Proposed is a method for producing a sintered ore with which it is possible to prevent yield reduction when using a carbon material having a low combustion start temperature. A method for producing a sintered ore that creates a granulated raw material for sintering by granulating a blended sintering raw material containing a carbon material as a solid fuel and sinters the granulated raw material for sintering to obtain a sintered ore, wherein the carbon material is a blend of two or more types of carbon material and is sintered using a blend having a weight average of the sintering start temperature of 550°C or more. Preferably, one with a sintering start temperature of less than 550°C is used as part of the two or more types of carbon materials.
This defect occurrence factor estimation device comprises: a defect occurrence depth calculation means for calculating a depth position, in a slab stage, of a surface defect in a product; a defect occurrence rate calculation means for calculating a defect occurrence rate for each slab depth; an inclusion adhesion rate calculation means for calculating an inclusion adhesion rate for each distance from a solidification start position during slab molding, on the basis of the defect occurrence rate for each slab depth; and a defect occurrence factor estimation means for estimating a defect occurrence factor, by selecting a portion of production conditions by using an estimation model that is trained in advance and that receives the production conditions of the product as input data and outputs the inclusion adhesion rate as output data, and estimating an inclusion adhesion rate in the case where the selected production conditions are changed stepwise.
A press forming analysis method according to the present invention includes: a die model creation step (S1) for creating a die model having a virtual thickness using two-dimensional elements, and setting the boundary conditions of the two-dimensional elements so that the parts of the die model that correspond to the ribs of the real die are rigid and the parts that do not correspond to the ribs are non-rigid; and a press forming load acquisition step (S3) for performing press forming analysis using the die model created in the die model creation step (S1) to acquire the press forming load.
G06F 30/23 - Optimisation, vérification ou simulation de l’objet conçu utilisant les méthodes des éléments finis [MEF] ou les méthodes à différences finies [MDF]
B21D 22/00 - Mise en forme sans coupage, par estampage, repoussage ou emboutissage
A projection polishing system comprises: a shape measurement device (3) that measures a three-dimensional shape and orientation of an object material; a projection detection device (4) that detects a projection that is present on a surface of the object material and recognizes the position and shape of the projection; a polishing device (7) provided with a polishing tool for polishing the projection; and a polishing tool control device (5) that calculates a trajectory for movement of the polishing tool on the basis of the measured three-dimensional shape and orientation of the object material, and the detected position and shape of the projection, and controls the polishing device so that the polishing tool moves along the trajectory while changing the angle of contact of the polishing tool with the projection.
B24B 49/12 - Appareillage de mesure ou de calibrage pour la commande du mouvement d'avance de l'outil de meulage ou de la pièce à meuler; Agencements de l'appareillage d'indication ou de mesure, p.ex. pour indiquer le début de l'opération de meulage impliquant des dispositifs optiques
B24B 27/00 - Autres machines ou dispositifs à meuler
B24B 49/16 - Appareillage de mesure ou de calibrage pour la commande du mouvement d'avance de l'outil de meulage ou de la pièce à meuler; Agencements de l'appareillage d'indication ou de mesure, p.ex. pour indiquer le début de l'opération de meulage tenant compte de la pression de travail
B25J 13/08 - Commandes pour manipulateurs au moyens de dispositifs sensibles, p.ex. à la vue ou au toucher
5.
NONORIENTED ELECTROMAGNETIC STEEL SHEET AND METHOD FOR MANUFACTURING SAME
Provided is a nonoriented electromagnetic steel sheet that achieves both fine magnetic properties and punch-out workability. Further, proposed is a method for manufacturing the nonoriented electromagnetic steel sheet. This nonoriented electromagnetic steel sheet has a component composition containing, in mass%, not more than 0.0050% of C, 2.0-5.0% of Si, 0.2-1.8% of Mn, not more than 0.020% of P, not more than 0.0050% of S, 0.25-2.00% of Al, more than 0.0030% but not more than 0.0150% of N, not more than 0.0050% of O, and 0.01-0.10% of one of or the total of the two of Sn and Sb, the remaining portion being Fe and unavoidable impurities. The number of AlN particles having a particle size not less than 0.8 μm existing in a sheet thickness cross section of the steel sheet in the rolling direction is 10 particles or more per 1 mm2. In this method for manufacturing a nonoriented electromagnetic steel sheet, the heating of a slab is performed using a heat initiation temperature of 300°C or higher and a heating temperature of 1100-1300°C. The annealing temperature of a hot-rolled sheet is set to 800-950°C and the annealing temperature for the finish annealing is set to 850-1050°C.
C21D 8/12 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication d'objets à propriétés électromagnétiques particulières
Provided is a method for evaluating delayed fracture properties of a metal material, wherein delayed fracture properties caused by hydrogen penetrating into the interior of the metal material due to atmospheric corrosion can be accurately evaluated and delayed fracture properties in actual usage environments can be simulated. In this method for evaluating delayed fracture properties of a metal material, a step comprising the following steps (A) and (B) is performed at least once. Step (A): a step including a chloride deposition step (a1) for depositing chlorides on the metal material in an atmosphere having a relative humidity Ha1 of 80% or higher and a temperature Ta1 of 60°C or lower. Step (B): a step in which a cycle having a predetermined drying step (b1), a predetermined wetting step (b2), a predetermined transition step (b3), and a predetermined transition step (b4) is performed at least once.
G01N 17/00 - Recherche de la résistance des matériaux aux intempéries, à la corrosion ou à la lumière
7.
METHOD FOR IDENTIFYING PORTION CAUSING INCREASE IN FORMING LOAD, METHOD FOR MANUFACTURING PRESS FORMED PART, DEVICE FOR IDENTIFYING PORTION CAUSING INCREASE IN FORMING LOAD, AND PROGRAM FOR IDENTIFYING PORTION CAUSING INCREASE IN FORMING LOAD
The method for identifying a portion causing an increase in a forming load according to the present invention comprises: step S1 for setting an evaluation region in a press-forming die model 15; step S3 for calculating the forming load distribution of the press-forming die model 15; step S5 for calculating a load evaluation value for each evaluation region; step S7 for changing the deformation resistance of one evaluation region in the press-forming die model, and calculating the load evaluation value of the evaluation region in which the deformation resistance has been changed; and step S9 for identifying an evaluation region in which the load evaluation value varies before and after the deformation resistance change of the press-forming die model, and identifying the portion of a press formed part 1 corresponding to the identified evaluation region as a portion that causes an increase in the forming load.
This method for manufacturing a press-molded article is for manufacturing a press-molded article that includes at least a top plate section, a vertical wall section, and a ridge section that is a portion connecting the top plate section and the vertical wall section. The method comprises: a first molding step in which a metal plate blank is press-molded into an intermediate molded article that includes an intermediate top plate section, an intermediate vertical wall section, and an intermediate ridge section connecting the intermediate top plate section and the intermediate vertical wall section, and that includes, in one or a plurality of locations in the intermediate top plate section including the intermediate ridge section, a protruding section which is higher than the reference height of the top plate surface; and a second molding step in which the intermediate molded article is press-molded into a press-molded article.
A residual stress distribution calculation method according to the present invention is used to calculate a distribution of residual stress occurring in a metal plate that has been subjected to plastic deformation, and includes: a process (S10) for acquiring a surface deformation history of a deformed part 33 of the metal plate 31 in the course of the deformation causing the plastic deformation of the metal plate 31, and acquiring a strain history and a spin history occurring in the deformed part 33, from the acquired surface deformation history; a process (S20) for successively updating a stress in a material coordinate system at each measurement point set in the deformed part 33 of the metal plate 31, from the start of deformation to the end of deformation in the course of the deformation; and a process (S30) for calculating the residual stress distribution by converting the stress in the material coordinate system at each measurement point at the end of deformation into a stress in a global coordinate system.
Provided is an oriented electromagnetic steel sheet that can effectively inhibit generation of a magnetizing inrush current when used as a material of an iron core for a transformer. In the oriented electromagnetic steel sheet having been subjected to magnetic domain refinement, magnetization changing with a 50 Hz sine wave is generated in a rolling direction of the oriented electromagnetic steel sheet, a power source is shut down when the magnetization reaches 1.50 T, and a residual magnetic flux density Br, which is a magnetic flux density 0.1 s after the shutdown, is 1.00 T or less.
C21D 8/12 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication d'objets à propriétés électromagnétiques particulières
This surface defect detecting method for optically detecting a surface defect of a strip-shaped body includes an image acquisition step for detecting reflected light from the strip-shaped body, obtained by illuminating a surface of the strip-shaped body, and imaging the surface of the strip-shaped body while scanning relative thereto, to acquire a plurality of images including the surface of the strip-shaped body, an average image calculation step for calculating an average image of the plurality of acquired images, an image correction step for obtaining a corrected image by performing shading correction of each of the plurality of acquired images using the average image, and a defect detection step for detecting a surface defect of the strip-shaped body on the basis of the corrected image, wherein the average image calculation step includes recognizing an inspection target region, of the image, in which the strip-shaped body is present, in each of the plurality of images, and arranging that only pixels in the inspection target region contribute to the average image.
G01N 21/892 - Recherche de la présence de criques, de défauts ou de souillures dans un matériau mobile, p.ex. du papier, des textiles caractérisée par la crique, le défaut ou la caractéristique de l'objet examiné
A gutter management system according to the present invention comprises: a measurement device that is arranged above a gutter facing the gutter and measures the inner surface shape of the gutter; and a determination device that determines the wear state of the gutter using at least the measured data of the inner surface shape and a prescribed determination model.
Provided is a welded joint which excels in normal temperature toughness and the matrixes of which are relatively thin and high-strength steel sheets. The thickness of each of the matrix steel sheets is 0.8-10 mm. Among the matrix steel sheets, at least one of the matrix steel sheets has: a steel structure in which the total surface area proportion of martensite and bainite is greater than 50%; and a tensile strength of at least 980 MPa. The oxygen amount and the Vicker's hardness of the welded metal of a weld satisfy a prescribed relationship.
Provided are: continuous annealing equipment capable of swiftly responding to a fluctuation in material characteristics and minimizing a fluctuation in mechanical characteristics of a product; a continuous annealing method; a cold-rolled steel sheet manufacturing method; and a plated steel sheet manufacturing method. The continuous annealing equipment is for a steel sheet and is provided with a heating zone (6), a soaking zone (7), and a cooling zone (8) in this order, said continuous annealing equipment comprising: at least one induction heating device (9) which is provided between the soaking zone (7) and the cooling zone (8); and a measurement device (transformation ratio meter 10) which measures at least one steel sheet phase fraction at or after an outlet of the induction heating device (9).
