STEEL SHEET, COATED STEEL SHEET, AND METHODS FOR MANUFACTURING SAME

TECHNICAL FIELD

This disclosure relates to a steel sheet, a hot-dip galvanized steel sheet, a hot-dip aluminum-coated steel sheet, and an electrogalvanized steel sheet, and methods for manufacturing the same, and in particular to a steel sheet with excellent formability and hole expansion formability and high yield ratio that is preferably used in parts in the industrial fields of automobiles, electronics, and the like.

BACKGROUND

In recent years, enhancement of fuel efficiency of automobiles has become an important issue from the viewpoint of global environment protection. Consequently, there is an active movement to reduce the thickness of automotive body components through increases in strength of steel sheets as automotive body materials, and thereby reduce the weight of automotive body itself.

In general, however, strengthening of steel sheets leads to deterioration in formability, causing the problem of cracking during forming. It is thus not simple to reduce the thickness of steel sheets. Therefore, it is desirable to develop materials with increased strength and good formability. In addition to good formability, steel sheets with a tensile strength (TS) of 590 MPa or more are required to have, in particular, enhanced impact energy absorption properties. To enhance impact energy absorption properties, it is effective to increase yield ratio (YR). The reason is that a higher yield ratio enables the steel sheet to absorb impact energy more effectively with less deformation.

Moreover, in the case of using a steel sheet in an automotive body, stretch flanging according to the shape of the automotive body is performed, so that excellent hole expansion formability is required, too.

For example, JPS61157625A (PTL 1) proposes a high-strength steel sheet with extremely high ductility having a tensile strength of 1000 MPa or higher and a total elongation (EL) of 30% or more, utilizing deformation induced transformation of retained austenite.

In addition, JPH1259120A (PTL 2) proposes a high-strength steel sheet with well-balanced strength and ductility that is obtained from high-Mn steel through heat treatment in a ferrite-austenite dual phase region.

Moreover, JP2003138345A (PTL 3) proposes a high-strength steel sheet with improved local ductility that is obtained from high-Mn steel through hot rolling to have a microstructure containing bainite and martensite after subjection to the hot rolling, followed by annealing and tempering to cause fine retained austenite, and subsequently tempered bainite or tempered martensite in the microstructure.

CITATION LIST
Patent Literature

PTL 1:JPS61157625A

PTL 2: JPH1259120A

PTL 3: JP2003138345A

SUMMARY
Technical Problem

The steel sheet described in PTL 1 is manufactured by austenitizing a steel sheet containing C, Si, and Mn as basic components, and subjecting the steel sheet to a so-called austempering process whereby the steel sheet is quenched to and held isothermally in a bainite transformation temperature range. During the austempering process, C concentrates in austenite to form retained austenite.

However, while a high concentration of C beyond 0.3% is required for the formation of a large amount of retained austenite, such a high C concentration above 0.3% leads to a significant decrease in spot weldability, which may not be suitable for practical use in steel sheets for automobiles. Additionally, the main objective of PTL 1 is improving the ductility of steel sheets, without any consideration for the hole expansion formability, bendability, or yield ratio.

PTLs 2 and 3 describe techniques for improving the ductility of steel sheets from the perspective of formability, but do not consider the bendability, yield ratio, or hole expansion formability of the steel sheet.

To address these issues, it could thus be helpful to provide a steel sheet, a hot-dip galvanized steel sheet, a hot-dip aluminum-coated steel sheet, and an electrogalvanized steel sheet that are excellent in formability and hole expansion formability with TS of 590 MPa or more and YR of 68% or more, and methods for manufacturing the same.

Solution to Problem

To manufacture a high-strength steel sheet that can solve the above issues, with excellent formability and hole expansion formability as well as high yield ratio and high tensile strength, we made intensive studies from the perspectives of the chemical compositions and manufacturing methods of steel sheets. As a result, we discovered that a high-strength steel sheet with high yield ratio that is excellent in formability such as ductility and hole expansion formability can be manufactured by appropriately controlling the chemical composition and microstructure of steel.

