Abstract: A manufacturing apparatus employs three-dimensional (3D) printing technology and computer numerical controlled (CNC) positioning technology that creates composite structures of any size. The composite structures exhibit predefined characteristics suitable for different applications. The composite structures consist of plastic sheathing melded together to form bladders, as well as fabric impregnated with one or more resin-based compounds. The composite structures assume any of a myriad of predefined shapes. The composite structures exhibit fire-resistance, water-resistance, water containment, phase-change capability, ballistic protection, low weight, and may further be operable as a solar panel or be electrically conductive. The composite structures are optionally constructed with vias or pathways, through which pipes, electrical conduit, and other building materials may be threaded.

Abstract: A manufacturing apparatus employs three-dimensional (3D) printing technology and computer numerical controlled (CNC) positioning technology that creates composite structures of any size. The composite structures exhibit predefined characteristics suitable for different applications. The composite structures consist of plastic sheathing melded together to form bladders, as well as fabric impregnated with one or more resin-based compounds. The composite structures assume any of a myriad of predefined shapes. The composite structures exhibit fire-resistance, water-resistance, water containment, phase-change capability, ballistic protection, low weight, and may further be operable as a solar panel or be electrically conductive. The composite structures are optionally constructed with vias or pathways, through which pipes, electrical conduit, and other building materials may be threaded.

Abstract: A manufacturing apparatus employs three-dimensional (3D) printing technology and computer numerical controlled (CNC) positioning technology that creates composite structures of any size. The composite structures exhibit predefined characteristics suitable for different applications. The composite structures consist of plastic sheathing melded together to form bladders, as well as fabric impregnated with one or more resin-based compounds. The composite structures assume any of a myriad of predefined shapes. The composite structures exhibit fire-resistance, water-resistance, water containment, phase-change capability, ballistic protection, low weight, and may further be operable as a solar panel or be electrically conductive. The composite structures are optionally constructed with vias or pathways, through which pipes, electrical conduit, and other building materials may be threaded.

Abstract: A manufacturing apparatus employs three-dimensional (3D) printing technology and computer numerical controlled (CNC) positioning technology that creates composite structures of any size. The composite structures exhibit predefined characteristics suitable for different applications. The composite structures consist of plastic sheathing melded together to form bladders, as well as fabric impregnated with one or more resin-based compounds. The composite structures assume any of a myriad of predefined shapes. The composite structures exhibit fire-resistance, water-resistance, water containment, phase-change capability, ballistic protection, low weight, and may further be operable as a solar panel or be electrically conductive. The composite structures are optionally constructed with vias or pathways, through which pipes, electrical conduit, and other building materials may be threaded.

Abstract: A multilayered ballistic protection assembly for windows is disclosed. The multilayered ballistic protection assembly consists of a tough resistant material that absorbs impacts, separated by deflecting “stroking” volumes that allow movement of the resistance layer without causing breakage of the underlying glass window. The resistance layer exhibits extraordinary in-plane strength with only a marginal out-of-plane strength. The multilayered ballistic protection assembly may vary considerably in material strength and assembly, depending on its intended use. The number of layers making up the assembly is determined by the degree of desired protection, the size of the object to be protected, and the strength of the resistance and stroking materials used to protect the object. Among other applications, the multilayered ballistic protection assembly is designed to protect glass from impacts due to severe weather and other debris-generating hazards.

Abstract: A multilayered ballistic protection assembly for windows is disclosed. The multilayered ballistic protection assembly consists of a tough resistant material that absorbs impacts, separated by deflecting “stroking” volumes that allow movement of the resistance layer without causing breakage of the underlying glass window. The resistance layer exhibits extraordinary in-plane strength with only a marginal out-of-plane strength. The multilayered ballistic protection assembly may vary considerably in material strength and assembly, depending on its intended use. The number of layers making up the assembly is determined by the degree of desired protection, the size of the object to be protected, and the strength of the resistance and stroking materials used to protect the object. Among other applications, the multilayered ballistic protection assembly is designed to protect glass from impacts due to severe weather and other debris-generating hazards.