Provided is a resistance spot welding method suited for manufacturing a welded joint that exhibits superior delayed fracture resistance. In the resistance spot welding method, two or more superimposed steel plates are sandwiched between a pair of welding electrodes and energized while being pressurized to form a nugget on the superimposed surfaces of the steel plates, and the steel plates are thereby bonded, the resistance spot welding method being characterized in that, after the bonding, a steady magnetic field is applied to a weld mark generated on the surface of the bonded steel plates through the bonding such that the magnetic flux density becomes 0.1-15 T at an angle θ, formed by a surface normal direction of the bonded steel plates and the application direction of the steady magnetic field, exceeding 0°.
22) and chlorine ions (Cl-25050 particle diameter, which is the median diameter located at the 50th percentile of the mass cumulative distribution, of 10-200 μm, and an apparent density of 3.5-5.0 mg/m3.
Provided are: a steel sheet having high strength, excellent in terms of ductility and hole expansibility, and having highly stable mechanical properties along the sheet width direction; a member; and methods for producing the steel sheet and the member. The steel sheet has a composition containing, in terms of mass%, 0.08-0.35% C, 0.4-3.0% Si, 1.5-3.5% Mn, up to 0.02% P, up to 0.01% S, up to 1.0% sol. Al, and up to 0.015% N, the remainder comprising Fe and unavoidable impurities, and has a steel structure in which the areal content of ferrite is 5% or less (including 0%), the total areal content of tempered martensite and lower bainite is 70% or higher, the volume content of retained austenite is 5-15%, and the areal content of fresh martensite is 10% or less (including 0%). The steel sheet has a standard deviation of sheet-width-direction total elongation (EL) of 0.9% or less.
Provided are: a steel sheet having high strength, excellent in terms of ductility and hole expansibility, and having highly stable mechanical properties along the longitudinal direction of the coil; and a method for producing the steel sheet. The steel sheet has a composition containing, in terms of mass%, 0.08-0.35% C, 0.4-3.0% Si, 1.5-3.5% Mn, up to 0.02% P, up to 0.01% S, up to 1.0% sol. Al, and up to 0.015% N, the remainder comprising Fe and unavoidable impurities, and has a steel structure in which the areal content of ferrite is 5% or less (including 0%), the total areal content of tempered martensite and lower bainite is 70% or higher, the volume content of retained austenite is 5-15%, and the areal content of fresh martensite is 10% or less (including 0%). The steel sheet has a standard deviation of coil-longitudinal-direction tensile strength (TS) of 30 MPa or less.
This calculation method is used for manufacturing or using a product, and comprises: a step (S2) for calculating a feature amount by using one or more input values selected from a predetermined input value group and one or more first models; and a step (S3) for calculating a deviation amount which is a deviation from each of the first models with respect to the predetermined input value from the input value group, by using one or more input values selected from the input value group and one or more second models. The second models and the first models are machine learning models generated by using one or more teacher data items each selected from a predetermined teacher data group.
STEEL TUBE EXHIBITING EXCELLENT FATIGUE CHARACTERISTICS AGAINST HYDROGEN AND PRODUCTION METHOD THEREFOR, AND STEEL MATERIAL AND PRODUCTION METHOD THEREFOR
The purpose of the present invention is to provide a steel tube and a production method therefor, the steel tube being suitable for steel structures used in high pressure hydrogen gas environments, such as line pipes for 100% hydrogen gas or natural gas including hydrogen gas with a hydrogen partial pressure of 1 MPa or more (natural gas is gas having a hydrocarbon such as methane or ethane as the main component), and also exhibiting excellent fatigue characteristics in a high pressure hydrogen gas environment; and to provide a steel material and a production method therefor. This steel tube exhibits excellent fatigue characteristics in hydrogen and has a specific component composition and a specific structure, a crack growth rate da/dN of 1.0×10-6m·cycle-1 or less when the stress intensity factor range in hydrogen of 1 MPa or more is 20 MPa√m.
B21B 17/00 - Laminage des tubes par des cylindres dont les axes sont pratiquement perpendiculaires à l'axe des pièces travaillées, p.ex. laminage "axial"
C21D 8/02 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de produits plats ou de bandes
C21D 8/10 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de corps tubulaires
C21D 9/08 - Traitement thermique, p.ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliers; Fours à cet effet pour corps tubulaires ou tuyaux
C22C 38/60 - Alliages ferreux, p.ex. aciers alliés contenant du plomb, du sélénium, du tellure, de l'antimoine, ou plus de 0,04% en poids de soufre
B22D 11/00 - Coulée continue des métaux, c. à d. en longueur indéfinie
22.
LINE PIPE STEEL MATERIAL HAVING EXCELLENT HYDROGEN EMBRITTLEMENT RESISTANCE, MANUFACTURING METHOD THEREFOR, LINE PIPE STEEL TUBE HAVING EXCELLENT HYDROGEN EMBRITTLEMENT RESISTANCE, AND MANUFACTURING METHOD THEREFOR
The purpose of the present invention is to provide a line pipe steel material that is suitable for use in a steel structure used in a high-pressure hydrogen gas environment, such as a line pipe for 100% hydrogen gas or a natural gas (natural gas being a gas having a hydrocarbon such as methane or ethane as a primary component) containing hydrogen having a hydrogen partial pressure of at least 1 MPa, and that has high strength and excellent hydrogen embrittlement resistance in a high-pressure hydrogen gas environment. The purpose of the present invention is also to provide a manufacturing method therefor, as well as a line pipe steel tube and a manufacturing method therefor. Provided is a line pipe steel material having excellent hydrogen embrittlement resistance that has a specific chemical composition and a specific structure, wherein the fatigue limit stress in hydrogen that is at 1 MPa or higher is at least 200 MPa, and the ratio of the fatigue limit stress in hydrogen that is at 1 MPa or higher to the fatigue limit stress in an inert gas environment is at least 0.90.
C21D 8/02 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de produits plats ou de bandes
C21D 8/10 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de corps tubulaires
C22C 38/60 - Alliages ferreux, p.ex. aciers alliés contenant du plomb, du sélénium, du tellure, de l'antimoine, ou plus de 0,04% en poids de soufre
The present invention relates to a method for manufacturing a press-formed product 1 that is curved in top view and has at least a top plate part 3 and a vertical wall part 5 continuous from the top plate part 3, the method reducing an error from a target shape due to springback of the press-formed product 1 after being released from a die. The method comprises: a forming step for performing press-forming using a forming die provided with a first prospective angle that introduces a torsion (reverse torsion) due to springback in a reverse direction to a torsion (normal torsion) that would be caused by springback if the press-forming were performed in a single step without providing the die with the prospective angle; and a restriking step for press-forming a formed product 17 formed in the forming step, using a restrike die provided with a second prospective angle for reducing the reverse torsion.
Provided is a casting mold that enables a temperature detection interval to be shortened without having to execute specialized processing of a slit groove. A casting mold 12 is used in continuous casting of steel. The casting mold 12 includes a plurality of casting-mold copper sheets. At least one of the plurality of casting-mold copper sheets includes optical fiber-type temperature sensors 50 embedded in locations in at least two tiers which differ in the casting direction and embedded so as to extend in the width direction of the casting-mold copper sheet.
Provided is a weld joint having relatively thin high-strength steel plates as a base material and excellent room-temperature fracture toughness. In the present invention, the plate thickness of the base-material steel plates is 0.8-10 mm, at least one of the base-material steel plates has a tensile strength of at least 980 MPa and a steel structure in which the total area fraction of martensite and bainite is more than 50%, and the amount of oxygen in the welded metal in welded sections and the total area fraction of the martensite and bainite in the welded metal satisfy a prescribed relationship.
In order to efficiently confirm joining of threaded joints on pipes, the present invention provides a clearance measuring method, for a pair of threaded joints having a male joint and a female joint corresponding to the male joint, for measuring the clearance between the thread of the male joint and the thread of the female joint. The clearance measuring method includes: a joining completed state setting step for setting a joining completed state in which joining of the male joint and the female joint is completed, on the basis of data on thread shapes of the male joint and the female joint; a clearance measuring step for measuring, in the joining completed state, the clearance between the thread of the male joint and the thread of the female joint corresponding to the thread of the male joint; and a rotated state setting step for setting a state in which rotation is made by a predetermined angle in such a direction as to enjoining the joining, if the joining of the male joint and the female joint is not an unjoined state after the clearance measuring step. The steps from the clearance measuring step to the rotated state setting step are repeatedly executed until the joining is unjoined.
G01B 21/16 - Dispositions pour la mesure ou leurs détails, où la technique de mesure n'est pas couverte par les autres groupes de la présente sous-classe, est non spécifiée ou est non significative pour mesurer la distance ou le jeu entre des objets espacés
F16L 15/00 - Raccords avec filetage; Formes des filetages pour ces raccords
G01B 21/20 - Dispositions pour la mesure ou leurs détails, où la technique de mesure n'est pas couverte par les autres groupes de la présente sous-classe, est non spécifiée ou est non significative pour mesurer des contours ou des courbes, p.ex. pour déterminer un profil
27.
CONTINUOUS ANNEALING FACILITY, CONTINUOUS ANNEALING METHOD, METHOD FOR PRODUCING COLD-ROLLED STEEL SHEET, AND METHOD FOR PRODUCING PLATED STEEL SHEET
Provided are: a continuous annealing facility in which a steel sheet phase fraction under a high-temperature condition is predicted with high accuracy and the fluctuations in the predicted phase fraction is rapidly reflected in an annealing condition; a continuous annealing method; a method for producing a cold-rolled steel sheet; and a method for producing a plated steel sheet. The continuous annealing facility is a continuous annealing facility for steel sheets, and is provided with a heating zone (6), a soaking zone (7) and a cooling zone (8) in this order, in which at least one induction heating device (9) and a control device that presets the conditions for operation of the induction heating device on the basis of the phase fraction during annealing which has been acquired by a phase fraction prediction model are provided between the soaking zone (7) and the cooling zone (8).
Provided are a high aging-efficiency maraging steel and a method for producing the same. The maraging steel comprises: a component composition that includes, in mass%, C at 0.02% or less, Si at 0.1% or less, Mn at 0.1% or less, P at 0.01% or less, S at 0.01% or less, N at 0.01% or less, Ni at 12-25%, Co at 5-12%, Mo at 2-7%, Ti at 0.5-1.5%, and Al at 0.01-0.1%, with the balance made up of iron and inevitable impurities; and a steel structure having a transformed martensitic phase at an area ratio of 90% or more.
B22F 10/28 - Fusion sur lit de poudre, p.ex. fusion sélective par laser [FSL] ou fusion par faisceau d’électrons [EBM]
C21D 6/00 - Traitement thermique des alliages ferreux
C21D 9/00 - Traitement thermique, p.ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliers; Fours à cet effet
C21D 9/46 - Traitement thermique, p.ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliers; Fours à cet effet pour tôles
C22C 38/14 - Alliages ferreux, p.ex. aciers alliés contenant du titane ou du zirconium
29.
