A non-oriented electrical steel sheet wherein: the chemical composition of a base material contains, in terms of mass%, not more than 0.0050% C, more than 3.50% but not more than 4.50% Si, less than 0.60% Mn, 0.25-0.65% Al, not more than 0.030% P, not more than 0.0020% S, not more than 0.0040% N, less than 0.0040% Ti, less than 0.0040% Nb, less than 0.0040% Zr, less than 0.0040% V, less than 0.200% Cu, less than 0.500% Ni, and Sn and/or Sb in a total amount of not more than 0.030%, with the remainder being Fe and impurities; [4.3≤Si+Al+0.5×Mn≤5.0] is satisfied; the average crystal grain size of the base material is more than 40 μm but not more than 140 μm, the degree of integration of the {111} direction is not less than 3.0, the degree of integration of the {110} direction is not more than 0.15; and the sheet thickness is 0.10-0.30 mm.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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
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
H01F 1/147 - Alliages caractérisés par leur composition
Provided is a disc brake device for a railway vehicle capable of suppressing warpage of a brake disc. A disc brake device (1) is provided with a brake disc (2) and a brake lining (4). The brake disc (2) is fastened to s wheel by a plurality of bolts (6) inserted into a plurality of bolt holes (21). The brake lining (4) includes a plurality of sliding member sets (41). Each of the sliding member sets (41) includes an inner circumferential sliding member (42i) and an outer circumferential sliding member (42o). When a projection area (PA) of the inner circumferential sliding member (42i) and the outer circumferential sliding member (42o) formed on a sliding surface (22) of the brake disc (2) is divided into inner circumferential projection areas (PAi) and outer circumferential projection areas (PAo) with a virtual circle (PC) passing through the center of each bolt hole (21) as a boundary, the area of the outer circumferential projection areas (PAo) is larger than the area of the inner circumferential projection areas (PAi).
F16D 65/12 - DisquesTambours pour freins à disques
B61H 5/00 - Emploi ou aménagements de freins comportant de substantielles surfaces de freinage radiales pressées l'une contre l'autre selon un mouvement axial, p. ex. freins à disques
F16D 65/092 - Bandes, sabots ou patinsPivots ou leurs organes de support pour freins à engagement axial, p. ex. freins à disques
3.
PLATED STEEL SHEET AND METHOD FOR MANUFACTURING SAME
Provided is a plated steel sheet which has low lightness from immediately after being produced and in which detachment of a plating layer is suppressed. A plated steel sheet according to the present invention has a plating layer comprising 1.0-22.0 mass% of Al and 1.5-10.0 mass% of Mg, the remaining portion being Zn and an optionally added trace additive. The plated steel sheet has a surface lightness (L*) of 50 or less, and has an X-ray diffraction spectrum, obtained through X-ray diffraction, satisfying all of (1)-(3). (1): A/B is 0.001-0.015. (2): A/C is 1.2 or more. (3): The half width d of a peak indicated by A is 0.30-1.00 deg. A represents the peak intensity of a peak indicating the 100 plane of ZnO at which 2θ appears in 31.27-32.27 deg, B represents the peak intensity of a peak indicating the 101 plane of Zn at which 2θ appears in 42.73-43.73 deg, and C represents the intensity when 2θ is 30.00 deg.
θθθ in the cementite particles is no more than 1.00%, the average particle diameter of the cementite particles is no more than 1.50 μm, and the spheroidization rate of the cementite particles is at least 85%.
A threaded joint (100) comprises a pin (10) and a box (20), and in a fastened state, seal surfaces (12, 22) interfere and come into contact with each other, a male thread bottom surface (112) interferes and comes into contact with a female thread top surface (212), and load flank faces (114, 214) come into press-contact with each other. When the surface of the box (20) is covered with a base coating film (25) including an alloy plating layer (251) and with a single solid lubricating coating film (26) in a single body state, the film thickness (tS214) of the solid lubricating coating film (26) on the female thread load flank face (214) is smaller than the film thickness (tS212) of the solid lubricating coating film (26) on the female thread top surface (212), and the film thickness (tS22) of the solid lubricating coating film (26) on the box seal surface (22) is greater than the film thickness (tS214) of the solid lubricating coating film (26) on the female thread load flank face (214).
F16L 15/04 - Raccords avec filetageFormes des filetages pour ces raccords avec des joints d'étanchéité supplémentaires
8.
ELECTRIC RESISTANCE WELDED PIPE MANUFACTURING METHOD, INDUCTION COIL FOR ELECTRIC RESISTANCE WELDED PIPE MANUFACTURING DEVICE, AND ELECTRIC RESISTANCE WELDED PIPE MANUFACTURING DEVICE
[Problem] To improve heating efficiency in manufacturing an electric resistance welded pipe while preventing damage to an impeder and overheating of the surface of an open pipe. [Solution] In an electric resistance welded pipe manufacturing method according to the present invention, an induction coil includes: a pair of inclined conductor parts provided so as to be inclined at a predetermined angle with respect to a vertical direction in a side view; a connection conductor part that is provided at an end section of the pair of inclined conductor parts on the downstream side in a traveling direction so as to connect the pair of inclined conductor parts to each other, and that is arranged so as to extend across an opening in a plan view; and power source connection conductor parts that are provided at end sections of the pair of inclined conductor parts on the upstream side in the traveling direction and that are connected to a power source, wherein the pair of inclined conductor parts are arranged so as to gradually separate from the opening toward the upstream side in the traveling direction in a plan view.
θθθ in the cementite particles is no more than 1.00%, the average particle diameter of the cementite particles is no more than 1.50 μm, and the spheroidization rate of the cementite particles is 75% or more but less than 85%.
In this hot-rolled steel sheet, the A value represented by formula (1) is 0.0150 mass% or more, the M value represented by formula (2) is 930 or less, the metal structure at a position 1/4 of the sheet thickness from the surface comprises, in terms of area%, no less than 50% and less than 80% ferrite, more than 20% and no more than 50% bainite, 0-5% pearlite, and 0-2% MA, the average crystal grain size is 10 μm or less, the BH amount is 45 MPa or more, and the tensile strength is 780 MPa or more.
Provided are: a sealing can body (1) including a lid (10), a body (20), and a welding metal (30) that joins the lid (10) and the body (20), the sealing can body (1) being characterized in that the lid (10) is made of a stainless steel material and the body (20) is made of a plated steel material having a Ni-based plating layer on the surface of a base steel material, or the lid (10) is made of a plated steel material having a Ni-based plating layer on the surface of a base steel material and the body (20) is made of a stainless steel material, and in that [Cr] + 4 × [Ni] ≧ 5.0 is satisfied when [Cr] denotes the average amount of Cr in the welding metal (30) and [Ni] denotes the average amount of Ni in the welding metal (30); and a method for manufacturing said sealing can body.
H01M 50/128 - Boîtiers primairesFourreaux ou enveloppes caractérisés par le matériau ayant une structure en couches comprenant au moins trois couches dont au moins deux couches de matériaux inorganiques uniquement
11 which occurs at the end surface due to pressing and the hole expansion ratio λ of the raw material steel sheet or the pre-processed raw material steel sheet satisfy formula (1), and when such portion is considered to be a first region, in a section of or the entirety of that first region the following are true: the converted tensile strength obtained by converting from the hardness of the end surface is 1.50 times or less the tensile strength of the raw material steel sheet or the pre-processed raw material steel sheet; the arithmetic mean roughness Ra is 3.00 μm or less in relation to the line roughness along the extension direction of the end surface of the raw material steel sheet or the pre-processed raw material steel sheet; and the ratio (Rz/RSm) of the maximum height Rz in relation to the line roughness along the extension direction of the end surface to the average length RSm of a roughness curve element is 0.20 or less. The press method also includes a press step for pressing the raw material steel sheet or the pre-processed raw material steel sheet.
Provided is a weld metal in which chemical components thereof are, in mass percentage with reference to the total mass of the weld metal, 0.2-0.8% of C, 0.03-0.5% of Si, 5.1-20% of Mn, 0-0.05% of P, 0-0.05% of S, 0-5% of Cu, 6-20% of Ni, 0-10% of Cr, 0-10% of Mo, 0-5% of Nb, 0-5% of V, 0-5% of Ta, 0-5% of Hf, 0-5% of Ti, 0-5% of Zr, 0-1% of Co, 0-1% of Pb, 0-1% of Sn, 0-5% of W, 0-0.1% of Mg, 0.001-0.1% of Al, 0-5% of Ca, 0-0.5% of B, 0-0.5% of REM, 0-0.5% of N, and 0.001-0.15% of O, the balance being Fe and impurities. The weld metal contains greater than 1% of Nb, greater than 1% of V, no less than 0.001% of Ta, no less than 0.001% of Hf, no less than 0.1% of Ti, and/or greater than 0.5% of Zr as at least one type of element selected from the group consisting of Nb, V, Ta, Hf, Ti, and Zr.
This automobile side-module is for reinforcing side outers of an automobile and is formed through hot-stamp molding of a plurality of integrated steel sheets. When S (m20.25100.25100.20.2 is more than 0.10.
A copper-plated steel sheet 10 comprises a base steel sheet 20 and a copper plating film 30 formed on at least one surface of the base steel sheet 20. The copper plating film 30 continuously covers the base steel sheet 20 at a thickness of 1.0 μm or more when viewed in a cross section parallel to the thickness direction, and has at least 25 protrusions 31 having a height of 1.0 μm or more per 1000 µm.
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
C25D 7/00 - Dépôt électrochimique caractérisé par l'objet à revêtir
A copper-plated steel sheet 10 comprises: a base steel plate 20; and a dendritic copper plating film 30 formed on at least one surface of the base steel plate 20. When the copper-plated steel sheet 10 is immersed in 0.5 mass% dilute sulfuric acid at 25°C for 5 seconds, and is subsequently washed with water and dried, the lightness L* of the copper plating film 30 measured within one hour after drying is 50-71.
maxmax) of the blank (30, 30A, 30B). With respect to at least one of the first steel sheet (31) and the second steel sheet (32), the surface (311, 321) positioned on the outer side in the overlapping section (361) has been subjected to a treatment for increasing the emissivity compared to at least one of other surface of the plurality of steel sheets.