Specifically, a steel sheet that has a steel composition containing Mn: 2.60 mass % or more and 4.20 mass % or less, with the addition amounts of other alloying elements such as Ti being adjusted appropriately, is hot rolled to obtain a hot-rolled sheet. The hot-rolled sheet is then subjected to pickling to remove scales, retained in a temperature range of [Ac₁transformation temperature+20° C.] to [Ac₁transformation temperature+120° C.] for 600 s to 21,600 s, and optionally cold rolled at a rolling reduction of less than 30% to obtain a cold-rolled sheet. Further, the hot-rolled sheet as annealed after the hot rolling or the cold-rolled sheet is retained in a temperature range of [Ac₁transformation temperature+10° C.] to [Ac₁transformation temperature+100° C.] for 20 s to 900 s, and subsequently cooled.

Through this process, the hot-rolled sheet or the cold-rolled sheet has a microstructure that contains, in area ratio, 20% or more and 65% or less of polygonal ferrite, 8% or more of non-recrystallized ferrite, and 5% or more and 25% or less of martensite, and, in volume fraction, 8% or more of retained austenite, where the average aspect ratio of crystal grains of each phase (polygonal ferrite, martensite, and retained austenite) is 2.0 or more and 15.0 or less, the polygonal ferrite has an average grain size of 6 μm or less, the martensite has an average grain size of 3 μm or less, and the retained austenite has an average grain size of 3 μm or less. Moreover, the microstructure of the hot-rolled sheet or the cold-rolled sheet can be controlled so that a value obtained by dividing a Mn content in the retained austenite (in mass %) by a Mn content in the polygonal ferrite (in mass %) equals 2.0 or more, making it possible to obtain 8% or more of retained austenite stabilized with Mn.

This disclosure has been made based on these discoveries.

Specifically, the primary features of this disclosure are as described below.

1. A steel sheet comprising: a chemical composition containing (consisting of), in mass %, C: 0.030% or more and 0.250% or less, Si: 0.01% or more and 3.00% or less, Mn: 2.60% or more and 4.20% or less, P: 0.001% or more and 0.100% or less, S: 0.0200% or less, N: 0.0100% or less, and Ti: 0.005% or more and 0.200% or less, and optionally further containing, in mass %, at least one selected from the group consisting of Al: 0.01% or more and 2.00% or less, Nb: 0.005% or more and 0.200% or less, B: 0.0003% or more and 0.0050% or less, Ni: 0.005% or more and 1.000% or less, Cr: 0.005% or more and 1.000% or less, V: 0.005% or more and 0.500% or less, Mo: 0.005% or more and 1.000% or less, Cu: 0.005% or more and 1.000% or less, Sn: 0.002% or more and 0.200% or less, Sb: 0.002% or more and 0.200% or less, Ta: 0.001% or more and 0.010% or less, Ca: 0.0005% or more and 0.0050% or less, Mg: 0.0005% or more and 0.0050% or less, and REM: 0.0005% or more and 0.0050% or less, with the balance consisiting of Fe and inevitable impurities; and a steel microstructure that contains, in area ratio, 20% or more and 65% or less of polygonal ferrite, 8% or more of non-recrystallized ferrite, and 5% or more and 25% or less of martensite, and that contains, in volume fraction, 8% or more of retained austenite, where an average aspect ratio of crystal grains of each of the polygonal ferrite, the martensite, and the retained austenite is 2.0 or more and 15.0 or less, wherein the polygonal ferrite has an average grain size of 6 μm or less, the martensite has an average grain size of 3 μm or less, the retained austenite has an average grain size of 3 μm or less, and a value obtained by dividing a Mn content in the retained austenite in mass % by a Mn content in the polygonal ferrite in mass % equals 2.0 or more.

2. The steel sheet according to 1., wherein the retained austenite has a C content that satisfies the following formula in relation to the Mn content in the retained austenite:

0.09*[Mn]−0.026−0.150≤[C]≤0.09*[Mn]−0.026+0.150

where

[C] is the C content in the retained austenite in mass %, and

[Mn] is the Mn content in the retained austenite in mass %.