STEEL PIPE FOR LINE PIPE HAVING EXCELLENT HYDROGEN EMBRITTLEMENT RESISTANCE CHARACTERISTICS, METHOD OF MANUFACTURING SAME, STEEL MATERIAL FOR LINE PIPE, AND METHOD OF MANUFACTURING SAME
The purpose of the present invention is to provide a steel pipe for a line pipe and a method of manufacturing the same, and a steel material for a line pipe and a method of manufacturing the same, the steel pipe for a line pipe being suitable for steel structures that are used in a high-pressure hydrogen gas environment, such as a line pipe for 100% hydrogen gas or natural gas containing hydrogen with a hydrogen partial pressure of more than or equal to 1 MPa (natural gas is a gas having hydrocarbon, such as methane or ethane, as a major component), the steel pipe for a line pipe having high strength and excellent hydrogen embrittlement resistance characteristics in a high-pressure hydrogen gas environment. The steel pipe for a line pipe is characterized by having excellent hydrogen embrittlement resistance characteristics and a specific component composition and a specific structure, wherein the fatigue limit stress in hydrogen of more than or equal to 1 MPa is more than or equal to 200 MPa, and the value of the fatigue limit stress in hydrogen of more than or equal to 1 MPa over the fatigue limit stress in an inert gas environment is more than or equal to 0.90.
B21B 17/00 - Laminage des tubes par des cylindres dont les axes sont pratiquement perpendiculaires à l'axe des pièces travaillées, p.ex. laminage "axial"
C21D 8/00 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique
C21D 8/10 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de corps tubulaires
C21D 9/08 - Traitement thermique, p.ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliers; Fours à cet effet pour corps tubulaires ou tuyaux
The purpose of the present invention is to provide: a steel material which has excellent fatigue characteristics in a high-pressure hydrogen gas environment and is suitable for use in a steel structure, which is used in the high-pressure hydrogen gas environment, such as a line pipe for 100% hydrogen gas or natural gas (which is gas mainly composed of hydrocarbons such as methane and ethane) that contains hydrogen having a hydrogen partial pressure of 1 MPa or more; a method for producing the steel material; a steel pipe; and a method for manufacturing the steel pipe. The steel material has a specific component composition and a specific structure, and has excellent fatigue characteristics in hydrogen, wherein the crack growth rate da/dN at a stress intensity factor (= 20 MPa√m) in hydrogen of at least 1 MPa is at most 1.0×10-6m·cycle-1.
C21D 8/02 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de produits plats ou de bandes
C21D 8/10 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de corps tubulaires
C22C 38/60 - Alliages ferreux, p.ex. aciers alliés contenant du plomb, du sélénium, du tellure, de l'antimoine, ou plus de 0,04% en poids de soufre
31.
STEEL MATERIAL FOR LINE PIPES AND PRODUCTION METHOD THEREFOR, AND STEEL TUBE FOR LINE PIPES AND PRODUCTION METHOD THEREFOR
The purpose of the present invention is to provide: a steel material for line pipes and a production method therefor, the steel material for line pipes being suitable for steel structures used in high pressure hydrogen gas environments, such as line pipes for 100% hydrogen gas or natural gas including hydrogen gas with a hydrogen partial pressure of 1 MPa or more (natural gas is gas having a hydrocarbon such as methane or ethane as the main component), and having high strength and an excellent hydrogen embrittlement resistant property against a high pressure hydrogen gas environments; and a steel tube for line pipes and a production method therefor. The steel material for line pipes has a specific chemical composition, and has an area fraction of retained austenite of 0-3%, a hydrogen diffusion coefficient at room temperature of 1.5×10-10m2/s or more, and a hydrogen solid solubility of 0.05 mass ppm/√P or less.
C21D 8/02 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de produits plats ou de bandes
C21D 8/10 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de corps tubulaires
C22C 38/60 - Alliages ferreux, p.ex. aciers alliés contenant du plomb, du sélénium, du tellure, de l'antimoine, ou plus de 0,04% en poids de soufre
32.
HIGH-STRENGTH LINE PIPE STEEL MATERIAL HAVING EXCELLENT FRACTURE TOUGHNESS IN HYDROGEN, METHOD FOR MANUFACTURING SAME, STEEL TUBE FOR HIGH-STRENGTH LINE PIPES, AND METHOD FOR MANUFACTURING SAME
C21D 8/02 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de produits plats ou de bandes
C21D 8/10 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de corps tubulaires
C22C 38/60 - Alliages ferreux, p.ex. aciers alliés contenant du plomb, du sélénium, du tellure, de l'antimoine, ou plus de 0,04% en poids de soufre
33.
WARPED METAL BELT SHAPE ESTIMATION METHOD, METAL BELT ACCEPTANCE DETERMINATION METHOD, METAL BELT MANUFACTURING METHOD, AND WARPED METAL BELT SHAPE ESTIMATION FACILITY
Provided are a warped metal belt shape estimation method, a metal belt acceptance determination method, and a warped metal belt shape estimation device which can estimate a warped shape in a plate width direction in a state where the tension is unloaded, from the warped shape in the plate width direction in a state where the tension in a longitudinal direction is loaded onto the warped shape in the plate width direction generated by rapid cooling of the metal belt. This warped metal belt shape estimation method estimates the warped shape in the plate width direction of the metal belt in an un-tensioned state where the tension is unloaded, from the shape in the plate width direction of the metal belt in a tensioned state where the tension in the longitudinal direction is loaded, wherein the method comprises: a plate width direction shape measurement step for measuring a plate width direction shape distribution of the metal belt in the tensioned state; an approximate curve calculation step for calculating the plate width direction shape distribution, which is measured in the plate width direction shape measurement step, as an approximate curve approximated by a quadratic curve or a circular arc; and a warped shape estimation step for using the plate width direction shape distribution and the approximate curve to estimate the warped shape in the plate width direction of the metal belt in the unloaded state.
A press forming fracture determination method according to the present invention involves: (P1) acquiring a metal plate forming limit expressed as a relationship between a maximum principal strain and a minimum principal strain of a test piece 100 stretch-formed using various degrees of bending deformation, and the degree of bending deformation; and (P3) determining the presence or absence of fracture generation in the press formed part on the basis of the acquired metal plate forming limit, the maximum principal strain and the minimum principal strain calculated for the press formed part, and the degree of bending deformation.
G06F 30/20 - Optimisation, vérification ou simulation de l’objet conçu
G06F 30/23 - Optimisation, vérification ou simulation de l’objet conçu utilisant les méthodes des éléments finis [MEF] ou les méthodes à différences finies [MDF]
Provided are: a water content measurement method capable of reliably measuring a water content of a measured object, even when a layer thickness of the measured object fluctuates; a water content measurement device; and a manufacturing method for coke. The water content measurement method includes: a microwave measurement step of, when transmitted microwaves are transmitted to a measured object S by a microwave transmission unit 11 that moves relative to the measured object S, receiving, by using a microwave reception unit 12, the transmitted microwaves that have passed through the measured object S as received microwaves, and finding the attenuation thereof and the phase difference between the transmitted microwaves and the received microwaves; a bulk density calculation step of calculating an amount of the measured object S, a movement speed of the measured object S relative to the microwave transmission unit 11, and the bulk density of the measured object S on the basis of the layer thicknesses of the measured object S; and a water content calculation step of calculating a water content of the measured object S using the phase difference, the attenuation, and the bulk density measured by a microwave evaluation unit 13.
G01N 9/36 - Analyse des matériaux en mesurant le poids spécifique ou la densité, p.ex. détermination de la quantité d'humidité
G01N 22/00 - Recherche ou analyse des matériaux par l'utilisation de micro-ondes ou d'ondes radio, c. à d. d'ondes électromagnétiques d'une longueur d'onde d'un millimètre ou plus
38.
BULK DENSITY DETECTION METHOD AND DEVICE, WATER CONTENT CALCULATION METHOD AND DEVICE, AND METHOD FOR PRODUCING COKE
Provided are a bulk density detection method and device, a water content calculation method and device, and a method of producing coke that enable highly accurate detection of bulk density without needing to use a special device. This bulk density detection method is for emitting microwaves at an object and detecting the bulk density of the object, said method comprising: a microwave emission step for emitting emission microwaves of each of a plurality of wavelengths at the object; a microwave receiving step for receiving the emission microwaves, having been transmitted through the object, as reception microwaves for each of the plurality of wavelengths; an attenuation amount calculation step for calculating, for each of the plurality of wavelengths, an attenuation amount that is the difference in energy between the emission microwaves and the reception microwaves; a wavelength identification step for extracting a wavelength distribution of the attenuation amounts that is based on a predetermined regular wavelength distribution, with regard to the relationship between the calculated attenuation amounts and the wavelengths corresponding to the attenuation amounts, and also identifying, in the wavelength distribution, a predetermined representative wavelength included in the regular wavelength distribution; and a bulk density detection step for detecting the bulk density of the object on the basis of the identified representative wavelength.
G01N 22/00 - Recherche ou analyse des matériaux par l'utilisation de micro-ondes ou d'ondes radio, c. à d. d'ondes électromagnétiques d'une longueur d'onde d'un millimètre ou plus
C10B 57/04 - Autres procédés de carbonisation ou de cokéfaction; Caractéristiques générales des procédés de distillation destructive utilisant des charges de composition spéciale
G01N 9/24 - Recherche du poids spécifique ou de la densité des matériaux; Analyse des matériaux en déterminant le poids spécifique ou la densité en observant la propagation de l'onde ou de la radiation des particules à travers le matériau
Provided is a low-yield-ratio hot-rolled steel sheet having excellent strength and low-temperature toughness. The steel sheet has a predetermined component composition. The steel structure of the sheet thickness center part has a main phase, which is ferrite, and a second phase in which the total area ratio of pearlite and pseudopearlite is 6-25% and the area ratio of upper bainite is 5% or less. When a region surrounded by boundaries where the orientation difference between adjacent crystals is 15° or more is taken as a crystal grain, the average crystal grain size of the steel structure containing the main phase and the second phase in the sheet thickness center part is 10.0-30.0 μm, the area ratio of crystal grains having a crystal grain size within this average crystal grain size±5.0 μm is 35% or more, and the number of crystal grains in which the ratio (major axis)/(minor axis) of the major axis to the minor axis is 3.0 or more is 30/mm2 or fewer.
B21B 1/22 - Méthodes de laminage ou laminoirs pour la fabrication des produits semi-finis de section pleine ou de profilés; Séquence des opérations dans les trains de laminoirs; Installation d'une usine de laminage, p.ex. groupement de cages; Succession des passes ou des alternances de passes pour laminer des bandes ou des feuilles en longueurs indéfinies
B21C 37/08 - Fabrication de tubes à joints soudés ou brasés
B21C 37/15 - Fabrication de tubes de formes particulières; Fabrication de garnitures de tubes
C21D 8/02 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de produits plats ou de bandes
C22C 38/60 - Alliages ferreux, p.ex. aciers alliés contenant du plomb, du sélénium, du tellure, de l'antimoine, ou plus de 0,04% en poids de soufre
C21D 9/08 - Traitement thermique, p.ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliers; Fours à cet effet pour corps tubulaires ou tuyaux
C21D 9/50 - Traitement thermique, p.ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliers; Fours à cet effet pour joints de soudure
40.