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
A copper-plated steel sheet 10 comprises a base steel sheet 20 and a copper plating film 30 formed on at least one surface of the base steel sheet 20. The copper-plated film 30, when a cross section parallel to a thickness direction is viewed, comprises a base film portion 31 continuously covering the base steel sheet 20 and projection portions 32 dendritically grown from the base film portion 31. The volume proportion of the projection portions 32 in a range extending from the base film portion 31 to the height of 10 μm is 0.10% or higher.
This steel sheet has a prescribed chemical composition. In the metal structure in a position at 1/4 of the sheet thickness from the surface, bainite is 60.0% to less than 90.0%, martensite is more than 10.0% to 40.0%, and the total of ferrite, pearlite, and retained austenite is 10.0% or less by area. The value obtained by dividing the standard deviation of the aspect ratios of prior austenite grains by the average value of the aspect ratios of the prior austenite grains is 0.50 or less, and the average grain size of the prior austenite grains is 30 μm or less.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
C22C 38/58 - Alliages ferreux, p. ex. aciers alliés contenant du chrome et du nickel et plus de 1,5% en poids de manganèse
20.
SPOT-WELDED JOINT AND METHOD FOR MANUFACTURING SPOT-WELDED JOINT
A spot-welded joint according to one aspect of the present disclosure is provided with two or more overlapped steel plates and a nugget joining the steel plates. The metal structure at both ends of the nugget in a virtual line along the joint interface of the steel plates as measured in a cross section of the nugget contains 5-40 area% of fresh martensite, and 95 area% or more of the balance is one or both of tempered martensite and bainite. Preferably, the metal structure at both ends of the nugget contains at least 2 area% of bainite.
Provided are a layered iron core manufacturing device and manufacturing method that facilitate the assembly of an adhesive application means and can shorten the time required for maintenance. This manufacturing device 1 for a layered iron core 4 comprises: an adhesive application means 6 for applying an adhesive to a site on a steel sheet 2 corresponding to an iron core thin sheet 3; and a forward/reverse drive unit 7 for switching whether or not the adhesive is to be applied by the adhesive application means 6. The adhesive application means 6 has a discharge unit 60 that is configured so as to discharge the adhesive from the tip of a passage 60a. The adhesive application means 6 or the discharge unit 60 comprises a member made of a solid or non-porous organic resin. The passage 60a is formed by a wall surface of the solid or non-porous organic resin. The adhesive application means 6 is disposed so that, when the adhesive is to be applied, the adhesive discharged from the tip of the discharge unit 60 in accordance with vertical movement of the steel sheet 2 that accompanies punching of the iron core thin sheet 3 from the steel sheet 2 is brought into contact with the steel sheet 2.
H02K 15/02 - Procédés ou appareils spécialement adaptés à la fabrication, l'assemblage, l'entretien ou la réparation des machines dynamo-électriques des corps statoriques ou rotoriques
B21D 28/02 - Découpage à l'emporte-pièce ou poinçonnage de flans ou d'objets, avec ou sans production de déchetsEntaillage
H01F 41/02 - Appareils ou procédés spécialement adaptés à la fabrication ou à l'assemblage des aimants, des inductances ou des transformateursAppareils ou procédés spécialement adaptés à la fabrication des matériaux caractérisés par leurs propriétés magnétiques pour la fabrication de noyaux, bobines ou aimants
Provided is a metal material having excellent scratch resistance and excellent corrosion resistance. A metal material (1) according to the present disclosure comprises: a metal base material (10); a lower resin layer (20) formed on the metal base material (10); and an outermost resin layer (30) formed on the lower resin layer (20). The hardness HL the lower resin layer (20) is 0.18 GPa or greater. The hardness HH of the outermost resin layer (30) satisfies formula (1), and the thickness TL (μm) of the lower resin layer and the thickness TH (μm) of the outermost resin layer satisfy formula (2). (1): HH/HL < 0.90 (2): TL + TH > 3.0
B05D 1/36 - Applications successives de liquides ou d'autres matériaux fluides, p. ex. sans traitement intermédiaire
B32B 15/08 - 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
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
Provided is a decorative metal plate that exhibits excellent chemical resistance and maintains excellent corrosion resistance even when subjected to a bending process. In a decorative metal plate (1) according to the present disclosure, a lower-layer resin layer (20) formed on a metal substrate (10) contains 0.2-30.0 mass% of a rust-preventive pigment and a first organic resin. When the rust-preventive pigment is in particulate form, the average particle diameter is 1.00 μm or less. An upper-layer resin layer (30) contains at least 95 mass% of a second organic resin. When a 180° bending process is performed with an inner bending radius of 2t so that the upper-layer resin layer (30) side of the decorative metal plate (1) curves outward, in a surface region of the surface of the upper-layer resin layer (30) in the outwardly curved portion of the decorative metal plate (1) after the bending process that is a square of 200 μm × 200 μm and in which the ridge line of the curved portion is located at the center position of each side in a pair of opposing sides of the square, the crack area ratio of the upper-layer resin layer (30) is 10.0% or less.
B32B 15/08 - 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
B32B 27/20 - Produits stratifiés composés essentiellement de résine synthétique caractérisée par l'emploi d'additifs particuliers utilisant des charges, des pigments, des agents thixotropiques
C22C 18/04 - Alliages à base de zinc avec l'aluminium comme second constituant majeur
C22C 21/02 - Alliages à base d'aluminium avec le silicium comme second constituant majeur
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 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
A threaded joint (100) comprises a pin (10) and a box (20). The pin (10) has a pin inner seal surface (11) and a male-threaded portion (12). The male-threaded portion (12) includes an inner male-threaded portion (121) and an outer male-threaded portion (122). The box (20) has a box inner seal surface (21) and a female-threaded portion (22). The female-threaded portion (22) includes an inner female-threaded portion (221) and an outer female-threaded portion (222). A gap (G) of 0.2 mm or more is formed between a thread crest surface (123) of the male-threaded portion (12) and a thread groove bottom surface (224) of the female-threaded portion (22) and/or between a thread groove bottom surface (124) of the male-threaded portion (12) and a thread crest surface (223) of the female-threaded portion (22). The threaded joint (100) satisfies the condition of L/t ≥ 1.0 or D ≥ 11.0 [mm]. L is the length of a complete engagement region (40), t is the wall thickness of a steel pipe body, and D is the distance from a contact position (P1) of the inner seal surfaces (11, 21) to the inner male-threaded portion (121).
This waste plastic treatment facility comprises: a wind power sorting device (10) to which waste plastic is supplied; a means (20) for agglomerating waste plastic separated as low-density objects in the wind power sorting device (10); and a coke oven (30) into which the agglomerated waste plastic and waste plastic separated as high-density objects in the wind power sorting device (10) are charged and which thermally decomposes the waste plastics.
C10B 53/07 - Distillation destructive spécialement conçue pour des matières premières solides particulières ou sous forme spéciale de matières polymères synthétiques, p. ex. pneumatiques
C08J 11/12 - Récupération ou traitement des résidus des polymères par coupure des chaînes moléculaires des polymères ou rupture des liaisons de réticulation par voie chimique, p. ex. dévulcanisation uniquement par traitement à la chaleur sèche
26.
LAMINATED IRON CORE MANUFACTURING APPARATUS AND MANUFACTURING METHOD
Provided are a laminated iron core manufacturing apparatus and manufacturing method that make it possible to more reliably separate a laminated iron core from an iron core thin plate group and to increase the speed at which the iron core thin plates are punched. A laminated iron core 4 manufacturing apparatus 1 according to the present invention is for manufacturing a laminated iron core 4 obtained by punching and forming iron core thin plates 3 having a prescribed shape from a steel plate 2 and laminating and bonding a prescribed number of the iron core thin plates 3. The manufacturing apparatus 1 comprises: a punching part 5 for punching the iron core thin plates 3 from the steel plate 2; an adhesive application part 6 for applying an adhesive to sites corresponding to the iron core thin plates 3 of the steel plate 2; a lamination part 7 for forming an iron core thin plate group 30 by laminating and adhering the iron core thin plates 3 in a state in which the adhesive is applied; and a separation part 8 that bites between iron core thin plates 3 adjacent to each other in the iron core thin plate group 30 and separates the laminated iron core 4 from the iron core thin plate group 30. The lamination part 7 has a plurality of pairs of lateral pressure application parts 71 that apply lateral pressure to the iron core thin plate group 30, each pair of lateral pressure application parts 71 are arranged so as to face each other with the iron core thin plate group 30 interposed therebetween, and at least one of the lateral pressure application parts 71 also serves as the separation part.
Provided are a manufacturing device and a manufacturing method for a laminated iron core, which are capable of more easily assembling an adhesive application means and shortening a time required for maintenance. A manufacturing device 1 for a laminated iron core 4 according to the present invention includes: an adhesive application means 6 for applying an adhesive to a region corresponding to an iron core thin plate 3 of a steel plate 2; a forward/backward drive unit 7 for switching whether or not to perform application of the adhesive by the adhesive application means 6; and a buffer member 8 for allowing displacement of the adhesive application means 6 in a forward/backward direction. The adhesive application means 6 has a discharge unit 60 configured to discharge the adhesive from the tip of the passage 60a. The adhesive application means 6 is disposed so that, when the adhesive is applied, the adhesive discharged from the tip of the discharge unit 60 is brought into contact with the steel plate 2 according to the vertical movement of the steel plate 2 in association with the punching formation of the iron core thin plate 3 from the steel plate 2. The adhesive application means 6 is configured so that the contact pressure of the tip to the steel plate 2 is adjusted by the buffer member 8.
