Abstract: A system and method for bending one or more thin glass structures. The system includes heating, bending and cooling zones, each having a plurality of modules aligned and connected to each other to define elongated tunnels, wherein adjacent heating modules are separated from each other by a furnace door. A conveyance mechanism carries the one or more thin glass structures through the modules via the elongated tunnels. Each of the modules include one or more heating elements, each heating element being independently controllable by element or set of elements as a function of a temperature profile for the one or more thin glass structures. The temperature profile can be determined as a function of temperature on the one or more thin glass structures.

Abstract: A mechanism for bending glass comprising a seating device and a mold configured to bend a substrate to a desired shape, the substrate adaptable to be provided on the seating device. A position of the mold in relation to the seating device can be controlled by a programmable counterweight system.

Abstract: This disclosure is directed to porous ceramic processing; and in particular to a method using selected pore forming materials to avoid high exotherms during the ceramic firing process, and the green bodies formed using the selected pore forming materials. The selected pore forming materials are homogeneous wax/non-ionic surfactant particles formed by a prilling process in which the wax is melted and the non-ionic surfactant is mixed into the wax prior to prilling. The disclosure is useful in the manufacture porous ceramic honeycomb bodies including ceramic honeycomb filter traps.

Abstract: This disclosure is directed to porous ceramic processing; and in particular to a method using selected pore forming materials to avoid high exotherms during the ceramic firing process, and the green bodies formed using the selected pore forming materials. The selected pore forming materials are homogeneous wax/non-ionic surfactant particles formed by a prilling process in which the wax is melted and the non-ionic surfactant is mixed into the wax prior to prilling. The disclosure is useful in the manufacture porous ceramic honeycomb bodies including ceramic honeycomb filter traps.

Abstract: The disclosure provides a composition including a porous cordierite honeycomb body as defined herein having excellent strength, high thermal shock resistance, and reduced microcrack properties. The disclosure also provides methods of making and using the composition, for example, as a catalyst carrier.

Abstract: The disclosure provides a composition including a porous cordierite honeycomb body as defined herein having excellent strength, high thermal shock resistance, and reduced microcrack properties. The disclosure also provides methods of making and using the composition, for example, as a catalyst carrier.

Abstract: The invention is directed to a method for growing metal fluoride crystals suitable for use in below 200 nm optical lithography systems, the method comprising including at least the step of heating a crystal growth furnace to a temperature in the range of 1400-2000° C. to purify the furnace by removal of sulfur and chlorine prior to using the furnace for growing metal fluoride single crystals.