METHOD FOR PRODUCING HOT METAL USING SOLID REDUCING FURNACE AND SUBMERGED ARC FURNACE
Provided is a method for producing a hot metal, whereby it becomes possible to achieve high energy efficiency in a melting step when reduced iron is produced from iron ore in a solid reducing furnace and then the reduced iron is melted in a SAF to produce a hot metal. The method for producing a hot metal according to the present invention comprises a step for producing first reduced iron from low-grade iron ore pellets, an optional step for producing second reduced iron from high-grade iron ore pellets, an optional step for producing third reduced iron from lump ore, an optional step for preparing fourth reduced iron, and a step for melting the first reduced iron to fourth reduced iron in a SAF and adding a slag-making material to the resultant product for basicity adjustment purpose, in which the following formula is satisfied. 150.0 ≤ S1×W1+S2×W2+S3 ≤ 400.0, in which S1: the slug ratio of the first reduced iron, W1: the blend ratio of the first reduced iron, S2: the average slug ratio of the second reduced iron to fourth reduced iron, W2: the total blend ratio of the second reduced iron to fourth reduced iron, and S3: the amount of the slag-making material to be added in the melting step.
Provided is a method that is for controlling a warp shape of a metallic band, and that makes it possible to reduce the height of warp in a metallic band on the downstream side of a temper rolling mill by performing control on a warp shape having a W-shaped cross section in the plate width direction or on a warp shape that is approximated by a high-dimensional function. The method for controlling the warp shape of a metallic band is for use in a metallic band manufacturing facility comprising a temper rolling mill 31 for correcting the shape of a metallic band 1 conveyed continuously and a warp shape measurement device for measuring the warp shape of the metallic band, and controls an exit-side warp which is the warp shape of the metallic band 1 on the downstream side of the temper rolling mill 31. The method involves: calculating an approximate curve for the warp shape of the metallic band 1 using an approximation method selected from among parabola approximation, circular arc approximation, and envelope approximation; and setting, on the basis of the calculated approximate curve, operational parameters, for the temper rolling mill 31, capable of reducing the warp height in the exit-side warp shape.
B21B 37/28 - Commande de la planéité ou du profil pendant le laminage de bandes, de feuilles ou de tôles
B21B 1/22 - Méthodes de laminage ou laminoirs pour la fabrication des produits semi-finis de section pleine ou de profilés; Séquence des opérations dans les trains de laminoirs; Installation d'une usine de laminage, p.ex. groupement de cages; Succession des passes ou des alternances de passes pour laminer des bandes ou des feuilles en longueurs indéfinies
B21B 37/38 - Commande de la planéité ou du profil pendant le laminage de bandes, de feuilles ou de tôles utilisant la flexion du cylindre
B21B 38/02 - Procédés ou dispositifs de mesure spécialement adaptés aux laminoirs, p.ex. détection de la position, inspection du produit pour mesurer la planéité ou le profil des bandes
B21C 51/00 - Dispositifs de mesure, de calibrage, d'indication, de comptage ou de marquage, spécialement conçus pour être utilisés dans la production ou la manipulation des matériaux concernés par les sous-classes
METHOD OF PREDICTING FORM OF WARPING IN METAL STRIP, METHOD OF CONTROLLING FORM OF WARPING IN METAL STRIP, METHOD OF MANUFACTURING METAL STRIP, METHOD OF GENERATING WARPING-FORM PREDICTION MODEL, AND DEVICE FOR CONTROLLING FORM OF WARPING IN METAL STRIP
Provided, for metal-strip continuous-annealing lines that include a cooling zone where metal-strip cooling is carried out and a temper mill in which post-cooling metal-strip form rectification is carried out, is a method of predicting metal-strip warping form, in which the form of metal-strip warping on the entry-side is taken into consideration to enable quick prediction of the form of warping on the exit side. This method of predicting metal-strip warping form is for predicting an exit-side warping form, which is the form of warping in metal strip 1 along the downstream side of a temper mill 40 in a metal-strip continuous-annealing line that includes: heating equipment for heating metal strip; cooling equipment 30 for cooling metal strip 1 that has been heated in a heating zone; the temper mill 40 for rectifying the form of the metal strip 1 that has been cooled with the cooling equipment; and an entry-side warping form measuring device 16 for measuring, between the cooling equipment 30 and the temper mill 40, an entry-side warping form, which is the form of warping in the metal strip along the upstream side of the temper mill. The form of warping on the exit side is predicted on the basis of: the form of warping on the entry side; and at least one among parameters of operation of the temper mill 40.
B21B 37/28 - Commande de la planéité ou du profil pendant le laminage de bandes, de feuilles ou de tôles
B21B 1/22 - Méthodes de laminage ou laminoirs pour la fabrication des produits semi-finis de section pleine ou de profilés; Séquence des opérations dans les trains de laminoirs; Installation d'une usine de laminage, p.ex. groupement de cages; Succession des passes ou des alternances de passes pour laminer des bandes ou des feuilles en longueurs indéfinies
B21B 37/00 - Dispositifs ou procédés de commande spécialement adaptés aux laminoirs ou aux produits laminés
B21B 37/74 - Commande de la température, p.ex. en refroidissant ou en chauffant les cylindres ou le produit
B21B 38/02 - Procédés ou dispositifs de mesure spécialement adaptés aux laminoirs, p.ex. détection de la position, inspection du produit pour mesurer la planéité ou le profil des bandes
B21C 51/00 - Dispositifs de mesure, de calibrage, d'indication, de comptage ou de marquage, spécialement conçus pour être utilisés dans la production ou la manipulation des matériaux concernés par les sous-classes
C21D 9/52 - Traitement thermique, p.ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliers; Fours à cet effet pour bandes métalliques
The purpose of the present invention is to provide a welded member and a method for manufacturing the same. The present invention relates to a welded member in which a sheet set obtained by stacking two or more steel sheets is welded together through resistance spot welding, wherein: the average value of the shortest distance from the center of a welding point to the end surface of the steel sheet is 3.0 mm or greater; if there are a plurality of welding points, then the average distance between the centers of adjacent welding points is 6.0 mm or greater; at least one of the two or more steel sheets has a decarbonated layer on a steel-sheet obverse layer; and, on the steel sheet having the decarbonated layer, the thickness of the decarbonated layer between a base-material part and a welding-heat-affected part satisfies formula (1). (1): tw/tb < 1.0
The present invention provides a carbonaceous material which is used for the production of a sintered ore, and is capable of preventing troubles in the exhaust gas system caused by exhaust gas processing, the troubles including, for example, the generation of tar in pipes and the occurrence of white smoke in an electric dust collector. This carbonaceous material is a solid fuel for the production of a sintered ore, and has an electrical conductivity of 1.0 × 10-9S/m or more and a volatile content (VM) of 15% or less. In cases where this carbonaceous material is composed of a plurality of kinds of carbonaceous materials, 80% or more of the plurality of kinds of carbonaceous materials have an electrical conductivity of 1.0 × 10-9 S/m or more at 80°C to 200°C, and the weighted average of the volatile contents (VM) is 15% or less.
Provided is a method for recovering nickel, cobalt, and manganese from a compound including metal oxides of nickel, cobalt, and manganese in which the concentration of manganese in recovered materials is kept low while increasing the concentrations of nickel and cobalt. The method for recovering nickel, cobalt, and manganese includes: a mixing step in which a reducing agent and a compound containing metal oxides of nickel, metal oxides of cobalt, and metal oxides of manganese are mixed and a mixture is produced; and a heating step in which the mixture is heated to obtain a first product and a second product having a higher concentration of manganese than the first product. In the mixing step, one or more substances selected from among carbon reducing agents containing carbon as a component thereof, silicon reducing agents containing silicon as a component thereof, and aluminum reducing agents containing aluminum as a component thereof are used as the reducing agent, and the reducing agent is used in an amount satisfying a predetermined range.
C22B 3/06 - Extraction de composés métalliques par voie humide à partir de minerais ou de concentrés par lixiviation dans des solutions inorganiques acides
C22B 3/26 - Traitement ou purification de solutions, p.ex. de solutions obtenues par lixiviation par extraction liquide-liquide utilisant des composés organiques
H01M 10/54 - Récupération des parties utiles des accumulateurs usagés
49.
HIGH-STRENGTH NON-ORIENTED ELECTROMAGNETIC STEEL PLATE AND METHOD FOR MANUFACTURING SAME
When a steel slab containing, in mass%, 0.0050% or less of C, 2.0-5.0% of Si, 0.2-1.8% of Mn, 0.5-2.5% of Al, 0.001-0.100% of Mo, and 0.02-0.10% in total of Sn and Sb, the contents of Si, Al and Mn satisfying a predetermined relationship, is hot-rolled, hot roll-annealed, cold-rolled, and finish annealed to manufacture a non-oriented electromagnetic steel plate, the soaking temperature in the finish annealing is set to 500°C or higher and below a temperature T determined from the contents of Si, Al and Mn, the time to maintain the soaking temperature is set to 60 seconds or less, and the residence time at 500°C or higher is set to 100 seconds or less to yield a tensile strength of 700-950 MPa and a dislocation density at the center of the plate thickness of at least 1.2×1014m-2, thereby providing a non-oriented electromagnetic steel plate having high strength after finish annealing and having low core loss after strain relief annealing.
C21D 8/12 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication d'objets à propriétés électromagnétiques particulières
C21D 9/46 - Traitement thermique, p.ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliers; Fours à cet effet pour tôles
Provided are: a steel sheet and a member that have tensile strength of at least 780 MPa, excellent press-moldability, ductility, and expansion flange moldability, and excellent material stability in a sheet width direction; and a method of manufacturing the steel sheet and the member. The present invention has a component composition and a steel structure with prescribed ranges. The combined surface modulus of quenched martensite and residual austenite with an aspect ratio of 3 or less and a circle-equivalent diameter of at least 2.0 μm, with respect to the total surface modulus of quenched martensite and residual austenite, is 20% or less. The surface modulus of a carbon-concentrated region where the carbon concentration is at least 0.5% by mass is 20% or less with respect to the entire structure.
Provided is a method for producing an iron ore pellet, whereby it is possible to obtain a high-strength green pellet in which bursting can be suppressed. This method for producing an iron ore pellet is characterized by having a step for mixing a binder and iron ore having a total Fe content of 63% by mass to obtain a mixture, a step for granulating the mixture to obtain a green pellet, and a step for firing the green pellet to obtain an iron ore pellet, the iron ore having a core ore 10 having a grain size of more than 1 mm, and a fine ore 12 having a grain size of 1 mm or less.
C22B 1/242 - Agglutination; Briquetage avec des liants
52.