H02K 15/02 - Procédés ou appareils spécialement adaptés à la fabrication, l'assemblage, l'entretien ou la réparation des machines dynamo-électriques des corps statoriques ou rotoriques
B21D 28/02 - Découpage à l'emporte-pièce ou poinçonnage de flans ou d'objets, avec ou sans production de déchetsEntaillage
H01F 41/02 - Appareils ou procédés spécialement adaptés à la fabrication ou à l'assemblage des aimants, des inductances ou des transformateursAppareils ou procédés spécialement adaptés à la fabrication des matériaux caractérisés par leurs propriétés magnétiques pour la fabrication de noyaux, bobines ou aimants
H02K 15/121 - Imprégnation, chauffage ou séchage des bobinages, des stators, des rotors ou des machines des noyaux
28.
MANUFACTURING APPARATUS AND MANUFACTURING METHOD FOR LAMINATED IRON CORE
Provided are a manufacturing apparatus and a manufacturing method for a laminated iron core, the apparatus and method being capable of suppressing unnecessary spreading of an adhesive and reducing the risk of the adhesive entering unintended areas. According to the present invention, a manufacturing apparatus 1 for a laminated iron core 4 forms an iron core thin plate 3 having a predetermined shape by punching from a steel plate 2, and manufactures a laminated iron core 4 in which a predetermined number of the iron core thin plates 3 are laminated and bonded. The manufacturing apparatus 1 comprises: an adhesive application means 14 for applying an adhesive 140 to a portion 2a of a steel plate 2 corresponding to an iron core thin plate 3; and a punching part 15 for punching the iron core thin plate 3 from the steel plate 2 after the application of the adhesive 140 by the adhesive application means 14, the punching part 15 being composed of a die including an upper die 130 and a lower die 131. The upper die 130 or the lower die 131 is provided with: a recessed part 50 provided at a position corresponding to the part 2a to which the adhesive 140 has been applied; and a ventilation port 51 for providing communication between the internal space of the recessed part 50 and the outside of the upper die 130 or the lower die 131.
H02K 15/02 - Procédés ou appareils spécialement adaptés à la fabrication, l'assemblage, l'entretien ou la réparation des machines dynamo-électriques des corps statoriques ou rotoriques
B21D 28/02 - Découpage à l'emporte-pièce ou poinçonnage de flans ou d'objets, avec ou sans production de déchetsEntaillage
H01F 41/02 - Appareils ou procédés spécialement adaptés à la fabrication ou à l'assemblage des aimants, des inductances ou des transformateursAppareils ou procédés spécialement adaptés à la fabrication des matériaux caractérisés par leurs propriétés magnétiques pour la fabrication de noyaux, bobines ou aimants
H02K 15/121 - Imprégnation, chauffage ou séchage des bobinages, des stators, des rotors ou des machines des noyaux
29.
DEVICE FOR MANUFACTURING LAMINATED CORE AND METHOD FOR MANUFACTURING LAMINATED CORE
This device for manufacturing a laminated core comprises: an upper die and a lower die for pressing a strip-form steel sheet being fed toward the downstream side to punch a steel sheet component; a lamination unit that is provided to the lower die and bonds and laminates the punched steel sheet component using an adhesive; and a coating unit that is provided on the upstream side from the lamination unit of the lower die or the upper die in the feeding direction of the strip-form steel sheet and applies the adhesive to one surface of the strip-form steel sheet. The coating unit has a plurality of discharge port units for continuously discharging the adhesive, and each of the discharge port units is configured from a non-metal material.
H02K 15/02 - Procédés ou appareils spécialement adaptés à la fabrication, l'assemblage, l'entretien ou la réparation des machines dynamo-électriques des corps statoriques ou rotoriques
30.
DEVICE FOR MANUFACTURING LAMINATED CORE AND METHOD FOR MANUFACTURING LAMINATED CORE
This device for manufacturing a laminated core comprises: an upper mold and a lower mold for punching a core by pressing a steel strip being transported downstream; a lamination part which is provided in the lower mold and laminates a punched core; an application part which is provided upstream of the lamination part in the lower mold in the transport direction of the steel strip, and applies an adhesive to the lower surface of the steel strip, the application part being in contact with a restraint part, provided in the lower mold, and thus restrained in movement in a direction crossing the mold opening/closing direction; and a discharge mechanism which is provided in the lower mold and discharges the remaining unapplied adhesive from the application part.
H02K 15/02 - Procédés ou appareils spécialement adaptés à la fabrication, l'assemblage, l'entretien ou la réparation des machines dynamo-électriques des corps statoriques ou rotoriques
31.
HOT-DIP PLATED STEEL MATERIAL AND METHOD FOR PRODUCING HOT-DIP PLATED STEEL MATERIAL
C23C 8/16 - Oxydation au moyen de composés contenant de l'oxygène, p. ex. H2O, CO2
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
Provided is a cooling structure (1) having water-cooling medium flow paths (25) formed so as to be in contact with a bottom surface portion (10a) of a battery pack (10). The cooling structure (1) has a flow path formation part (21) that forms a portion of the water-cooling medium flow paths (25). The flow path formation part (21) is joined to an adherend member by an adhesion part (30). The adherend member is made of a steel sheet obtained by forming an inorganic coating or a resin coating as a chemical conversion coating on an Al-based plated steel sheet or a Zn-based plated steel sheet. The flow path formation part (21) is made of an aluminum alloy. The thickness of the adhesion part (30) is at least 0.0005 mm. The adhesion part (30) protrudes by at least 0.1 mm toward the water-cooling medium flow paths (25). The flow path interval between the water-cooling medium flow paths (25) is at most 20 mm. The width of the water-cooling medium flow paths (25) is at most 60 mm.
C23C 22/40 - Traitement chimique de surface de matériaux métalliques par réaction de la surface avec un milieu réactif laissant des produits de réaction du matériau de la surface dans le revêtement, p. ex. revêtement par conversion, passivation des métaux au moyen de solutions aqueuses au moyen de solutions aqueuses acides d'un pH < 6 contenant des molybdates, des tungstates ou des vanadates
C23C 22/53 - Traitement du zinc ou des alliages à base de zinc
C23C 22/56 - Traitement de l'aluminium ou des alliages à base d'aluminium
C23C 26/00 - Revêtements non prévus par les groupes
H01M 10/613 - Refroidissement ou maintien du froid
H01M 10/651 - Moyens de commande de la température associés de façon structurelle avec les éléments caractérisés par des paramètres spécifiés par une valeur numérique ou une formule mathématique, p. ex. rapports, tailles ou concentrations
H01M 10/655 - Structures solides pour l'échange ou la conduction de la chaleur
H01M 10/6568 - Liquides caractérisés par des circuits d'écoulement. p. ex. boucles, situés à l'extérieur des éléments ou des boîtiers des éléments
33.
HOT DIPPED STEEL MATERIAL AND METHOD FOR PRODUCING HOT DIPPED STEEL MATERIAL
This hot dipped steel material has: a steel material; and a plating layer that is formed on the surface of the steel material and has a specific chemical composition. The thickness of the plating layer is 5 μm or more. The plating layer has a first region and a second region, and satisfies the following formulae (1) to (6): (1) Ra_A ≤ 10.0; (2) Ra_B ≤ 10.0; (3) 1.5 ≤ |Ra_A - Ra_B|; (4) 150 ≤ HV_x ≤ 350; (5) 200 ≤ HV_max; and (6) 0.80 ≤ HV_big/HV_sml ≤ 1.50.
B24C 1/04 - Méthodes d'utilisation de jet abrasif en vue d'effectuer un travail déterminéUtilisation d'équipements auxiliaires liés à ces méthodes pour travailler uniquement certaines parties déterminées, p. ex. pour graver la pierre ou le verre
B24C 11/00 - Emploi de matériaux abrasifs spécifiés pour les jets abrasifs
This determination system comprises: an imaging device provided in a conveyance machine for conveying iron scrap; and a foreign matter determination device that acquires a determination target image captured by the imaging device and determines whether the iron scrap includes foreign matter.
A crawler link (7), which is a wear-resistant component, comprises: a high-hardness part (7A) that is composed of steel having a specific component composition, has a hardness of 57-60 HRC, and has a martensite structure; and a low-hardness part (7B) that is a region other than the high-hardness part (7A), has a lower hardness than the high-hardness part (7A), and has a martensite structure. The high-hardness part (7A) includes: a parent phase composed of martensite; and carbides (92) dispersed in a lath (91) of the parent phase. The area ratio of the carbides (92) in the cross section of the high-hardness part (7A) is at least 9%.
This cutting device cuts a workpiece sandwiched in a first direction, wherein: a first tool 110 and a second tool 120 are arranged facing one other in the first direction; a blade portion 110a of the first tool and a blade portion 120a of the second tool each have a pressing surface S1 perpendicular to the first direction and a first vertical wall surface S2 perpendicular to the pressing surface S1; at least one of the blade portion 110a of the first tool and the blade portion 120a of the second tool has a tool inclined surface S3 between the pressing surface S1 and the first vertical wall surface S2, the angle formed by the pressing surface S1 and the tool inclined surface S3 being an obtuse angle; and a clearance C [mm] between the first tool 110 and the second tool 120 and a distance d [mm] between the pressing surfaces S1 satisfy formula (A). (A): n
B23D 19/06 - Machines à cisailler ou dispositifs de cisaillage taillant au moyen de disques rotatifs ayant des disques de cisaillage rotatifs disposés par paires travaillant conjointement avec plusieurs paires de disques de cisaillage espacées travaillant simultanément, p. ex. pour rogner ou fabriquer des bandes
In this blast furnace operation method, a first reducing gas containing a hydrogen-based reducing gas as a main component is blown into a blast furnace, a second reducing gas recovered and separated from furnace top exhaust gas and containing at least 50% of CO gas by volume fraction is blown into the blast furnace, and the temperature of the second reducing gas is raised to a blowing temperature before the second reducing gas is blown into the blast furnace, wherein the blowing temperature of the second reducing gas is determined on the basis of the amount of the first reducing gas blown into the blast furnace and the amount of the second reducing gas blown into the blast furnace.
