STEEL SHEET, MEMBER, AND METHODS FOR MANUFACTURING THE SAME

Abstract
Provided are a steel sheet and a member, having high strength and high delayed fracture resistance, and methods for manufacturing the steel sheet and the member. The steel sheet has a specific chemical composition and a microstructure in which the area fraction of martensite is 95% to 100%, with the balance being one or more of bainite, ferrite, and retained austenite. In the steel sheet, prior-austenite grains have an average grain size of 18 μm or less, 90 mass % or more of the total content of Nb and Ti contained is present as a carbonitride having an equivalent circular diameter of 100 nm or more, and a Nb carbonitride and a Ti carbonitride, having an equivalent circular diameter of 1.0 μm or more, are present at a rate of 800 pieces/mm2 or less in total. The steel sheet has a tensile strength of 1310 MPa or more.
Description
FIELD OF THE INVENTION

The present invention relates to a high strength steel sheet for cold press forming and a member, which are used in an automobile or the like after being subjected to cold press forming, and methods for manufacturing the steel sheet and the member.


BACKGROUND OF THE INVENTION

In recent years, steel sheets with 1310 MPa or more tensile strength TS have been increasingly used for automotive frame parts for the purpose of weight saving and crashworthiness of automobiles. For bumpers, impact beam parts, and the like, the use of steel sheets with 1.8 GPa or more tensile strength TS has been studied.


Conventionally, high strength steel sheets provided by hot press forming have been used for steel sheets with 1310 MPa or more tensile strength TS, but from the viewpoint of cost and productivity, the use of high strength steel sheets provided by cold pressing is being studied.


When a high strength steel sheet with 1310 MPa or more tensile strength TS is formed into a part by cold pressing, an increase in residual stress within the part and deterioration of delayed fracture resistance of the steel sheet itself may occur to cause a delayed fracture.


The delayed fracture is a phenomenon that occurs as follows: when a part is in a state with a high stress and is placed in a hydrogen entry environment, hydrogen enters a steel sheet forming the part, to reduce interatomic bonding forces or cause local deformation, thus resulting in the formation of microcracks, and the microcracks propagate, thus leading to a fracture.


As a technique for improving such delayed fracture resistance, for example, Patent Literature 1 discloses, on the basis of the results showing that precipitation of fine carbides serving as hydrogen trapping sites improves the delayed fracture resistance, a high strength cold rolled steel sheet having high hydrogen embrittlement resistance and high workability. The steel sheet has a chemical composition containing C: 0.05% to 0.30%, Si: 0% to 2.0%, Mn: more than 0.1% and 2.8% or less, P: 0.1% or less, S: 0.005% or less, N: 0.01% or less, and Al: 0.01% to 0.50% and also containing one or two or more of Nb, Ti, and Zr in an amount of 0.01% or more in total and in such an amount that [% C]−[% Nb]/92.9×12−[% Ti]/47.9×12−[% Zr]/91.2×12>0.03 is satisfied, with the balance being iron and incidental impurities. The steel sheet has a microstructure including tempered martensite with an area fraction of 50% or more (including 100%), with the balance being ferrite. The state of distribution of precipitates in the tempered martensite is such that the number of precipitates having an equivalent circle diameter 1 to 10 nm is 20 or more per μm2 of the tempered martensite, and the number of precipitates having an equivalent circle diameter of 20 nm or more and including one or two or more of Nb, Ti, and Zr is 10 or less per μm2 of the tempered martensite. The average grain size of ferrite surrounded by a high-angle grain boundary with a misorientation of 150 or more is 5 μm or less.


Patent Literature 2 discloses a high strength heat treated steel having high delayed fracture resistance. The steel contains C: 0.1% to 0.5%, Si: 0.10% to 2%, Mn: 0.44% to 3%, N≤0.008%, and Al: 0.005% to 0.1%, and contains one or two or more of V: 0.05% to 2.82%, Mo: 0.1% or more and less than 3.0%, Ti: 0.03% to 1.24%, and Nb: 0.05% to 0.95%, with the mass % ratio relative to C being 0.5 (0.18V+0.06Mo+0.25Ti+0.13Nb)/C, the balance being Fe and incidental impurities. The steel has a tensile strength of 1200 to 1600 MPa.


PATENT LITERATURE



  • PTL 1: Japanese Patent No. 4712882

  • PTL 2: Japanese Patent No. 4427010



SUMMARY OF THE INVENTION

However, the techniques in the related art have yet to be sufficient to ensure high strength and provide high delayed fracture resistance.


The present invention has been made to solve this problem, and an object thereof is to provide a steel sheet and a member, having a tensile strength of 1310 MPa or more (TS 1310 MPa) and high delayed fracture resistance, and methods for manufacturing the steel sheet and the member.


High delayed fracture resistance means that σ10 is 0.80 or more when tensile strength TS is 1310 MPa or more and less than 1500 MPa, σ10 is 0.50 or more when tensile strength TS is 1500 MPa or more and less than 1800 MPa, or σ10 is 0.35 or more when tensile strength TS is 1800 MPa or more, where σ0 is a fracture stress measured when immersion is not performed, and σ1 is a fracture stress measured after hydrogen is allowed to enter and diffuse by immersion, the fracture stress being measured as follows: conventional strain rate technique (CSRT) specimen (a tensile test specimen having a reduced section with a width of 12.5 mm and a length of 25 mm, both ends of the reduced section having a semicircular notch with a radius of 3 mm) is cut out from a steel sheet at the ¼ position in the width direction of the steel sheet such that a direction perpendicular to the rolling direction is the longitudinal direction of the specimen, a 10 mass % aqueous ammonium thiocyanate solution and a McIlvaine buffer solution having a pH of 3 are mixed at a volume ratio of 1:1, in the resulting solution (pH 3) at 20° C. adjusted such that the fluid volume per cm2 of surface area of the test specimen is 20 ml, the CSRT specimen is immersed for 24 hours to allow hydrogen to enter and diffuse through the test specimen, and immediately after the lapse of 24 hours, a tensile test is carried out at a crosshead speed of 1 mm/min to measure the fracture stress.


To solve the above problem, the present inventors have conducted intensive studies and found that delayed fracture resistance can be greatly improved when the following conditions are all satisfied.

    • i) The area fraction of martensite is 95% or more.
    • ii) The average grain size of prior-austenite grains (prior-γ grain size) is 18 μm or less.
    • iii) Of Nb and Ti contained, 90 mass % or more are present as precipitates having an equivalent circular diameter of 100 nm or more.
    • iv) A Nb carbonitride and a Ti carbonitride, having an equivalent circular diameter of 1.0 μm or more, are present at a rate of 800 pieces/mm2 or less.


Aspects of the present invention have been completed by further studies based on the above findings, and are as follows.

    • [1] A steel sheet having a chemical composition containing, in mass %:
      • C: 0.12% or more and 0.40% or less,
      • Si: 1.5% or less,
      • Mn: 1.7% or less,
      • P: 0.03% or less,
      • S: less than 0.0020%,
      • sol. Al: 0.20% or less,
      • N: 0.005% or less, and
      • one or more of Nb and Ti with a total content of 0.005% or more and 0.080% or less,
      • with the balance being Fe and incidental impurities,
      • in which the steel sheet has a microstructure in which an area fraction of martensite relative to the entire microstructure is 95% or more and 100% or less, with the balance being one or more of bainite, ferrite, and retained austenite,
      • prior-austenite grains have an average grain size of 18 μm or less,
      • 90 mass % or more of the total content of Nb and Ti contained is present as a carbonitride having an equivalent circular diameter of 100 nm or more, a Nb carbonitride and a Ti carbonitride, having an equivalent circular diameter of 1.0 μm or more, are present at a rate of 800 pieces/mm2 or less in total, and
      • the steel sheet has a tensile strength of 1310 MPa or more.
    • [2] The steel sheet according to [1], in which the prior-austenite grains have an average grain size of 10 μm or less.
    • [3] The steel sheet according to [1] or [2], in which a fracture stress σ0 before immersion in a solution containing a 10 mass % aqueous ammonium thiocyanate solution and a McIlvaine buffer solution having a pH of 3,
      • a fracture stress a, after immersion in the solution, and the tensile strength satisfy (A), (B), or (C) below:
    • (A) Tensile strength: 1310 MPa or more and less than 1500 MPa, and σ10 is 0.80 or more,
    • (B) Tensile strength: 1500 MPa or more and less than 1800 MPa, and σ10 is 0.50 or more,
    • (C) Tensile strength: 1800 MPa or more, and σ10 is 0.35 or more.
    • [4] The steel sheet according to any one of [1] to [3], in which the chemical composition contains, in mass %, S: less than 0.0010%.
    • [5] The steel sheet according to any one of [1] to [4], in which the chemical composition further contains, in mass %, B: 0.0100% or less.
    • [6] The steel sheet according to any one of [1] to [5], in which the chemical composition further contains, in mass %, one or two selected from Cu: 1.0% or less and Ni: 1.0% or less.
    • [7] The steel sheet according to any one of [1] to [6], in which the chemical composition further contains, in mass %, one or two or more selected from Cr: 1.0% or less, Mo: less than 0.3%, V: 0.5% or less, Zr: 0.2% or less, and W: 0.2% or less.
    • [8] The steel sheet according to any one of [1] to [7], in which the chemical composition further contains, in mass %, one or two or more selected from Ca: 0.0030% or less, Ce: 0.0030% or less, La: 0.0030% or less, REM (excluding Ce and La): 0.0030% or less, and Mg: 0.0030% or less.
    • [9] The steel sheet according to any one of [1] to [8], in which the chemical composition further contains, in mass %, one or two selected from Sb: 0.1% or less and Sn: 0.1% or less.
    • [10] The steel sheet according to any one of [1] to [9], in which a coating layer is disposed on a surface of the steel sheet.
    • [11] A member obtained by subjecting the steel sheet according to any one of [1] to [10] to at least one of forming and welding.
    • [12] A method for manufacturing a steel sheet, including:
      • heating a steel slab having the chemical composition according to any one of [1] and [4] to [9] from 1000° C. to a heat holding temperature of 1250° C. or higher in terms of slab surface temperature at an average heating rate of 10° C./min or less, and holding the steel slab at the heat holding temperature for 30 minutes or more,
      • then performing hot finish rolling at a finish rolling temperature not lower than an Ar3 temperature,
      • performing cooling at an average cooling rate of 40° C./s or more in a range from the finish rolling temperature to 650° C.,
      • then performing cooling and coiling at a coiling temperature of 600° C. or lower to obtain a hot rolled steel sheet,
      • cold rolling the hot rolled steel sheet at a rolling reduction of 40% or more to obtain a cold rolled steel sheet, and
      • performing continuous annealing including:
        • heating the cold rolled steel sheet from 700° C. to an annealing temperature set to 800° C. to 950° C. at an average heating rate of 0.4° C./s or more,
        • performing holding at the annealing temperature for 600 seconds or less, performing cooling from a cooling start temperature of 680° C. or higher to a cooling stop temperature of 260° C. or lower at an average cooling rate of 70° C./s or more, and
        • then performing holding at a holding temperature of 150° C. to 260° C. for 20 to 1500 seconds.
    • [13] The method for manufacturing a steel sheet according to
    • [12], further including performing coating treatment on a steel sheet surface after the continuous annealing.
    • [14] A method for manufacturing a member, comprising a step of subjecting a steel sheet manufactured by the method for manufacturing a steel sheet according to [12] or [13] to at least one of forming and welding.