ENERGY OPERATION ASSISTANCE SYSTEM, INFORMATION PROCESSING DEVICE, DISPLAY TERMINAL DEVICE, ENERGY OPERATION ASSISTANCE METHOD, AND STEEL MILL OPERATION METHOD
2222222 optimization unit. Further, a display terminal device is provided with an information acquisition unit, an information display unit, and an output unit.
Provided is a high strength electric resistance welded pipe having excellent SSC resistance. This electric resistance welded pipe has an absolute value of residual stress in the circumferential direction of the pipe inner surface of 10 MPa or more and an absolute value of residual shear stress of the pipe inner surface of 300 MPa or less. The steel structure of a base material portion of the electric resistance welded pipe at the center in the thickness direction is configured such that the total of ferrite and bainite is at least 90% in terms of volume ratio, and the average crystal grain diameter is 9.0 μm or less. The steel structure at a position 0.1 mm outside of the pipe inner surface of the base material portion in the pipe radial direction is configured such that the total of ferrite and bainite is at least 95% in terms of volume ratio.
C21D 8/02 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de produits plats ou de bandes
C22C 38/58 - Alliages ferreux, p.ex. aciers alliés contenant du chrome et du nickel et plus de 1,5% en poids de manganèse
B21B 1/22 - Méthodes de laminage ou laminoirs pour la fabrication des produits semi-finis de section pleine ou de profilés; Séquence des opérations dans les trains de laminoirs; Installation d'une usine de laminage, p.ex. groupement de cages; Succession des passes ou des alternances de passes pour laminer des bandes ou des feuilles en longueurs indéfinies
B21C 37/08 - Fabrication de tubes à joints soudés ou brasés
B21C 37/30 - Finition des tubes, p.ex. calibrage, polissage
A method for manufacturing a press-molded article 1 provided with at least a top plate portion 3 having a concave curved portion in a side view and a longitudinal wall portion 7 connecting from the top plate portion 3 through a punch-shoulder-radiused portion 5, the method comprising: a first molding step for press-molding an intermediate molded article 19 having an intermediate top plate portion 21 that curves in the same direction as the top plate portion 3, a step-shaped portion 17 that comprises a step formed continuous with a ridge portion 23 formed in an area corresponding to the punch-shoulder-radiused portion 5, and an outward surface portion 25 that extends outward continuous from the step-shaped portion 17 and curves in the same direction as the intermediate top plate portion 21; and a second molding step for press-molding the intermediate molded article 19 into a press-molded article 1.
Provided is a steel cast slab that contains from 2.0 mass% to less than 7.5 mass% of Ni and has few surface cracks. The steel cast slab containing Ni is composed of, in mass%, C: 0.03% to 0.10%, Si: 0.01% to 0.50%, Mn: 0.10% to 1.00%, P: 0.001% to 0.010%, S: 0.0001% to 0.0050%, Ni: 2.0% to less than 7.5%, Al: 0.010% to 0.080%, N: 0.0010% to 0.0050%, and O: 0.0005% to 0.0040%, with the remainder comprising Fe and unavoidable impurities. The density of solidified nuclei in the surface of the steel cast slab is 0.35/mm2 or more.
B22D 11/00 - Coulée continue des métaux, c. à d. en longueur indéfinie
B22D 11/108 - Alimentation en additifs, poudres ou similaires
B22D 11/12 - Accessoires pour le traitement ultérieur ou le travail sur place des barres coulées
B22D 11/16 - Commande ou régulation des opérations ou du fonctionnement
C21D 8/02 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de produits plats ou de bandes
C21D 9/00 - Traitement thermique, p.ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliers; Fours à cet effet
Provided is a tundish for continuous casting that enables the purity of molten steel to be increased. This tundish for continuous casting comprises an accommodation section that retains molten steel that has been supplied. The accommodation section comprises: one or more molten steel outflow ports out of which the molten steel is allowed to flow; and a weir that is disposed more to the upstream side of the molten steel than the one or more molten steel outflow ports and that is formed in a hollow cylindrical shape. The weir includes: a base section; a wall section erected from the base section; an eave section disposed so as to cover the peripheral ridge at one end of the wall section and to oppose the base section of the weir; and a gas supply section that supplies an inert gas into an internal space surrounded by the wall section and the base section. The gas supply section includes: a porous section, in the entirety of which a plurality of pores are formed; a support section that supports the porous section and is disposed in the wall section of the weir; and piping that is disposed in the wall section of the weir, between the support section and the base section of the weir, and that discharges the inert gas.
Provided is a tundish for continuous casting that is capable of improving the cleanliness of molten steel. This tundish for continuous casting includes an accommodating portion for storing supplied molten steel. The accommodating portion includes: one or a plurality of molten steel outflow ports allowing the molten steel to flow out; and a gas supply portion which is disposed further upstream, in the direction of flow of the molten steel, than the one or plurality of molten steel outflow ports, and which supplies an inert gas into a space surrounded by the accommodating portion. The gas supply portion comprises: a porous portion which is formed in the shape of a box having a bottom portion and a wall portion, and which has a plurality of pores formed over the entirety thereof; a supporting portion which supports the porous portion and which is provided in the wall portion of the gas supply portion; and piping which is provided in the wall portion of the gas supply portion between the supporting portion and the bottom portion of the gas supply portion, and which ejects the inert gas.
SINTERING PROCESS CONTROL METHOD, OPERATION GUIDANCE METHOD, SINTERED ORE MANUFACTURING METHOD, SINTERING PROCESS CONTROL DEVICE, OPERATION GUIDANCE DEVICE, SINTERING OPERATION GUIDANCE SYSTEM, AND TERMINAL DEVICE
Provided is a sintering process control method which uses a physical model, which can calculate the state of a sintering process including a temperature distribution of a sintering raw material in the longitudinal direction and thickness direction in a sintering machine, to control the sintering process, wherein the sintering process control method comprises: a first prediction step (S2) for using the physical model to obtain first future predicted values of control variables when the current operation variables are maintained; and an operation amount calculation step (S5) for calculating an operation amount of a specific operation variable so as to reduce the difference between target values and overlapping predicted values of the control variables, which are based on the first predicted values and a step response when specific operation variables, which are a portion of the operation variables, are changed by a unit quantity.
Provided is a method that makes it possible to more easily and quantitatively obtain the surface wettability of a solid with respect to a discretionary liquid. The present invention is a method for evaluating the wettability of solid surfaces in which surfaces to be evaluated in two solids are made to face each other with a space therebetween, at least all of the bottom edge sections of the two solids are arranged so as to be present on the same plane and the result is used as a test material, an immersion test is performed in which the test material is immersed in an evaluation liquid so that all of the bottom edge section of the test material is parallel to the surface of the evaluation liquid, a wetting height which is the difference between the height of the surface of the evaluation liquid and the height of the liquid surface of the evaluation liquid entering into a gap between the two solids is measured at a discretionary immersion time, and the measured value is designated as a wettability evaluation value for the solid surfaces with respect to the evaluation liquid.
G01N 13/00 - Recherche des effets de surface ou de couche limite, p.ex. pouvoir mouillant; Recherche des effets de diffusion; Analyse des matériaux en déterminant les effets superficiels, limites ou de diffusion
Provided is a mixed powder for powder metallurgy that uses a fatty acid amide, which is a clean lubricant, and that exhibits excellent compression properties and removability of a molded article, not only at normal temperatures but also after a rise in mold temperature. The mixed powder for powder metallurgy comprises an iron-based powder and a fatty acid amide as a lubricant, wherein: the fatty acid amide includes a saturated fatty acid bisamide, a saturated fatty acid monoamide, and an unsaturated fatty acid amide; the unsaturated fatty acid amide includes an unsaturated fatty acid bisamide and/or an unsaturated fatty acid monoamide; and when the added amounts of the saturated fatty acid bisamide, the saturated fatty acid monoamide, the unsaturated fatty acid bisamide, and the unsaturated fatty acid monoamide in terms of parts by mass with respect to 100 parts by mass of the iron-based powder are represented as b1, b2, b3, and b4, respectively, the following expressions (1) to (3) are satisfied. (1): 0<(b1)+(b2)+(b3)+(b4)≤2.0 (2): 0<(b1)/(b2)<0.45 (3): 0<[(b3)+(b4)]/[(b1)+(b2)+(b3)+(b4)]≤0.35
B22F 1/10 - Poudres métalliques contenant des agents lubrifiants ou liants; Poudres métalliques contenant des matières organiques
B22F 1/00 - Poudres métalliques; Traitement des poudres métalliques, p.ex. en vue de faciliter leur mise en œuvre ou d'améliorer leurs propriétés
B22F 1/105 - Poudres métalliques contenant des agents lubrifiants ou liants; Poudres métalliques contenant des matières organiques contenant des agents lubrifiants ou liants inorganiques, p.ex. des sels métalliques
B22F 1/17 - Particules métalliques revêtues de métal
Provided are: a laser welding method to prevent cracks and obtain welded joints having excellent weld metal toughness; and a laser welded joint. This laser welding method comprises: butting steel material members together; coating the surface of the steel material including a weld line with a flux having a predetermined composition; and then performing laser welding to create a welded joint, wherein the steel material has a chemical composition containing, in mass%, 0.04-0.15% of C, 0.05-1.00% of Si, 0.50-2.50% of Mn, 0.030% or less of P, 0.020% or less of S, 0.050% or less of Al, 0.050% or less of Ti, 0.010% or less of O, and 0.008% or less of N, with the remainder comprising Fe and inevitable impurities, and having a carbon equivalent Ceq of 0.30-0.45 as expressed by equation (1). (1): Ceq=[C]+[Mn]/6+[Si]/24+[Cu]/20+[Ni]/40+[Cr]/5+[Mo]/4
Provided is a square steel pipe having excellent buckling resistance. In this square steel pipe, which has a plurality of flat portions and corner portions alternating in the pipe circumference direction, the yield strength of the flat portions in the pipe circumference direction is set to be 0.83-1.20 times the yield strength of the flat portions in the pipe axial direction, and the yield strength of the corner portions in the pipe circumference direction is set to be 0.90-1.30 times the yield strength of the flat portions in the pipe axial direction.
Provided is a resin-coated metal sheet that achieves slipperiness, scrape resistance, and ink adhesiveness with respect to a resin coating layer. This resin-coated metal sheet 1 comprises a resin coating layer 3 that is formed on at least one surface of a metal sheet 2, and that contains at least 75% by mass of a polyester resin in relation to the total resin content. The resin coating layer 3 has at least a three-layer structure including a topmost layer 3a, a middle layer 3b, and a bottommost layer 3c. The melting point of the resin coating layer 3 is 230°C to 254°C, inclusive. The topmost layer 3a contains a polyolefin. The melting point of the polyolefin is 80°C to 140°C, inclusive. When measured by Raman spectroscopy, the dispersed particle size of the polyolefin on the topmost surface and the interior in the thickness direction of the resin coating layer 3 is 0.018 µm to 5.0 µm, inclusive.