The present invention provides an Ni-based alloy tube which is capable of achieving sufficient nitriding resistance in a high-temperature ammonia environment. An Ni-based alloy tube according to the present disclosure has a chemical composition set forth in the description, and a developed area ratio Sdr on the inner surface of the Ni-based alloy tube satisfies formula (1). (1): Cr/((2.0 + 0.8 × Fe + 6.0 × Ti) × (1.5 + 10.0 × Sdr)) ≥ 0.9 In formula (1), the content, in mass%, of an element is assigned to each of the corresponding element symbols. In cases where an element is not contained, "0" is assigned to the corresponding element symbol.
C22C 19/05 - Alliages à base de nickel ou de cobalt, seuls ou ensemble à base de nickel avec du chrome
B21C 23/00 - Extrusion des métauxExtrusion par percussion
B21C 23/08 - Fabrication de fils, de barres, de tubes
C22F 1/00 - Modification de la structure physique des métaux ou alliages non ferreux par traitement thermique ou par travail à chaud ou à froid
C22F 1/10 - Modification de la structure physique des métaux ou alliages non ferreux par traitement thermique ou par travail à chaud ou à froid du nickel ou du cobalt ou de leurs alliages
39.
FILM-LAMINATED STEEL SHEET AND METHOD FOR MANUFACTURING DRAWN AND IRONED CAN
[Problem] To further improve the punching property while maintaining ironing moldability during drawing-and-ironing molding. [Solution] A film-laminated steel sheet according to the present invention comprises: a steel sheet that serves as a base material; a film layer that is provided on the front and back surfaces of the steel sheet and that is constituted by a thermoplastic polyester film; and a wax layer that is provided on the film layer, wherein the adhesion amount of the wax layer is within the range of 0.030-0.135 g/m2 per surface, the adhesion amount of the wax layer is different between the front-side surface and the back-side surface of the steel sheet, and the adhesion amount ratio, which is obtained by dividing the adhesion amount of the wax layer on a large-adhesion-amount-side surface by the adhesion amount of the wax layer on a small-adhesion-amount-side surface, is within the range of 1.05-1.35.
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 1/12 - Boîtes de conserves, barils, tonneaux ou fûts
B65D 65/42 - Emploi de substances enduites ou imprégnées
40.
FILM-LAMINATED STEEL SHEET AND METHOD FOR MANUFACTURING DI CAN
[Problem] To further improve drawing moldability while maintaining punch release properties during DI molding. [Solution] A film-laminated steel sheet according to the present invention comprises: a steel sheet serving as a base material; a film layer composed of a thermoplastic polyester film and disposed on the front and back surfaces of the steel sheet; and a wax layer disposed on the film layer, wherein the coating weight of the wax layer is 0.030-0.120 g/m2 per surface, the coating weight of the wax layer differs between the front surface and the back surface of the steel sheet, and the coating weight ratio obtained by dividing the coating weight of the wax layer on a higher coating weight-side surface by the coating weight of the wax layer on a lower coating weight-side surface is in the range of 1.04-1.67.
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 1/12 - Boîtes de conserves, barils, tonneaux ou fûts
B65D 65/42 - Emploi de substances enduites ou imprégnées
41.
STRUCTURAL MEMBER, METHOD FOR MANUFACTURING STRUCTURAL MEMBER, AND MOLD
A structural member (S, S2) comprises a wheel house (20) and side frames (31). The wheel house (20) includes a wheel house body (21) and a flange (22). The wheel house body (21) forms a space for accommodating a wheel. The flange (22) protrudes outward from the distal end of the wheel house body (21). The side frames (31) are formed integrally with the wheel house (20). The side frames (31) are joined to the wheel house (20) by welding. In each side frame (31), the minimum value of the Vickers hardness of the heat affected zone of a welded portion (50) is 70% or more of the Vickers hardness of the non-welded portions.
A prediction device according to the present invention comprises a prediction unit that calculates a first fraction for a first period and a second fraction for a second period for each phase of a plating layer on the basis of how much of each of a plurality of components is included in the plating layer, calculates the period length of the first period, which is until a portion of the corrosion of the plating layer reaches a base steel, on the basis of a corrosion rank for each phase, the first fraction for each phase, and a first corrosion speed for each phase, calculates the period length of the second period, which follows the first period, on the basis of the corrosion rank for each phase, the second fraction for each phase, and a second corrosion speed for each phase, and calculates the total of the period length of the first period and the period length of the second period as prediction results for the corrosion resistance of the plating layer.
G01N 17/00 - Recherche de la résistance des matériaux aux intempéries, à la corrosion ou à la lumière
C23C 2/00 - 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 immergéAppareils à cet effet
Provided is a welded joint characterized by comprising: a plurality of overlapped steel sheets; a spot welding part having a nugget, a pressure contact part formed around the nugget, and a heat-affected part; and a separation part, at least one of the steel sheets being an Al-containing plated steel sheet provided with a base material steel sheet and a plating layer formed on at least the surface, from among the surfaces of the base material steel sheet, that corresponds to an overlap surface where a plurality of steel sheets overlap, the plating layer of the Al-containing plated steel sheet containing Zn and/or the steel sheet adjacent to the Al-containing plated steel sheet having Zn-containing plating on the surface thereof that corresponds to the overlap surface, the plating layer in the separation part on the outside of the heat-affected part having a prescribed chemical composition, the thickness of an Fe-Al phase being 10-200 μm in the plating layer of the separation part in a region 1 mm from the end section of the pressure contact part, and the area ratio of a Zn-rich phase being 0-20%.
Provided is a steel sheet characterized in that the tensile strength thereof is 1660 MPa or more, the metal structure thereof has, in terms of area%, 85.0% or more of martensite and 1.0%-7.0% of residual austenite, the balance structure making up 10.0% or less.
Provided is a welded joint in which: a base material has a specific chemical composition in which α in the below formula is 5.0 to 16.0; the tensile strength is 615 MPa to 930 MPa; as regards the microstructure at a position 1/4 of the thickness from the surface, the total of the area percentages of lower bainite and martensite is 15.0% or more, the total of the area percentages of upper bainite, lower bainite, and martensite is 90.0% or more, and the area percentage of residual austenite is less than 1.7%; and the effective grain size in the region between the melt line of the weld part and a position that is 1 mm away from the melt line of the welding heat-affected part is 100.0 μm. Also provided is a pressure vessel including the welded joint. α=0.50×√[C]×(1+0.64[Si])×(1+4.10[Mn])×(1+0.27[Cu])×(1+0.52[Ni])×(1+2.33[Cr])×(1+3.14[Mo])
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
B23K 9/23 - Soudage ou découpage à l'arc tenant compte des propriétés des matériaux à souder
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
An evaluation device (100) evaluates the vibration of a magnetic material. The evaluation device (100) is provided with a magnetic core (10), a plurality of winding parts (20), and first measurement devices (31, 32, 33). The magnetic core (10) is made of a magnetic material. The magnetic core (10) includes a leg part (11). The winding parts (20) are arranged with a gap (G) in the axial direction of the leg part (11), and are attached to the leg part (11) in such a manner that the leg part (11) is exposed from the gap (G). The winding parts (20) are constructed to excite the magnetic core (10) by energization. The first measurement devices (31, 32, 33) measure the vibration of the leg part (11).
G01H 17/00 - Mesure des vibrations mécaniques ou des ondes ultrasonores, sonores ou infrasonores non prévue dans les autres groupes de la présente sous-classe
G01R 33/12 - Mesure de propriétés magnétiques des articles ou échantillons de solides ou de fluides
The hot-rolled steel sheet according to the present invention has a desired chemical composition, and in the internal region, the average aspect ratio of prior-austenite grains is 4.00-6.00, the area ratio of the martensite is 90% or more, and the value obtained by dividing the average aspect ratio of prior-austenite grains in the surface layer region by the average aspect ratio of prior-austenite grains in the internal region is less than 0.950.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
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
This hot-stamp molded body has a desired chemical composition, has a tensile strength of 1800 MPa or more, has an average value of residual stress on a steel sheet surface of −250 MPa or less, and has an Hvs/Hvi ratio of 0.90 or less, Hvs/Hvi being the ratio of the average hardness Hvs in a surface layer region that is a region 20-50 μm deep from the surface and the average hardness Hvi at a depth of 1/4 of the plate thickness from the surface.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
C22C 38/58 - Alliages ferreux, p. ex. aciers alliés contenant du chrome et du nickel et plus de 1,5% en poids de manganèse
B24C 1/10 - Méthodes d'utilisation de jet abrasif en vue d'effectuer un travail déterminéUtilisation d'équipements auxiliaires liés à ces méthodes pour augmenter la compacité des surfaces, p. ex. par grenaillage
B24C 11/00 - Emploi de matériaux abrasifs spécifiés pour les jets abrasifs
C21D 1/18 - DurcissementTrempe avec ou sans revenu ultérieur
C21D 7/06 - Modification des propriétés physiques du fer ou de l'acier par déformation par travail à froid de la surface par grenaillage ou similaire
C21D 9/00 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet
C21D 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
This shock-absorbing member is long in one direction and comprises a hollow tube and a reinforcement arranged in a fixed manner inside the hollow tube. The hollow tube comprises a steel material having a tensile strength of 650-1600 MPa. The reinforcement comprises a steel material having a tensile strength of 590-1600 MPa. In a cross section perpendicular to the lengthwise direction of the shock-absorbing member, the hollow tube has a top wall section and a pair of side wall sections, the reinforcement has a horizontal plate connected between the pair of side wall sections and a vertical plate connected between the top wall section and a position between one end and the other end of the horizontal plate, the hollow tube has a first part, a second part, and a third part arranged in this order along the lengthwise direction, and the second part has a fold start point section.