According to aspects of the present invention, a steel sheet and a member, having high strength and high delayed fracture resistance, and methods for manufacturing the steel sheet and the member are provided.







DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

Hereinafter, an embodiment of the present invention will be described.


A steel sheet according to aspects of the present invention has a chemical composition containing, in mass %, C: 0.12% or more and 0.40% or less, Si: 1.5% or less, Mn: 1.7% or less, P: 0.03% or less, S: less than 0.0020%, sol. Al: 0.20% or less, N: 0.005% or less, and one or more of Nb and Ti with a total content of 0.005% or more and 0.080% or less, with the balance being Fe and incidental impurities. The steel sheet has a microstructure in which an area fraction of martensite relative to the entire microstructure is 95% or more and 100% or less, with the balance being one or more of bainite, ferrite, and retained austenite; prior-austenite grains (hereinafter also referred to as prior-γ grains) have an average grain size (prior-γ grain size) of 18 μm or less; 90 mass % or more of the total content of Nb and Ti contained is present as a carbonitride having an equivalent circular diameter of 100 nm or more; a Nb carbonitride and a Ti carbonitride, having an equivalent circular diameter of 1.0 μm or more, are present at a rate of 800 pieces/mm2 or less in total; and the steel sheet has a tensile strength of 1310 MPa or more.


Chemical Composition


The reason for the limitation of the range of the chemical composition of the steel sheet according to aspects of the present invention will be described below. It should be noted that % related to a component content means “mass %”.


C: 0.12% or More and 0.40% or Less


C is contained to improve hardenability to provide a martensite steel microstructure and from the viewpoint of increasing the strength of martensite to achieve a tensile strength of 1310 MPa or more (hereinafter also referred to as TS≥1310 MPa). Excessively added C forms iron carbide and segregates at grain boundaries, causing worsening of delayed fracture resistance. Therefore, the C content is limited to be in the range of 0.12% or more and 0.40% or less necessary to achieve the strength of steel. The C content is preferably 0.37% or less.


Si: 1.5% or Less


Si is contained as an element for strengthening through solid solution strengthening and from the viewpoint of suppressing the formation of film-shaped carbide during tempering in the temperature range of 200° C. or higher to improve delayed fracture resistance. Si is contained also from the viewpoint of reducing Mn segregation at a central portion in the thickness direction to suppress the formation of MnS. Furthermore, Si is contained to suppress decarburization and deboronization due to oxidation of a surface layer during annealing on a continuous annealing line (CAL). Although the lower limit of the Si content is not specified, Si is desirably contained in an amount of 0.02% or more from the viewpoint of producing the above effect. The Si content is preferably 0.10% or more, more preferably 0.20% or more.


However, an excessively high Si content results in a large amount of Si segregation, leading to deterioration of delayed fracture resistance. The excessively high Si content also leads to a significant increase in rolling load in hot rolling and cold rolling and a decrease in toughness. Therefore, the Si content is 1.5% or less (including 0%). The Si content is preferably 1.2% or less, more preferably 1.0% or less.


Mn: 1.7% or Less


Mn is contained to adjust the area fraction of martensite to be in a predetermined range in order to improve the hardenability of steel and achieve desired strength. However, excessive addition of Mn results in segregation of Mn to reduce workability and weldability. Therefore, the Mn content is 1.7% or less. The Mn content is preferably 1.5% or less. The Mn content is more preferably 1.4% or less. The Mn content is still more preferably 1.2% or less. To stably achieve the predetermined area fraction of martensite on an industrial scale, Mn is preferably contained in an amount of 0.2% or more. The Mn content is more preferably 0.4% or more, still more preferably 0.6% or more.


P: 0.03% or Less


P is an element that strengthens steel, but when the content thereof is high, delayed fracture resistance and spot weldability significantly deteriorate. Therefore, the P content is 0.03% or less. From the above viewpoint, the P content is preferably 0.004% or less. Although the lower limit of the P content is not specified, the lower limit that is industrially feasible at present is 0.002%.


S: Less than 0.0020%


S forms MnS and greatly reduces delayed fracture resistance at a sheared edge surface. Therefore, the S content needs to be at least less than 0.0020% to reduce MnS. From the viewpoint of improving delayed fracture resistance, the S content is preferably less than 0.0010%. The S content is more preferably 0.0004% or less. Although the lower limit is not specified, the lower limit that is industrially feasible at present is 0.0002%.


Sol. Al: 0.20% or Less


Al is contained to perform sufficient deoxidization and reduce inclusions in steel. Although the lower limit of the sol. Al content is not particularly specified, the sol. Al content is desirably 0.005% or more in order to stably perform deoxidization. The sol. Al content is more desirably 0.01% or more. The sol. Al content is preferably 0.02% or more. However, when the sol. Al content exceeds 0.20%, cementite formed during coiling is less easily dissolved in an annealing process, and delayed fracture resistance deteriorates. Therefore, the sol. Al content is 0.20% or less. The sol. Al content is preferably 0.10% or less, more preferably 0.05% or less.


N: 0.005% or Less


N is an element that forms nitride and carbonitride inclusions such as TiN, (Nb, Ti) (C, N), and AlN in steel, and delayed fracture resistance deteriorates through the formation of these inclusions. These inclusions inhibit the achievement of the steel microstructure required in accordance with aspects of the present invention and have an adverse effect on the delayed fracture resistance at a sheared edge surface. To minimize such an adverse effect, the N content is 0.005% or less. The N content is preferably 0.0040% or less. Although the lower limit is not specified, the lower limit that is industrially feasible at present is 0.0006%.


One or More of Nb and Ti with Total Content of 0.005% or More and 0.080% or Less


Nb and Ti contribute to increasing strength through the refinement of the internal structure of martensite and also improve delayed fracture resistance by reducing the prior-γ grain size. From this viewpoint, one or more of Nb and Ti are contained with a total content of 0.005% or more. The total content of Nb and Ti is preferably 0.010% or more, more preferably 0.020% or more. However, when the total content of one or more of Nb and Ti exceeds 0.080%, Nb and Ti do not completely dissolve in slab reheating, increasing coarse inclusion particles such as TiN, Ti(C, N), NbN, Nb(C, N), and (Nb, Ti) (C, N), and delayed fracture resistance rather deteriorates. Therefore, the upper limit of the total content of Nb and Ti is 0.080%. The total content of Nb and Ti is preferably 0.07% or less, more preferably 0.06% or less.


The steel sheet according to aspects of the present invention has a chemical composition containing the components described above and Fe (iron) and incidental impurities constituting the balance. In particular, a steel sheet according to an embodiment of the present invention preferably has a chemical composition containing the components described above with the balance being Fe and incidental impurities.


In addition to the base components described above, the chemical composition of the steel sheet according to aspects of the present invention may contain the following optional elements. In accordance with aspects of the present invention, when any of these optional components is contained in an amount less than a preferred lower limit described below, the element is regarded as being contained as an incidental impurity.


B: 0.0100% or Less


B is an element that improves the hardenability of steel and offers an advantage in that martensite having a predetermined area fraction is formed even when the Mn content is low. To produce this effect of B, the B content is preferably 0.0002% or more, more preferably 0.0005% or more. The B content is still more preferably 0.0010% or more. From the viewpoint of immobilizing N, B is desirably added in combination with 0.002% or more of Ti. However, when B is contained in an amount exceeding 0.0100%, not only its effect plateaus, but also the dissolution rate of cementite during annealing may be retarded to leave behind undissolved cementite, thus deteriorating the delayed fracture resistance at a sheared edge surface. For these reasons, when B is contained, the B content is desirably 0.0100% or less. The B content is preferably 0.0065% or less, more preferably 0.0030% or less, still more preferably 0.0025% or less.


Cu: 1.0% or Less


Cu improves the corrosion resistance of automobiles under service conditions. When Cu is contained, corrosion products thereof cover the surface of the steel sheet to inhibit hydrogen entry into the steel sheet. Cu is an element that is unintentionally incorporated when scrap metal is utilized as a raw material, and permitting the unintentional incorporation of Cu enables recycled materials to be used as raw materials, thus reducing the manufacturing cost. From the above viewpoints, Cu is preferably contained in an amount of 0.01% or more, and further from the viewpoint of improving delayed fracture resistance, Cu is desirably contained in an amount of 0.05% or more. The Cu content is more preferably 0.10% or more. However, since an excessively high Cu content may cause a surface defect, the Cu content is desirably 1.0% or less. For these reasons, when Cu is contained, the Cu content is 1.0% or less. The Cu content is more preferably 0.50% or less, still more preferably 0.30% or less.


Ni: 1.0% or Less


Ni is also an element that improves corrosion resistance. In addition, Ni reduces surface defects that are likely to occur when Cu is contained. Therefore, from the above viewpoints, Ni is desirably contained in an amount of 0.01% or more. The Ni content is more preferably 0.05% or more, still more preferably 0.10% or more. However, an excessively high Ni content results in uniform scale formation in a heating furnace to cause a surface defect, and also results in a significantly increased cost. Therefore, when Ni is contained, the Ni content is 1.0% or less. The Ni content is more preferably 0.50% or less, still more preferably 0.30% or less.


Cr: 1.0% or Less


Cr can be added to produce the effect of improving the hardenability of steel. To produce this effect, Cr is preferably contained in an amount of 0.01% or more. The Cr content is more preferably 0.05% or more, still more preferably 0.10% or more. However, a Cr content exceeding 1.0% retards the dissolution rate of cementite during annealing to leave behind undissolved cementite, thus deteriorating the delayed fracture resistance at a sheared edge surface. The Cr content exceeding 1.0% also deteriorates pitting corrosion resistance, and further deteriorates chemical convertibility. Thus, when Cr is contained, the Cr content is 1.0% or less. The delayed fracture resistance, the pitting corrosion resistance, and the chemical convertibility all tend to begin deteriorating when the Cr content exceeds 0.2%, and thus from the viewpoint of preventing these deteriorations, the Cr content is more preferably 0.2% or less.


