SPECIFICATION

This invention relates to transparent ceramic armor designed to provide light weight ballistic protection primarily for aircraft against armor piercing projectiles.

Presently available transparent armors are inefficient in providing ballistic protection due to their inability to induce severe projectile shatter and their tendency to crack on impact.

It is the object of this invention to obtain adequate protection by shattering small arms projectiles with a light weight composite armor having a hard transparent ceramic face plate bonded by a transparent adhesive to a tough resilient transparent plastic back-up plate.

It is also the object of this invention to utilize this shattering of the projectile by the face plate which spreads the impact force per unit area to reduce the requirements of the back-up plate, in that the excess energy per unit area to be absorbed by the back-up plate is proportionately lessened.

This particular transparent armor has been designed and tested to afford complete protection against caliber 0.30 AP M2 projectiles with a muzzle velocity of 2770 f.p.s., but obviously could be engineered for other and larger projectiles.

A composite material that will meet these requirements was constructed with commercially available materials using as the material for the face plate, transparent magnesium oxide or aluminum oxide with a back-up plate of a transparent plastic a polycarbonate resin such as "Lexan" and the two plates were bonded together with a transparent adhesive. Other types of transparent plastic backing materials such as glass, plexiglass, fiberglass, lucite etc., can be used in either a monophasic or multiphasic form.

The drawing illustrates the composition and dimensions of the transparent armor plates actually tested, together with the protection afforded by recording the ballistic limit of each, in which:

FIG. 1 is a composite of transparent armor 10, in which the face plate 11 is transparent magnesium oxide, 0.50" thick, bonded with a transparent adhesive (not shown) to a back-up plate 12 of transparent plastic "Lexan", 0.75" thick, has an area density of 14 pounds per square foot and provides a ballistic limit of 3220 f.p.s. for protection;

FIG. 2 is a composite of transparent armor 13 in which the transparent face plate 14 is aluminum oxide, 0.250" thick, bonded with a transparent adhesive to a back-up plate of transparent "Lexan" 1.00" thick, has an area density of 11.4 pounds per square foot and provides a ballistic limit of 2435 f.p.s. which is not satisfactory for protection against a projectile with a muzzle velocity of 2770 f.p.s. This deficiency may be corrected by increasing slightly the thickness of the face plate, such as 0.10";

FIG. 3 is a composite of transparent armor 16 in which the transparent face plate is made up of two transparent plates 17 and 18 of aluminum oxide each 0.250" thick with a transparent back-up plate 19 of "Lexan" 1.00" thick, all plates being bonded together with a transparent adhesive (not shown) and having an area density of 16.4 pounds per square foot which has a ballistic limit of 3820 f.p.s. for protection.

The composite armor of this invention is designed to meet the requirements of ballistic protection with light weight ceramic material that is completely transparent and has an improved capability of protection as compared to standard steel armor of equal areal density.

This comparison is shown in the following table in which competent ballistic protection is provided against caliber 0.30 AP M2 projectiles with a muzzle velocity of 2770 feet per second:

Areal Density

30 pounds per square foot for Laminated Glass

20 pounds per square foot for High Hardness Steel

10 pounds per square foot for Opaque Ceramic Composites

14-16.4 pounds per square foot for Translucent Ceramic and Plastic Back-up

14-16.4 pounds per square foot for Transparent Ceramic and Plastic Back-up

Areal density is a term used particularly in armor evaluation. Also where the same materials are translucent and are employed in the composite armor, it should be noted that due to the elastic constant and the accoustical velocity determinations that the results sought are practically identical with that of the transparent plates.