B62D 21/15 - Châssis, c.-à-d. armature sur laquelle une carrosserie peut être montée comportant des moyens amortisseurs de chocs, p. ex. châssis conçus pour changer de forme ou de dimensions d'une façon définitive ou temporaire à la suite d'une collision avec un autre corps
B60R 19/18 - Moyens pour absorber le choc situés à l'intérieur du pare-chocs
B62D 21/00 - Châssis, c.-à-d. armature sur laquelle une carrosserie peut être montée
Disclosed is a technology for imparting a color tone difference to a silicon nitride-based sintered body. A silicon nitride-based sintered body according to the present disclosure is characterized by having a plurality of crystal grains and a grain boundary phase that bonds the crystal grains to each other, and by having a lightness difference of 5 or more in terms of the L* value. The silicon nitride-based sintered body according to the present disclosure is obtained, for example, by kneading a silicon nitride powder and a powder of an auxiliary starting material so as to obtain a granulated body, and subsequently molding the granulated body and firing the molded body under specific conditions.
Disclosed is a technique that increases the brightness of a surface of a silicon nitride-based sintered body. A silicon nitride-based sintered body according to the present disclosure has a plurality of crystal grains and a grain boundary phase that binds the crystal grains to each other, has an L* value of 55 or more in at least a portion of the surface, and has a thickness of 10 mm or more. The silicon nitride-based sintered body according to the present disclosure is obtained, for example, by kneading a silicon nitride powder and a powder of a sub-raw material to obtain a granulated body, and then molding and sintering the granulated body under a predetermined condition.
The hot-rolled steel sheet according to the present invention has a desired chemical composition, and in the internal region, the average aspect ratio of prior-austenite grains is 3.00 to 5.50, the area ratio of bainite is 70 to 95%, the area ratio of martensite is 5 to 30%, and the value obtained by dividing the average aspect ratio of prior-austenite grains in the surface layer region by the average aspect ratio of prior-austenite grains in the internal region is less than 1.00.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
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 hot-rolled steel sheet according to the present invention has a desired chemical composition, and in the internal region, the average aspect ratio of prior-austenite grains is 2.00 or more and less than 4.00, the area ratio of the martensite is 90% or more, and the value obtained by dividing the average aspect ratio of prior-austenite grains in the surface layer region by the average aspect ratio of prior-austenite grains in the internal region is less than 0.950.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
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
This impact absorption member is provided in a vehicle body, is formed along a prescribed longitudinal direction, and includes a closed cross section part in which a cross section orthogonal to the longitudinal direction has a closed cross-sectional shape. The impact absorption member is provided with: a low-strength part; a high-strength part that has the central part in the plate thickness direction in parallel with the low-strength part, the central part having a higher Vickers hardness than the central part in the plate thickness direction of the low-strength part; and a joining part that joins the low-strength part and the high-strength part. The maximum bending angle of the high-strength part is set according to the maximum bending angle of the low-strength part.
This shock absorption member has a configuration in which a breaking start-point is provided in a hollow tube, or a configuration in which a breaking start-point is provided in a reinforcement. The shock absorption member further includes a pair of reinforcement parts that extend along an extension direction of each ridge section of the hollow tube, each reinforcement part being provided at a position adjacent to the ridge section on an outer surface of a side wall part when the hollow tube is viewed in a cross section perpendicular to the longitudinal direction at a position of a start point section.
F16F 7/12 - Amortisseurs de vibrationsAmortisseurs de chocs utilisant une déformation plastique de ses organes
B62D 21/15 - Châssis, c.-à-d. armature sur laquelle une carrosserie peut être montée comportant des moyens amortisseurs de chocs, p. ex. châssis conçus pour changer de forme ou de dimensions d'une façon définitive ou temporaire à la suite d'une collision avec un autre corps
F16F 7/00 - Amortisseurs de vibrationsAmortisseurs de chocs
57.
ESTIMATION DEVICE, ESTIMATION METHOD, ESTIMATION SYSTEM, EVALUATION METHOD, AND COMPUTER PROGRAM
This estimation device comprises a control unit that, by using an estimation model constructed in advance by using known data including supplementary information that is information on iron scrap including iron to be recycled and information on a concentration of an impurity element included in the iron scrap, estimates a concentration of an impurity element included in iron scrap to be evaluated.
25i250i00≤0.70; the Mg content in the surface oxide film is 0.05 atom% or more; and the adhesion amount of the plating layer is 20 g/m2 or more per surface.
This steel material has a prescribed chemical composition, wherein, in a cross-section perpendicular to the rolling direction, when d/2 is defined as the length of a line segment connecting the center of gravity of the cross-section to the surface of the cross-section which is nearest to the center of gravity, and a d/4 part is defined as the position of d/4 in the direction of the center of gravity from said surface, at the d/4 part of the cross-section, the number density of MnS with an area of 1.0-10.0 μm2is not more than 70.0 per mm2, the number density of MnS with an area of greater than 10.0 μm2is not more than 4.00 per mm2, and the number density of Nb-based precipitates with an area or not less than 20.0 μm2is not more than 0.20 per mm2.
C21D 1/32 - Recuit d'adoucissement, p. ex. sphéroïdisation
C21D 8/06 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de barres ou de fils
C21D 9/00 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet
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
61.
METHOD FOR PRODUCING GRAIN-ORIENTED ELECTRICAL STEEL SHEET, GRAIN-ORIENTED ELECTRICAL STEEL SHEET, AND INDUSTRIAL PRODUCT
The present invention provides a method for producing a grain-oriented electrical steel sheet in which a plurality of grooves that extends in a direction that is generally parallel to the width direction of a steel sheet is formed in the longitudinal direction of the steel sheet, the method including: a first groove formation step for forming a first groove comprising a plurality of grooves which extends in a direction that is generally parallel to the width direction on a cold-rolled steel sheet that serves as a material for the grain-oriented electrical steel sheet; a secondary recrystallization annealing step for annealing the cold-rolled steel sheet, on which the first groove has been formed, so as to align the easy axis of magnetization of the cold-rolled steel sheet in the longitudinal direction to form a grain-oriented electrical steel sheet; and a second groove formation step for forming a second groove comprising a plurality of grooves which extends in a direction that is generally parallel to the width direction on the grain-oriented electrical steel sheet using a contact-type groove formation process.
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 particuliersFours à cet effet pour tôles
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
H01F 1/147 - Alliages caractérisés par leur composition
θθθ is not more than 1.50%; the average particle diameter of the cementite particles is not more than 1.50 μm; the maximum particle diameter of the cementite particles is not more than 5.00 μm; and the spheroidization ratio of the cementite particles is not less than 75%.
A vehicle subframe 10 is fixed to a vehicle body, and includes a structural member that extends in a curved manner in a planar view from above the vehicle body, wherein: the structural member is made of a steel material and has an open cross-sectional shape in a direction perpendicular to an extension direction; the cross-sectional shape differs depending on a position in the extension direction of the structural member; and the structural member includes a reinforcing member 14 that is fixed at a predetermined position in the extension direction of the structural member.
[Problem] To provide a battery case and a lithium-ion battery that have exceptional electrolyte resistance and make it possible to prevent peeling of an oxide film on the inner-surface side of the battery case. [Solution] The present invention relates to a battery case for a lithium ion-battery, the battery case having a case body portion that accommodates a battery unit and a lithium-salt-containing electrolyte solution, and a lid portion that seals the case body portion. The material of the case body portion and the lid portion is a plated steel sheet in which a plating layer is provided to a base material steel sheet. A weld part at which the case body portion and the lid portion are joined to each other by welding is present in the battery case. The inner-surface side of the battery case at the weld part has a weld metal that contains not less than 0.3 mass% but less than 60.0 mass% of the main constituent component of the plating layer, and an oxide film layer that is present in a portion of the surface of the weld metal that may contact the electrolyte solution. The oxide film layer has a thickness of 5.0 μm or less.