Mo: Less than 0.3%


Mo can be added for the purpose of producing the effect of improving the hardenability of steel, the effect of forming Mo-containing fine carbide serving as a hydrogen trapping site, and the effect of improving delayed fracture resistance by refining martensite. When Nb and Ti are added in large amounts, coarse precipitates thereof are formed, and delayed fracture resistance rather deteriorates. However, the dissolution limit of Mo is higher than those of Nb and Ti. When Mo is added in combination with Nb and Ti, their complex fine precipitates are formed to refine the microstructure. Therefore, adding Mo in combination with small amounts of Nb and Ti enables dispersion of a large number of fine carbides while refining the microstructure without leaving behind coarse precipitates, thus improving delayed fracture resistance. To produce this effect, Mo is desirably contained in an amount of 0.01% or more. The Mo content is more preferably 0.03% or more, still more preferably 0.05% or more. However, when Mo is contained in an amount of 0.3% or more, chemical convertibility deteriorates. Thus, when Mo is contained, the Mo content is less than 0.3%. The Mo content is preferably 0.2% or less.


V: 0.5% or Less


V can be added for the purpose of producing the effect of improving the hardenability of steel, the effect of forming V-containing fine carbide serving as a hydrogen trapping site, and the effect of improving delayed fracture resistance by refining martensite. To produce these effects, the V content is desirably 0.003% or more. The V content is more preferably 0.03% or more, still more preferably 0.05% or more. However, when V is contained in an amount exceeding 0.5%, castability significantly deteriorates. Thus, when V is contained, the V content is 0.5% or less. The V content is more preferably 0.3% or less, still more preferably 0.2% or less. Furthermore, the V content is preferably 0.1% or less.


Zr: 0.2% or Less


Zr contributes to increasing strength through the reduction in prior-γ grain size and consequent refinement of the internal structure of martensite and also improves delayed fracture resistance. In addition, Zr increases strength and improves delayed fracture resistance through the formation of fine Zr carbide and carbonitride serving as hydrogen trapping sites. In addition, Zr improves castability. From these viewpoints, the Zr content is desirably 0.005% or more. The Zr content is more preferably 0.010% or more, still more preferably 0.015% or more. However, when Zr is added in a large amount, the number of ZrN and ZrS coarse precipitates that remain undissolved during slab heating in the hot rolling step increases, deteriorating the delayed fracture resistance at a sheared edge surface. Thus, when Zr is contained, the Zr content is 0.2% or less. The Zr content is more preferably 0.1% or less, still more preferably 0.04% or less.


W: 0.2% or Less


W contributes to increasing strength and improving delayed fracture resistance through the formation of fine W carbide and carbonitride serving as hydrogen trapping sites. From this viewpoint, W is desirably contained in an amount of 0.005% or more. The W content is more preferably 0.010% or more, still more preferably 0.030% or more. However, when W is contained in a large amount, the number of coarse precipitates that remain undissolved during slab heating in the hot rolling step increases, deteriorating the delayed fracture resistance at a sheared edge surface. Thus, when W is contained, the W content is 0.2% or less. The W content is more preferably 0.1% or less.


Ca: 0.0030% or Less


Ca immobilizes S by forming CaS to improve delayed fracture resistance. To produce this effect, Ca is desirably contained in an amount of 0.0002% or more. The Ca content is more preferably 0.0005% or more, still more preferably 0.0010% or more. However, when Ca is added in a large amount, surface quality and bendability are deteriorated, and thus the Ca content is preferably 0.0030% or less. For these reasons, when Ca is contained, the Ca content is 0.0030% or less. The Ca content is more preferably 0.0025% or less, still more preferably 0.0020% or less.


Ce: 0.0030% or Less


Ce also immobilizes S to improve delayed fracture resistance. To produce this effect, Ce is desirably contained in an amount of 0.0002% or more. The Ce content is more preferably 0.0003% or more, still more preferably 0.0005% or more. However, when Ce is added in a large amount, surface quality and bendability are deteriorated, and thus the Ce content is desirably 0.0030% or less. For these reasons, when Ce is contained, the Ce content is 0.0030% or less. The Ce content is more preferably 0.0020% or less, still more preferably 0.0015% or less.


La: 0.0030% or Less


La also immobilizes S to improve delayed fracture resistance. To produce this effect, La is desirably contained in an amount of 0.0002% or more. The La content is more preferably 0.0005% or more, still more preferably 0.0010% or more. However, when La is added in a large amount, surface quality and bendability are deteriorated, and thus the La content is desirably 0.0030% or less. For these reasons, when La is contained, the La content is 0.0030% or less. The La content is more preferably 0.0020% or less, still more preferably 0.0015% or less.


REM: 0.0030% or Less


REM also immobilizes S to improve delayed fracture resistance. To produce this effect, REM is desirably contained in an amount of 0.0002% or more. The REM content is more preferably 0.0003% or more, still more preferably 0.0005% or more. However, when REM is added in a large amount, surface quality and bendability are deteriorated, and thus the REM content is desirably 0.0030% or less. For these reasons, when REM is contained, the REM content is 0.0030% or less. The REM content is more preferably 0.0020% or less, still more preferably 0.0015% or less.


The term “REM” as used herein refers to scandium (Sc) with atomic number 21, yttrium (Y) with atomic number 39, and lanthanide elements from lanthanum (La) with atomic number 57 to lutetium (Lu) with atomic number 71 excluding Ce and La. The term “REM concentration” as used herein refers to a total content of one or two or more elements selected from REM above.


Mg: 0.0030% or Less


Mg immobilizes O by forming MgO to improve delayed fracture resistance. To produce this effect, Mg is desirably contained in an amount of 0.0002% or more. The Mg content is more preferably 0.0005% or more, still more preferably 0.0010% or more. However, when Mg is added in a large amount, surface quality and bendability are deteriorated, and thus the Mg content is desirably 0.0030% or less. For these reasons, when Mg is contained, the Mg content is 0.0030% or less. The Mg content is more preferably 0.0020% or less, still more preferably 0.0015% or less.


Sb: 0.1% or Less


Sb suppresses oxidation and nitridation of the surface layer to thereby suppress decreases in C and B. The suppression of decreases in C and B leads to suppression of ferrite formation in the surface layer, contributing to increasing strength and improving delayed fracture resistance. From this viewpoint, the Sb content is desirably 0.002% or more. The Sb content is more preferably 0.004% or more, still more preferably 0.006% or more. However, when the Sb content exceeds 0.1%, castability deteriorates, and Sb segregates at prior-γ grain boundaries to deteriorate the delayed fracture resistance at a sheared edge surface. Thus, the Sb content is desirably 0.1% or less. For these reasons, when Sb is contained, the Sb content is 0.1% or less. The Sb content is more preferably 0.05% or less, still more preferably 0.02% or less.


Sn: 0.1% or Less


Sn suppresses oxidation and nitridation of the surface layer to thereby suppress decreases in C and B contents in the surface layer. The suppression of decreases in C and B leads to suppression of ferrite formation in the surface layer, contributing to increasing strength and improving delayed fracture resistance. From this viewpoint, the Sn content is desirably 0.002% or more. The Sn content is preferably 0.003% or more. However, when the Sn content exceeds 0.1%, castability deteriorates, and Sn segregates at prior-γ grain boundaries to deteriorate the delayed fracture resistance at a sheared edge surface. Thus, when Sn is contained, the Sn content is 0.1% or less. The Sn content is more preferably 0.05% or less, still more preferably 0.01% or less.


Steel Microstructure


A steel microstructure of the steel sheet according to aspects of the present invention has the following features.

    • (Feature 1) The area fraction of martensite relative to the entire microstructure is 95% or more and 100% or less, with the balance being one or more of bainite, ferrite, and retained austenite.
    • (Feature 2) Prior-austenite grains have an average grain size of 18 μm or less.
    • (Feature 3) 90 mass % or more of the total content of Nb and Ti contained is present as a carbonitride having an equivalent circular diameter of 100 nm or more.
    • (Feature 4) A Nb carbonitride and a Ti carbonitride, having an equivalent circular diameter of 1.0 μm or more, are present at a rate of 800 pieces/mm2 or less.


These features will hereinafter be described.


(Feature 1) The area fraction of martensite relative to the entire microstructure is 95% or more and 100% or less, with the balance being one or more of bainite, ferrite, and retained austenite.


To achieve both high strength, that is, TS≥1310 MPa, and high delayed fracture resistance, the total area fraction of martensite in the steel microstructure is 95% or more, more preferably 99% or more, still more preferably 100%. When microstructures other than martensite and bainite are included, the balance is constituted by ferrite and retained austenite (retained γ). The portion other than these microstructures is constituted by traces of carbides, sulfides, nitrides, and oxides. The martensite also includes martensite that has not been self-tempered during continuous cooling or not been tempered by being held at about 150° C. or higher for a certain period of time. The area fraction of martensite may be 100% with no balance.


(Feature 2) Prior-austenite grains have an average grain size of 18 μm or less.


The delayed fracture surface of steel whose parent phase is martensite is often an intergranular fracture surface, and the origin of a delayed fracture and the crack growth path in the early stage of the delayed fracture are considered to lie on a prior-γ grain boundary. Reduction in prior-γ grain size suppresses intergranular fracture to significantly improve delayed fracture resistance. The mechanism is probably as follows: reduction in prior-γ grain size increases the volume fraction of prior-γ grain boundaries and decreases the concentration of grain boundary embrittling elements such as P on grain boundaries. From the viewpoint of delayed fracture resistance, the average grain size of prior-austenite grains (average prior-γ grain size) is 18 μm or less. The average grain size is preferably 10 μm or less, more preferably 7 μm or less, still more preferably 5 μm or less.


(Feature 3) 90 mass % or more of the total content of Nb and Ti contained is present as a carbonitride having an equivalent circular diameter of 100 nm or more.


It is thought that Nb and Ti are precipitated in the hot rolling step and the coiling step and produce a pinning effect to reduce the prior-γ grain size in the coiling step and the annealing step, and form fine precipitates of 50 nm or less to non-diffusively trap hydrogen in steel in the interface between the precipitates and the parent phase, thereby effectively helping suppress delayed fracture. However, in the case of a steel sheet for cold pressing including a continuous annealing step, Nb-based precipitates and Ti-based precipitates are coarsened, and thus large amounts of Nb and Ti need to be added in order to trap hydrogen in an amount sufficient to suppress delayed fracture. In addition, precipitates having hydrogen trapping ability may increase the amount of hydrogen that enters steel to rather worsen delayed fracture resistance.


Meanwhile, the present inventors have found that Nb-based precipitates and Ti-based precipitates of 100 nm or more, which have been thought not to have hydrogen trapping ability and to be ineffective in suppressing delayed fracture, significantly improve delayed fracture resistance. This effect is apparent when 90 mass % or more of the total content of Nb and Ti in steel are constituted by Nb and Ti that form carbonitrides of 100 nm or more. Although the mechanism is not necessarily clear, the present inventors consider that Nb- and Ti-based carbonitrides of 100 nm or more dispersed in steel affect delayed fracture crack growth to suppress delayed fracture.


For these reasons, in the steel sheet according to aspects of the present invention, 90 mass % or more of the total content of Nb and Ti contained is present as a carbonitride having an equivalent circular diameter of 100 nm or more.