3. A coated steel sheet comprising: the steel sheet according to 1. or 2.; and one selected from a hot-dip galvanized layer, a galvannealed layer, a hot-dip aluminum-coated layer, and an electrogalvanized layer.

4. A method for manufacturing a steel sheet, the method comprising: heating a steel slab having the chemical composition according to 1.; hot rolling the steel slab with a finisher delivery temperature of 750° C. or higher and 1000° C. or lower to obtain a steel sheet; coiling the steel sheet at 300° C. or higher and 750° C. or lower; then subjecting the steel sheet to pickling to remove scales; retaining the steel sheet in a temperature range of [Ac₁transformation temperature+20° C.] to [Ac₁transformation temperature+120° C.] for 600 s to 21,600 s; optionally cold rolling the steel sheet at a rolling reduction of less than 30%; and then retaining the steel sheet in a temperature range of [Ac₁transformation temperature+10° C.] to [Ac₁transformation temperature+100° C.] for 20 s to 900 s and subsequently cooling the steel sheet, to manufacture the steel sheet according to 1. or 2.

5. The method according to 4., wherein a value obtained by dividing a volume fraction of the retained austenite after performing tensile working with an elongation value of 10% by a volume fraction of the retained austenite before the tensile working equals 0.3 or more.

6. The method according to 4., comprising after the cooling, either subjecting the steel sheet to one selected from hot-dip galvanizing treatment, hot-dip aluminum coating treatment, and electrogalvanizing treatment, or subjecting the steel sheet to hot-dip galvanizing treatment and then to alloying treatment at 450° C. or higher and 600° C. or lower, to manufacture the coated steel sheet according to 3.

Advantageous Effect

According to the disclosure, it becomes possible to provide a high-strength steel sheet with excellent formability and hole expansion formability and high yield ratio that exhibits TS of 590 MPa or more and YR of 68% or more. Steel sheets according to the disclosure are highly beneficial in industrial terms, because they can improve fuel efficiency when applied to, for example, automobile structural parts, by a reduction in the weight of automotive bodies.

BRIEF DESCRIPTION OF THE DRAWING

In the accompanying drawings:

FIG. 1 illustrates the relationship between the working ratio of tensile working and the volume fraction of retained austenite; and

FIG. 2 illustrates the relationship between the elongation of each steel sheet and the value obtained by dividing the volume fraction of retained austenite remaining in the steel sheet after subjection to tensile working with an elongation value of 10% by the volume fraction of retained austenite before the tensile working.

DETAILED DESCRIPTION

The following describes the present disclosure in detail.

First, the reasons for limiting the chemical composition of the steel to the aforementioned ranges in the present disclosure are explained. The % representations below indicating the chemical composition of the steel or steel slab are in mass % unless stated otherwise. The balance of the chemical composition of the steel or steel slab is Fe and inevitable impurities.

C: 0.030% or More and 0.250% or Less

C is an element necessary for causing a low-temperature transformation phase such as martensite to increase strength. C is also a useful element for increasing the stability of retained austenite and the ductility of steel. If the C content is less than 0.030%, it is difficult to ensure a desired area ratio of martensite, and desired strength is not obtained. It is also difficult to guarantee a sufficient volume fraction of retained austenite, and good ductility is not obtained. On the other hand, if C is excessively added to the steel beyond 0.250%, hard martensite excessively increases in area ratio, which causes more microvoids at grain boundaries of martensite and facilitates propagation of cracks during bend test and hole expansion test, leading to a reduction in bendability and stretch flangeability. If excessive C is added to steel, hardening of welds and the heat-affected zone (HAZ) becomes significant and the mechanical properties of the welds deteriorate, leading to a reduction in spot weldability, arc weldability, and the like. From these perspectives, the C content is 0.030% or more and 0.250% or less. The C content is preferably 0.080% or more. The C content is preferably 0.200% or less.

Si: 0.01% or More and 3.00% or Less

Si is an element that improves the strain hardenability of ferrite, and is thus a useful element for ensuring good ductility. If the Si content is below 0.01%, the addition effect is limited. Thus the lower limit is 0.01%. On the other hand, excessively adding Si beyond 3.00% not only embrittles the steel, but also causes red scales or the like to deteriorate surface characteristics. Therefore, the Si content is 0.01% or more and 3.00% or less. The Si content is preferably 0.20% or more. The Si content is preferably 2.00% or less.