H01M 50/15 - Couvercles caractérisés par leur forme pour des cellules prismatiques ou rectangulaires
H01M 50/103 - Boîtiers primairesFourreaux ou enveloppes caractérisés par leur forme ou leur structure physique prismatique ou rectangulaire
H01M 50/107 - Boîtiers primairesFourreaux ou enveloppes caractérisés par leur forme ou leur structure physique ayant une section transversale courbe, p. ex. ronde ou elliptique
H01M 50/145 - Boîtiers primairesFourreaux ou enveloppes pour protéger contre les dommages causés par des facteurs externes pour protéger contre la corrosion
H01M 50/152 - Couvercles caractérisés par leur forme pour des cellules ayant une section transversale courbée, p. ex. ronde ou elliptique
C22C 18/04 - Alliages à base de zinc avec l'aluminium comme second constituant majeur
C22C 19/03 - Alliages à base de nickel ou de cobalt, seuls ou ensemble à base de nickel
C22C 19/05 - Alliages à base de nickel ou de cobalt, seuls ou ensemble à base de nickel avec du chrome
C22F 1/00 - Modification de la structure physique des métaux ou alliages non ferreux par traitement thermique ou par travail à chaud ou à froid
C22F 1/16 - Modification de la structure physique des métaux ou alliages non ferreux par traitement thermique ou par travail à chaud ou à froid des autres métaux ou de leurs alliages
C23C 2/02 - Pré-traitement du matériau à revêtir, p. ex. pour le revêtement de parties déterminées de la surface
C23C 28/02 - Revêtements uniquement de matériaux métalliques
Provided are a steel material and a pressure vessel containing the steel material, the steel material containing 2.65-4.45% of Ni in terms of mass%, comprising C, Si, Mn, P, S, Al, O, N, Cu, Cr, Mo, B, Nb, Ti, V, Mg, Ca, REM, Fe, and impurities within prescribed composition ranges, and being such that: α, represented by the expression α = 0.50 × √[C] × (1 + 0.64[Si]) × (1 + 4.10[Mn]) × (1 + 0.27[Cu]) × (1 + 0.52[Ni]) × (1 + 2.33[Cr]) × (1 + 3.14[Mo]), is 4.0-16.0; β, represented by the expression β = [Mn] × [P]-[Mo]/100, is 0.017 or lower; the tensile strength is 590-930 MPa; the microstructure at a site at 1/4 of the thickness in the thickness direction from the surface of the steel material includes lower bainite and martensite; the total area ratio of the lower bainite and the martensite is 15.0% or higher; and the total area ratio of upper bainite, the lower bainite, and the martensite is 90.0% or higher.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 particuliersFours à cet effet
C21D 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
C21D 9/50 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour joints de soudure
C22C 38/08 - Alliages ferreux, p. ex. aciers alliés contenant 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
Provided are a steel material and a pressure vessel that includes the steel material, the steel material having a specific chemical composition in which α is 5.0-16.0 and a tensile strength of 615-930 MPa, and a microstructure in a location at 1/4 of the thickness from the surface of the steel material including lower bainite and martensite, the total area ratio of the lower bainite and the martensite being 15.0% or more, the total area ratio of the upper bainite, the lower bainite, and the martensite being 90.0% or more, the area ratio of residual austenite being less than 1.7%, and the Mn concentration of a center segregation part in a location at 1/2 of the thickness being 2.00% or less. α = 0.50 × √[C] × (1 + 0.64[Si]) × (1 + 4.10[Mn]) × (1 + 0.27[Cu]) × (1 + 0.52[Ni]) × (1 + 2.33[Cr]) × (1 + 3.14[Mo])
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 particuliersFours à cet effet
C21D 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
C21D 9/50 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour joints de soudure
C22C 38/08 - Alliages ferreux, p. ex. aciers alliés contenant du nickel
C22C 38/54 - Alliages ferreux, p. ex. aciers alliés contenant du chrome et du nickel et du bore
Provided is a rail capable of obtaining excellent wear resistance and damage resistance. A rail (1) according to an embodiment of the present invention contains 0.80%-1.20% of C, 0.80%-2.50% of Si, 0.10%-2.00% of Mn, 0.0250% or less of P, and 0.0250% or less of S in terms of mass%, with the balance being Fe and impurities. The metal structure of a head surface part (10A) has a pearlite area ratio of 95% or more and a Vickers hardness of 400 HV or more. In the head surface part (10A), the Si positive segregation degree, which is the ratio of the maximum value of the Si concentration in a Si positive segregation band to the Si concentration in a bulk region, is more than 1.00 to 1.35, and the Si negative segregation degree, which is the ratio of the minimum value of the Si concentration in a Si negative segregation band to the Si concentration in the bulk region, is 0.90 to less than 1.00.
This invention provides a welded joint that, even after PWHT, has a tensile strength of at least 780 MPa and excels in toughness. A welded joint (1) according to the present invention contains a weld metal in a welded part (2), and is characterized in that the weld metal has a specific chemical composition, and in a region between a depth position of 2 mm from the surface and a depth position of 12 mm from the surface in the center part of the welded part (2), the same contains a reheated zone region (32) at a structure ratio of 34% or more.
B23K 31/00 - Procédés relevant de la présente sous-classe, spécialement adaptés à des objets ou des buts particuliers, mais non couverts par un seul des groupes principaux
B23K 9/095 - Surveillance ou commande automatique des paramètres de soudage
B23K 35/30 - Emploi de matériaux spécifiés pour le soudage ou le brasage dont le principal constituant fond à moins de 1550 C
C21D 9/50 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour joints de soudure
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
This automotive structural member is provided with a hat-shaped first member and a hat-shaped second member. The first member has a first top plate, two first vertical walls, two first flanges, and first standing parts. The first flanges are respectively located between the first vertical walls and the first standing parts. The second member has a second top plate, two second vertical walls, and two second flanges. The second top plate is positioned between the two first vertical walls of the first member. The second vertical walls respectively face the first vertical walls of the first member. Each gap formed between the second vertical wall and the first vertical wall is 5.0 mm or less. The second flanges are respectively joined to the first flanges. The second member comprises a steel material having a tensile strength of 690 MPa or more.
B60R 19/04 - Pare-chocs, c.-à-d. éléments pour recevoir ou absorber les chocs pour protéger les véhicules ou dévier les chocs provenant d'autres véhicules ou objets formés de plusieurs sections
B62D 21/15 - Châssis, c.-à-d. armature sur laquelle une carrosserie peut être montée comportant des moyens amortisseurs de chocs, p. ex. châssis conçus pour changer de forme ou de dimensions d'une façon définitive ou temporaire à la suite d'une collision avec un autre corps
25i250i00 ≤ 0.70; the Mg content in the surface oxide film is 0.10% by atom or more; and the adhesion amount of the plating layer is 20 g/m2 or more per one surface.
The present invention provides a plated steel sheet which is characterized by including a base steel sheet and a plating layer that is formed on the surface of the base steel sheet, and which is also characterized in that: the plating layer has a specific chemical composition; the plating layer includes an Fe-Al phase that is located at the interface with the base steel sheet, and a main layer that is located on the Fe-Al phase; in a cross-section of the main layer, the area ratio of a Mg-Al-Zn-Si intermetallic compound phase having an Al content of 10% by mass or more is 0.010% or more; the Fe-Al phase contains 3.0-15.0% by mass of Si and 2.0-15.0% by mass of Zn; and the adhesion amount of the plating layer is 20 g/m2 or more per one surface.
This steel material has a prescribed chemical composition. When the Al content in mass% is defined as [Al] and the N content is defined as [N], the [Al] and the [N] satisfy a prescribed relationship. In a cross section perpendicular to a rolling direction, if the length of a line segment connecting the center of gravity of the cross section and the surface of the cross section closest to the center of gravity is defined as d/2, when the position of d/2 in the direction of the center of gravity from the surface is defined as a d/2 part, and the position of d/4 in the direction of the center of gravity from the surface is defined as a d/4 part, the solid solution Al amount is 0.018 mass% or more and the solid solution N amount is 0.009 mass% or more in both the d/2 part and the d/4 part, the number density of MnS having an area of 1.0-10.0 μm2is 70.0 particles/mm2or less in the d/4 part, and the number density of MnS having an area exceeding 10.0 μm2is 4.0 particles/mm2 or less.
C21D 8/06 - Modification des propriétés physiques par déformation en combinaison avec, ou suivie par, un traitement thermique pendant la fabrication de barres ou de fils
C22C 38/50 - Alliages ferreux, p. ex. aciers alliés contenant du chrome et du nickel et du titane ou du zirconium
A sub-frame 10 for a vehicle is fixed to a vehicle body, and comprises a structural member which is curved and extends in a plan view from an upper direction of the vehicle body. The structural member is made of steel material, and cross-sectional shapes thereof in a direction perpendicular to the extension direction are closed cross sections and vary according to a position of the structural member in the extension direction.
θθθ is 1.30% or less. The average particle diameter of the cementite particles is 1.50 μm or less. The maximum particle diameter of the cementite particles is 5.00 μm or less. The spheroidizing rate of the cementite particles is 75% or greater.
A joint structure of an automobile frame member comprises a first member and a second member. The first member includes a top plate, two vertical walls, two first ridgeline portions, and a continuous flange. The second member includes a first wall surface facing an axial end portion of the first member, a second wall surface extended from the first wall surface to the other side from the first member side, and a second ridgeline portion sandwiched between the first wall surface and the second wall surface. The continuous flange has an interval h, between the second ridgeline portion and the top plate, satisfying -10 mm ≤ h ≤ 10 mm, and angles θ formed by a surface perpendicular to the top plate and the two vertical walls, respectively, each satisfy 20° ≤ θ ≤ 45°.