Although the upper limit of the carbonitride size is not particularly specified, Nb- and Ti-based precipitates newly precipitated in the hot rolling step and the coiling step often have a size of 500 nm or less. Thus, in accordance with aspects of the present invention, the carbonitrides of Nb and Ti described above are preferably carbonitrides having an equivalent circular diameter of 100 nm or more and 500 nm or less.


(Feature 4) A Nb carbonitride and a Ti carbonitride, having an equivalent circular diameter of 1.0 μm or more, are present at a rate of 800 pieces/mm2 or less in total. In steel in which the prior-γ grain size is sufficiently fine and intergranular fracture is suppressed, a delayed fracture originates from an inclusion of 1.0 μm or more in the steel, and thus it is important to reduce inclusions of 1.0 μm or more. Nb- and Ti-based precipitates have high dissolution temperatures and account for a particularly large proportion of inclusions of 1.0 μm or more. Thus, in accordance with aspects of the present invention, to improve delayed fracture resistance, a Nb carbonitride and a Ti carbonitride, having an equivalent circular diameter of 1.0 μm or more, are present at a rate of 800 pieces/mm2 or less in total, more preferably 100 pieces/mm2 or less, still more preferably 50 pieces/mm2 or less. In accordance with aspects of the present invention, the Nb carbonitride and the Ti carbonitride, having an equivalent circular diameter of 1.0 μm or more, are often present at a rate of 5 pieces/mm2 or more in total.


Methods of measuring the features of the steel microstructure above will be described.


The area fractions of martensite, bainite, and ferrite are measured in the following manner. An L section (a section parallel to the rolling direction and perpendicular to the steel sheet surface) of the steel sheet is polished and then etched with nital, four view areas are observed under SEM at a magnification of 2000× at a position ¼ thickness deep from the steel sheet surface, and microstructure images captured are subjected to image analysis. Here, martensite and bainite are microstructures exhibiting a gray or white color in SEM. By contrast, ferrite is a region exhibiting a black color in SEM. Martensite and bainite include traces of carbides, nitrides, sulfides, and oxides, but since it is difficult to exclude them, area fractions of regions including them are used as the area fractions of martensite and bainite.


Here, bainite has the following features. Specifically, bainite is in the form of a plate having an aspect ratio of 2.5 or more and is a microstructure that is somewhat blacker than martensite. The plate has a width (breadth) of 0.3 to 1.7 μm. The distribution density of a carbide having a diameter of 10 to 200 nm inside bainite is 0 to 3 pieces/μm2.


Retained austenite (retained γ) is measured by chemically polishing a surface of the steel sheet by 200 μm with oxalic acid and analyzing the resulting surface by an X-ray diffraction intensity method. Integral intensities of peaks of (200) α, (211) α, (220) α, (200)γ, (220)γ, and (311)γ diffraction planes measured with Mo-Kα radiation are used to make calculations.


The average grain size of prior-austenite grains (prior-γ grain size) is measured in the following manner. An L section (a section parallel to the rolling direction and perpendicular to the steel sheet surface) of the steel sheet is polished and then etched with a chemical solution (e.g., a saturated aqueous picric acid solution or a saturated aqueous picric acid solution with ferric chloride added) for etching prior-γ grain boundaries, four view areas are observed under a light microscope at a magnification of 500× at a position ¼ thickness deep from the steel sheet surface, 15 lines are drawn at intervals of 10 μm or more in actual length in each of the thickness direction and the rolling direction in the images obtained, the number of intersections of grain boundaries and the lines is counted. Furthermore, the total line length is divided by the number of intersections, and the value obtained is multiplied by 1.13, whereby the prior-γ grain size (average grain size of prior-austenite grains) can be measured.


The percentage of Nb and Ti forming carbonitrides having an equivalent circular diameter of 100 nm or more among Nb and Ti contained can be measured by the following method.


After a predetermined amount of sample is electrolyzed in an electrolyte, a sample piece is taken out of the electrolyte and immersed in a solution having dispersibility. Subsequently, precipitates contained in the solution are filtered through a filter with a pore size of 100 nm. The precipitates collected on the filter with a pore size of 100 nm are the carbonitrides having a diameter (equivalent circular diameter) of 100 nm or more. The residue on the filter and the filtrate obtained by the filtering were analyzed for Nb amount and Ti amount to determine the contents of Nb and Ti in the carbonitrides having a diameter of 100 nm or more and carbonitrides having a diameter of less than 100 nm. For the analysis, inductively coupled plasma (ICP) emission spectroscopic analysis can be used. The percentage of the total amount of Nb and Ti in the carbonitrides having a diameter of 100 nm or more to the total amount of Nb and Ti in steel is then calculated.


The number (distribution density) of the Nb carbonitride and the Ti carbonitride per mm2 can be determined as follows: after an L section (a section parallel to the rolling direction and perpendicular to the steel sheet surface) of the steel sheet is polished, in a region extending from the ⅕ thickness position to the ⅘ thickness position of the steel sheet without etching, that is, a region extending from a position ⅕ deep from the steel sheet surface in the thickness direction to the middle of the thickness and further to the ⅘ position, regions of 2 mm2 or more are continuously photographed by SEM, and the number of the carbonitrides are calculated in the SEM photographs captured. Here, the SEM images are preferably backscattered electron images. The magnification in the photographing may be 2000×. However, when it is difficult to accurately discern the size of precipitates at a magnification of 2000×, individual inclusion particles may be enlarged to 10000 times as appropriate to demarcate the carbonitrides.


Tensile Strength (TS): 1310 MPa or More


The deterioration of delayed fracture resistance is significantly apparent when the tensile strength of a material is 1310 MPa or more. One of the features according to aspects of the present invention is that the delayed fracture resistance is good even at 1310 MPa or more. Therefore, the tensile strength is 1310 MPa or more in accordance with aspects of the present invention. The tensile strength of the steel sheet according to aspects of the present invention may be 2100 MPa or less.


The tensile strength can be measured by a tensile test in accordance with JIS Z 2241 using a JIS No. 5 tensile test specimen cut out at a coil width ¼ position such that a direction perpendicular to the rolling direction is the longitudinal direction of the specimen.


In the steel sheet according to aspects of the present invention, σ0, σ1, and a tensile strength preferably satisfy (A), (B), or (C) below, where σ0 is a fracture stress before immersion in a solution containing a 10 mass % aqueous ammonium thiocyanate solution and a McIlvaine buffer solution having a pH of 3, and σ1 is a fracture stress after immersion in the solution.

    • (A) Tensile strength: 1310 MPa or more and less than 1500 MPa, and σ01 is 0.80 or more,
    • (B) Tensile strength: 1500 MPa or more and less than 1800 MPa, and σ10 is 0.50 or more,
    • (C) Tensile strength: 1800 MPa or more, and σ10 is 0.35 or more.


The fracture stress σ0 and the fracture stress σ1 can be determined using a conventional strain rate technique (CSRT) specimen cut out from the steel sheet at the ¼ position in the width direction of the steel sheet such that a direction perpendicular to the rolling direction is the longitudinal direction of the specimen. The CSRT specimen may be a tensile test specimen having a reduced section with a width of 12.5 mm and a length of 25 mm, both ends of the reduced section having a semicircular notch with a radius of 3 mm.


The fracture stress σ1 can be measured as follows: a 10 mass % aqueous ammonium thiocyanate solution and a McIlvaine buffer solution having a pH of 3 are mixed at 1:1, in the resulting solution at 20° C. adjusted such that the fluid volume per cm2 of surface area of the test specimen is 20 ml, the CSRT specimen is immersed for 24 hours to allow hydrogen to enter and diffuse through the test specimen, and immediately after the lapse of 24 hours, a tensile test is carried out at a crosshead speed of 1 mm/min. The fracture stress σ0 can be determined under the same conditions except that the immersion is not performed.


The steel sheet according to aspects of the present invention described above may be a steel sheet having a coating layer on its surface. The coating layer may be formed of Zn or other metal. The coating layer may be a hot-dip coating layer or an electroplated coating layer.


Next, a method for manufacturing the steel sheet according to aspects of the present invention will be described.


The method for manufacturing the steel sheet according to aspects of the present invention is a method for manufacturing a steel sheet, including heating a steel slab having the above chemical composition from 1000° C. to a heat holding temperature of 1250° C. or higher in terms of slab surface temperature at an average heating rate of 10° C./min or less, and holding the steel slab at the heat holding temperature for 30 minutes or more, then performing hot finish rolling at a finish rolling temperature not lower than an Ar3 temperature, performing cooling at an average cooling rate of 40° C./s or more in the range from the finish rolling temperature to 650° C., then performing cooling and coiling at a coiling temperature of 600° C. or lower to obtain a hot rolled steel sheet, cold rolling the hot rolled steel sheet at a rolling reduction of 40% or more to obtain a cold rolled steel sheet, and performing continuous annealing including heating the cold rolled steel sheet from 700° C. to an annealing temperature set to 800° C. to 950° C. at an average heating rate of 0.4° C./s or more, performing holding at the annealing temperature for 600 seconds or less, performing cooling from a cooling start temperature of 680° C. or higher to a cooling stop temperature of 260° C. or lower at an average cooling rate of 70° C./s or more, performing reheating as needed, and then performing holding at a holding temperature of 150° C. to 260° C. for 20 to 1500 seconds.


Hot Rolling


In the slab heating before the hot rolling, dissolution of sulfides is promoted to reduce the size and number of inclusions by setting the average heating rate from 1000° C. to a heat holding temperature of 1250° C. or higher to 10° C./min or less. Since Nb and Ti have high dissolution temperatures, dissolution of Nb and Ti is promoted to reduce the size and number of inclusions by setting the heat holding temperature to 1250° C. or higher in terms of slab surface temperature and the holding time to 30 minutes or more. The heat holding temperature is preferably 1300° C. or higher, more preferably 1350° C. or higher. The average heating rate from 1000° C. to a heat holding temperature of 1250° C. or higher is preferably 2° C./min or more. The heat holding temperature in terms of slab surface temperature is preferably 1380° C. or lower. The time to hold the slab at the heat holding temperature is preferably 250 minutes or less.


Here, the average heating rate is expressed as “(temperature (° C.) at completion of slab heating−temperature (° C.) at start of slab heating)/heating time (min) from start of heating to completion of heating”.


When the finish rolling temperature is lower than the Ar3 temperature in the hot finish rolling, ferrite is formed to cause stress concentration at ferrite interfaces in a final product, thus promoting delayed fracture. Therefore, the finish rolling temperature (FT) is not lower than the Ar3 temperature.


As cooling after the hot finish rolling, cooling at an average cooling rate of 40° C./s or more is performed in the range from the finish rolling temperature to 650° C. When the average cooling rate is less than 40° C./s, Nb and Ti carbonitrides are coarsened to increase carbonitrides having an equivalent circular diameter of 1.0 μm or more, and desired delayed fracture resistance cannot be obtained. The average cooling rate is preferably 250° C./s or less, more preferably 200° C./s or less.


