1. The Field of the Invention
The present invention relates to armor plates and articles of manufacture incorporating the armor plates.
2. The Relevant Technology
Armor is a material or system of materials designed to protect from ballistic threats. Transparent armor, in addition to providing protection from the ballistic threat is also designed to be optically transparent, which allows a person to see through the armor and/or to allow light to illuminate the area behind the armor.
In the general field of ballistic armors, existing armor systems are typically comprised of many layers of projectile resistant material separated by polymer interlayers, which bond the projectile resistant materials. In a typical armor laminate the strike surface is a hard layer of projectile resistant material that is designed to break up or deform projectiles upon impact. The interlayer materials are used to mitigate the stresses from thermal expansion mismatches as well as to stop crack propagation into the polymers.
For most armor plates, efforts are usually made to make the armor plate light weight. This is particularly true of transparent armor plates, which are often used for protective visors and goggles. Currently existing military specification for protective visors and goggles requires that the lens should be able to stop 0.22-caliber 17 grain FSP projectile at 550-feet per second (fps). For comparison, most handguns give more than 1000 fps bullet velocity and rifles up to 3000 fps. To stop bullets from handguns one needs an inch thick polycarbonate plate and around two inches thickness for a rifle bullet.
The present invention relates to a composite armor plate and articles of manufacture incorporating the armor plate. The composite armor plate typically uses at least four layers of material that are configured to create a compression wave from the impact of a projectile and absorb the compression wave by fracturing one of the layers. The four-layer system of the invention can be made comparatively lighter, stronger, and/or thinner than armor materials using conventional laminates. In one embodiment, the armor plate can be transparent. Transparent armor plates can be incorporated into windows, helmets, goggles, and similar devices where transparency and/or translucency are desired. In other embodiments, the armor plate can include one or more layers that are opaque.
The four-layer system of the present invention can achieve a lighter, thinner armor by placing a deformable layer on the front side of a ballistic-resistant ceramic layer. The ceramic layer is in turn backed by a fracture layer and a spall liner. Upon ballistic impact, the deformable layer creates a compression wave that spreads out through the ceramic layer and is absorbed by the fracture layer. The spall liner backing the fracture layer catches the fracture layer as it disintegrates from the impact. The use of a deformable layer in front of the strong ceramic layer allows an intensive compression wave with a large surface area to be generated. When the large surface area compression wave strikes the fracture layer, the larger surface area results in comparatively better disintegration of the fracture layer, thereby absorbing a comparatively larger amount of energy. Depending on the plate geometry, projectile size and speed, orders of-magnitude increase in energy absorption can be achieved using a deformable layer and a fracture layer with a ceramic layer in between.
Armor plate 100 has a strike surface 117 upon which a bullet 118 or any other type of projectile impinges. Armor plate 100 also includes a back surface 119 opposite the strike surface 117. Strike surface 117 is configured to receive the initial impact of bullet 118 and back surface 119 is configured to be the surface closest to the object for which the armor plate provides protection. For example, where armor plate 100 is used as a window in an armored vehicle, strike surface 117 is positioned outside the vehicle and back surface 119 communicates with the interior of the vehicle.
In one embodiment, the deformable layer 110 has a first side 120 configured to be strike surface 117 upon which bullet 118 impinges. Deformable layer 110 is configured to generate a compression wave from the impact of bullet 118. In one embodiment the deformable layer 110 comprises a material having an elongation before failure of at least 20%. Materials having an elongation before failure of at least 20% typically generate an intense compression wave upon ballistic impact. In a more preferred embodiment, the deformable layer may include a material having an elongation before failure of at least about 50%, even more preferably about 100% or more. Examples of suitable transparent materials that can be used for the deformable layer 110 include, but are not limited to, polycarbonate, polyurethanes, elastic acrylic polymers, and combinations of these. Examples of nontransparent deformable materials that can be used include aluminum, titanium, and combinations of these.
Deformable layer 110 also has a backside 122 that opposes first side 120. Backside 122 is adjacent ceramic layer 112. As will be discussed below in greater detail, backside 122 may be adhered to or otherwise bonded directly to ceramic layer 112 or alternatively backside 122 may be held in direct contact with ceramic layer 112 without being bonded thereto. For example, deformable layer 110 and ceramic layer 112 can be adhered using a resin such as, but not limited to, poly(vinylbutiral) or secured together by fixing the layers within a frame and/or clamping.
