This invention relates to an armor for protection against large caliber projectiles where the armor has a ceramic layer and a metallic layer.
Ceramic armors are known. However, previous armors are much too heavy or too bulky or too expensive or they do not provide sufficient protection or any protection against large caliber projectiles. Traditional soft armor used in many types of protective vests are typically made of layers of flexible fabric or non-woven textile using fibers such as aramid (such as Kevlar® or Twaron®) or polyethylene (such as Spectra Shield® or Dyneema®) or other types of fibers. When a bullet strikes these layered armors, the impact produces a bulge which deforms the back surface of the armor. Since the armor is worn adjacent to the body, this bulge, or deformation, projects into the body of the wearer which can cause tissue damage or trauma to the underlaying body part.
U.S. Pat. No. 5,534,343 teaches the use of an inner layer of flexible cellular material in a flexible armor.
U.S. Pat. No. 5,349,893 discloses a ceramic armor having an inner layer of rigid, semi-flexible or semi-rigid cellular material.
U.S. Pat. No. 5,847,308 issued to Singh et al. teaches a passive roof armor system which includes a stack of ceramic tiles and glass layers.
U.S. Pat. No. 6,203,908 issued to Cohen is directed to an armor having an outer steel layer, layers of high density ceramic bodies bonded together, and an inner layer of high-strength anti-ballistic fibres such as KEVLAR™.
U.S. Pat. No. 6,135,006 issued to Strasser et al. discloses a multi-layer composite armor which includes alternating hard and ductile layers formed of fiber-reinforced ceramic matrix composite.
Canadian Patent application Serial No. 2,404,739 to Lucuta et al. discloses a multi-layer ceramic armor with improved ceramic components to deflect a projectile on impact, bonded to a shock absorbing layer constructed of a polymer-fiber composite material, and further bonded to a backing of ballistic composite or metallic material. In the designs presented by Lucuta et al. all ceramic materials are backed by: polymer-fiber composite, additional ceramic components, or polymeric components while the current design uses a metallic layer directly bonded to the ceramic. The backing layer in traditional armour is made of a ballistic composite material. Lucuta et al. claim the use of a ballistic composite or metallic layer.
United States Patent Publication No. US2004/0118271A1 to Puckett et al. is directed to reducing the impact of armor deformation by reducing the peak load using a trauma reduction layer such as cellular honeycomb urethane materials. The current design proposes the use of a polymeric layer between the armor and wearer to further reduce the impact, and this process is generally known and used in the armor industry.
Therefore there is a need for an armor that overcomes that provides better protection to underlying tissue and organs of the person wearing the armor.
It is an object of the invention to provide an armor and a method of construction thereof that is lightweight and relatively thin, yet provides protection against large caliber projectiles. It is a further object of the present invention to provide an armor and method of construction where the armor can be used as body armor or as protection for vehicles or other objects with reduced deformation and trauma when impacted by large caliber projectiles.
In another aspect of the invention there is provided personal armor for protection against large caliber armor piercing projectiles comprising a ceramic layer with a first confinement layer on a front thereof, said ceramic layer being backed by a first nonporous solid metallic layer of high strength and ductility for distributing an impact load from a projectile and ceramic debris and for confining the debris in an impact zone within said ceramic layer, said first nonporous solid metallic layer being thinner than said ceramic layer, said first nonporous solid metallic layer being 1.11 mm or less in thickness and backed by a ballistic composite layer made of ballistic fabrics, fabric weaves and polymeric matrix materials for stopping a projectile and ceramic debris while minimizing deformation, with the various layers being bonded together by a suitable adhesive, said sequence of ceramic layer, nonporous solid metallic layer and ballistic composite layer exhibiting a back face deformation of 44 mm or less in clay as measured in accordance with a National Institute of Justice (NIJ) Standard when impacted on a front surface of said ceramic layer by projectile threats corresponding to NIJ Threat Levels up to 0.50 caliber, armor piercing, high energy projectiles.