The average cooling rate is expressed as “(temperature (finish rolling temperature) (° C.) at start of cooling-temperature (° C.) at completion of cooling (650° C.))/cooling time (s) from start of cooling to completion of cooling”.


When the coiling temperature is higher than 600° C., only the coarsening of Nb- and Ti-based precipitates precipitated in fine austenite regions proceeds, so that coarse precipitates increase to reduce delayed fracture resistance. Therefore, the coiling temperature is 600° C. or lower.


The Ar3 temperature is determined as follows.





Ar3 temperature(° C.)=910−310×[C]−80×[Mn]−20×[Cu]−15×[Cr]−55×[Ni]−80×[Mo]


(In the formula, [M] represents a content (mass %) of an element M in the steel slab, and the value of an element not contained is zero (0).)


Cold Rolling


When the rolling reduction (cold rolling reduction) is 40% or more in the cold rolling, the recrystallization behavior and texture orientation in the subsequent continuous annealing can be stabilized. When the rolling reduction is less than 40%, some austenite grains may be coarsened during annealing to decrease the strength. The cold rolling reduction is preferably 80% or less. The cold rolling reduction is more preferably 70% or less.


Continuous Annealing


The cold rolled steel sheet is subjected to annealing on a continuous annealing line (CAL) and, when necessary, tempering and temper rolling.


Increasing the heating rate is effective in reducing the prior-γ grain size, and the average heating rate at 700° C. or higher for reducing the prior-γ grain size to 10 μm or less is 0.4° C./s or more.


The average heating rate here is expressed as “(annealing temperature (° C.) described below −700 (° C.))/heating time (s) from 700° C. to annealing temperature”.


To sufficiently reduce carbides such as cementite particles left undissolved after annealing, the annealing is performed at high temperature for a long period of time. Specifically, the annealing temperature needs to be 800° C. or higher. Annealing at higher than 950° C. results in an excessively large prior-γ grain size, and thus the annealing temperature is 950° C. or lower, more preferably 900° C. or lower. A long soaking time (holding time) also results in an excessively large prior-γ grain size, and thus soaking (holding) is performed for 600 seconds or less.


To reduce ferrite and retained γ to achieve a martensite area fraction of 95% or more, cooling (rapid cooling) needs to be performed from a cooling start temperature of 680° C. or higher to a cooling stop temperature of 260° C. or lower at an average cooling rate of 70° C./s or more. Preferably, cooling is performed from a cooling start temperature at an average cooling rate of 700° C./s or more.


When the cooling start temperature is lower than 680° C., ferrite is formed in a large amount, and, in addition, carbon is concentrated in austenite (γ) to lower the Ms temperature, resulting in an increase in untempered martensite (fresh martensite). When the cooling rate is low, upper and lower bainite may be formed to increase the amount of retained austenite (retained γ) and fresh martensite. When the cooling stop temperature is higher than 260° C., upper and lower bainite may be formed to increase the amount of retained γ and fresh martensite. The acceptable limit of the area fraction of fresh martensite in martensite is 5% relative to 100% of martensite, and the amount of fresh martensite falls within this range when the above-described conditions are employed.


For the above reason, the cooling start temperature is 680° C. or higher. The upper limit of the cooling start temperature is preferably 940° C.


For the above reason, the cooling stop temperature is 260° C. or lower. The lower limit of the cooling stop temperature is preferably 150° C.


The upper limit of the average cooling rate is preferably 1000° C./s.


The average cooling rate here is expressed as “(cooling start temperature (° C.)−cooling stop temperature (° C.))/cooling time (s) from start of cooling to stop of cooling”.


Carbides distributed inside martensite are formed during holding in a low temperature range after quenching. For the achievement of high delayed fracture resistance and a tensile strength of 1310 MPa or more (TS≥1310 MPa), the formation of the carbides needs to be appropriately controlled.


To achieve this, it is necessary to control the holding time to 20 to 1500 seconds at a holding temperature of 150° C. to 260° C.


When the holding temperature is lower than its lower limit 150° C. or the holding time is short, the carbide distribution density in the transformation phase is insufficient, deteriorating delayed fracture resistance. When the holding temperature is higher than its upper limit 260° C., carbides in grains and at block grain boundaries may be noticeably coarsened, deteriorating delayed fracture resistance.


The steel sheet thus obtained may be subjected to skin pass rolling from the viewpoint of stabilizing the press formability by, for example, adjusting the surface roughness and flattening the sheet shape. In this case, the skin pass elongation is preferably 0.1% to 0.6%. In this case, from the viewpoint of shape flattening, it is preferable to use a dull roll as a skin pass roll and adjust the roughness Ra of the steel sheet to 0.8 to 1.8 μm.


The steel sheet obtained may be subjected to coating treatment. The coating treatment provides a steel sheet having a coating layer on its surface. The type of coating treatment is not particularly limited, and may be hot-dip coating, electroplating, or coating treatment involving alloying after hot-dip coating. When the above skin pass rolling is performed in the case where coating treatment is performed, the skin pass rolling is performed after the coating treatment.


As described above, aspects of the present invention provide a high strength cold rolled steel sheet with greatly improved delayed fracture resistance, and using the high strength steel sheet contributes to improvement of part strength and weight saving. The steel sheet according to aspects of the present invention preferably has a thickness of 0.5 mm or more. The steel sheet according to aspects of the present invention preferably has a thickness of 2.0 mm or less.


Next, a member according to aspects of the present invention and a method for manufacturing the member will be described.


The member according to aspects of the present invention is obtained by subjecting the steel sheet according to aspects of the present invention to at least one of forming and welding. The method for manufacturing the member according to aspects of the present invention includes a step of subjecting a steel sheet manufactured by the method for manufacturing a steel sheet according to aspects of the present invention to at least one of forming and welding.


The steel sheet according to aspects of the present invention has a tensile strength of 1310 MPa or more and high delayed fracture resistance. Accordingly, the member obtained using the steel sheet according to aspects of the present invention also has high strength and has higher delayed fracture resistance than conventional high strength members.


Use of the member according to aspects of the present invention enables weight saving. Therefore, the member according to aspects of the present invention is suitable for use in, for example, vehicle frame parts.


For the forming, any common forming method such as press forming can be used without limitation. For the welding, any common welding such as spot welding or arc welding can be used without limitation.


EXAMPLES
Example 1

Hereinafter, Examples of the present invention will be described.


Steels having chemical compositions shown in Table 1 were obtained by steelmaking and then cast into slabs.


The slabs were subjected to heat treatment and rolling shown in Table 2 to obtain steel sheets having a thickness of 1.4 mm.


Specifically, a slab having each chemical composition was heated to a heat holding temperature shown in Table 2 in terms of slab surface temperature at an average heating rate of 6° C./min and held for a heat holding time shown in Table 2. Thereafter, hot finish rolling at a finish rolling temperature shown in Table 2 was performed, and cooling at an average cooling rate of 50° C./s in the range from the finish rolling temperature to 650° C. was performed.


Thereafter, cooling and coiling at a coiling temperature shown in Table 2 were performed to obtain a hot rolled steel sheet, and the hot rolled steel sheet was cold rolled at a rolling reduction (cold rolling reduction) shown in Table 2 to obtain a cold rolled steel sheet.


Thereafter, the cold rolled steel sheet was heated from 700° C. to an annealing temperature shown in Table 2 at an average heating rate shown in Table 2 and soaked at the annealing temperature for a soaking time shown in Table 2.


Thereafter, cooling was performed from a cooling start temperature shown in Table 2 to a cooling stop temperature shown in Table 2 at an average cooling rate shown in Table 2, reheating was performed as needed, and then continuous annealing including holding at a holding temperature shown in Table 2 for a holding time shown in Table 2 was performed.


In Table 2, the cold rolled steel sheet (CR) of No. 4 was electrogalvanized into an electrogalvanized steel sheet (EG). In Table 2, the surface temperature of the slabs was measured with a radiation thermometer, and the central temperature of the slabs was determined by heat transfer calculations.










TABLE 1







Steel
Chemical composition (mass %)

