Mn: 2.60% or More and 4.20% or Less

Mn is one of the very important elements for the disclosure. Mn is an element that stabilizes retained austenite, and is thus a useful element for ensuring good ductility. Mn can also increase the TS of the steel through solid solution strengthening. These effects can be obtained when the Mn content in the steel is 2.60% or more. On the other hand, excessively adding Mn beyond 4.20% results in a rise in cost. From these perspectives, the Mn content is 2.60% or more and 4.20% or less. The Mn content is preferably 3.00% or more. The Mn content is preferably 4.20% or less.

P: 0.001% or More and 0.100% or Less

P is an element that has a solid solution strengthening effect and can be added depending on the desired TS. P also facilitates ferrite transformation, and thus is also a useful element for forming a multi-phase structure in the steel sheet. To obtain this effect, the P content in the steel sheet needs to be 0.001 or more. However, if the P content exceeds 0.100%, weldability degrades and, when a galvanized layer is subjected to alloying treatment, the alloying rate decreases, impairing galvanizing quality. Therefore, the P content is 0.001% or more and 0.100% or less. The P content is preferably 0.005% or more. The P content is preferably 0.050% or less.

S: 0.0200% or Less

S segregates to grain boundaries, embrittles the steel during hot working, and forms sulfides to reduce the local deformability of the steel sheet. Therefore, the S content is 0.0200% or less, preferably 0.0100% or less, and more preferably 0.0050% or less. Under production constraints, however, the S content is preferably 0.0001% or more. Therefore, the S content is preferably 0.0001% or more and 0.0200% or less. The S content is more preferably 0.0001% or more. The S content is more preferably 0.0100% or less. The S content is further preferably 0.0001% or more. The S content is further preferably 0.0050% or less.

N: 0.0100% or Less

N is an element that deteriorates the anti-aging property of the steel. The deterioration in anti-aging property becomes more pronounced, particularly when the N content exceeds 0.0100%. Accordingly, smaller N contents are more preferable. However, under production constraints, the N content is preferably 0.0005% or more. Therefore, the N content is preferably 0.0005% or more and 0.0100% or less. The N content is more preferably 0.0010% or more. The N content is more preferably 0.0070% or less.

Ti: 0.005% or More and 0.200% or Less

Ti is one of the very important elements for the disclosure. Ti is useful for achieving strengthening by precipitation of the steel. Ti can also ensure a desired area ratio of non-recrystallized ferrite, and contributes to increasing the yield ratio of the steel sheet. Additionally, making use of relatively hard non-recrystallized ferrite, Ti can reduce the difference in hardness from a hard secondary phase (martensite or retained austenite), and also contributes to improving stretch flangeability. These effects can be obtained when the Ti content is 0.005% or more. On the other hand, if the Ti content in the steel exceeds 0.200%, hard martensite excessively increases in area ratio, which causes more microvoids at grain boundaries of martensite and facilitates propagation of cracks during bend test and hole expansion test, leading to a reduction in the bendability and stretch flangeability of the steel sheet. Therefore, the Ti content is 0.005% or more and 0.200% or less. The Ti content is preferably 0.010% or more. The Ti content is preferably 0.100% or less.

The basic components according to this disclosure have been described above. The balance other than the components described above is Fe and inevitable impurities. Additionally, the following elements may b e optionally contained as appropriate.

The chemical composition of the steel may further contain at least one selected from the group consisting of Al: 0.01% or more and 2.00% or less, Nb: 0.005% or more and 0.200% or less, B: 0.0003% or more and 0.0050% or less, Ni: 0.005% or more and 1.000% or less, Cr: 0.005% or more and 1.000% or less, V: 0.005% or more and 0.500% or less, Mo: 0.005% or more and 1.000% or less, Cu: 0.005% or more and 1.000% or less, Sn: 0.002% or more and 0.200% or less, Sb: 0.002% or more and 0.200% or less, Ta: 0.001% or more and 0.010% or less, Ca: 0.0005% or more and 0.0050% or less, Mg: 0.0005% or more and 0.0050% or less, and REM: 0.0005% or more and 0.0050% or less.