B32B 15/09 - Produits stratifiés composés essentiellement de métal comprenant un métal comme seul composant ou comme composant principal d'une couche adjacente à une autre couche d'une substance spécifique de résine synthétique comprenant des polyesters
B32B 27/36 - Produits stratifiés composés essentiellement de résine synthétique comprenant des polyesters
B65D 25/36 - Habillage ou revêtements externes formés par application d'un matériau en feuille
B65D 65/40 - Emploi de stratifiés pour des buts particuliers d'emballage
B65D 65/42 - Emploi de substances enduites ou imprégnées
64.
RESIN-COATED METAL PLATE FOR CONTAINER, AND METHOD FOR MANUFACTURING SAME
Provided is a resin-coated metal plate for a container, in which breakage of a resin coating layer in can making, and planing of the resin coating layer due to insufficient ability to slide during can making can be suppressed, and the plate has excellent adhesion to printing paint after can making. A resin-coated metal plate 1 for a container comprises a polyester resin coating layer 3 on at least one surface of a metal plate 2, the polyester resin coating layer 3 containing 0.010-1.0 mass% of an organic lubricant in which the half-value width of a peak due to C=O stretching vibration in the vicinity of 1730 cm-1is 24 cm-1to 28 cm -1, determined by laser Raman spectroscopy analysis from measurement with linearly polarized laser light having a wavelength of 532 nm incident on the surface of the polyester resin coating layer 3 with the plane of polarization of the laser light parallel to the rolling direction of the metal plate, and the contact angle of diiodomethane on the surface of the polyester resin coating layer after heat treatment for two minutes from room temperature to 240°C being 23-40°.
B32B 15/09 - Produits stratifiés composés essentiellement de métal comprenant un métal comme seul composant ou comme composant principal d'une couche adjacente à une autre couche d'une substance spécifique de résine synthétique comprenant des polyesters
B65D 25/36 - Habillage ou revêtements externes formés par application d'un matériau en feuille
65.
STEEL SHEET FOR HOT PRESSING, HOT-PRESSED MEMBER AND METHOD FOR PRODUCING HOT-PRESSED MEMBER
Provided is a steel sheet for hot pressing that has excellent rapid heating compatibility, that can prevent liquid metal embrittlement cracking, and that has excellent post-hot-pressing coating adhesion. The steel sheet for hot pressing comprises: a base steel sheet; and a coating layer which is provided on both surfaces of the base steel sheet and which has a thickness of 0.5 to 6.0 µm. The coating layer is formed of Ni or an Ni-based alloy, and the Zn content in the coating layer is 0-30 mass%.
C22C 38/60 - Alliages ferreux, p.ex. aciers alliés contenant du plomb, du sélénium, du tellure, de l'antimoine, ou plus de 0,04% en poids de soufre
C23C 14/14 - Matériau métallique, bore ou silicium
C23C 14/16 - Matériau métallique, bore ou silicium sur des substrats métalliques, en bore ou en silicium
C23C 28/00 - Revêtement pour obtenir au moins deux couches superposées, soit par des procédés non prévus dans un seul des groupes principaux , soit par des combinaisons de procédés prévus dans les sous-classes et
C25D 5/26 - Dépôt sur des surfaces métalliques auxquelles un revêtement ne peut être facilement appliqué sur des surfaces de fer ou d'acier
C25D 5/48 - Post-traitement des surfaces revêtues de métaux par voie électrolytique
66.
HIGH-STRENGTH HOT-DIP-GALVANIZED STEEL SHEET AND PRODUCTION METHOD FOR SAME
According to the present invention, a method for producing a high-strength hot-dip-galvanized steel sheet that has at least 20 g/m2but no more than 120 g/m222 and 0.5–10.0 vol ppm of HCl, the remainder being nitrogen and unavoidable impurities. (1): Dew point X≥(-50+[Si mass%]×(T-600)/30+[Mn mass%]×(T-600)/25)
C23C 2/16 - Procédés de trempage à chaud ou d'immersion pour appliquer le matériau de revêtement à l'état fondu sans modifier la forme de l'objet immergé; Appareils à cet effet Élimination de l'excès des revêtements fondus; Commande ou régulation de l'épaisseur du revêtement en utilisant des fluides sous pression, p.ex. par des lames d'air
C21D 8/12 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication d'objets à propriétés électromagnétiques particulières
A method for producing a grain-oriented electromagnetic steel sheet, the method comprising hot-rolling a steel material having a given composition, cold-rolling the hot-rolled sheet to obtain a cold-rolled sheet having a final sheet thickness, and subjecting the cold-rolled sheet to decarburization annealing serving also as primary recrystallization annealing and then to finish annealing, wherein the cold-rolling includes final cold rolling conducted by at least one pass at a steel sheet temperature in the range of 150-350°C. The decarburization annealing is conducted such that in the course of temperature rising, the cold-rolled sheet is rapidly heated from 400°C to a temperature T (°C) between 700°C and 900°C at an average heating rate of 250 °C/s or higher and that a time period of 0.10 s or longer but shorter than 1.00 s is set during which the heating rate for any temperatures between 500°C and 700°C is not higher than 2/3 the average heating rate. Thus, a grain-oriented electromagnetic steel sheet having excellent magnetic properties is produced. The rapid heating in the decarburization annealing is conducted using a transverse-type induction heater.
C21D 8/12 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication d'objets à propriétés électromagnétiques particulières
A method for producing a grain-oriented electromagnetic steel sheet, the method comprising: hot-rolling a steel material to obtain a hot-rolled sheet; subjecting the hot-rolled sheet to cold rolling once or subjecting the hot-rolled sheet to cold rolling two or more times and to process annealing interposed therebetween, thereby obtaining a cold-rolled sheet having a final sheet thickness; and subjecting the cold-rolled sheet to decarburization annealing serving also as primary recrystallization annealing and then to finish annealing. The decarburization annealing is conducted such that in the course of temperature rising, the cold-rolled sheet is rapidly heated from 400°C to a temperature T (°C) between 700°C and 900°C at an average heating rate of 250 °C/s or higher and that a time period of 0.10 s or longer but shorter than 1.00 s is set during which the heating rate for any temperatures between 500°C and 700°C is not higher than 2/3 the average heating rate. Thus, a grain-oriented electromagnetic steel sheet having excellent magnetic properties is produced. The rapid heating in the decarburization annealing is conducted using a transverse-type induction heater.
C21D 8/12 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication d'objets à propriétés électromagnétiques particulières
This press-formed product manufacturing method includes: a reference press-formed product shape acquisition step for acquiring a reference press-formed product shape 5; a corrugated blank press-formed product shape acquisition step for acquiring a corrugated blank press-formed product shape 9; a first deviation amount acquisition step for obtaining a deviation amount between the reference press-formed product shape 5 and the corrugated blank press-formed product shape 9; a period-shifted corrugated blank press-formed product shape acquisition step for acquiring a period-shifted corrugated blank press-formed product shape 13; a second deviation amount acquisition step for obtaining a deviation amount between the reference press-formed product shape 5 and the period-shifted corrugated blank press-formed product shape 13; a countermeasure-requiring site identification step for identifying a countermeasure-requiring site; a convex pattern imparting step for imparting a convex pattern 23, 27 to an actual mold; and an actual press-forming step for performing press-forming using the actual mold to which the convex pattern 23, 27 has been imparted.
Provided is an iron ore pellet production method with which both suppression of bursting and strength of an iron ore pellet are achieved. This iron ore pellet production method involves a crystalline water removal treatment step for eliminating crystalline water from iron ore having an iron content ratio of 63% by mass or less to obtain dewatered ore, wherein iron ore in a state of being heated to 100°C-800°C is kept for 5-200 minutes in the crystalline water removal treatment step.
Provided are a method for producing an iron-based soft magnetic composite powder and an iron-based soft magnetic composite powder. The method for producing an iron-based soft magnetic composite powder includes a first mixing step that adds an aluminum dihydrogen tripolyphosphate dihydrate powder to an iron-based soft magnetic powder and stirs and mixes to obtain a first composite powder in which a coating layer of aluminum dihydrogen tripolyphosphate dihydrate has been formed on the surface of the iron-based soft magnetic particles. In the spectrum of the aluminum dihydrogen tripolyphosphate dihydrate powder analyzed by x-ray diffraction, the peak intensity of the (112) plane of the aluminum dihydrogen tripolyphosphate dihydrate is 1.5 times or more the peak intensity of the (102) plane of aluminum orthophosphate.
This method of controlling hot finish rolling is for hot finish rolling coordinated control that controls a rolling state by finding a control gain that will minimize an evaluation function, by using the evaluation function that has a weight gain set for each of a plurality of state variables and a plurality of operation amount variables. The method comprises: a step in which a normalizing means normalizes the weight gains; a step in which a comparative evaluation means comparatively evaluates the normalized weight gains of the state variables and also comparatively evaluates the normalized weight gains of the operation amount variables; and a step in which a gain adjusting means adjusts the weight gain of a state variable and/or the weight gain of an operation amount variable on the basis of the results of the comparative evaluations.
Provided is a high-strength galvanized steel sheet having a yield strength of 1000 MPa or higher and having exceptional workability, impact resistance, and crack arrestability. The amount of diffusible hydrogen in the steel sheet is 0.60 mass ppm or less. The steel sheet has a component composition containing, in terms of mass, 0.150-0.450% of C, 0.50-3.00% of Si, 1.50-4.00% of Mn, 0.100% or less of P, 0.0200% or less of S, 0.100% or less of Al, 0.0100% or less of O, and 0.0100% or less of N, the balance being Fe and unavoidable impurities. The steel sheet has a microstructure in which the total area ratio of tempered martensite and bainite is 55-95%, the area ratio of retained austenite is 5-30%, and the abundance ratio X/Y between structures X having a nanohardness of 7.0 GPa or higher and structures Y having a nanohardness of 6.5 GPa or lower is 0.5-2.5.
Provided is a high strength steel sheet which has a yield strength of 800 MPa or more and exhibits excellent workability, collision yield strength, and crack-stopping properties. The diffusible hydrogen amount in the steel is 0.50 ppm by mass or less. The constituent composition of the steel contains, in terms of mass%, 0.150-0.500% of C, 0.01-3.00% of Si, 1.50-4.00% of Mn, 0.100% or less of P, 0.0200% or less of S, 0.100% or less of Al, 0.0100% or less of N and 0.0100% or less of O, with the remainder comprising Fe and unavoidable impurities. The total areal ratio of tempered martensite and bainite is 55-95%. The existence ratio (A/B) of a structure A having a nanohardness of 7 GPa or more and a structure B having a nanohardness of 6 GPa or less is 0.8-2.5. The solid solution carbon concentration in retained austenite is 0.50-0.90 mass%.