grade
C
Si
Mn
P
S
sol.Al
N
Ti
Nb
B





A
0.14
1.42
0.81
0.006
0.0007
0.042
0.0031
0.012
0.006



B
0.19
1.42
0.60
0.004
0.0004
0.030
0.0025
0.040




C
0.26
1.24
1.17
0.013
0.0003
0.035
0.0043
0.050
0.019



D
0.30
0.26
0.74
0.010
0.0006
0.036
0.0047
0.050
0.015



E
0.22
0.26
0.56
0.024
0.0006
0.030
0.0023
0.014
0.010



F
0.28
0.81
1.03
0.015
0.0008
0.049
0.0034
0.035
0.020



G
0.33
1.44
0.80
0.008
0.0004
0.041
0.0025
0.023
0.008



H
0.20
0.30
0.40
0.019
0.0004
0.027
0.0020
0.010
0.015



I
0.25
0.30
1.10
0.017
0.0009
0.024
0.0028
0.030
0.012



J
0.18
0.30
1.50
0.022
0.0007
0.024
0.0027
0.025
0.021
0.0062


K
0.32
0.21
1.35
0.008
0.0007
0.049
0.0021
0.014
0.007
0.0017


M
0.28
0.49
0.77
0.007
0.0007
0.040
0.0041
0.048
0.007
0.0016


L
0.16
0.49
0.66
0.028
0.0005
0.033
0.0032
0.012
0.005
0.0010


N
0.17
0.72
0.91
0.024
0.0002
0.030
0.0033
0.018
0.018
0.0015


O
0.19
0.72
0.30
0.014
0.0003
0.040
0.0016
0.007
0.020
0.0020


P
0.24
1.24
1.25
0.018
0.0005
0.036
0.0020
0.012
0.013
0.0010


Q
0.24
1.24
1.32
0.024
0.0008
0.040
0.0030
0.030
0.016
0.0021


R
0.20
1.24
0.49
0.023
0.0005
0.028
0.0040
0.041
0.006
0.0008


S
0.15
1.11
1.51
0.029
0.0008
0.033
0.0042
0.010
0.005
0.0023


T
0.22
1.11
0.62
0.027
0.0006
0.032
0.0035
0.008
0.002
0.0010


U
0.26
0.70
1.13
0.014
0.0005
0.032
0.0037
0.010
0.021
0.0020


V
0.22
0.70
1.34
0.026
0.0006
0.045
0.0039
0.006
0.030
0.0009


W
0.17
0.70
1.12
0.010
0.0008
0.028
0.0034
0.007
0.002
0.0020


X
0.20
0.93
0.62
0.026
0.0002
0.031
0.0028
0.010
0.012
0.0016


Y
0.27
0.93
1.30
0.015
0.0002
0.025
0.0018
0.040
0.022
0.0015


Z
0.31
0.86
0.80
0.010
0.0004
0.029
0.0031
0.031
0.012
0.0026


AA
0.32
0.86
1.12
0.015
0.0002
0.030
0.0039
0.040
0.011
0.0016


AB
0.27
0.13
1.08
0.013
0.0003
0.023
0.0024
0.050
0.010
0.0020


AC
0.10
1.42
1.31
0.004
0.0003
0.037
0.0044
0.060
0.004



AD
0.42
0.26
0.82
0.023
0.0004
0.044
0.0036
0.035
0.008



AE
0.31
1.58
1.00
0.008
0.0007
0.045
0.0038
0.041
0.008



AF
0.32
0.21
1.36
0.050
0.0002
0.026
0.0029
0.030
0.012



AG
0.27
0.49
1.02
0.009
0.0020
0.047
0.0032
0.018
0.012



AH
0.25
0.72
0.99
0.021
0.0003
0.230
0.0026
0.023
0.022



AI
0.36
1.11
1.05
0.012
0.0003
0.020
0.0055
0.020
0.018



AJ
0.30
0.93
0.73
0.029
0.0002
0.038
0.0045
0.010
0.080



AK
0.30
0.93
0.40
0.210
0.0003
0.026
0.0024
0.001
0.002



AL
0.24
0.13
1.60
0.024
0.0007
0.035
0.0041
0.080
0.010



AM
0.30
0.13
0.00
0.011
0.0002
0.021
0.0014
0.005
0.016
0.0112















Ar3



Steel
Chemical composition (mass %)
temperature












grade
others
Ti + Nb
(° C.) (*1)
Remarks





A

0.018
802
Conforming


B

0.040
803
Conforming


C

0.069
736
Conforming


D

0.065
758
Conforming


E

0.024
797
Conforming


F

0.055
741
Conforming


G

0.031
744
Conforming


H

0.025
816
Conforming


I

0.042
745
Conforming


J

0.046
734
Conforming


K

0.021
703
Conforming


M

0.055
762
Conforming


L

0.017
808
Conforming


N

0.036
785
Conforming


O

0.027
827
Conforming


P

0.025
736
Conforming


Q

0.046
730
Conforming


R

0.047
809
Conforming


S

0.015
743
Conforming


T

0.010
792
Conforming


U
Cu: 0.20
0.031
735
Conforming


V
Ni: 0.20, Mg: 0.0010
0.036
724
Conforming


W
Mo: 0.05, V: 0.05
0.009
764
Conforming


X
Mo: 0.10, Ca: 0.0020
0.022
790
Conforming


Y
Cr: 0.10, Mo: 0.05, Ce: 0.0010
0.062
717
Conforming


Z
La: 0.0010, Sb: 0.006, REM: 0.0010
0.043
750
Conforming


AA
Zr: 0.008, Sn: 0.003, W: 0.050
0.051
721
Conforming


AB

0.060
740
Conforming


AC

0.064
774
Comparative


AD

0.043
714
Comparative


AE

0.049
734
Comparative


AF

0.042
702
Comparative


AG

0.030
745
Comparative


AH

0.045
753
Comparative


AI

0.038
714
Comparative


AJ

0.090
759
Comparative


AK

0.003
785
Comparative


AL

0.090
708
Comparative


AM

0.021
817
Comparative





The balance other than the above is Fe and incidental impurities.


(*1) Ar3 temperature = 910-310 × [C]-80 × [Mn]-20 × [Cu]-15 × [Cr]-55 × [Ni]-80 × [Mo] (In the formula, [M] is a content (mass %) of an element M.)


















TABLE 2









Hot rolling




















Heat


Cold rolling
Continuous annealing















Steel

Heat holding
holding
Finish rolling
Coiling
Rolling
Annealing
Average


sheet
Steel
temperature
time
temperature
temperature
reduction
temperature
heating


No.
grade
(° C.)
(min)
(° C.)
(° C.)
(%)
(° C.)
rate (° C./s)





1
A
1250
150
870
580
60
900
0.5


2
B
1250
150
870
580
60
900
0.5


3
C
1250
150
870
580
60
900
0.5


4
D
1250
150
870
580
60
900
0.5


5
E
1250
180
870
550
60
900
0.5


6
F
1250
180
870
550
60
900
0.5


7
G
1280
180
870
550
65
900
0.5


8
H
1280
180
870
550
65
900
0.5


9
I
1280
120
870
550
65
900
0.8


10
J
1280
120
890
550
65
870
0.8


11
K
1280
120
890
600
65
870
0.8


12
M
1280
120
890
600
65
870
0.8


13
L
1320
100
890
600
65
870
0.8


14
N
1320
100
890
600
65
870
0.8


15
O
1320
100
890
600
65
870
0.8


16
P
1320
100
890
600
65
870
0.8


17
Q
1320
40
890
570
65
870
0.8


18
R
1320
40
890
570
65
870
1.0


19
S
1350
40
890
570
65
890
1.0


20
T
1350
40
860
570
58
890
1.0


21
U
1350
200
860
570
58
890
1.0


22
V
1350
200
860
570
58
890
1.0


23
W
1350
200
860
570
58
890
1.0


24
X
1350
200
860
590
58
890
1.0


25
Y
1260
160
860
590
58
890
1.0


26
Z
1260
160
860
590
58
920
0.7


27
AA
1260
160
860
590
53
920
0.7


28
AB
1260
160
910
590
53
920
0.7


29
AC
1260
80
910
590
53
920
0.7


30
AD
1260
80
910
590
53
920
0.7


31
AE
1320
80
910
590
53
920
0.7


32
AF
1320
60
910
580
53
860
0.7


33
AG
1320
60
910
580
56
860
0.7


34
AH
1320
60
910
580
56
860
0.7


35
AI
1250
60
870
580
56
860
0.7


36
AJ
1250
180
870
590
56
860
1.2


37
AK
1250
180
870
590
56
860
1.2


38
AL
1250
180
870
590
56
860
1.2


39
AM
1250
180
870
590
56
860
1.2


40
Y
1210
180
870
590
59
910
1.2


41
Y
1290
20
880
590
59
910
1.2


42
Y
1290
150
880
650
59
910
1.2


43
Y
1290
150
880
570
59
910
0.1


44
Y
1290
150
880
570
59
910
0.9


45
Y
1290
150
880
570
59
940
0.9


46
Y
1290
150
880
570
59
960
0.9













Continuous annealing















Steel

Cooling start
Average
Cooling stop
Holding




sheet
Soaking
temperature
cooling
temperature
temperature
Holding



No.
time (s)
(° C.)
rate (° C./s)
(° C.)
(° C.)
time (s)
Remarks





1
360
760
840
30
180
780
Conforming


2
360
760
840
30
180
780
Conforming


3
360
760
840
30
180
780
Conforming


4
360
760
840
30
180
780
Conforming


5
360
780
840
30
180
780
Conforming


6
360
780
840
30
190
780
Conforming


7
360
780
840
30
190
780
Conforming


8
420
780
790
30
190
780
Conforming


9
420
780
790
30
190
900
Conforming


10
420
790
790
30
190
900
Conforming


11
420
790
790
30
190
900
Conforming


12
420
790
790
30
190
900
Conforming


13
420
790
790
25
200
900
Conforming


14
420
720
790
25
200
900
Conforming


15
420
720
790
25
200
900
Conforming


16
420
690
860
25
200
900
Conforming


17
480
720
860
25
200
900
Conforming


18
480
720
860
25
200
1080
Conforming


19
480
720
860
25
200
1080
Conforming


20
480
750
860
25
210
1080
Conforming


21
480
750
860
25
210
1080
Conforming


22
480
750
860
25
210
1080
Conforming


23
480
750
860
25
210
1080
Conforming


24
480
750
860
25
210
1080
Conforming


25
540
830
860
25
210
1080
Conforming


26
540
830
 80
23
230
600
Conforming


27
540
830
820
23
230
600
Conforming


28
540
830
820
23
230
600
Conforming


29
540
830
820
23
230
600
Comparative


30
540
810
820
23
230
600
Comparative


31
540
810
820
23
230
600
Comparative


32
180
810
820
23
240
600
Comparative


33
180
810
760
23
240
540
Comparative


34
180
810
760
23
240
540
Comparative


35
180
810
760
23
240
540
Comparative


36
180
860
760
34
240
540
Comparative


37
180
860
760
34
170
540
Comparative


38
180
860
760
34
170
540
Comparative


39
240
860
760
34
170
540
Comparative


40
240
860
760
34
170
720
Comparative


41
240
860
760
34
170
720
Comparative


42
240
800
760
34
190
720
Comparative


43
240
800
830
34
190
720
Comparative


44
240
670
830
34
190
720
Comparative


45
540
800
830
15
190
720
Conforming


46
540
800
830
15
190
720
Comparative









For each of the steel sheets obtained, its metallic microstructure was quantified by the above-described method, and, furthermore, a tensile test and a delayed fracture resistance evaluation test were performed.


Specifically, the microstructure was measured in the following manner.


The area fractions of martensite, bainite, and ferrite were measured in the following manner. An L section (a section parallel to the rolling direction and perpendicular to the steel sheet surface) of the steel sheet was polished and then etched with nital, four view areas were observed under SEM at a magnification of 2000× at a position ¼ thickness deep from the steel sheet surface, and microstructure images captured were subjected to image analysis. Here, martensite and bainite are microstructures exhibiting a gray or white color in SEM. Here, bainite has the following features. Specifically, bainite is in the form of a plate having an aspect ratio of 2.5 or more and is a microstructure that is somewhat blacker than martensite. The plate has a width (breadth) of 0.3 to 1.7 μm. The distribution density of a carbide having a diameter of 10 to 200 nm inside bainite is 0 to 3 pieces/μm2. By contrast, ferrite is a region exhibiting a black color in SEM. Martensite and bainite include traces of carbides, nitrides, sulfides, and oxides, but since it is difficult to exclude them, area fractions of regions including them were used as the area fractions of martensite and bainite. Retained austenite (retained γ) was measured by chemically polishing a surface of the steel sheet by 200 μm with oxalic acid and analyzing the resulting surface by an X-ray diffraction intensity method. Integral intensities of peaks of (200)α, (211)α, (220)α, (200)γ, (220)γ, and (311)γ diffraction planes measured with Mo-Kα radiation were used to make calculations.


The average grain size of prior-austenite grains (prior-γ grain size) was measured in the following manner. An L section (a section parallel to the rolling direction and perpendicular to the steel sheet surface) of the steel sheet was polished and then etched with a chemical solution (e.g., a saturated aqueous picric acid solution or a saturated aqueous picric acid solution with ferric chloride added) for etching prior-γ grain boundaries, four view areas were observed under a light microscope at a magnification of 500× at a position ¼ thickness deep from the steel sheet surface, 15 lines were drawn at intervals of 10 μm or more in actual length in each of the thickness direction and the rolling direction in the images obtained, and the number of intersections of grain boundaries and the lines was counted. The total line length was divided by the number of intersections, and the value obtained was multiplied by 1.13 to determine the prior-γ grain size.