The thickness of deformable layer 110 may be selected to enhance the generation of the compression wave. In one embodiment the deformable layer 110 has a thickness in a range from about 0.5 mm to about 10 mm, more preferably about 1 mm to about 4 mm. Opposing faces 120 and 122 can be disposed in parallel alignment so that the thickness is constant where the faces can be angled relative to each other so that the thickness varies one or both of faces 120 and 122. Faces 120 and 122 can also be contoured, such as curved, so that they are not planar.
In a preferred embodiment, deformable layer 110 is a single layer of a homogeneous material. However, in some embodiments the deformable layer 110 may be made from a plurality of sub-layers that together are highly deformable (e.g., the sub-layers together have an elongation before failure of at least about 20%).
Ceramic layer 112 is positioned adjacent to and between deformable layer 110 and fracture layer 114. Ceramic layer 112 has a front side surface 124 and an opposing backside surface 128. Backside surface 128 is adjacent fracture layer 114. Ceramic layer 112 can be adhered to or otherwise bonded to deformable layer 110 and/or fracture layer 114 similarly to the connection between ceramic layer 112 and deformable layer 110.
Ceramic layer 112 is made from a strong, ballistic-resistant material having a high sound velocity. The ceramic material will typically have a sound velocity in a range from about 2-50 km/s, more specifically 4-30 km/s, or even more specifically 8-20 km/s. Ceramic layer 112 may also be transparent. Examples of suitable transparent material include sapphire, aluminum oxinitride (AlON), spinel, AlN, alumina, and combinations of these. Nontransparent materials can also be used. Examples of nontransparent materials include, but are not limited to, silicon carbide, boronitride, boron carbide, diamond, and combinations of these. These materials and similar materials with a high sound velocity are advantageous for allowing the compression wave generated in the deformable layer 110 to spread out as it travels through ceramic layer 112 and for providing toughness in a thin layer.
The thickness 132 of ceramic layer 112 is typically selected to provide maximum strength while minimizing weight. Ceramics such as sapphire, aluminum oxynitride (AlON), and spinels typically need to have a minimal thickness before they will outperform plastic materials (e.g., about 0.25 mm). After this minimal thickness ceramics tend to provide better protection than plastics, but with increased weight, as the density of transparent ceramics are 2 to 3 times higher than the density of plastics. Thus, even where cost is not an issue, practical weight restrictions in some cases will limit the thickness of ceramic layers.
Even when relatively thick ceramic layers can be used, a thick ceramic layer tends to transfer impact velocity to the substrate (e.g. the frames of protective eyewear), which may not be able to handle increased forces and the whole system must be strengthened, again with weight increase. Thus in some embodiments of the invention it is desirable to minimize the thickness of the ceramic layer 112. In one embodiment, the thickness may be less than 10 mm, more preferably less than about 6 mm, even more preferably less than about 4 mm, and most preferably less than about 2 mm. In one embodiment of thickness 132 can be in a range from about 0.5 mm to about 6 mm, more preferably about 0.8 mm to about 4 mm, and most preferably from about 1 mm to about 2 mm.
In one embodiment of the invention ceramic layer 112 may be a continuous and/or homogeneous layer of the ceramic material. However in an alternative embodiment ceramic layer 112 may include a plurality of sub-layers of the ceramic material. The sub-layers may be the same or different ceramic materials and may be bonded or adhered together as previously discussed with respect to the connection between deformable layer 110 and ceramic layer 112.
Fracture layer 114 is adjacent to and between ceramic layer 112 and spall liner 116. Fracture layer 114 has a front side 130 and an opposing backside 134. Backside 134 may be adhered to or bonded to a front surface 136 of spall liner 116 any manner similar to the connection between deformable layer 110 and ceramic layer 112 as discussed above.
Fracture layer 114 is configured to receive a compression wave that has traveled through ceramic layer 112. Fracture layer 114 is configured to at least partially disintegrate upon receiving the compression wave. Fracture layer 114 is selected to have a low fracture toughness and high surface energy, which will maximize fracture absorption energy, typically at the expense of impact resistance. Typically, a lower fracture threshold will give better energy absorption and less momentum transfer to the armor plate supporting structure. In one embodiment, fracture layer 114 can be made from a brittle transparent material. Examples of suitable materials include glass, soda glass, transparent silicates, and combinations of these. Examples of nontransparent materials include nontransparent silicates. Within a given glass type, absorbed fracture energy can be manipulated by tempering the glass.
Fracture layer 114 is selected to have a lower impact resistance than ceramic layer 112. However, fracture layer 114 is configured to absorb substantial amounts of energy through fracturing. If desired, fracture layer 114 can even be configured to absorb more energy than ceramic layer 112. To achieve high energy absorption by fracture layer 114, armor plate 100 is configured to cause a relatively large volume of fracture layer 114 to fracture into fine particles.