In another embodiment of the armor the composite layer may be backed by an additional metallic layer to further reduce dynamic deformation.
Preferably, the first metallic layer is extremely thin relative to a thickness of the ceramic layer.
Still more preferably, the confinement layer is a fiber reinforced polymeric layer.
Preferably, the first metallic layer is made from titanium.
A method of constructing an armor for protection against large caliber projectiles, the method comprising affixing a first metallic layer to a back of a ceramic layer, affixing a confinement layer to a front of the ceramic layer, affixing a composite layer to a back of the first metallic layer, and using a suitable adhesive to affix the various layers together. A second metallic layer may be used to back the composite layer.
In
In
The confinement layer is preferably a glass fiber reinforced layer. Preferably, the confinement layer 6 is held together with a urethane matrix. The metallic layer 8 is preferably made from titanium and, still more preferably, is a titanium alloy containing substantially 6% aluminum (for example, Titanium alloy ASTM B265, Grade 5, with nominal weight contents of 6% Aluminum, 4% Vanadium). The titanium layer is extremely thin relative to the ceramic layer 4. The composite layer 10 is formed of multiple layers, preferably multiple layers of Kevlar (a trade-mark). The ceramic layer is preferably boron carbide or silicon carbide. However, boron carbide is much more expensive than silicon carbide. Even though the boron carbide works better than the silicon carbide, in many applications of the armor, the silicon carbide will perform extremely well and boron carbide will not be required. The ceramic layer may be a mosaic (a series of smaller tiles shaped to fit together to cover a larger area without gaps) but is preferably a solid layer of ceramic. The anti-trauma layer is preferably a foam layer.
In
In
In
In
In some uses of the armor, it will be unnecessary to use the anti-trauma layer 12 so that the armor consists, from front to rear, of the confinement layer 6, the ceramic layer 4, the first metallic layer 8 and the composite layer 10 respectively. The armor is further described in the following examples.
A multi-component armor plate has a confinement layer, ceramic layer and first metallic layer that is 250 mm wide and 300 mm in height. The composite layer, a second metallic layer and anti-trauma layer has dimensions of 250 mm in width by 300 mm in height. The total mass is approximately 4.8 kg.
In example 1, the layers have the following thicknesses:
All layers in the example are bonded using a urethane adhesive.
The design set out in example 1 was evaluated using NIJ (National Institute of Justice) Standard 0101.04 which incorporates impact of armor on a clay backing. A deformation level of 44 mm or less in clay is considered to result in survivable injuries to a human. The above design resulted in a deformation level of 44 mm when impacted by large caliber projectiles. The armor of example 1 was located within a vest (not shown) when the tests were conducted. The layer materials and thicknesses will vary in accordance with the specific requirements or circumstances of use.
The anti-trauma layer is preferably a polymeric foam layer. The purpose of the anti-trauma layer is to reduce blunt trauma and to increase separation between the armor and the torso of a user. The anti-trauma layer reduces impact loading, improves load distribution and energy absorption. Preferably, the anti-trauma layer is 128 kg/m3 rigid polyurethane foam having a thickness of 15 mm. The foam layer is preferably FR-6708 (a trademark) sold by General Plastics Manufacturing Company.
Improved bonding and performance of the ceramic layer is achieved by ensuring a surface roughness of 1.26 (Ra), which is attained through sand blasting the ceramic tiles. The ballistic performance of the ceramic tile is improved significantly by the thin metallic backing. The metallic backing preferably has high strength and ductility. The use of the confinement layer and the metallic backing allows for a higher-density and lower-cost ceramic such as silicon carbide to be used in place of the more expensive boron carbide. (Currently boron carbide is approximately 2.5 times more expensive than silicon carbide). The composite backing is preferably comprised of various ballistic fabrics, fabric weaves and polymeric matrix materials to maximize the ballistic performance. The purpose of the composite backing is to stop the projectile and ceramic debris while minimizing deformation.