The percentage of Nb and Ti forming carbonitrides having an equivalent circular diameter of 100 nm or more among Nb and Ti contained can be measured by the following method.


After a predetermined amount of sample is electrolyzed in an electrolyte, a sample piece is taken out of the electrolyte and immersed in a solution having dispersibility. Subsequently, precipitates contained in the solution are filtered through a filter with a pore size of 100 nm. The precipitates collected on the filter with a pore size of 100 nm are the carbonitrides having a diameter (equivalent circular diameter) of 100 nm or more. The residue on the filter and the filtrate obtained by the filtering were analyzed for Nb amount and Ti amount to determine the contents of Nb and Ti in the carbonitrides having a diameter of 100 nm or more and carbonitrides having a diameter of less than 100 nm. For the analysis, inductively coupled plasma (ICP) emission spectroscopic analysis can be used. The percentage of the total amount of Nb and Ti in the carbonitrides having a diameter of 100 nm or more to the total amount of Nb and Ti in steel is then calculated.


The number (distribution density) of the Nb carbonitride and the Ti carbonitride per mm2 can be determined as follows: after an L section (a vertical section parallel to the rolling direction) of the steel sheet is polished, in a region extending from the ⅕ thickness position to the ⅘ thickness position of the steel sheet without etching, that is, a region extending from a position ⅕ deep from the steel sheet surface in the thickness direction to the middle of the thickness and further to the ⅘ position, regions of 2 mm2 or more are continuously photographed by SEM, and the number of the carbonitrides are calculated in the SEM photographs captured. Here, the SEM images are preferably backscattered electron images. The magnification in the photographing may be 2000×. However, when it is difficult to accurately discern the size of precipitates at a magnification of 2000×, individual inclusion particles may be enlarged to 10000 times as appropriate to demarcate the carbonitrides.


For the tensile test, a JIS No. 5 tensile test specimen was cut out at a coil width ¼ position such that a direction perpendicular to the rolling direction is the longitudinal direction of the specimen, and a tensile test (in accordance with JIS Z 2241) was performed to evaluate YP, TS, and El.


The evaluation of delayed fracture resistance was performed in the following manner. A conventional strain rate technique (CSRT) specimen was cut out from the obtained steel sheet (coil) at the coil width ¼ position in the width direction of the steel sheet such that a direction perpendicular to the rolling direction was the longitudinal direction of the test specimen. The CSRT specimen was a tensile test specimen having a reduced section with a width of 12.5 mm and a length of 25 mm, both ends of the reduced section having a semicircular notch with a radius of 3 mm. A 10 mass % aqueous ammonium thiocyanate solution and a McIlvaine buffer solution having a pH of 3 were mixed at a volume ratio of 1:1, in the resulting solution (pH 3) at 20° C. adjusted such that the fluid volume per cm2 of surface area of the test specimen was 20 ml, the CSRT specimen was immersed for 24 hours to allow hydrogen to enter and diffuse through the test specimen, and immediately after the lapse of 24 hours, a tensile test was carried out at a crosshead speed of 1 mm/min to measure a fracture stress. The delayed fracture resistance was evaluated by σ10, where σ0 is a fracture stress measured when immersion is not performed, and σ1 is a fracture stress measured after hydrogen is allowed to enter and diffuse by immersion. Here, those whose σ10 values were 0.80 or more when TS was 1310 MPa or more and less than 1500 MPa, those whose σ10 values were 0.50 or more when TS was 1500 MPa or more and less than 1800 MPa, and those whose σ10 values were 0.35 or more when TS was 1800 MPa or more were evaluated as having high delayed fracture resistance.


The microstructure and properties of the steel sheets obtained are shown in Table 3.




















TABLE 3










Amount of
Number












Nb and Ti
density of









Martensite
Balance
Prior-γ
carbonitrides
Nb and Ti







Steel

area
area
grain
of 100 nm
carbonitrides







sheet
Steel
fraction
fraction
size
or more
(piece/mm2)
TS
σ0
σ1




No.
grade
(%)
(%) (*1)
(μm)
(mass %)
(*2)
(MPa)
(MPa)
(MPa)
σ1/σ0
Remarks


























1
A
100
0
8.2
93
81
1373
1580
1462
0.93
Conforming


2
B
100
0
5.3
92
298
1520
1745
1199
0.69
Conforming


3
C
100
0
3.8
93
610
1723
1990
1483
0.75
Conforming


4
D
100
0
3.9
93
553
1830
2110
1520
0.72
Conforming


5
E
100
0
7.0
94
127
1601
1833
1678
0.92
Conforming


6
F
100
0
4.3
92
453
1742
1999
1208
0.60
Conforming


7
G
100
0
5.8
94
171
1900
2154
1641
0.76
Conforming


8
H
100
0
5.9
93
84
1513
1746
1498
0.86
Conforming


9
I
100
0
4.8
93
253
1640
1885
1487
0.79
Conforming


10
J
100
0
4.5
91
281
1435
1633
1524
0.93
Conforming


11
K
100
0
7.0
94
84
1849
2120
975
0.46
Conforming


12
L
100
0
4.1
95
377
1735
1985
1188
0.60
Conforming


13
M
100
0
6.9
95
41
1368
1567
1465
0.93
Conforming


14
N
100
0
4.7
96
119
1398
1600
1510
0.94
Conforming


15
O
100
0
5.0
95
49
1454
1673
1308
0.78
Conforming


16
P
96
4
5.5
95
60
1532
1761
1102
0.63
Conforming


17
Q
100
0
4.2
95
202
1599
1835
1478
0.81
Conforming


18
R
100
0
4.3
96
244
1478
1701
1498
0.88
Conforming


19
S
100
0
6.8
96
22
1340
1443
1437
1.00
Conforming


20
T
100
0
8.4
94
14
1498
1716
1541
0.90
Conforming


21
U
100
0
4.5
98
44
1590
1820
1635
0.90
Conforming


22
V
100
0
4.1
98
41
1482
1701
1433
0.84
Conforming


23
W
100
0
8.8
93
11
1346
1545
1430
0.93
Conforming


24
X
100
0
5.5
98
31
1431
1650
1504
0.91
Conforming


25
Y
100
0
4.3
93
501
1625
1864
1475
0.79
Conforming


26
Z
100
0
4.9
95
301
1688
1946
1328
0.68
Conforming


27
AA
100
0
4.4
93
374
1712
1963
1075
0.55
Conforming


28
AB
100
0
4.0
92
466
1570
1802
1231
0.68
Conforming


29
AC
100
0
3.9
93
504
1089
1260
1249
0.99
Comparative


30
AD
100
0
4.9
93
297
2001
2312
743
0.32
Comparative


31
AE
100
0
4.2
95
255
1686
1926
930
0.48
Comparative


32
AF
100
0
4.5
96
183
1690
1943
597
0.31
Comparative


33
AG
100
0
5.2
94
98
1553
1762
707
0.40
Comparative


34
AH
100
0
4.2
93
175
1997
2280
689
0.30
Comparative


35
AI
100
0
5.6
94
288
1790
2031
956
0.47
Comparative


36
AJ
100
0
3.2
92
884
1646
1998
824
0.41
Comparative


37
AK
100
0
12.9
88
21
1857
2129
680
0.32
Comparative


38
AL
100
0
3.2
97
868
1687
1943
669
0.34
Comparative


39
AM
100
0
6.4
96
65
1854
2119
597
0.28
Comparative


40
Y
100
0
6.5
97
865
1762
2022
749
0.37
Comparative


41
Y
100
0
7.7
96
1020
1765
2025
843
0.42
Comparative


42
Y
100
0
11.0
95
620
1708
1957
944
0.48
Comparative


43
Y
100
0
13.0
94
521
1702
1949
902
0.46
Comparative


44
Y
92
8
5.1
95
510
1627
1867
923
0.49
Comparative


45
Y
100
0
17.5
94
480
1702
1957
992
0.51
Conforming


46
Y
100
0
19.5
93
480
1699
1958
886
0.45
Comparative





(*1) Balance area fraction: Total area fraction of bainite, ferrite, and retained austenite


(*2) Number density of Nb and Ti carbonitrides: Total number density of a Nb carbonitride and a Ti carbonitride having an equivalent circular diameter of 1.0 μm or more






Steel sheets within the scope according to aspects of the present invention had high strength and high delayed fracture resistance.


By contrast, No. 29 (steel grade AC) had an insufficient C content and insufficient TS.


No. 30 (steel grade AD) had an excessive C content, thus failing to achieve sufficient delayed fracture resistance.


No. 31 (steel grade AE) had an excessive Si content, thus failing to achieve sufficient delayed fracture resistance.


No. 32 (steel grade AF) had an excessive P content, thus failing to achieve sufficient delayed fracture resistance.


No. 33 (steel grade AG) had an excessive S content, thus failing to achieve sufficient delayed fracture resistance.


No. 34 (steel grade AH) had an excessive sol. Al content, thus failing to achieve sufficient delayed fracture resistance.


No. 35 (steel grade AI) had an excessive N content, thus failing to achieve sufficient delayed fracture resistance.


No. 36 (steel grade AJ) and No. 38 (steel grade AL) had an excessive total Nb and Ti content, which resulted in an excessive presence of precipitates of 1.0 μm or more, thus failing to achieve sufficient delayed fracture resistance.


No. 37 (steel grade AK) had an insufficient total Nb and Ti content, thus failing to achieve sufficient delayed fracture resistance.


No. 39 (steel grade AM) had an excessive B content, thus failing to achieve sufficient delayed fracture resistance.


No. 40 (steel grade Y), in which Nb and Ti were not sufficiently dissolved due to a low heating temperature (slab surface temperature (SRT)) and thus Nb and Ti precipitates of 1.0 μm or more were present in large numbers, failed to achieve sufficient delayed fracture resistance.


No. 41 (steel grade Y), in which Nb and Ti were not sufficiently dissolved due to too short a slab heat holding time and thus Nb and Ti precipitates of 1.0 μm or more were present in large numbers, failed to achieve sufficient delayed fracture resistance.


No. 42 (steel grade Y) was coiled at a high coiling temperature (CT), thus failing to achieve sufficient delayed fracture resistance.


No. 43 (steel grade Y) was heated at a low average heating rate during annealing, thus failing to achieve sufficient delayed fracture resistance.


No. 44 (steel grade Y) was cooled at a low cooling start temperature, which resulted in ferrite formation and insufficient martensite formation, thus failing to achieve sufficient delayed fracture resistance.


No. 46 (steel grade Y) was annealed at a high annealing temperature, which resulted in insufficient reduction in prior-γ grain size, thus failing to achieve sufficient delayed fracture resistance.