The energy absorbed by fracture layer 114 depends on the velocity of the crack propagation and the fractured grain size.
In order to absorb large amount of energy, fractured particle size must be sufficiently small. The absorbed energy increases exponentially with a decrease in the diameter of the fractured particle size do to the increase in surface area.
The thickness of fracture layer 114 can be selected to provide adequate volume for absorbing a compression wave generated in deformable layer 110. With reference now to
Fracture layer 114 is backed by spall liner 116 to stop (i.e. catch) the fractured glass particles. Spall liner 116 has a front surface 136 that is adjacent fracture layer 114. In one embodiment, a back surface 140 of spall liner 116 is configured to be the back surface 119 of armor plate 110.
When a bullet strikes armor plate 100 and fracture layer 114 is pulverized, the disintegrated particles will be small, but can still carry residual momentum. Spall liner 116 is made from a material capable of capturing the fine particles generated from fracture layer 114. In one embodiment spall liner 116 may have relatively high elasticity such that spall liner 116 can expand to absorb the momentum of the fractured particles without rupturing. Examples of suitable materials that can be used to make spall liner 116 include polymers such as polycarbonate; woven ballistic fibers including para-aramids (e.g., Kevlar), ultra-high strength polyethylene fiber (e.g., Spectra and Dyneema), poly(p-phenylene-2,6-benzobisoxazole) (PBO), and/or boron fibers; polyurethane; and combinations of these. In one embodiment, spall liner 116 can be made from a transparent material such as polycarbonate or Dynema. Alternatively, spall liner 116 can be nontransparent.
The thickness of spall liner 116 is selected to ensure sufficient strength to withstand the residual momentum of the fractured particles from fracture layer 114. Typically the thickness of spall liner 116 may be in a range from about 0.5 mm to about 10 mm, more specifically between about 1 mm and 4 mm.
In contrast, the proposed invention takes a counterintuitive approach. Armor plate 100 includes a soft material in front ceramic layer 112 (i.e., deformable layer 110). Instead of mitigating a shock wave, deformable layer 110 and ceramic layer 112 are amplifying the shock wave. As a projectile moves through deformable layer 110, pressure on ceramic layer 112 builds up, effectively accumulating the compression wave. Lattice wave generation also lasts longer.
The speed of sound in deformable layer 110 may be selected to be relatively small. When the compression wave reaches ceramic layer 112, for example sapphire, it accelerates to the speed of sound (e.g., from 3 km/s to 11 km/s), thus becoming more intense. The compression wave also spreads out. When the compression waves hits the fracture layer 114 it is close in intensity to the impact point, but can be spread out over the area two orders of magnitude larger than the projectile cross-section area.
When a brittle solid fractures, the amount of energy absorbed depends on the grain size of the fractured material. The fracture energy is inversely proportional to the square root of the fractured grain size. Thus, how the layer fractures may be important to its ability to absorb impact energy. Armor plates manufactured according to methods known in the art tend to have a fracture zone that look like a cone propagating from the location of the impact, where the material closest to the impact site may have a fine grain fracture size, but much of the fractured material has a large grain fracture size and low energy dissipation. In contrast, the armor plate 100 of the present invention disperses the impact laterally, which causes fine grain fractures to occur over a much wider surface area. This energy absorption allows the armor plate 100 of the present invention to protect against higher velocity projectiles compared to known armor plates with a similar thickness.
With reference now to
The layers of armor plate 100 can also be held together in parallel using means other than an adhesive. For example, armor plate 100 can have deformable layer 110, ceramic layer 112, and/or fracture layer 114 in free contact with one another, but clamped together using a frame or other clamping mechanism. A frame or other substrate, such as those illustrated in the devices shown in
The overall thickness of armor plate 100 will typically depend on the amount of protection desired. Armor plates for preventing the penetration of high momentum projectiles may be of greater thickness than those for preventing the penetration of lower momentum projectiles, but with increased weight. In one embodiment the combined thickness of the deformable layer, ceramic layer, fracture layer, and spall liner have a thickness of less than 50 mm, more preferably less than 25 mm, even more preferably less than 20 mm, and most preferably less than 15 mm. In an alternative embodiment, the deformable layer, the ceramic layer, the fracture layer, and the spall liner have a combined thickness in a range from about 4 mm to about 25 mm, more preferably from about 5 mm to about 20 mm, and most preferably about 6 mm to about 15 mm.
