A high-strength steel sheet having a tensile strength of 1320 MPa or more is disclosed. The above-described high-strength steel sheet includes a specific component composition, wherein a diffusible hydrogen in steel is 0.50 ppm by mass or less, tempered martensite and bainite are 70.0% or more, fresh martensite is 15.0% or less, iron-based carbides existing in the tempered martensite and the bainite have an average equivalent circular radius of 0.10 m or less and an average aspect ratio of 4.5 or less, and a proportion p of tempered martensite and bainite including iron-based carbides, which have major axes facing the same direction within a range of 0 to 10, at a number density of 7 to 35/m.sup.2 among the tempered martensite and the bainite is 25 to 70%.

Provided is a welded joint comprising a plurality of steel sheets stacked together, a spot weld having a nugget joining the plurality of steel sheets, and a pressure weld and heat affected zone formed around the nugget, and a separation part positioned around the pressure weld, wherein one or more of the plurality of steel sheets is a plated steel sheet comprising a base steel sheet and a plating layer formed on at least a surface corresponding to a stacking surface of the plurality of steel sheets of surfaces of the base steel sheet, the plating layer at the separation part at an outside of the heat affected zone has a predetermined chemical composition, and at the plating layer of the separation part of a region up to 500 m from an end of the pressure weld, a ratio of an area ratio of an phase with respect to a total of area ratios of the phase and phase is 10 to 100%.

Provided are a steel sheet; a related member; and methods for manufacturing the same. The steel sheet has a chemical composition including, in mass %, C: 0.06 to 0.25%, Si: 0.4 to 2.5%, Mn: 1.5 to 3.5%, P: 0.02% or less, S: 0.01% or less, sol. Al: less than 1.0%, and N: less than 0.015%, the balance being Fe and incidental impurities, the steel sheet being such that the steel sheet includes a steel microstructure including, in area fraction, polygonal ferrite: 10% or less (including 0%), tempered martensite: 40% or more, fresh martensite: 20% or less (including 0%), bainitic ferrite having 20 or less internal carbides per 10 m.sup.2: 3 to 40%, and, in volume fraction, retained austenite: 5 to 20%, and the steel sheet has S.sub.C0.5/S.sub.C0.3100 of 20% or more.

A method to provide for an enameled glazing including, a glass sheet, an enamel coating on at least a part of a first surface of the glass sheet, a multilayer coating on at least a part of a first surface of the glass sheet and at least partially on top of the enamel coating, such that the enamel coating either comprises no Bi.sub.4Si.sub.3O.sub.12, or, if it comprises Bi.sub.4Si.sub.3O.sub.12, the enamel coating exhibits a crystallinity ratio <5, as measured by XRD, where the crystallinity ratio is the ratio of Bi.sub.4Si.sub.3O.sub.12/Cr.sub.2CuO.sub.4.

A wire includes a ferrous core. The ferrous core can be coated. The coatings can include nickel, molybdenum, zinc and Fe. A process of forming a wire can include placing a metal strip alongside a ferrous wire core, bending the strip around the core, and seam welding the strip to form a metal tube around the core. The process of forming a wire can include applying a metal layer to a ferrous metal rod to form a plated rod, placing a metal strip alongside the rod, bending the strip around the rod, and seam welding the strip to form a metal tube around the rod. The process of forming a wire can include coating a ferrous wire core with a layer of nickel, molybdenum or a nickel alloy that circumferentially surrounds the ferrous wire core.

A hot stamped body, including: a steel material; and a plated layer, wherein a chemical composition of the plated layer contains, in mass %, 0 to 70% of Al, 10 to 60% of Fe, 0 to 20% of Si, and a C-group element being any one kind or two kinds of Li and Y, with a content of 0.00001 to 0.3% in total, and optionally further contains any one kind or two or more kinds of Sb, Pb, B, Cu, Ti, Cr, Nb, Ni, Mn, Mo, Ag, Co, Sn, and Bi, and a remainder being of Zn and an impurity, wherein the plated layer contains an n-Zn phase or a Zn-containing phase is used.

A method of producing a hot dip-coated high-strength steel strip with plasticity brought about by microstructural transformation starting from producing a hot-rolled steel strip, etching and optionally cold rolling the hot-rolled steel strip to give a cold-rolled steel strip, subsequently continuously annealing in a continuous process of hot dip coating the cold- or hot-rolled steel strip, subsequently cooling the cold- or hot-rolled steel strip to an intermediate temperature, subsequently further cooling the cold- or hot-rolled steel strip from the intermediate temperature to a cooling stop temperature within a temperature range and at an average cooling rate, and then keeping the temperature within a temperature range, then hot dip coating the cold- or hot-rolled steel strip, and cooling the hot dip coated cold- or hot-rolled steel strip at an average cooling rate to ambient temperature. The corresponding hot dip-coated high-strength steel strip thus has plasticity brought about by microstructural transformation.

Disclosed in the present invention are a high-strength steel composite galvanized sheet resistant to LME cracking during spot welding, and a preparation method therefor. The high-strength steel composite galvanized sheet comprises a high-strength steel body (1), low-carbon steel composite layers (2) and a galvanized layer (3), wherein two low-carbon steel composite layers (2) are respectively compounded and rolled on two surfaces of the high-strength steel body (1), the galvanized layer (3) is formed on the surface of at least one low-carbon steel composite layer (2), and a high-strength steel composite galvanized sheet is thus formed. In the present invention, the low-carbon steel composite layers are compounded and rolled on the surfaces of the high-strength steel body, such that liquid metal is prevented from permeating into a base material along a grain boundary during spot welding; therefore, the sensitivity of the high-strength steel composite galvanized sheet to LME during spot welding is reduced, LME cracking during spot welding is effectively avoided, the problem of LME cracking during spot welding is mitigated, the resistance spot-welding performance of the high-strength steel body is improved, and the mechanical properties of a spot-welded joint are obviously improved.

The disclosure relates to a steel wire and a spring having excellent antibacterial properties and corrosion resistance, and methods of manufacturing the same. The steel wire having excellent antibacterial properties and corrosion resistance includes: a steel wire; and a plating layer formed on the steel wire, wherein the plating layer includes a zinc (Zn)-aluminum (Al) plating layer plated on a surface of the steel wire, and a doping layer formed by doping a surface of the ZnAl plating layer with a metal in a colloidal form. The method of manufacturing the steel wire having excellent antibacterial properties and corrosion resistance includes forming a plating layer on a surface of a steel wire, wherein the forming of the plating layer includes forming a ZnAl plating layer by plating the surface of the steel wire, and forming a doping layer by doping a surface of the ZnAl plating layer with a metal in a colloidal form.

Provided is a steel sheet that simultaneously achieves a strength of TS: 1310 MPa or more and excellent delayed fracture resistance. The steel sheet has a defined chemical composition and a complex structure consisting mainly of martensite and bainite, where carbides in the grains of martensite and bainite are 5% or more and 25% or less, the average circle equivalent diameter of carbides is 10 nm or more and 80 nm or less, and the particle size distribution of carbides satisfies Expression (1).