Provided is a process control method, a blast furnace operation method, a molten pig iron production method, and a process control apparatus, which are for achieving suppression of variability in molten pig iron temperature while reducing a reduction material ratio in a blast furnace. This process control method comprises: a response prediction step for determining a predictive value of a future molten pig iron temperature by using a physical model with which it is possible to calculate the internal state of a blast furnace; and a manipulation degree determination step for determining the deviation between a target value and the predictive value of the molten pig iron temperature determined in the response prediction step, and determining the degrees by which a fine powdered coal ratio and a blown air moisture are to be manipulated, so as to minimize or maximize an evaluation function having a term corresponding to the deviation and a term for reducing a reduction material ratio or the blown air moisture.
Disclosed is a component for solid oxide fuel cells that is excellent in both electrical conductivity and chromium poisoning resistance. As a substrate, a ferritic stainless steel having a chemical composition containing, in mass%, Cr: 14.0 % to 32.0 % and Al: 2.50 % to 7.00 % is used. Precious metal particles are coated on a surface of the substrate. The precious metal particles have: an average particle size of 1 μm or more and 10 μm or less; a coating thickness of 0.5 μm or more and 10 μm or less; and a surface coverage of 1.0 % or more.
Provided is a method for producing a pellet, the method being capable of suppressing green pellet bursting. This method for producing an iron ore pellet comprises: a crushing step for obtaining ore powder by crushing iron ore having an iron content of 63 mass% or less. The volatile content of the iron ore is 3.3 mass% or greater. The iron ore powder has a cumulative 90% diameter in the grain size distribution by volume of 150 μm or less and a grain size distribution index based on the harmonic mean diameter of 14,700 to 510,000.
This method for manufacturing a press-molded article 1 is a method for manufacturing a press-molded article 1 having a main body part 11, which has a top plate part 5 and vertical wall parts 7 formed with ridgeline parts 9 interposed therebetween, and an outer flange part 3 formed on an end of the main body part 11 so as to be continuous from the top plate part 5, the ridgeline parts 9, and the vertical wall parts 7, the method including: an intermediate molding step for molding an intermediate molded article 24 that has the top plate part 5 and the vertical wall parts 7 formed with the ridgeline parts 9 interposed therebetween and that has a step formation part 27 at a root section of an outward-flange-equivalent part 25 so that the outward-flange-equivalent part 25 bulges outwards; and a target shape molding step for folding the outward-flange-equivalent part 25 of the intermediate molded article 24 outwards, forming an outward flange part 3, and molding a target shape.
Provided are a method for controlling a process, a method for operating a blast furnace, a method for manufacturing molten metal, and a device for controlling a process that make it possible to highly accurately predict, and control, the state of a blast furnace. In this method for controlling a process: the pig iron production speed, the gas permeability, and the hot metal temperature of a blast furnace are acquired by means of observed values or calculated values; and the pig iron production speed, the gas permeability, and the hot metal temperature are simultaneously controlled on the basis of the acquired observed values or calculated values, as well as a target value for the hot metal temperature (target hot metal temperature), a target value for the pig iron production speed (target pig iron production speed), and a management value for the gas permeability (furnace interior pressure loss upper limit).
Provided is an electromagnetic steel strip friction stir welding method that can, under high processing efficiency, suppress fracturing of a coil weld section on a manufacturing line, said fracturing being due to degradation in the shape or degradation in the mechanical properties of the coil weld section. Later-cooling-style double-sided friction stir welding is performed according to conditions such that the respective steel compositions of a weld section and a thermal process-affected section that are formed due to the welding will be ferrite phase-based compositions and simultaneously satisfy expressions (1)-(4).
B23K 20/12 - Soudage non électrique par percussion ou par une autre forme de pression, avec ou sans chauffage, p.ex. revêtement ou placage la chaleur étant produite par friction; Soudage par friction
B21B 15/00 - Systèmes permettant d'effectuer des opérations auxiliaires pour le travail des métaux, spécialement combinés, disposés ou adaptés pour être associés aux laminoirs
Provided is a friction stir joining method which is for an electromagnetic steel strip and which, while having a high working efficiency, is capable of preventing a coil joining section in a manufacturing line from breaking due to the deterioration of mechanical characteristics and the deterioration of the shape of the coil section. Post-cooling-type two-surface friction stir joining is performed under a condition satisfying both the relationships of formulas (1) and (2).
B23K 20/12 - Soudage non électrique par percussion ou par une autre forme de pression, avec ou sans chauffage, p.ex. revêtement ou placage la chaleur étant produite par friction; Soudage par friction
B21B 15/00 - Systèmes permettant d'effectuer des opérations auxiliaires pour le travail des métaux, spécialement combinés, disposés ou adaptés pour être associés aux laminoirs
Provided are manufacturing equipment, a manufacturing method, and an acceptability determination method for a metal band by which it is possible to reliably perform quality assurance regarding the warpage of a metal band. The manufacturing equipment for a metal band comprises: a heating unit (6) that continuously heats a metal band being conveyed; a cooling unit (8) that cools the metal band heated by the heating unit; a shape correction unit (13) that corrects the shape of the metal band cooled by the cooling unit; a first warpage measurement unit (14) that is disposed downstream of the shape correction unit, and that measures the warpage of the metal band; and a warpage determination unit (41) that determines the position information of the metal band in relation to the front end, and determines the correlation between the warpage of the metal band measured by the first warpage measurement unit and the position information of the metal band in relation to the front end.
Provided is an annealing facility which more actively controls carbon in steel, thereby contributing to further improvement of magnetic properties. This annealing facility has a heating zone, a soaking zone, and a cooling zone on a steel strip conveyance line, wherein: the conveyance line can pass a steel strip having a thickness of 2.8 mm or greater; the soaking zone has a means for maintaining the ambient temperature at 900°C or greater; the cooling zone has a means for supplying a refrigerant to the steel strip to set the average cooling rate in a temperature range of 750°C to 120°C to at least 50°C/s; and a means for removing the refrigerant is provided on the outlet side of the cooling zone.
C21D 8/12 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication d'objets à propriétés électromagnétiques particulières
C21D 9/56 - Fours continus pour bandes ou fils métalliques
A method for producing a grain-oriented electromagnetic steel sheet, the method preventing a break during cold rolling when a grain-oriented electromagnetic steel sheet is produced by subjecting a steel slab, which contains, in mass%, 0.03% to 0.08% of C, 2.0% to 5.0% of Si, 0.005% to 1.0% of Mn, less than 0.010% of Al, 0.006% or less of N and 0.0060% or less of O, while containing S and Se within the range where (S + 0.405 × Se) is 0.0015% to 0.0060%, to hot rolling, hot rolled sheet annealing, cold rolling, decarburization annealing that doubles as primary recrystallization annealing, and subsequent finish annealing, by performing at least two consecutive passes of rolling within the temperature range of 1050°C to 1150°C during the hot rolling, and setting the inter-pass time between the two passes to 60 s or less, the draft of each pass to 20% or more, and the strain rate to 15 s-1 or more; and a hot rolled sheet which is used for this production method.
C21D 8/12 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication d'objets à propriétés électromagnétiques particulières
Provided is a stainless steel sheet which is for a fuel cell separator and has excellent press workability and Fe ion elution resistance. The stainless steel sheet has a composition containing, in mass%, 18.0-24.0% of Cr and 3.00% or less of Ni, has a steel microstructure containing an austenitic phase and a ferritic phase, the fraction of the austenitic phase being at least 30% and the total fraction of the austenitic phase and the ferritic phase being at least 95%, and has a total elongation of at least 40%.
C22C 38/40 - Alliages ferreux, p.ex. aciers alliés contenant du chrome et du nickel
C22C 38/58 - Alliages ferreux, p.ex. aciers alliés contenant du chrome et du nickel et plus de 1,5% en poids de manganèse
H01M 8/0228 - Composites sous forme de produits en couches ou enrobés
H01M 8/10 - PROCÉDÉS OU MOYENS POUR LA CONVERSION DIRECTE DE L'ÉNERGIE CHIMIQUE EN ÉNERGIE ÉLECTRIQUE, p.ex. BATTERIES Éléments à combustible; Leur fabrication Éléments à combustible avec électrolytes solides
A granular metal production device with which it is possible to make molten metal into granular metal of a predetermined grain size or less even if the height is restricted. The molten metal in a first flow path (9) collides with a step (11) at the inlet of a second flow path (10) created by a difference in opening area, causing rapid speed fluctuations to occur, when molten metal flows from the upper first flow path (9) into the lower second flow path (10) in a discharge port (4) provided in the bottom (3a) of a container (3). As a result, a speed distribution of the flow speed occurs within the cross-section of the molten metal flowing down from the second flow path (10), and this speed distribution allows the molten metal that collides with the collision structure (5) and scatters to be reliably granulated.
B22D 5/00 - Machines ou installations pour la coulée de gueuses ou produits similaires
B22D 23/00 - Procédés de coulée non prévus dans les groupes
B22D 25/02 - Coulée particulière caractérisée par la nature du produit d'œuvres d'art
B22F 9/08 - Fabrication des poudres métalliques ou de leurs suspensions; Appareils ou dispositifs spécialement adaptés à cet effet par des procédés physiques à partir d'un matériau liquide par coulée, p.ex. à travers de petits orifices ou dans l'eau, par atomisation ou pulvérisation
This cold-rolling method includes a calculation step for calculating the levelling amount of a rolling machine using the out-of-plane deformation amount of a steel sheet measured on the upstream side of the rolling machine, a control step for controlling the levelling of the rolling machine on the basis of the levelling amount calculated in the calculation step, and a cold rolling step for cold-rolling the steel sheet using the rolling machine controlled in the control step.
B21B 37/58 - Commande de la force de laminage; Commande de l'écartement des cylindres
B21B 1/22 - Méthodes de laminage ou laminoirs pour la fabrication des produits semi-finis de section pleine ou de profilés; Séquence des opérations dans les trains de laminoirs; Installation d'une usine de laminage, p.ex. groupement de cages; Succession des passes ou des alternances de passes pour laminer des bandes ou des feuilles en longueurs indéfinies
B21B 37/28 - Commande de la planéité ou du profil pendant le laminage de bandes, de feuilles ou de tôles
B21B 37/68 - Commande de la cambrure ou de la direction des bandes, des feuilles ou des tôles, p.ex. prévention des méandres
B21B 38/02 - Procédés ou dispositifs de mesure spécialement adaptés aux laminoirs, p.ex. détection de la position, inspection du produit pour mesurer la planéité ou le profil des bandes
B21C 51/00 - Dispositifs de mesure, de calibrage, d'indication, de comptage ou de marquage, spécialement conçus pour être utilisés dans la production ou la manipulation des matériaux concernés par les sous-classes
90.