Example 2

A galvanized steel sheet obtained by galvanizing the steel sheet according to the manufacturing condition No. 4 (Conforming Example) in Table 2 in Example 1 was subjected to press forming to manufacture a member of Inventive Example. Furthermore, a galvanized steel sheet obtained by galvanizing the steel sheet according to the manufacturing condition No. 4 (Conforming Example) in Table 2 in Example 1 and a galvanized steel sheet obtained by galvanizing the steel sheet according to the manufacturing condition No. 7 (Conforming Example) in Table 2 in Example 1 were joined by spot welding to manufacture a member of Inventive Example.


These members of Inventive Example have a tensile strength TS of 1800 MPa or more and a σ10 value of 0.35 or more, specifically, 0.70 or more, thus having high delayed fracture resistance, showing that these members are suitable for use in automotive parts and the like.


Similarly, the steel sheet according to the manufacturing condition No. 4 (Conforming Example) in Table 2 in Example 1 was subjected to press forming to manufacture a member of Inventive Example. Furthermore, the steel sheet according to the manufacturing condition No. 4 (Conforming Example) in Table 2 in Example 1 and a steel sheet according to the manufacturing condition No. 7 (Conforming Example) in Table 2 in Example 1 were joined by spot welding to manufacture a member of Inventive Example. These members of Inventive Example have a tensile strength TS of 1800 MPa or more and a σ10 value of 0.35 or more, specifically, 0.7 or more, thus having high delayed fracture resistance, showing that these members are suitable for use in automotive parts and the like.

Claims
  • 1.-14. (canceled)
  • 15. A steel sheet comprising a chemical composition containing, in mass %, C: 0.12% or more and 0.40% or less,Si: 1.5% or less,Mn: 1.7% or less,P: 0.03% or less,S: less than 0.0020%,sol. Al: 0.20% or less,N: 0.005% or less, andone or more of Nb and Ti with a total content of 0.005% or more and 0.080% or less,with the balance being Fe and incidental impurities,wherein the steel sheet has a microstructure in which an area fraction of martensite relative to the entire microstructure is 95% or more and 100% or less, with the balance being one or more of bainite, ferrite, and retained austenite,prior-austenite grains have an average grain size of 18 μm or less,90 mass % or more of the total content of Nb and Ti contained is present as a carbonitride having an equivalent circular diameter of 100 nm or more,a Nb carbonitride and a Ti carbonitride, having an equivalent circular diameter of 1.0 μm or more, are present at a rate of 800 pieces/mm2 or less in total, andthe steel sheet has a tensile strength of 1310 MPa or more, andoptionally wherein a coating layer is disposed on a surface of the steel sheet.
  • 16. The steel sheet according to claim 15, wherein the prior-austenite grains have an average grain size of 10 μm or less.
  • 17. The steel sheet according to claim 15, wherein a fracture stress σ0 before immersion in a solution containing a 10 mass % aqueous ammonium thiocyanate solution and a McIlvaine buffer solution having a pH of 3, a fracture stress σ1 after immersion in the solution, andthe tensile strength satisfy (A), (B), or (C) below:(A) Tensile strength: 1310 MPa or more and less than 1500 MPa, and σ1/σ0 is 0.80 or more,(B) Tensile strength: 1500 MPa or more and less than 1800 MPa, and σ1/σ0 is 0.50 or more,(C) Tensile strength: 1800 MPa or more, and σ1/σ0 is 0.35 or more.
  • 18. The steel sheet according to claim 16, wherein a fracture stress σ0 before immersion in a solution containing a 10 mass % aqueous ammonium thiocyanate solution and a McIlvaine buffer solution having a pH of 3, a fracture stress G1 after immersion in the solution, andthe tensile strength satisfy (A), (B), or (C) below:(A) Tensile strength: 1310 MPa or more and less than 1500 MPa, and σ1/σ0 is 0.80 or more,(B) Tensile strength: 1500 MPa or more and less than 1800 MPa, and σ1/σ0 is 0.50 or more,(C) Tensile strength: 1800 MPa or more, and σ1/σ0 is 0.35 or more.
  • 19. The steel sheet according to claim 15, wherein the chemical composition contains, in mass %, one or two or more selected from the following groups A to F: group A:S: less than 0.0010%,group B:B: 0.0100% or less,group C:one or two selected from Cu: 1.0% or less and Ni: 1.0% or less,group D:one or two or more selected from Cr: 1.0% or less, Mo: less than 0.3%, V: 0.5% or less, Zr: 0.2% or less, and W: 0.2% or less,group E:one or two or more selected from Ca: 0.0030% or less, Ce: 0.0030% or less, La: 0.0030% or less, REM (excluding Ce and La): 0.0030% or less, and Mg: 0.0030% or less.group F:one or two selected from Sb: 0.1% or less and Sn: 0.1% or less.
  • 20. The steel sheet according to claim 16, wherein the chemical composition contains, in mass %, one or two or more selected from the following groups A to F: group A:S: less than 0.0010%,group B:B: 0.0100% or less,group C:one or two selected from Cu: 1.0% or less and Ni: 1.0% or less,group D:one or two or more selected from Cr: 1.0% or less, Mo: less than 0.3%, V: 0.5% or less, Zr: 0.2% or less, and W: 0.2% or less,group E:one or two or more selected from Ca: 0.0030% or less, Ce: 0.0030% or less, La: 0.0030% or less, REM (excluding Ce and La): 0.0030% or less, and Mg: 0.0030% or less.group F:one or two selected from Sb: 0.1% or less and Sn: 0.1% or less.
  • 21. The steel sheet according to claim 17, wherein the chemical composition contains, in mass %, one or two or more selected from the following groups A to F: group A:S: less than 0.0010%,group B:B: 0.0100% or less,group C:one or two selected from Cu: 1.0% or less and Ni: 1.0% or less,group D:one or two or more selected from Cr: 1.0% or less, Mo: less than 0.3%, V: 0.5% or less, Zr: 0.2% or less, and W: 0.2% or less,group E:one or two or more selected from Ca: 0.0030% or less, Ce: 0.0030% or less, La: 0.0030% or less, REM (excluding Ce and La): 0.0030% or less, and Mg: 0.0030% or less.group F:one or two selected from Sb: 0.1% or less and Sn: 0.1% or less.
  • 22. The steel sheet according to claim 18, wherein the chemical composition contains, in mass %, one or two or more selected from the following groups A to F: group A:S: less than 0.0010%,group B:B: 0.0100% or less,group C:one or two selected from Cu: 1.0% or less and Ni: 1.0% or less,group D:one or two or more selected from Cr: 1.0% or less, Mo: less than 0.3%, V: 0.5% or less, Zr: 0.2% or less, and W: 0.2% or less,group E:one or two or more selected from Ca: 0.0030% or less, Ce: 0.0030% or less, La: 0.0030% or less, REM (excluding Ce and La): 0.0030% or less, and Mg: 0.0030% or less.group F:one or two selected from Sb: 0.1% or less and Sn: 0.1% or less.
  • 23. A member obtained by subjecting the steel sheet according to claim 15 to at least one of forming and welding.
  • 24. A member obtained by subjecting the steel sheet according to claim 16 to at least one of forming and welding.
  • 25. A member obtained by subjecting the steel sheet according to claim 17 to at least one of forming and welding.
  • 26. A member obtained by subjecting the steel sheet according to claim 18 to at least one of forming and welding.
  • 27. A member obtained by subjecting the steel sheet according to claim 19 to at least one of forming and welding.
  • 28. A member obtained by subjecting the steel sheet according to claim 20 to at least one of forming and welding.
  • 29. A member obtained by subjecting the steel sheet according to claim 21 to at least one of forming and welding.
  • 30. A member obtained by subjecting the steel sheet according to claim 22 to at least one of forming and welding.
  • 31. A method for manufacturing a steel sheet, comprising: heating a steel slab having the chemical composition according to claim 15 from 1000° C. to a heat holding temperature of 1250° C. or higher in terms of slab surface temperature at an average heating rate of 10° C./min or less and holding the steel slab at the heat holding temperature for 30 minutes or more,then performing hot finish rolling at a finish rolling temperature not lower than an Ar3 temperature,performing cooling at an average cooling rate of 40° C./s or more in a range from the finish rolling temperature to 650° C.,then performing cooling and coiling at a coiling temperature of 600° C. or lower to obtain a hot rolled steel sheet,cold rolling the hot rolled steel sheet at a rolling reduction of 40% or more to obtain a cold rolled steel sheet, andperforming continuous annealing including: heating the cold rolled steel sheet from 700° C. to an annealing temperature set to 800° C. to 950° C. at an average heating rate of 0.4° C./s or more,performing holding at the annealing temperature for 600 seconds or less,performing cooling from a cooling start temperature of 680° C. or higher to a cooling stop temperature of 260° C. or lower at an average cooling rate of 70° C./s or more, andthen performing holding at a holding temperature of 150° C. to 260° C. for 20 to 1500 seconds,and optionally further comprising performing coating treatment on a steel sheet surface after the continuous annealing.
  • 32. A method for manufacturing a steel sheet, comprising: heating a steel slab having the chemical composition according to claim 19 from 1000° C. to a heat holding temperature of 1250° C. or higher in terms of slab surface temperature at an average heating rate of 10° C./min or less and holding the steel slab at the heat holding temperature for 30 minutes or more,then performing hot finish rolling at a finish rolling temperature not lower than an Ar3 temperature,performing cooling at an average cooling rate of 40° C./s or more in a range from the finish rolling temperature to 650° C.,then performing cooling and coiling at a coiling temperature of 600° C. or lower to obtain a hot rolled steel sheet,cold rolling the hot rolled steel sheet at a rolling reduction of 40% or more to obtain a cold rolled steel sheet, andperforming continuous annealing including: heating the cold rolled steel sheet from 700° C. to an annealing temperature set to 800° C. to 950° C. at an average heating rate of 0.4° C./s or more,performing holding at the annealing temperature for 600 seconds or less,performing cooling from a cooling start temperature of 680° C. or higher to a cooling stop temperature of 260° C. or lower at an average cooling rate of 70° C./s or more, andthen performing holding at a holding temperature of 150° C. to 260° C. for 20 to 1500 seconds,and optionally further comprising performing coating treatment on a steel sheet surface after the continuous annealing.
  • 33. A method for manufacturing a member, comprising a step of subjecting a steel sheet manufactured by the method for manufacturing a steel sheet according to claim 31 to at least one of forming and welding.
  • 34. A method for manufacturing a member, comprising a step of subjecting a steel sheet manufactured by the method for manufacturing a steel sheet according to claim 32 to at least one of forming and welding.
Priority Claims (1)
Number Date Country Kind
2020-216037 Dec 2020 JP national
CROSS REFERENCE TO RELATED APPLICATIONS

This is the U.S. National Phase application of PCT/JP2021/048106, filed Dec. 24, 2021, which claims priority to Japanese Patent Application No. 2020-216037, filed Dec. 25, 2020, the disclosures of these applications being incorporated herein by reference in their entireties for all purposes.

PCT Information
Filing Document Filing Date Country Kind
PCT/JP2021/048106 12/24/2021 WO