B62D 21/02 - Châssis, c.-à-d. armature sur laquelle une carrosserie peut être montée comprenant des éléments d'armature disposés longitudinalement ou transversalement
B60R 19/04 - Pare-chocs, c.-à-d. éléments pour recevoir ou absorber les chocs pour protéger les véhicules ou dévier les chocs provenant d'autres véhicules ou objets formés de plusieurs sections
Provided are a steel material and a pressure vessel that includes the steel material. The steel material has a specific chemical composition that results in α as given by the following formula being 4.0–16.0, the tensile strength is 590–930 MPa, the microstructure at 1/4 of the thickness from the surface includes lower bainite and martensite, the total area percentage of lower bainite and martensite is at least 15.0%, the total area percentage of upper bainite, lower bainite, and martensite is at least 90.0%, and the Mn concentration of a center segregation part at 1/2 of the thickness is no more than 2.00%. α=0.50×√[C]×(1+0.64[Si])×(1+4.10[Mn])×(1+0.27[Cu])×(1+0.52[Ni])×(1+2.33[Cr])×(1+3.14[Mo])
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 particuliersFours à cet effet
C21D 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
C21D 9/50 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour joints de soudure
C22C 38/08 - Alliages ferreux, p. ex. aciers alliés contenant du nickel
C22C 38/54 - Alliages ferreux, p. ex. aciers alliés contenant du chrome et du nickel et du bore
This steel material has a specific chemical composition resulting in α being 5.0-16.0 and β being 0.017 or less, has a tensile strength of 615-930 MPa, and has, at a site 1/4 of the thickness from the surface, a micro-structure which includes lower bainite and martensite, and in which the total of the area percentages of the lower bainite and the martensite is 15.0% or more, the total of the area percentages of upper bainite, the lower bainite, and the martensite is 90.0% or more, and the area percentage of retained austenite is less than 1.7%. α=0.50×√[C]×(1+0.64[Si])×(1+4.10[Mn])×(1+0.27[Cu])×(1+0.52[Ni])×(1+2.33[Cr])×(1+3.14[Mo]) β=[Mn]×[P]-[Mo]/100
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 particuliersFours à cet effet
C21D 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
C21D 9/50 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour joints de soudure
C22C 38/08 - Alliages ferreux, p. ex. aciers alliés contenant 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
Provided is a steel material having a specific chemical composition in which Ceq represented by formula (1) is not less than 0.350, wherein: tensile strength is 490-720 MPa; in the microstructure at a site which is at 1/4 of the thickness from the surface, a transformation structure generated at a low temperature has a total area ratio of not less than 70%; and average crystal grain size is not more than 25.0 μm. Formula (1): Ceq=[C]+[Mn]/6+[Ni]/15+[Cu]/15+[Cr]/5+[Mo]/5+[V]/5
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 particuliersFours à cet effet
C21D 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
C21D 9/50 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour joints de soudure
C22C 38/06 - Alliages ferreux, p. ex. aciers alliés contenant de l'aluminium
C22C 38/58 - Alliages ferreux, p. ex. aciers alliés contenant du chrome et du nickel et plus de 1,5% en poids de manganèse
Provided is a welded joint which has a specific chemical composition in which Ceq represented by formula (1) is 0.350 to 0.490 inclusive, and a tensile strength of 490 MPa to 720 MPa inclusive, wherein: the number density of inclusions having an equivalent circle diameter of 0.01 µm to 0.50 µm inclusive and containing Ti and N is 1.0 × 105or more per mm2 in a portion at 1/4 of the thickness and a portion at 1/2 of the thickness from the surface in the thickness direction; in the portion at 1/4 of the thickness and the portion at 1/2 of the thickness, the average particle diameter of inclusions containing Ti and N is 150 nm or less; and the effective crystal grain size in a region between the fusion line of the welded part and a position of the heat affected zone separated by 1 mm from the fusion line is 100.0 μm or less. Also provided is a pressure vessel which includes the welded joint. Formula (1): Ceq = [C] + [Mn]/6 + [Ni]/15 + [Cu]/15 + [Cr]/5 + [Mo]/5 + [V]/5
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 38/14 - Alliages ferreux, p. ex. aciers alliés contenant du titane ou du zirconium
C22C 38/58 - Alliages ferreux, p. ex. aciers alliés contenant du chrome et du nickel et plus de 1,5% en poids de manganèse
83.
FE-BASED AMORPHOUS ALLOY AND THIN FE-BASED AMORPHOUS ALLOY STRIP
An Fe-based amorphous alloy according to one embodiment of the present disclosure has an amorphous structure and contains, in terms of at%, 8.0-18.0% B, 0-2.0% Si, 0.10-5.00% C, 0.10-3.50% P, 0-0.60% Mn, and 78.00-86.00% Fe, with the remainder being impurities.
C22C 45/02 - Alliages amorphes avec le fer comme constituant majeur
B22D 11/00 - Coulée continue des métaux, c.-à-d. en longueur indéfinie
B22D 11/06 - Coulée continue des métaux, c.-à-d. en longueur indéfinie dans des moules dont les parois se déplacent, p. ex. entre des rouleaux, des plaques, des courroies, des chenilles
H01F 1/147 - Alliages caractérisés par leur composition
H01F 1/153 - Alliages métalliques amorphes, p. ex. métaux vitreux
C21D 6/00 - Traitement thermique des alliages ferreux
The present application discloses a ceramic sintered body that exhibits both toughness and abrasion resistance. A ceramic sintered body according to the present disclosure contains a first compound and a second compound. The first compound is silicon carbide, and the second compound is a diboride of a Group 4 element. The proportion of the second compound in the ceramic sintered body is 50-70 mass%. In a case where a 300 µm x 300 µm area of a polished surface of the ceramic sintered body is divided into 400 15 µm x 15 µm compartments, and the areal ratio of the first compound is specified for each of the compartments, the coefficient of variation CV of the areal ratio of the first compound is more than 0.14 and less than 0.23.
C04B 35/58 - Produits céramiques mis en forme, caractérisés par leur compositionCompositions céramiquesTraitement de poudres de composés inorganiques préalablement à la fabrication de produits céramiques à base de non oxydes à base de borures, nitrures ou siliciures
This steel sheet has a desired chemical composition and is such that in a metal structure at a position that is 1/4 of the sheet thickness from the surface, prior austenite grains having an aspect ratio of less than 2.0 constitute less than 20% in terms of area%, prior austenite grains having an aspect ratio of greater than or equal to 2.0 and less than 6.0 constitute greater than or equal to 40%, prior austenite grains having an aspect ratio of greater than or equal to 6.0 constitute less than 30%, bainite constitutes 70-95%, and martensite constitutes 5-30%.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
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
2233 is 4.0 mass% or more and the content of crystal water is 5 mass% or more, is reduced with a reducing gas using a fluidized bed; and a fluidized bed heat treatment step in which the iron ore powder, in which at least a part thereof is metallized by the fluidized bed reduction step, is heat treated with a non-oxidizing gas using a fluidized bed. The temperature in the fluidized bed in the fluidized bed heat treatment step is higher than the temperature in the fluidized bed in the fluidized bed reduction step, and the gas flow rate of the non-oxidizing gas in the fluidized bed in the fluidized bed heat treatment step is 1.5 times or more higher than the gas flow rate of the reducing gas in the fluidized bed in the fluidized bed reduction step, or four times or more the minimum fluidization velocity of the fluidized bed in the fluidized bed reduction step.
A press device (20) is provided with punches (21, 22), pads (23, 24), a die (25), and a support mechanism (26). A first punch (21) includes a punch top surface (211). A second punch (22) includes a punch top surface (221), a punch shoulder (222), a punch side surface (223), and a punch flange surface (224). The die (25) includes a die bottom surface (251), a die shoulder (252), a die side surface (253), and a die flange surface (254). The support mechanism (26) supports the second punch (22) such that the punch shoulder (222) is disposed closer to the die bottom surface (251) side than the punch top surface (211). The support mechanism (26) is configured to move the second punch (22) relative to the first punch (21) in a pressing direction (D1).
B21D 5/01 - Cintrage des tôles le long de lignes droites, p. ex. pour former un pli simple entre des marteaux et des enclumes ou butées
B21D 19/08 - Mise en forme ou autres traitements des bords, p. ex. des bords des tubes par l'action unique ou successive d'outils presseurs, p. ex. de mors d'étaux
B21D 24/04 - Serre-flansMoyens de montage des serre-flans
88.
METHOD FOR FORMING METAL PLATE, RAW METAL PLATE, AND BATTERY TRAY
In a forming method for processing a metal plate and a battery tray according to the present invention, a raw metal plate (10A) has a predetermined excess length at each edge part and a predetermined corner shape at a corner part. For the raw metal plate (10A), in a portion of a first edge part (15) that lies further toward a blank corner part (17) than a straight line (L11), the blank corner part (17), and a portion of a second edge part (16) that lies further toward the blank corner part (17) than a straight line (L21), an outer shape line (163) of the raw metal plate (10A) is located outside, namely on the side opposite to a bottom surface part (110C) relative to the polygonal line comprising a line segment (P1P3) and a line segment (P3P2).
An electromagnetic steel sheet with an adhesive coating film according to the present invention comprises: an electromagnetic steel sheet; and an adhesive coating film provided on at least a part of one surface or both surfaces of the electromagnetic steel sheet, the adhesive coating film containing a cross-linkable thermoplastic resin A and a thermoplastic resin B other than the cross-linkable thermoplastic resin A. The adhesive coating film has a hardness of 200-260 MPa. The adhesive coating film has a hardness of 200-300 MPa after heating at 200°C for 5 minutes.
C23C 26/00 - Revêtements non prévus par les groupes
B32B 7/025 - Propriétés électriques ou magnétiques
B32B 15/08 - 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
H01F 1/147 - Alliages caractérisés par leur composition
H01F 27/245 - Noyaux magnétiques fabriqués à partir de tôles, p. ex. à grains orientés
A battery unit (100) is provided with a plurality of cooling members (10) and a plurality of battery cells (20). Each of the cooling members (10) include a first member (11) and a second member (12). The first member (11) and the second member (12) are each formed of a metal plate. The second member (12), together with the first member (11), forms a space (13) into which a cooling liquid is supplied. Each of the battery cells (20) uses a metal can (21) as an exterior material. Each of the battery cells (20) is disposed between the space (13) of one of the cooling members (10) and the space (13) of another one of the cooling members (10). Each of the battery cells (20) is bonded to the first member (11) or the second member (12) in one of the cooling members (10) and/or another one of the cooling members (10).
H01M 10/647 - Éléments prismatiques ou plans, p. ex. éléments de type poche
H01M 10/653 - Moyens de commande de la température associés de façon structurelle avec les éléments caractérisés par des matériaux électriquement isolants ou thermiquement conducteurs
H01M 10/6555 - Barres ou plaques disposées entre les éléments
H01M 10/6568 - Liquides caractérisés par des circuits d'écoulement. p. ex. boucles, situés à l'extérieur des éléments ou des boîtiers des éléments
A battery unit (100) is provided with a battery tray (10), cooling members (20), and reinforcing members (30). Each of the cooling members (20) includes a top plate (21) facing a bottom plate (11) outside the battery tray (10), and a flange (22) joined to the bottom plate (11). The reinforcing members (30) are overlaid on and joined to the cooling members (20) on both sides in the longitudinal direction of the cooling members (20). Each of the cooling members (20) includes ridge portions (241, 242, 243, 244). Each of the reinforcing members (30) includes ridge portions (31, 32, 33, 34) formed so as to be respectively continuous with the ridge portions (241, 242, 243, 244). Each of the ridge portions (31, 32, 33, 34) extends in the longitudinal direction of the cooling members (20) to the outside of the battery tray (10).
