Provided are a heating furnace and a graphite production method both of which allow a carbonization step and a graphitization step to be consecutively performed. The heating furnace is a heating furnace for producing graphite from a polymeric material, and includes a heating furnace body for subjecting the polymeric material to heat treatment. The heating furnace body includes a closed vessel for containing the polymeric material. A gas outlet pipe is connected to the closed vessel, the gas outlet pipe being for letting, out of the heating furnace body, a pyrolytic gas generated from the polymeric material.

Provided are a heating furnace and a graphite production method both of which allow a carbonization step and a graphitization step to be consecutively performed. The heating furnace is a heating furnace for producing graphite from a polymeric material, and includes a heating furnace body for subjecting the polymeric material to heat treatment. The heating furnace body includes a closed vessel for containing the polymeric material. A gas outlet pipe is connected to the closed vessel, the gas outlet pipe being for letting, out of the heating furnace body, a pyrolytic gas generated from the polymeric material.

The invention relates to an injector configured for arrangement within a reaction chamber of a substrate processing apparatus to inject gas in the reaction chamber. The injector may be elongated along a first axis and configured with an internal gas conduction channel extending along the first axis and provided with at least one gas entrance opening and at least one gas exit opening. The injector may have a width extending along a second axis perpendicular to the first axis substantially larger than a depth of the injector extending along a third axis perpendicular to the first and second axis. The wall of the injector may have a varying thickness.

The present invention enables quick cooling of steam-treated objects and thus reduces the manufacturing time of steam-treated products such as black coated steel sheets. The present invention provides a method for manufacturing steam-treated products, which involves a steam treatment step that introduces steam into a closed container (10) containing a treatment object (1) and brings the treatment object (1) into contact with the steam, and a treated object cooling step that cools the object (1) treated with steam in the steam treatment step, wherein said treated object cooling step introduces coolant gas into said closed container (10), brings said treated object (1) into contact with the coolant gas, and discharges the introduced coolant gas from said closed container (10).

A furnace for removing a molybdenum-alloy refractory metal core through sublimation comprising a retort furnace having an interior; a sublimation fixture insertable within the interior of the retort furnace, the sublimation fixture configured to receive at least one turbine blade having the molybdenum-alloy refractory metal core; a flow passage thermally coupled to the retort furnace configured to heat a fluid flowing through the flow passage and deliver the fluid to the molybdenum-alloy refractory metal core causing sublimation of the molybdenum-alloy refractory metal core.

Based on the nitriding potential in the processing furnace calculated by the in-furnace nitriding potential calculator and the target nitriding potential, the introduction amount of the ammonia gas is changed while the introduction amount of the ammonia decomposition gas is kept constant, such that the nitriding potential in the processing furnace is brought close to the target nitriding potential.

An end-fired melting furnace and a method of melting raw materials by an end-fired melting furnace are provided, where the furnace includes a melting tank, a melting chamber, first and second ports, at least one burner, and at least one auxiliary fuel injector arranged in the end-fired melting furnace in a roof or in first and second side walls so that the at least one auxiliary fuel injector introduces a fraction X2 of auxiliary fuel, in a direction of re-circulating combustion products, without additional oxidiser, into the re-circulating combustion products in a direction of a flow of the re-circulating combustion products, and with a chosen velocity such that the fraction X2 of auxiliary fuel mixes with the re-circulating combustion products before being combusted by oxidiser entering the furnace.

The invention uses a furnace retort made of silicon carbide to create a sintering furnace having no cold areas during debinding while having low heat losses during sintering. This is achieved by varying the wall thickness of the retort and taking advantage of the large increase in thermal conductivity of silicon carbide at lower temperatures. The special properties of silicon carbide also allow rapid cooling by exposing the outside of the retort directly to a high flow of cooling air.

The invention uses a furnace retort made of silicon carbide to create a sintering furnace having no cold areas during debinding while having low heat losses during sintering. This is achieved by varying the wall thickness of the retort and taking advantage of the large increase in thermal conductivity of silicon carbide at lower temperatures. The special properties of silicon carbide also allow rapid cooling by exposing the outside of the retort directly to a high flow of cooling air.

A furnace for removing a molybdenum-alloy refractory metal core through sublimation comprising a retort furnace having an interior; a sublimation fixture insertable within the interior of the retort furnace, the sublimation fixture configured to receive at least one turbine blade having the molybdenum-alloy refractory metal core; a flow passage thermally coupled to the retort furnace configured to heat a fluid flowing through the flow passage and deliver the fluid to the molybdenum-alloy refractory metal core causing sublimation of the molybdenum-alloy refractory metal core.