A composite green sheet includes a green sheet, and a bulk metal film provided on the green sheet. Examples of the metal forming the metal film may include aluminum, aluminum alloys, copper, copper alloy, or the like.

A segmented composite exhaust flue which may be used to shield an area or object from convective, conductive, or radiated heat transfer from hot exhaust combustion gases is described. In certain embodiments, the composite exhaust flue may be used to protect structures from hot exhaust gases and particles such as those produced by cars, trucks, ships, boats, jets, rockets, as well as other vehicles with internal combustion engines, turbines, or rocket motors. In some embodiments, a composite exhaust flue may include an attachment frame removeably holding a plurality of ceramic composite panels where the ceramic composite panels have a ceramic fiber reinforced ceramic composite high temperature face sheet positioned over an insulating layer.

The invention relates to sealing a fuel rod composite cladding tube composed of silicon carbide regardless of the fuel rod cladding design architecture (e.g., monolithic, duplex with monolithic SiC on the inside and a composite made with SiC fibers and SiC matrix on the outside) preferably with sealed SiC end plug caps, additionally sealed with an interior braze and exterior SiC final coating, thus providing a double sealed end plug barrier effective at retaining gas tightness and providing mechanical strength for the sealed end joint while providing high chemical resistance.

Various embodiments include a metal-repaired ceramic matrix composite (CMC) article, and a method of repairing a CMC article having a defect. Particular embodiments include a method including: removing a defect-containing portion of the CMC article; forming at least one opening in a remaining portion of the CMC article; preparing a metal repair preform for replacing at least the removed portion of the CMC article, wherein a portion of the metal repair preform complements the at least one opening; and attaching the metal repair preform to the remaining portion of the CMC article.

A turbine component assembly is disclosed, including a first component, a second component, and an interface shield. The first component is arranged to be disposed adjacent to a hot gas path, and includes a ceramic matrix composite composition. The second component is adjacent to the first component and arranged to be disposed distal from the hot gas path across the first component. The interface shield is disposed on a contact region of the first component, and directly contacts the second component.

A refractory article can include a socket including a cavity that is configured to receive a post, a particulate material, and a binder. The binder is configured to bond the post to the socket. The refractory article can include a sleeve coupled to the socket and configured to bond the post to the socket. In an embodiment, the sleeve can bond to the binder. In another embodiment, a collar can be placed between the sleeve and the binder. The collar can be configured to bond the post to the socket. A method of forming a refractory article can include disposing a particulate material within a cavity of a socket and placing a binder material overlying the particulate material.

The present invention is related to a porous ceramic composite structure with high mechanical strength and a wide range of porosity which makes flow rate of fluid highly tunable. The porous ceramic composite structure comprises a dense ceramic sheath and one or more inner porous ceramic bodies. The ceramic sheath provides good mechanical properties, protects the one or more inner porous ceramic bodies, and allows the one or more inner porous ceramic bodies to undergo a wide range of porosity changes while still maintaining excellent mechanical properties.

A method for manufacturing an electrostatic chuck with multiple chucking electrodes made of ceramic pieces using metallic aluminum as the joining. The aluminum may be placed between two pieces and the assembly may be heated in the range of 770C to 1200C. The joining atmosphere may be non-oxygenated. After joining the exclusions in the electrode pattern may be machined by also machining through one of the plate layers. The machined exclusion slots may then be filled with epoxy or other material. An electrostatic chuck or other structure manufactured according to such methods.

This invention relates to a product and a method of preparing ceramic and/or ceramic hybrid materials through the construction of a printed die. The printed die being made by three dimensional printing or additive manufacturing processes possesses both an external geometry and an internal geometry.

Provided is a manufacturing method for a glass article, including: a filling step (S1) of interposing a powder (P), which is to be diffusion-bonded through heating, between a transfer container (7, 16) and a refractory brick (8a, 8b, 17a, 17b); a pre-heating step (S2) of heating the transfer container (7, 16) after the filling step (S1); and a molten glass supply step (S5) of, while heating the transfer container (7, 16), causing a molten glass (GM) to pass through an inside of the transfer container (7, 16) after the pre-heating step (S2). In this method, the molten glass supply step (S5) includes diffusion-bonding the powder (P) to form a bonded body (10, 20) configured to fix the transfer container (7, 16) to the refractory brick (8a, 8b, 17a, 17b).