PRESS FORMING ANALYSIS METHOD, PRESS FORMING FRACTURE DETERMINING METHOD FOR PRESS-FORMED ARTICLE, PRESS-FORMED ARTICLE MANUFACTURING METHOD, PRESS FORMING ANALYSIS DEVICE, AND PRESS FORMING ANALYSIS PROGRAM
A press forming analysis method according to the present invention includes a blank model creating step (S1) for creating a blank model, and a press forming analysis step (S2) for performing press forming analysis using the created blank model, wherein the blank model creating step (S1) includes: a blank mesh creating step (S1-1) for creating a finite element mesh for configuring the blank model; a grouping step (S1-2) for grouping finite elements constituting the finite element mesh into a plurality of groups; and a deformation condition setting step (S1-3) for setting conditions relating to deformation for the finite elements of each grouped group, the set conditions being different for each group.
B21D 22/00 - Mise en forme sans coupage, par estampage, repoussage ou emboutissage
G06F 30/23 - Optimisation, vérification ou simulation de l’objet conçu utilisant les méthodes des éléments finis [MEF] ou les méthodes à différences finies [MDF]
This material discharge control device 10 controls the discharge amount of a material 203 which is discharged from a material hopper 20. The material discharge control device 10 comprises a material property measuring device 12 for measuring the properties of the material 203 to be charged in the material hopper 20; and a control device 11 for controlling the discharge amount of the material 203 on the basis of the properties of the material 203.
A stress-strain relationship inference method according to the present invention involves: defining a converted parameter obtained by converting a parameter of the Yoshida-Uemori model; setting, as objective functions, the weighted residual sums of squares obtained by multiplying, by individual weighting coefficients, the residuals between experimental values and calculated values of a stress-strain curve under uniaxial tensile stress, the residuals between experimental values and calculated values of a stress-strain curve under repeated tension-compression stress, and the residuals between experimental values and calculated values of a mechanical characteristic value of a metal material; and determining the converted parameter and another parameter so as to minimize the objective functions under a restriction condition relating to possible ranges of the converted parameter and the other parameter.
G01N 3/08 - Recherche des propriétés mécaniques des matériaux solides par application d'une contrainte mécanique par application d'efforts permanents de traction ou de compression
B21D 22/00 - Mise en forme sans coupage, par estampage, repoussage ou emboutissage
G01N 3/32 - Recherche des propriétés mécaniques des matériaux solides par application d'une contrainte mécanique en appliquant des efforts répétés ou pulsatoires
G06F 30/23 - Optimisation, vérification ou simulation de l’objet conçu utilisant les méthodes des éléments finis [MEF] ou les méthodes à différences finies [MDF]
G06F 119/14 - Analyse des forces ou optimisation des forces, p.ex. forces statiques ou dynamiques
93.
CHEMICAL AGENT FOR FORMING SOLID LUBRICATION COATING, CHEMICAL AGENT PRODUCTION METHOD, CHEMICAL AGENT APPLICATION METHOD, OIL WELL PIPE, AND OIL WELL PIPE SCREW JOINT
The present invention provides a chemical agent which is environmentally friendly and a solid lubrication coating. Provided is a chemical agent for forming a solid lubrication coating on a metal surface. The main components are a solid lubricant, a binder resin, and a solvent. The solvent has water as the main component thereof, and a lower alcohol with a carbon number of three or less is added as an additive to the water. The volume of the additive is 0.5-45 with respect to a volume of 100 of the water in the solvent. Not less than 95% of the volume of the solvent is constituted by water and the additive. At least a metal soap is contained as the solid lubricant. The metal soap component is not less than 95% of the total combined weight of the metal soap and an alkali soap component. The particle size of the metal soap does not exceed the film thickness of the solid lubrication coating. The binder resin is constituted by a water-soluble or water-dispersible polymer and a copolymer. The binder resin contains a copolymer and a polymer having an acrylate or methacrylate structure in an amount of not less than 90% of the total weight of the binder resin.
C09D 133/00 - Compositions de revêtement à base d'homopolymères ou de copolymères de composés possédant un ou plusieurs radicaux aliphatiques non saturés, chacun ne contenant qu'une seule liaison double carbone-carbone et l'un au moins étant terminé par un seul ra; Compositions de revêtement à base de dérivés de tels polymères
C10M 129/40 - Acides carboxyliques; Leurs sels comportant des groupes carboxyle liés à des atomes de carbone acycliques ou cycloaliphatiques comportant au moins 8 atomes de carbone monocarboxyliques
C10M 129/44 - Acides carboxyliques; Leurs sels comportant des groupes carboxyle liés à des atomes de carbone acycliques ou cycloaliphatiques comportant au moins 8 atomes de carbone contenant des groupes hydroxyle
F16L 15/04 - Raccords avec filetage; Formes des filetages pour ces raccords avec des joints d'étanchéité supplémentaires
C10N 20/06 - Particules de forme ou de dimensions particulières
C10N 30/06 - Onctuosité; Résistance du film; Anti-usure; Résistance aux pressions extrêmes
C10N 40/00 - Utilisation ou application particulière de la composition lubrifiante
C10N 50/02 - Forme sous laquelle est appliqué le lubrifiant au matériau à lubrifier en solution ou en suspension dans un liquide porteur qui s'évapore ultérieurement pour laisser un revêtement lubrifiant
94.
COATING DRUG FOR FORMING SOLID LUBRICATING FILM, PRODUCTION METHOD FOR SAID COATING DRUG, OIL WELL PIPE REPAIRING METHOD, LUBRICATION IMPROVING METHOD FOR OIL WELL PIPE, AND OIL WELL PIPE
Provided is a drug which is environmentally friendly and durable for actual use in a well. The drug is for forming a solid lubricating film by being applied to a metal surface. The drug contains a solid lubricant, a binder resin, and a solvent as main components, wherein: the solvent contains water as a main component and is obtained by adding, as an additive, a lower alcohol having at most 3 carbon atoms to water; the volume of the additive is 0.5-10 with respect to 100 of the volume of the water; at least 95% of the volume of the solvent is composed of the water and the additive; the solid lubricant contains at least 95% of graphite and metallic soap and at most 1% of alkali soap, with respect to the total weight of solid lubricating components; the amount of the graphite is 0.5-5% with respect to the entire amount of the solid lubricant, in terms of weight ratio; the binder resin is a water-soluble or water-dispersible polymer; and the polymer is a polymer or copolymer containing at least 90% of monomers belonging to acrylate or methacrylate with respect to the total weight of the binder resin.
C09D 133/00 - Compositions de revêtement à base d'homopolymères ou de copolymères de composés possédant un ou plusieurs radicaux aliphatiques non saturés, chacun ne contenant qu'une seule liaison double carbone-carbone et l'un au moins étant terminé par un seul ra; Compositions de revêtement à base de dérivés de tels polymères
C10M 129/40 - Acides carboxyliques; Leurs sels comportant des groupes carboxyle liés à des atomes de carbone acycliques ou cycloaliphatiques comportant au moins 8 atomes de carbone monocarboxyliques
C10M 129/44 - Acides carboxyliques; Leurs sels comportant des groupes carboxyle liés à des atomes de carbone acycliques ou cycloaliphatiques comportant au moins 8 atomes de carbone contenant des groupes hydroxyle
F16L 15/04 - Raccords avec filetage; Formes des filetages pour ces raccords avec des joints d'étanchéité supplémentaires
C10N 20/06 - Particules de forme ou de dimensions particulières
C10N 40/00 - Utilisation ou application particulière de la composition lubrifiante
C10N 50/02 - Forme sous laquelle est appliqué le lubrifiant au matériau à lubrifier en solution ou en suspension dans un liquide porteur qui s'évapore ultérieurement pour laisser un revêtement lubrifiant
95.
OIL WELL PIPE, OIL WELL PIPE SCREW JOINT, AND COATING MATERIAL
Provided is an oil well pipe screw joint having a solid lubrication coat having excellent lubrication and anti-rust properties. This oil well pipe constitutes a box (2) having a female screw or a pin (1) having a male screw that is used in the oil well pipe screw joint formed by linking the box (2) to the pin (1). The outermost layer of a screw section has a resin coat constituted of a binder resin containing an alkaline soap as a solid lubricant. The resin coat has an alkaline soap layer on the surface thereof.
C10M 129/28 - Acides carboxyliques; Leurs sels comportant des groupes carboxyle liés à des atomes de carbone acycliques ou cycloaliphatiques
C10N 30/06 - Onctuosité; Résistance du film; Anti-usure; Résistance aux pressions extrêmes
C10N 30/12 - Inhibition de la corrosion, p.ex. agents antirouille, agents anticorrosifs
C10N 40/00 - Utilisation ou application particulière de la composition lubrifiante
C10N 50/02 - Forme sous laquelle est appliqué le lubrifiant au matériau à lubrifier en solution ou en suspension dans un liquide porteur qui s'évapore ultérieurement pour laisser un revêtement lubrifiant
96.
THICK STEEL SHEET AND MANUFACTURING METHOD THEREFOR
C21D 8/02 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de produits plats ou de bandes
The present invention proposes a method for producing a sintered ore with high productivity without requiring both an expensive anionic polymer dispersant and a step for grinding an iron ore into a fine powder. The present invention provides a method for producing a sintered ore, wherein a blended sintering starting material including iron ores of a plurality of brands is granulated together with additive water in a granulator, and the resultant granulated starting material for sintering is fired in a sintering machine so as to obtain a sintered ore. With respect to this method for producing a sintered ore, some or all of the additive water during the granulation is replaced with a dust slurry solution that is obtained by suspending solid dust in water at a concentration of 20-55 mass%.
00 of 70 J or more at 0°C and an Mn concentration distribution wherein: the area fraction of average Mn concentration regions, which are defined as the regions having an Mn concentration that is 0.9 to 1.1 times the average Mn content (% by mass), is less than 90%; the area fraction of Mn-enriched regions, which are defined as the regions having an Mn concentration that is not less than 1.15 times the average Mn content (% by mass), is 1.0% or more; and the average circle-equivalent diameter of the Mn-enriched regions is 7.0 µm or less.
C21D 8/02 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de produits plats ou de bandes
The rolling mill according to the present invention is provided with a pair of upper and lower rolls arranged in a housing and with a roll chock that holds each of the upper and lower rolls, and a liner having a vibration-reducing function is provided on at least one of a housing-facing surface of the roll chock or a housing surface corresponding to a housing-facing surface.
B21B 31/02 - Châssis de laminoir; Supports de cylindres
B21B 33/00 - Dispositifs de sécurité non prévus ailleurs; Disjoncteurs; Dispositifs pour libérer les cylindres coincés
F16F 7/00 - Amortisseurs de vibrations; Amortisseurs de chocs
F16F 15/02 - Suppression des vibrations dans les systèmes non rotatifs, p.ex. dans des systèmes alternatifs; Suppression des vibrations dans les systèmes rotatifs par l'utilisation d'organes ne se déplaçant pas avec le système rotatif
F16F 15/04 - Suppression des vibrations dans les systèmes non rotatifs, p.ex. dans des systèmes alternatifs; Suppression des vibrations dans les systèmes rotatifs par l'utilisation d'organes ne se déplaçant pas avec le système rotatif utilisant des moyens élastiques
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