Al is a useful element for increasing the area of a ferrite-austenite dual phase region and reducing annealing temperature dependency, i.e., increasing the stability of the steel sheet as a material. In addition, Al acts as a deoxidizer, and is also a useful element for maintaining the cleanliness of the steel. If the Al content is below 0.01%, however, the addition effect is limited. Thus the lower limit is 0.01%. On the other hand, excessively adding Al beyond 2.00% increases the risk of cracking occurring in a semi-finished product during continuous casting, and inhibits manufacturability. From these perspectives, the Al content is 0.01% or more and 2.00% or less. The Al content is preferably 0.20% or more. The Al content is preferably 1.20% or less.

Nb is useful for achieving strengthening by precipitation of the steel. The addition effect can be obtained when the content is 0.005% or more. Nb can also ensure a desired area ratio of non-recrystallized ferrite, as in the case of adding Ti, and contributes to increasing the yield ratio of the steel sheet. Additionally, making use of relatively hard non-recrystallized ferrite, Nb can reduce the difference in hardness from a hard secondary phase (martensite or retained austenite), and also contributes to improving stretch flangeability. On the other hand, if the Nb content in the steel exceeds 0.200%, hard martensite excessively increases in area ratio, which causes more microvoids at grain boundaries of martensite and facilitates propagation of cracks during bend test and hole expansion test. This leads to a reduction in the bendability and stretch flangeability of the steel sheet. This also increases cost. Therefore, when added to steel, the Nb content is 0.005% or more and 0.200% or less. The Nb content is preferably 0.010% or more. The Nb content is preferably 0.100% or less.

B may be added as necessary, since it has the effect of suppressing the generation and growth of ferrite from austenite grain boundaries and enables microstructure control according to the circumstances. The addition effect can be obtained when the B content is 0.0003% or more. If the B content exceeds 0.0050%, however, the formability of the steel sheet degrades. Therefore, when added to steel, the B content is 0.0003% or more and 0.0050% or less. The B content is preferably 0.0005% or more. The B content is preferably 0.0030% or less.

Ni is an element that stabilizes retained austenite, and is thus a useful element for ensuring good ductility, and that increases the TS of the steel through solid solution strengthening. The addition effect can be obtained when the Ni content is 0.005% or more. On the other hand, if the Ni content in the steel exceeds 1.000%, hard martensite excessively increases in area ratio, which causes more microvoids at grain boundaries of martensite and facilitates propagation of cracks during bend test and hole expansion test. This leads to a reduction in the bendability and stretch flangeability of the steel sheet. This also increases cost. Therefore, when added to steel, the Ni content is 0.005% or more and 1.000% or less.

Cr, V, and Mo are elements that may be added as necessary, since they have the effect of improving the balance between TS and ductility. The addition effect can be obtained when the Cr content is 0.005% or more, the V content is 0.005% or more, and/or the Mo content is 0.005% or more. However, if the Cr content exceeds 1.000%, the V content exceeds 0.500%, and/or the Mo content exceeds 1.000%, hard martensite excessively increases in area ratio, which causes more microvoids at grain boundaries of martensite and facilitates propagation of cracks during bend test and hole expansion test. This leads to a reduction in the bendability and stretch flangeability of the steel sheet, and also causes a rise in cost. Therefore, when added to steel, the Cr content is 0.005% or more and 1.000% or less, the V content is 0.005% or more and 0.500% or less, and/or the Mo content is 0.005% or more and 1.000% or less.

Cu is a useful element for strengthening of steel and may be added for strengthening of steel, as long as the content is within the range disclosed herein. The addition effect can be obtained when the Cu content is 0.005% or more. On the other hand, if the Cu content in the steel exceeds 1.000%, hard martensite excessively increases in area ratio, which causes more microvoids at grain boundaries of martensite and facilitates propagation of cracks during bend test and hole expansion test. This leads to a reduction in the bendability and stretch flangeability of the steel sheet. Therefore, when added to steel, the Cu content is 0.005% or more and 1.000% or less.