The armor of the present invention has withstood impacts by large caliber, armor piercing, high energy projectiles with low back face deformation. An example of projectiles is 0.5 caliber armor piercing projectiles.
The armor of example 1 had a maximum total areal density of 70 kg/m2 at the thickest portion (eg. over the heart) of areal densities. While the armor of the present invention can be used in various applications, it is preferred to use the armor in a torso protection vest.
The armor 20 described in Example 1 has an overall maximum thickness of substantially 49 mm. It may be desirable to vary the thickness and/or material in a specific area or areas of the armour to achieve the desired results, which may be a lower overall weight.
To date, the use of metallic layers in personal body armor does not represent the conventional approach due to weight concerns. However, the current design disclosed herein utilizes a thin metallic layer to improve performance and reduce the weight of other components including the ceramic and composite backing so that no significant weight penalty is incurred. The metallic layer enhances performance through distribution of the impact load from the projectile and ceramic on the composite, confinement of the ceramic debris in the impact zone, and through impedance matching between the ceramic and metallic layer. The enhanced performance resulting from this metallic layer also allows for the use of lower ballistic performance ceramics in applications. The preferred material is titanium due to light weight and exceptional performance in these conditions. Other metallic materials could be considered including aluminum, requiring increased thickness, and high-strength steel, resulting in added weight.
By comparison, Canadian Patent application Serial No. 2,404,739 to Lucuta et al. discloses a multi-layer ceramic armor with improved ceramic components to deflect a projectile on impact, bonded to a shock absorbing layer constructed of a polymer-fiber composite material, and further bonded to a backing of ballistic composite or metallic material. This differs from the armor design disclosed herein in component stacking sequence and purpose. In particular, the first metallic layer in the current design is used to support the ceramic and enhance penetration resistance. The first and second metallic layers also act to minimize deformation of the composite material upon impact. In the designs disclosed in Lucuta et al. all ceramic materials are backed by: polymer-fiber composite, additional ceramic components, or polymeric components while the present design uses a metallic layer directly bonded to the ceramic. The backing layer in traditional armor is made of a ballistic composite material. Lucuta et al. claim the use of a ballistic composite or metallic layer. The current design uses a ballistic composite, which may be further supported by a thin metallic layer to enhance performance.
As used herein, the terms “comprises”, “comprising”, “including” and “includes” are to be construed as being inclusive and open ended, and not exclusive. Specifically, when used in this specification including claims, the terms “comprises” and “comprising” and variations thereof mean the specified features, steps or components are included. These terms are not to be interpreted to exclude the presence of other features, steps or components.
The foregoing description of the preferred embodiments of the invention has been presented to illustrate the principles of the invention and not to limit the invention to the particular embodiment illustrated. It is intended that the scope of the invention be defined by all of the embodiments encompassed within the following claims and their equivalents.
This patent application relates to, and claims the priority benefit from, U.S. Provisional Patent Application Ser. No. 60/514,621 filed on Oct. 28, 2003 entitled CERAMIC ARMOUR AND METHOD OF CONSTRUCTION and which is incorporated herein in its entirety.
Number | Name | Date | Kind |
---|---|---|---|
5191166 | Smirlock et al. | Mar 1993 | A |
5349893 | Dunn | Sep 1994 | A |
5534343 | Landi et al. | Jul 1996 | A |
5996115 | Mazelsky | Dec 1999 | A |
6253655 | Lyons et al. | Jul 2001 | B1 |
6408733 | Perciballi | Jun 2002 | B1 |
7150217 | Kershaw | Dec 2006 | B2 |
7210390 | Olson et al. | May 2007 | B1 |
20040118271 | Puckett et al. | Jun 2004 | A1 |
20050066805 | Park et al. | Mar 2005 | A1 |
20060065111 | Henry | Mar 2006 | A1 |
Number | Date | Country |
---|---|---|
02055952 | Jul 2002 | WO |
03010484 | Feb 2003 | WO |
Number | Date | Country | |
---|---|---|---|
60514621 | Oct 2003 | US |