High-strength flat steel product and method for producing same

Abstract

Flat steel product exhibiting a tensile strength of at least 1200 MPa, comprises steel comprising carbon, silicon, manganese, aluminum, phosphorus, sulfur, nitrogen, optionally chromium, molybdenum, vanadium, titanium, niobium, boron or calcium, iron and unavoidable impurities. The flat steel product exhibits a structure comprising (in surface %) ferrite (less than 5), bainite (less than 10), untempered martensite (5-70), residual austenite (5-30), and tempered martensite (25-80), where at least 99% of iron carbide present in the tempered martensite exhibits a size of less than 500 nm. Flat steel product exhibiting a tensile strength of at least 1200 MPa, comprises steel comprising (in wt.%) carbon (0.1-0.5), silicon (0.1-2.5), manganese (1-3.5), aluminum (up to 2.5), phosphorus (up to 0.020), sulfur (up to 0.003), nitrogen (up to 0.02), optionally chromium (0.1-0.5), molybdenum (0.1-0.3), vanadium (0.01-0.1), titanium (0.001-0.15), niobium (0.02-0.05), boron (0.0005-0.005) or calcium (up to 0.01), iron and unavoidable impurities. The sum of the contents of vanadium, titanium and niobium is = 0.2 wt.%. The flat steel product exhibits a structure comprising (in surface %) ferrite (less than 5), bainite (less than 10), untempered martensite (5-70), residual austenite (5-30), and tempered martensite (25-80), where at least 99% of iron carbide present in the tempered martensite exhibits a size of less than 500 nm. An independent claim is also included for producing the flat steel product exhibiting high tensile strength, comprising providing an uncoated flat steel product made of the above steel, heating the flat steel product to an austenitizing temperature (T(HZ)), which is greater than (A(c3)) temperature (temperature at which transformation of ferrite into austenite is completed upon heating a steel) of the steel of the flat steel product, preferably to not > 960[deg] C at a heating rate (theta (H1), theta (H2)) of at least 3[deg] C / second, holding the flat steel product at the austenitizing temperature for an austenitizing period (t(HZ)) of 20-180 seconds, cooling the flat steel product to a cooling stop temperature (T(Q)), which is greater than the martensite stop temperature (T(Mf)) and less than the martensite start temperature (T(Ms) at a cooling rate (theta Q), which is less than or equal to theta (Q)(min) (where theta (Q)(min) is equal to -314.35 [deg] C / s + (268.74%C (carbon content of the steel) + 56.27%Si (silicon content of the steel) + 58.50% Al (aluminum content of the steel) + 43.40% Mn (manganese content of the steel) + 195.02% Mo (molybdenum content of the steel) + 166.60% Ti (titanium content of the steel) + 199.19% Nb (niobium content of the steel)) [deg] C / (wt.%x s)), holding the flat steel product at the cooling stop temperature (T(Q)) for a holding period (t(Q)) of 10-60 seconds, heating the flat steel product after cooling to the cooling stop temperature (T(Q)), to a partitioning temperature (T(p)), preferably 400-500[deg] C at a heating rate (theta (P1) of 2-80[deg] C / second, optionally and isothermally holding the flat steel product at the partitioning temperature (T(P)) for a holding period (t(Pi)) of up to 500 seconds, and cooling the flat steel product after heating to the partitioning temperature (T(P)), at a cooling rate (theta (P2)) of -3 to -25[deg] C / second.

Description

technical field [0001] The invention relates to a high-strength flat steel product and a method for producing the flat steel product. [0002] In particular, the invention relates to a high-strength flat steel product provided with a metallic protective layer and to a method for producing such a product. Background technique [0003] The flat steel products mentioned here are steel strips, steel sheets or sheet metal blanks produced therefrom, eg slabs. [0004] Unless otherwise explicitly stated, in the specification and claims of the present application, the contents of specific alloy elements are shown in weight % and the contents of specific structural components are shown in area %. [0005] When cooling rates or cooling rates or heating rates or heating rates are mentioned below, the cooling rates are given as negative values, since the cooling rates cause a decrease in temperature. Correspondingly, the cooling rate has a lower value during rapid cooling than during ...

AI Technical Summary

Problems solved by technology

Flat steel products with higher strength cannot usually be flame-coated because of the enormous loss of strength of the flat steel product due to the ensuing heating due to the tempering effect

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