A compositionally-graded structure including a body having a first major surface and a second major surface opposed from the first major surface along a thickness axis, the body including a metallic component and a ceramic component, wherein a concentration of the ceramic component in the body is a function of location within the body along the thickness axis, wherein transitions of the concentration of the ceramic component in the body are continuous such that distinct interfaces are not macroscopically established within the body, and wherein the concentration of the ceramic component is at least 95 percent by volume at at least one location within the body along the thickness axis.

A ballistic resistant, fragmentation debris capture laminate panel is comprised of one or more ballistic resistant and containment materials that have been laminated together with one or more thermoplastic resin substrates such as polycarbonate and/or PETG. The ballistic resistant, fragmentation debris capture laminate panel can be manufactured with a variety of ballistic resistant and containment materials, by autoclave or hot press methods, and include decorative and/or image bearing appearance. Specifically, a ballistic resistant laminate, fragmentation debris capture panel of the present invention can be manufactured to include materials, such as aramid fiber sheet, ballistic ceramic products, and/or metal fabric sheet, or combination thereof, to meet one or several ballistic resistant standards and fragmentation debris capture ratings selected by the user for a specific building, construction or structural application.

The invention relates to an armor plate (10) with a thickness of at least 2 mm and an edge length of at least 20 mm, wherein the armor plate (10) consists of a material that contains tungsten heavy metal or tungsten carbide as the essential component. The invention furthermore relates to an armor with a carrier (12), several such armor plates (10) and a permanently elastic adhesive layer (14), by means of which the armor plates (10) are connected to the carrier (12).

A system. The system includes a liquid container and an energy absorbing system positioned. The liquid container includes a wall which defines an interior volume of the liquid container. The energy absorbing system is within an interior volume of the liquid container. The energy absorbing system is configured such that if an object passes through the wall of the liquid container and impacts the energy absorbing system, an amount of energy absorbed by the energy absorbing system is at least 18% greater than an amount of energy absorbed by the wall of the liquid container. The energy absorbing system includes one or more energy absorbing members, wherein at least one of the one or more energy absorbing members comprises a metal and has a Brinell hardness of at least 150.

A modular armor system configured to be readily attached and detached from a frame surrounding a window in a vehicle or other structure, such as a building. The modular armor system may be configured to provide any desired ballistics protection rating. In one embodiment, the modular armor system includes a ballistics-grade armor panel having an outer strike face and an inner surface opposite the outer strike face. The modular armor system also includes a fastener coupled to the ballistics-grade armor panel. The fastener is configured to detachably couple the ballistics-grade armor panel to the frame surrounding the window in the vehicle or other structure.

A mixture including glass fragments is located in a containment vessel and is processed in a kiln to form a commercially useful building product. The mixture is initially heated over a first time period to a first temperature intermediate the glass transition point temperature and about 950 C. or 1,100 C. (Section A). At the first temperature the glass fragments slump and bond to each other and the mixture is soaked at this temperature for a second time period (Section B). After reducing the temperature (Section C), the mixture is annealed for another time period (Section D). Finally, the kiln is cooled to allow the mixture to be removed (Section E).

A modular armor system configured to be readily attached and detached from a frame surrounding a window in a vehicle or other structure, such as a building. The modular armor system may be configured to provide any desired ballistics protection rating. In one embodiment, the modular armor system includes a ballistics-grade armor panel having an outer strike face and an inner surface opposite the outer strike face. The modular armor system also includes a fastener coupled to the ballistics-grade armor panel. The fastener is configured to detachably couple the ballistics-grade armor panel to the frame surrounding the window in the vehicle or other structure.

A multi-layered ballistic material can include a polyurethane foam layer and a ballistic impact absorption layer. The polyurethane foam can be formed from an isocyanate and a polyol; a polymerization reactor initiator that is an isoprenoid compound; and a polymerization reaction accelerator.

An armor assembly having an armor panel, a base plate, and a resilient member coupled between the armor panel and the base plate is disclosed. An impact blast or projectile will strike the armor assembly and deflect the armor panel and the resilient member. The resilient member and armor panel absorb sufficient energy from the impact blast or projectile to prevent harm to underlying structures. The resilient member can be a spring or a solid member having a desired spring coefficient to protect against a certain impact load.

Antiballistic armour plate includes a ceramic body including a hard material, provided, on its inner face, with a back energy-dissipating coating. The ceramic body is monolithic. The constituent material of the ceramic body includes grains of ceramic material having a Vickers hardness that is higher than 15 GPa, and a matrix binding the grains, the matrix including a silicon nitride phase and/or a silicon oxynitride phase, the matrix representing between 5 and 40% by weight of the constituent material of the ceramic body. The maximum equivalent diameter of the grains of ceramic material is smaller than or equal to 800 micrometres. The constituent material of the ceramic body has an open porosity that is higher than 5% and lower than 14%. The metallic silicon content in the material, expressed per mm of thickness of the body, is lower than 0.5% by weight.