples of such alternative designs of the plate 10 are shown in
The hollow pellets 22 in the plate 10′ are spaced from one another along the combined rows RC by one solid pellet 12. In addition, all the combined rows RC are similarly arranged, i.e. the locations of the hollow pellets 22 is similar in all the combined rows RC.
Similarly to the plate 10, each of the hollow pellets 22 in the plate 10′ is surrounded by the solid pellets 12. The weight W′ of the plate 10′ substantially satisfies the condition: W′=WR≦0.75 W, where WR is the weight of the reference plate mentioned above. In the present example the above ratio yields a weight difference of about 5 kg/m2 between the plate 10′ and the reference plate.
The plate 10 according to any design described above further comprises a binder matrix 26 (
The plate 10 may be produced by a process disclosed in US 2007/003407 to the Applicant, the description of which is incorporated herein by reference, with the differences being mainly that, during the arrangement of the solid pellets 12 in a cavity of a mold, within the wrapping material 13 covering the cavity's walls, the hollow pellets 22 are inserted between the solid pellets 12, instead of the pellets 12, according to the arrangement described above; and in that the plate 10 does not have any additional layers (except for the wrapping) such as a backing layer.
As shown in
In particular, in this assembly 28, the plate 10 constitutes an auxiliary plate 30, which is located in front of the main armor plate 31 being spaced therefrom to a predetermined stand-off distance X, so that the outer face 18 of the plate 30 faces the expected threat direction O. The armor assembly 28 may be attached to the structure B by bolts 34 which may be the same bolts that hold the auxiliary plate 30 at the distance X from the main plate 31.
The auxiliary plate 30 is designed to deflect and shatter or at least to destabilize the projectiles P impacting thereon having a range of calibers. If the main armor 31 is designed so that it cannot stop alone or together with the structure B, any of the projectiles P, the inner diameter DIN of the hollow pellets 22 should satisfy the condition DIN<DS, where Ds is the smallest caliber in the range. However, if the main armor plate alone or together with the structure B, can stop the projectiles of the minimal caliber DM, the hollow elements 22 may have their holes' inner diameter DIN greater than DM but less than DG, where DG is a caliber greater than the smallest caliber in the range.
The armor plate 10 may also be used without the main plate described above, and this particularly concerns areas in armored vehicles, such as a track, where there is no space available for the incorporation of the main armor.
Those skilled in the art to which this subject matter pertains will readily appreciate that numerous changes, variations, and modifications can be made without departing from the scope of the subject matter, mutatis mutandis
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