Abstract: A radiant tube includes a conduit; and one or more heat transfer promoters disposed in the conduit, wherein the heat transfer promoter includes a body part on a center side of the conduit, and protruding parts protruding from the body part toward an inner wall surface of the conduit, the protruding parts are on an outer periphery of the body part to be arranged in a circumferential direction of the conduit, the protruding parts includes first protruding parts having a distal end portion facing the inner wall surface across a gap ?L, and a second protruding part, the number of first protruding parts is greater than the number of second protruding parts, and a ratio (?L/Dt) of the gap ?L to an equivalent diameter Dt of a conduit portion is x %, where the heat transfer promoter is disposed, and formula (1) is satisfied: 0.3%<x<7%.

Abstract: A radiant tube burner, wherein an opening cross section of the tube is virtually divided into four areas with two straight lines as boundaries, the two straight lines being obtained by tilting a minor axis of the oval, which is a shape of the opening cross section, by ±45° with a center of the oval as a center, and a flow rate of primary combustion air injected from primary combustion air nozzles located in the areas containing the minor axis of the oval of the virtually divided four areas is lower than a flow rate of the primary combustion air injected from the primary combustion air nozzles located in the areas not containing the minor axis of the oval the four areas.

Abstract: To provide a method for operating a blast furnace with which the combustion efficiency of a solid fuel, such as pulverized coal, is improved, thereby making it possible to improve productivity and reduce CO2 emissions. Pulverized coal and LNG are blown from an upstream lance configured by a double tube, and oxygen is blown from a downstream lance on the downstream side in a hot air blast direction, so that oxygen used for preceding combustion of the LNG is supplied from the downstream lance, and the pulverized coal whose temperature has been increased by the combustion of the LNG is combusted along with the supplied oxygen.

Abstract: A method for operating a blast furnace includes blowing pulverized coal and oxygen from an upstream lance configured by a double tube. LNG is blown from a downstream lance on the downstream side in a hot air blast direction, oxygen is supplied from the upstream lance, and the pulverized coal whose temperature has been increased by the combustion of the LNG is combusted along with the supplied oxygen or oxygen in an air blast. With respect to a direction perpendicular to the hot air blast and a downstream direction of the hot air blast, a blowing direction of the LNG from the downstream lance with respect to the blast direction ranges from ?30° to +45°. A blast pipe circumferential direction angle at a blowing position of the LNG from the downstream lance with respect to where the upstream lance is inserted into a blast pipe ranges from 160° to 200°.

Abstract: To provide a method for operating a blast furnace with which the combustion efficiency of a solid fuel, such as pulverized coal, is improved, thereby making it possible to improve productivity and reduce CO2 emissions. Pulverized coal and LNG are blown from an upstream lance configured by a double tube, and oxygen is blown from a downstream lance on the downstream side in a hot air blast direction, so that oxygen used for preceding combustion of the LNG is supplied from the downstream lance, and the pulverized coal whose temperature has been increased by the combustion of the LNG is combusted along with the supplied oxygen.

Abstract: To provide a method for operating a blast furnace with which the combustion efficiency of a solid fuel, such as pulverized coal, is improved, thereby making it possible to improve productivity and reduce CO2 emissions. Pulverized coal and oxygen are blown from an upstream lance 4 configured by a double tube, and LNG is blown from a downstream lance 6 on the downstream side in a hot air blast direction, so that oxygen to be used for combustion of the LNG is supplied from the upstream lance 4, and the pulverized coal whose temperature has been increased by the combustion of the LNG is combusted along with the supplied oxygen or oxygen in an air blast.

Abstract: In a semiconductor device having a laminated metal layer in which a metal layer whose main component is aluminum and a metal layer whose main component is nickel are laminated on each other, the ratio (tAl/tNi) of the thickness (tAl) of the metal layer whose main component is aluminum to that (tNi) of the metal layer whose main component is nickel is controlled to 5 or larger, so that part of the metal layer whose main component is aluminum remains even if an Al—Ni intermetallic compound is formed.

Abstract: An electroluminescent display device with decreased voltage requirements comprises a substrate having a major surface, a first electrode over the major surface, a light-emitting film over the first electrode, and a second electrode over the light-emitting film. At least one insulating film is disposed in contact with a major surface of the light-emitting film, which insulating film has a columnar crystal structure oriented parallel to an electric field formed between the two electrodes.

