The ceramic production and purification equipment of the present invention comprises a first fuselage, a furnace is fixedly arranged on the right end surface of the first fuselage, a cavity is provided in the first fuselage, and a top surface of the first fuselage is provided. A fixed block is fixedly fixed, and a feeding slot with an upward opening is provided in the fixed block. The device of the present invention can purify the ceramic before melting and casting. Compared with the traditional purification equipment, the device can remove iron impurities more thoroughly and the produced ceramics have higher purity. The equipment can also remove other impurities, while the operation is simple and clear, convenient and fast. In addition, the equipment can screen fine ceramic powder for melting, reducing the time required for melting ceramic powder, and the equipment has high purification efficiency.

A ceramic heater includes a ceramic plate having a wafer placement surface on which a wafer is to be placed, and incorporating a resistance heating element therein, and a ceramic tubular shaft having one end joined to a rear surface of the plate. The tubular shaft has a vertical sectional shape including an S-like portion or a curved portion having an inflection point in at least one position, and includes a through-hole penetrating the tubular shaft from the one end to the other end with an axis extending along the vertical sectional shape of the tubular shaft.

Provided is a hot isostatic pressing (HIP) device that improves the heat uniformity of a hot zone during a pressurization process of an object being processed. This HIP device (100) is provided with: an outer casing (4) having an open outer opening part (4H); an inner casing (5) having an open inn opening part (5H); a heat-insulating body (R) disposed between the outer casing (4) and the inner casing (5); a gas flow generation part (30); and a plurality of first gas conduits (12), A hot zone (P) in which a pressurization process is performed is formed inside the inner casing (5). During the pressurization process, a low-temperature pressurization medium gas which has been generated by the gas flow generation part (30) and has passed through the first gas conduits (12) moves upward in an inner flow passage (L1) between the casings, and then flows into the hot zone (P) from the inner opening part (5H), Even when the pressurization medium gas leaks from the vicinity of a bottom all part (20) and flows into the hot zone (P), the heat uniformity of the hot zone (P) is maintained.

The present disclosure is related to a method of producing a fired ceramic article. The method may include: heating a ceramic green body in a kiln, and controlling oxygen concentration in the kiln such that the oxygen concentration swings during the heating of the ceramic green body.

A setter for firing used for firing a honeycomb formed body and interposed between the honeycomb formed body and a shelf plate, the setter for firing including: a setter body part having a honeycomb placement surface at least partially in contact with a formed body end face of the honeycomb formed body and placing the honeycomb formed body on the honeycomb placement surface; and a setter supporting part that is provided below the setter body part and supports the setter body part, wherein a value obtained by dividing an area of the honeycomb placement surface of the setter body part by an area of a setter supporting surface of the setter supporting part that contacts the setter body part is in a range of 1.5 to 20.0.

A setter for firing in a plate which is used for firing a honeycomb formed body and interposed between the honeycomb formed body and a shelf plate, wherein the setter for firing has a setter lower surface section facing the shelf plate, the setter lower surface section including: a central region part formed by a region including a lower surface center of the setter lower surface section; and a peripheral region part formed by a peripheral region of the central region part, and the peripheral region part has at least four or more setter groove parts each having a recessed cross sectional shape and extending radially from the lower surface center respectively in a direction from a boundary with the central region part toward a setter outer circumferential section.

A workpiece carrier and method for producing a workpiece carrier (10) for providing and handling workpieces in high-temperature ovens for high-temperature treatment or similar, said workpiece carrier being made of a support grid (11) having workpiece holders (12) for positioning workpieces on the workpiece carrier, said support grid being made of support struts (14, 15, 16, 17, 19, 20) forming a grid structure (21), said support struts being made of carbon fiber-reinforced carbon (CFC), said workpiece holders being made of positioning devices (22) of the work-piece carrier arranged on the support struts, said positioning devices being arranged on the support struts such that the workpiece can be arranged on the workpiece holder in a predetermined position, said positioning devices comprising a bearing element (24) made of a ceramic fiber composite material, said positioning device being a support element (23) arranged on a support strut for arranging the bearing element.

A method of forming a setter for firing a ceramic has a sheet formation step (S1 to S3) to form a structure by sheet formation. The structure has a porous layer S1 with ceramic fibers. A shaping step S5 shapes the structure, into a predetermined shape. A coating step S6 impregnates the predetermined shape structure, with an impregnation liquid to form a dense layer S2 on the outer surface of the porous layer S1. The dense layer S2 is denser than the porous layer S1. A firing step S7, fires, at a predetermined temperature, the structure that has been subjected to the coating step S6.

A kiln car assembly for a firing kiln having a plurality of upper burners includes a kiln car with an uppermost plurality of ceramic green bodies, a plurality of vertical members, and a horizontal supporting plate for supporting the ceramic green bodies during a firing process in the kiln. Further, the kiln car assembly includes a covering table having a tabletop located between the uppermost plurality of ceramic green bodies and the upper burners, and a plurality of legs positioned on the horizontal supporting plate.

A method and plant for the thermal treatment of friction elements including a convective heating step which is performed within a convective tunnel oven. The friction elements are arranged laid, in an orderly manner, upon a plurality of trays each tray having a perforated resting plate upon which the friction elements are laid in a position next to one another only, but not overlapped. The trays are piled on top of each other whilst being kept distanced from one another in a stacking direction by an amount that is greater than the thickness of the friction elements. Groups of piled up trays containing the friction elements are arranged side by side on belt conveyor means that pass through the tunnel oven in order to transport the friction elements therethrough.