In some embodiments it may be desirable to make armor plate 100 as thin and as light as possible while achieving a desired level of protection from projectile impact. To achieve a desired thinness, it can be advantageous to make armor plate 100 with only four layers (i.e., deformable layer, ceramic layer, fracture layer, and spall liner) and optionally an adhesive between one or more of the layers and/or a surface coating for modifying optical transmissions (e.g., a tint).
In one embodiment, armor plate 100 may include additional layers on front surface 117 and/or back surface 119. For example, armor plate 100 may include coatings that modify the color and/or light transmission through armor plate 100. In one embodiment a tint coating may be applied to armor plate 100. For example, a tint coating may be desirable for an armor plate used as a window to reduce the amount of light entering through the window and/or to inhibit people on an outside of the window to see inside.
To form armor plate 100, the layers of armor plate 100 can be temporarily fastened together, for example, with tape, and then placed in an autoclave, optionally under vacuum. The armor plate 100 may be pressurized and/or heated. Pressures that may be used include atmospheric, greater than atmospheric, greater than 2 bar, greater than 4 bar or greater than 8 bar. In some embodiments, pressure may be applied in a pressure chamber or by mechanical means, for instance, rollers or a press. Pressure and heat may be applied until the adhesive layers 142 (e.g., PVB) reach a softening point, allowing air bubbles to be expelled and allowing the adhesive to clarify and flow.
The softening temperature of adhesives layers 142 may be, for example, greater than 70° C., greater than 100° C., greater than 150° C., greater than 200° C., or greater than 250° C. In some embodiments the optimum temperature will depend on the pressure applied and the specific adhesive material used to bind the layers. In an alternative embodiment adhesive layers 142 can be polymerized to join the layers of armor plate 100.
After hardening, cooling, and/or polymerizing, the layers of armor plate 100 are securely immobilized in relation to each other and may be mounted in a substrate.
While
In one embodiment armor plate 100 can be segmented into a panel of armor plates.
The following examples provide formulas for making transparent armor plates according to one embodiment of the invention.
Example 1 describes a first type of armored plate (Type I). Type I had a deformable layer of 0.05″ thick Lexan, followed by 0.065″ of sapphire (ceramic layer), then 0.125″ soda lime glass (fracture layer) and 0.0935″ of Lexan (spall liner). The sandwich was glued with a thin layer (25μ) of transparent poly(vinylbutiral) resin.
Example 2 describes a second type of armor plate (Type II). Type II sandwich was made of 0.05″ Lexan (deformable layer), 0.065″ sapphire (ceramic layer), 0.0625″ soda lime glass (fracture layer) and 0.125″ Lexan (spall liner). The sandwich was glued with a thin layer (25μ) of transparent poly(vinylbutiral)].
Example 3 describes a third type of armored plate (Type III). Type III was made of 0.05″ Lexan (deformable layer), followed by 0.1425″ of sapphire (ceramic layer), then 0.075″ glass (fracture layer) and 0.1″ of Lexan (spall liner).
Example 4 describes a fourth type of armored plate (Type IV). Type IV was made of 0.05″ Lexan (deformable layer), followed by 0.0625″ of sapphire (ceramic layer), then 0.125″ glass (fracture layer) and 0.1″ of Lexan (spall liner).
Example 5 describes a fifth type of armored plate (Type V). Type V was made of 0.1″ Lexan (deformable layer), followed by 0.12″ of spinel (ceramic layer), then 0.12″ glass (fracture layer) and 0.1″ of Lexan (spall liner).
Type III-V were bonded using an extra thick (1-1.2 mm) adhesive layer instead of the desired 25μlayer. As expected, this increase in the adhesives they are attenuated the shock wave on the interface between the ceramic she and the fracture layer, thereby adversely affecting armor plate performance. Nevertheless, Examples III-V outperform traditional transparent armor plates.
Ballistic tests were conducted at the Indian Head Naval Surface Warfare Center range. Tests were with 22-caliber 17-grain fragment simulating projectile (FSP). This FSP is a standard projectile for transparent armor testing. Changing propellant mass in a cartridge varied projectile velocity. Four Ohler model 57 beam interrupter velocity screens were used to measure the velocity. The target system had a motor controlled positioning. The velocity data was collected using a high-speed data acquisition system. A high speed Phantom camera provided video recordings of the shots. Example Test parameters are shown in Table 1 below, where PP indicates partial sample penetration. The tests shown in Table 1 are for Type I materials. Similar tests were performed for samples Types II-IV.
Test results for Types I-V are shown
As shown in
The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
The U.S. Government has a paid-up license in this invention and the right in limited circumstances to require the patent owner to license others on reasonable terms as provided for by the terms Contract No. N00173-07-C-2055 awarded by U.S. Naval Research Laboratory.