Abstract: A method of making electroluminescence emitting films each containing sulfide such as Sr, Ca, etc. as a base material and a rare earth element such as Ce, Eu, Pr, etc. as an emitting center by sputtering method, so that the electroluminescence emitting film can produce with high luminance and with various emission light colors. In the method, an element such as Sr to be sulfidized for a base material is used as a target. A sputtering gas such as Argon to be supplied to a sputtering apparatus is mixed with an H.sub.2 S gas as a base material sulfur compound. A rare earth element compound such as tris-cyclopentadienyl-cerium for an emitting center is gasified by a gas generator while being heated under supply of a carrier gas such as Ar, so that the gasified rare earth element compound is added to the sputtering gas.

Abstract: An electroluminescent display device with decreased voltage requirements comprises:(a) a substrate having a major surface;(b) a first electrode disposed over the major surface of the substrate;(c) a first insulating film disposed over the first electrode;(d) a light-emitting film disposed over the first insulating film;(e) a second insulating film disposed over the light-emitting film; and(f) a second electrode disposed over the second insulating film. The insulating films have a columnar structure oriented perpendicular to an electric field formed between the two electrodes, and either of the insulating films may be omitted.

Abstract: A method for manufacturing a thin-film EL device utilizes a Zn-Mn target that contains less Mn than the optimum Mn concentration on the basis of the finding that the light-emitting layer grown by the sputtering method contains more Mn than in the target. Manganese concentration on the target surface layer is controlled by changing the area ratio between ZnS and Mn exposed on the surface of the target. Manganese concentration on the target surface is controlled at preferably from 0.3 to 0.4 wt % when the target surface is sulfurized during sputtering and less than 0.1 wt % when the target surface is not sulfurized.

Abstract: A light-emitting layer is prepared by using sputtering gas containing H.sub.2 S gas at a concentration greater than 20% by volume, and by sputtering a target under the optimal electric discharge power corresponding to the concentration of H.sub.2 S gas. A light-emitting layer having good light-emitting characteristics is obtained under a high film-forming rate.

Abstract: A method of making electroluminescence emitting films each containing sulfide such as Sr, Ca, etc. as a base material and a rare earth element such as Ce, Eu, Pr, etc. as an emitting center by sputtering method, so that the electroluminescence emitting film can produce with high luminance and with various emission light colors. In the method, an element such as Sr to be sulfidized for a base material is used as a target. A sputtering gas such as Argon to be supplied to a sputtering apparatus is mixed with an H.sub.2 S gas as a base material sulfur compound. A rare earth element compound such as tris-cyclopentadienyl-cerium for an emitting center is gasified by a gas generator while being heated under supply of a carrier gas such as Ar, so that the gasified rare earth element compound is added to the sputtering gas.

Abstract: The present invention reduces weak points in the insulation films of electro-luminescence (EL) panels by constructing, at least the lower part of the insulating film, as a coated film comprising an insulator in film form created by coating a fluidic material in an EL indicating panel which includes a light emitting film disposed between a lower electrode film and an upper electrode film, and insulation films disposed in a way that will make contact with the light emitting film; and further by forming the contours of the light emitting film parts larger than the area in which the lower and upper electrode films intersect with each other in an EL indicating panel in which the light emitting film is divided into many light emitting film parts.

Abstract: During manufacture of electroluminescent elements, layers of material are deposited upon a substrate as it is moving in a vacuum chamber beneath masks that shield the terminal regions of transparent electrodes formed upon the substrate. The masks are arranged so as to not contact the substrate, and are placed between the layer-forming material source. First insulation films, the light-emitting layers, or the second insulation films, or combinations thereof may be deposited using the method.

Abstract: A liquid crystal display of the active matrix type includes a plurality of row electrodes orthogonal with a row of column electrodes and between each crosspoint is included a series arrangement of a liquid crystal element and a non-linear resistance provided by a parallel pair of oppositely poled diodes. Each of the diodes is constructed to have its photosensitive layer shielded from ambient light by its two electrodes, one of which is larger in cross-section than the light-sensitive layer and the other of which wraps around the edges of the layer.