A ground supported power boiler is described combining a refractory lined and insulated conical floor; an insulated cylindrical combustion chamber; a cylindrical furnace with water tube wall; a rectangular convective section; a single vertical steam drum; tangential injection of the fuel and combustion air; means for fluidizing the fuel bed; means for selectively stripping particulates from the flue gases; multi-stage particulate stripping and filtering from flue gases, means for using the walls of steam drum as steam/water droplet separator, means for recirculating and capturing heat from the flue gases; means for pressurizing the interior of the boiler above atmospheric pressure; means for heating and drying fuel prior to feeding the fuel to the boiler; means for creating hydrogen shift reaction; means for eliminating any need for sootblowing; and designed to not require the use of an induced draft fan.

A hybrid stepping motor has a connector housing formed integrally with an insulator having an upper insulator and a lower insulator. The hybrid stepping motor includes a stator core and output terminals concentrically disposed outside the stator core. A wiring pattern serving as the output terminals has connector pins and land portions disposed eccentrically with respect to one another. The land portions are formed on an outer edge side of the wiring pattern. A surface, which is an uppermost surface of the wiring pattern, is located below a lowermost surface, in which jumper wires and lead wires pass, of the lower insulator. The lead wires are pulled out from a lower side, and are pulled out to guiding grooves.

An exhaust gas treatment apparatus for treating an exhaust gas discharged from an EUV (Extreme Ultra Violet) exposure equipment by combustion treatment to make the exhaust gas harmless is disclosed. The exhaust gas treatment apparatus includes a cylindrical combustion chamber configured to combust a processing gas containing hydrogen, and a processing gas nozzle and an oxidizing gas nozzle provided on the combustion chamber and configured to blow the processing gas and an oxidizing gas, respectively, in a tangential direction to an inner circumferential surface of the combustion chamber, wherein the processing gas nozzle and the oxidizing gas nozzle are positioned in the same plane perpendicular to an axis of the combustion chamber.

An exhaust gas treatment apparatus for treating an exhaust gas discharged from an EUV (Extreme Ultra Violet) exposure equipment by combustion treatment to make the exhaust gas harmless is disclosed. The exhaust gas treatment apparatus includes a cylindrical combustion chamber configured to combust a processing gas containing hydrogen, and a processing gas nozzle and an oxidizing gas nozzle provided on the combustion chamber and configured to blow the processing gas and an oxidizing gas, respectively, in a tangential direction to an inner circumferential surface of the combustion chamber, wherein the processing gas nozzle and the oxidizing gas nozzle are positioned in the same plane perpendicular to an axis of the combustion chamber.

Disclosed is an apparatus for combusting recyclable or waste material. The apparatus comprises a cylindrical combustion chamber. The chamber comprises a first inlet in a side wall. The first inlet is in communication with a blower and an ignition means. The chamber also comprises a second inlet in a first end wall or a side wall. The second inlet is in communication with a source of recyclable or waste material. The chamber also comprises an outlet in a second end wall on a central axis of the chamber. The longitudinal axis of the first inlet is offset from the central axis of the chamber. In use, the blower forces the recyclable or waste material to circulate around the inside of the chamber.

Disclosed is an apparatus for combusting recyclable or waste material. The apparatus comprises a cylindrical combustion chamber. The chamber comprises a first inlet in a side wall. The first inlet is in communication with a blower and an ignition means. The chamber also comprises a second inlet in a first end wall or a side wall. The second inlet is in communication with a source of recyclable or waste material. The chamber also comprises an outlet in a second end wall on a central axis of the chamber. The longitudinal axis of the first inlet is offset from the central axis of the chamber. In use, the blower forces the recyclable or waste material to circulate around the inside of the chamber.

A combustion-type exhaust gas treatment apparatus has a combustion treatment chamber for treating exhaust gas by combusting and decomposing the exhaust gas, a main burner for forming a flame in the combustion treatment chamber by supplying a mixture gas produced by premixing a fuel gas and an oxidizing gas, and a scraper for scraping off solid matters adhering to an inner wall of the combustion treatment chamber. The mixture gas is adjusted within combustion range and supplied to the main burner during treatment for treating the exhaust gas by combusting and decomposing the exhaust gas when the scraper is not in operation, and the mixture gas is adjusted outside combustion range and supplied to the main burner during treatment for treating the exhaust gas by combusting and decomposing the exhaust gas when the scraper is in scraping operation.

A combustion-type exhaust gas treatment apparatus has a combustion treatment chamber for treating exhaust gas by combusting and decomposing the exhaust gas, a main burner for forming a flame in the combustion treatment chamber by supplying a mixture gas produced by premixing a fuel gas and an oxidizing gas, and a scraper for scraping off solid matters adhering to an inner wall of the combustion treatment chamber. The mixture gas is adjusted within combustion range and supplied to the main burner during treatment for treating the exhaust gas by combusting and decomposing the exhaust gas when the scraper is not in operation, and the mixture gas is adjusted outside combustion range and supplied to the main burner during treatment for treating the exhaust gas by combusting and decomposing the exhaust gas when the scraper is in scraping operation.

Example apparatus and methods providing for the improved chemical conversion of the combustible components of a gaseous medium are disclosed. In some examples, the apparatus includes a guiding body that guides the flow of the gaseous medium within a reaction chamber of the apparatus. In some examples, the guiding body of the disclosed apparatus is configured to stabilize a residence period of the gaseous medium in the reaction chamber. In some examples, the guiding body results in a flow path of the gaseous medium within the reaction chamber being optimized and/or maximized, and/or results in a short circuit flow of the gaseous medium in the reaction chamber being suppressed. In some disclosed examples, the guiding body causes at least a portion of the flow path of the gaseous medium within the reaction chamber to take the form of a cyclone flow.

Example apparatus and methods providing for the improved chemical conversion of the combustible components of a gaseous medium are disclosed. In some examples, the apparatus includes a guiding body that guides the flow of the gaseous medium within a reaction chamber of the apparatus. In some examples, the guiding body of the disclosed apparatus is configured to stabilize a residence period of the gaseous medium in the reaction chamber. In some examples, the guiding body results in a flow path of the gaseous medium within the reaction chamber being optimized and/or maximized, and/or results in a short circuit flow of the gaseous medium in the reaction chamber being suppressed. In some disclosed examples, the guiding body causes at least a portion of the flow path of the gaseous medium within the reaction chamber to take the form of a cyclone flow.