H01M 10/647 - Éléments prismatiques ou plans, p. ex. éléments de type poche
H01M 10/651 - Moyens de commande de la température associés de façon structurelle avec les éléments caractérisés par des paramètres spécifiés par une valeur numérique ou une formule mathématique, p. ex. rapports, tailles ou concentrations
92.
ELECTROMAGNETIC STEEL SHEET WITH ADHESIVE COATING, LAMINATED CORE, AND METHOD FOR MANUFACTURING SAME
This electromagnetic steel sheet with an adhesive coating has an electromagnetic steel sheet and an adhesive coating provided on at least a part of one surface or both surfaces of the electromagnetic steel sheet. The adhesive coating contains a crosslinkable thermoplastic resin A and a thermoplastic resin B other than the crosslinkable thermoplastic resin A, has a glass transition temperature of 45-80°C, and a melt flow rate at 100°C of 1-25 g/10 min.
C23C 26/00 - Revêtements non prévus par les groupes
B32B 7/025 - Propriétés électriques ou magnétiques
B32B 15/08 - 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
H01F 1/147 - Alliages caractérisés par leur composition
H01F 27/245 - Noyaux magnétiques fabriqués à partir de tôles, p. ex. à grains orientés
H02K 1/18 - Moyens de montage ou de fixation des parties magnétiques fixes sur ou aux structures constituant le stator
The present invention provides an automotive suspension component that, with a novel configuration, has excellent impact resistance in a bent part. An automotive suspension component (1) according to the present invention comprises a bent part (2) which is formed from a steel sheet, said automotive suspension component (1) being characterized in that: the steel sheet has a specific chemical composition containing C, Si, Al, Ti, and Sn as essential components; the Vickers hardness of the bent part is not less than 250 HV; the peak of in-crystal-grain orientation difference of an inner surface layer of the bent part is 1.0-3.0 degrees; and the peak of in-crystal-grain orientation difference of an outer surface layer of the bent part is 2.0-4.0 degrees.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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
H01F 1/147 - Alliages caractérisés par leur composition
H01F 27/245 - Noyaux magnétiques fabriqués à partir de tôles, p. ex. à grains orientés
H01F 41/02 - Appareils ou procédés spécialement adaptés à la fabrication ou à l'assemblage des aimants, des inductances ou des transformateursAppareils ou procédés spécialement adaptés à la fabrication des matériaux caractérisés par leurs propriétés magnétiques pour la fabrication de noyaux, bobines ou aimants
C21D 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
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
95.
GRAIN-ORIENTED ELECTRICAL STEEL SHEET AND MANUFACTURING METHOD THEREFOR
This grain-oriented electrical steel sheet has a plurality of magnetic domain control processing lines formed on a surface thereof, said magnetic domain control processing lines extending in a direction that intersects the rolling direction, wherein when a first magnetic domain image is a magnetic domain image of the surface, a second magnetic domain image is a magnetic domain image of the same location as the first magnetic domain image after the grain-oriented electrical steel sheet has been subjected to annealing in which the same is held at 800°C for 240 minutes or longer and cooled to 50°C or below at an average cooling speed of 25°C/h or less to 200°C and then 100°C/h or less thereafter, magnetized to a magnetic density of 1.9 T or greater by applying an AC magnetic field, and demagnetized by attenuating the AC magnetic field, a first region is a region in which the magnetic domain width derived from the second magnetic domain image is greater than the magnetic domain width derived from the first magnetic domain image by 100 μm or more, and a second region is a region other than the first region, the line density of the magnetic domain control processing lines in the second region in units of mm/mm2is smaller than the line density of the magnetic domain control processing lines in the first region in units of mm/mm2.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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
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
H01F 1/16 - Aimants ou corps magnétiques, caractérisés par les matériaux magnétiques appropriésEmploi de matériaux spécifiés pour leurs propriétés magnétiques en matériaux inorganiques caractérisés par leur coercivité en matériaux magnétiques doux métaux ou alliages sous forme de feuilles
96.
GRAIN-ORIENTED ELECTROMAGNETIC STEEL SHEET AND METHOD FOR PRODUCING GRAIN-ORIENTED ELECTROMAGNETIC STEEL SHEET
This grain-oriented electromagnetic steel sheet has a plurality of magnetic domain control processing lines on the surface thereof. When virtual lines are provided at 5-mm intervals inside an evaluation region, the standard deviation of the intervals of the magnetic domain control points, which are the intersecting points between the virtual lines and the magnetic domain control processing lines, is 1.25 mm or more, and an average value of the magnetic domain widths measured along the virtual lines is 600 μm or less for at least one virtual line.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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
H01F 1/147 - Alliages caractérisés par leur composition
H01F 27/245 - Noyaux magnétiques fabriqués à partir de tôles, p. ex. à grains orientés
H01F 41/02 - Appareils ou procédés spécialement adaptés à la fabrication ou à l'assemblage des aimants, des inductances ou des transformateursAppareils ou procédés spécialement adaptés à la fabrication des matériaux caractérisés par leurs propriétés magnétiques pour la fabrication de noyaux, bobines ou aimants
C21D 9/46 - Traitement thermique, p. ex. recuit, durcissement, trempe ou revenu, adapté à des objets particuliersFours à cet effet pour tôles
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
97.
GRAIN-ORIENTED ELECTROMAGNETIC STEEL SHEET AND METHOD FOR PRODUCING GRAIN-ORIENTED ELECTROMAGNETIC STEEL SHEET
AllDrAllDrDr| is an average value of absolute values of β angles at magnetic domain control points that are intersection points of a plurality of virtual lines with the magnetic domain control processing line, the virtual lines being provided in parallel at 2-mm intervals along the rolling direction of the grain-oriented electromagnetic steel sheet. Also provided is a method for producing a grain-oriented electromagnetic steel sheet, the method comprising: a step of acquiring a magnetic domain image of an original sheet for a grain-oriented electromagnetic steel sheet; a step of determining a magnetic domain control processing region on the basis of the distribution of the magnetic domain widths in the magnetic domain image; and a step of applying a magnetic domain control process to the magnetic domain control processing region determined on the basis of the distribution of the magnetic domain widths.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 particuliersFours à cet effet pour tôles
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
H01F 1/147 - Alliages caractérisés par leur composition
H01F 27/245 - Noyaux magnétiques fabriqués à partir de tôles, p. ex. à grains orientés
H01F 41/02 - Appareils ou procédés spécialement adaptés à la fabrication ou à l'assemblage des aimants, des inductances ou des transformateursAppareils ou procédés spécialement adaptés à la fabrication des matériaux caractérisés par leurs propriétés magnétiques pour la fabrication de noyaux, bobines ou aimants
98.
GRAIN-ORIENTED ELECTRICAL STEEL SHEET AND METHOD FOR MANUFACTURING SAME
This grain-oriented electrical steel sheet is provided with, on the surface thereof, a plurality of magnetic domain control processing lines that extend in a direction intersecting the rolling direction. When a square evaluation region in which the length of one side is 50 mm and one side is parallel to the rolling direction is set on the surface, and imaginary lines that are parallel to the rolling direction and that have a length of 50 mm are set inside the evaluation region at 5 mm intervals in a direction perpendicular to the rolling direction, in at least one of the imaginary lines, the maximum value of the spacing, in the rolling direction, between adjacent intersections from among the plurality of intersections between the imaginary line and the plurality of magnetic domain control processing lines is over 20 mm, and the average value of the magnetic domain width measured along the imaginary line is 600 μm or below.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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
H01F 1/16 - Aimants ou corps magnétiques, caractérisés par les matériaux magnétiques appropriésEmploi de matériaux spécifiés pour leurs propriétés magnétiques en matériaux inorganiques caractérisés par leur coercivité en matériaux magnétiques doux métaux ou alliages sous forme de feuilles
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
99.
GRAIN-ORIENTED ELECTRICAL STEEL SHEET AND METHOD FOR PRODUCING GRAIN-ORIENTED ELECTRICAL STEEL SHEET
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 particuliersFours à cet effet pour tôles
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
H01F 1/147 - Alliages caractérisés par leur composition
H01F 27/245 - Noyaux magnétiques fabriqués à partir de tôles, p. ex. à grains orientés
H01F 41/02 - Appareils ou procédés spécialement adaptés à la fabrication ou à l'assemblage des aimants, des inductances ou des transformateursAppareils ou procédés spécialement adaptés à la fabrication des matériaux caractérisés par leurs propriétés magnétiques pour la fabrication de noyaux, bobines ou aimants
100.
GRAIN-ORIENTED ELECTROMAGNETIC STEEL SHEET AND METHOD FOR MANUFACTURING GRAIN-ORIENTED ELECTROMAGNETIC STEEL SHEET
All Dr All Dr Dr | is the average value of absolute values of an α angle at a magnetic domain control point that is an intersection point of the magnetic domain control processing line and a plurality of virtual lines set at 2 mm intervals in parallel along a rolling direction of the grain-oriented electromagnetic steel sheet. A method for manufacturing a grain-oriented electromagnetic steel sheet according to another aspect of the present disclosure comprises: a step for measuring an α-angle distribution on the surface of an original sheet of a grain-oriented electromagnetic steel sheet; a step for identifying a region having an α-angle absolute value equal to or smaller than 5°; and a step for applying magnetic domain control processing to the region having the α-angle absolute value equal to or smaller than 5°.
C22C 38/00 - Alliages ferreux, p. ex. aciers alliés
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 particuliersFours à cet effet pour tôles
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
H01F 1/147 - Alliages caractérisés par leur composition
H01F 27/245 - Noyaux magnétiques fabriqués à partir de tôles, p. ex. à grains orientés
H01F 41/02 - Appareils ou procédés spécialement adaptés à la fabrication ou à l'assemblage des aimants, des inductances ou des transformateursAppareils ou procédés spécialement adaptés à la fabrication des matériaux caractérisés par leurs propriétés magnétiques pour la fabrication de noyaux, bobines ou aimants
brevets