Sn and Sb are elements that may be added as necessary from the perspective of suppressing decarbonization of a region extending from the surface layer of the steel sheet to a depth of about several tens of micrometers, which results from nitriding and/or oxidation of the steel sheet surface. Suppressing nitriding and/or oxidation in this way is useful for preventing a reduction in the area ratio of martensite in the steel sheet surface, and for ensuring the TS and stability of the steel sheet as a material. However, excessively adding Sn or Sb beyond 0.200% reduces toughness. Therefore, when Sn and/or Sb is added to steel, the content of each added element is 0.002% or more and 0.200% or less.

Ta forms alloy carbides or alloy carbonitrides, and contributes to increasing the strength of the steel, as is the case with Ti and Nb. It is also believed that Ta has the effect of effectively suppressing coarsening of precipitates when partially dissolved in Nb carbides or Nb carbonitrides to form complex precipitates, such as (Nb, Ta) (C, N), and providing a stable contribution to increasing the strength of the steel sheet through strengthening by precipitation. Therefore, Ta is preferably added to the steel according to the disclosure. The addition effect of Ta can be obtained when the Ta content is 0.001% or more. Excessively adding Ta, however, fails to increase the addition effect, but instead results in a rise in alloying cost. Therefore, when added to steel, the Ta content is 0.001% or more and 0.010% or less.

Ca, Mg, and REM are useful elements for causing spheroidization of sulfides and mitigating the adverse effect of sulfides on hole expansion formability (stretch flangeability). To obtain this effect, it is necessary to add any of these elements to steel in an amount of 0.0005% or more. However, if the content of each added element exceeds 0.0050%, more inclusions occur, for example, and some defects such as surface defects and internal defects are caused in the steel sheet. Therefore, when Ca, Mg, and/or REM is added to steel, the content of each added element is 0.0005% or more and 0.0050% or less.

The following provides a description of the microstructure. Sufficient ductility of the steel sheet can be ensured by facilitating the formation of polygonal ferrite in the microstructure. This, however, causes decreases in tensile strength and yield strength. Besides, therse mechanical properties also vary depending on the area ratio of martensite, and the ductility is greatly affected by the amount of retained austenite. Hence, the mechanical properties of the high-strength steel sheet can be effectively obtained by controlling the amounts (area ratio, volume fraction) of these phases (microstructures). As a result of conducting studies from this perspective, we newly discovered that the area ratios of polygonal ferrite and non-recrystallized ferrite are controllable by the rolling reduction in cold rolling. We also found out that the area ratio of martensite and the volume fraction of retained austenite are mainly determined by the addition amount of Mn. We further found out that, by omitting cold rolling or by limiting the rolling reduction in cold rolling to 30% or less, not only the area ratio of polygonal ferrite is reduced (i.e. can be controlled to an appropriate range) (relative to the whole microstructure), but also the microstructure shape of the final product changes greatly, yielding a steel sheet having crystal grains with a high aspect ratio. The value of hole expansion formability X is thus improved. In detail, the microstructure of a steel sheet with high ductility and favorable hole expansion formability is as follows.

Area Ratio of Polygonal Ferrite: 20% or More and 65% or Less

According to the disclosure, the area ratio of polygonal ferrite needs to be 20% or more to ensure sufficient ductility. On the other hand, to guarantee a TS of 590 MPa or more, the area ratio of soft polygonal ferrite needs to be 65% or less. The area ratio of polygonal ferrite is preferably 30% or more. The area ratio of polygonal ferrite is preferably 55% or less. As used herein, “polygonal ferrite” refers to ferrite that is relatively soft and that has high ductility.

Area Ratio of Non-Recrystallized Ferrite: 8% or More

In this disclosure, it is very important to set the area ratio of non-recrystallized ferrite to be 8% or more. In this regard, non-recrystallized ferrite is useful for increasing the strength of the steel sheet. However, non-recrystallized ferrite may cause a significant decrease in the ductility of the steel sheet, and thus is normally reduced in a general process. In contrast, according to the present disclosure, by using polygonal ferrite and retained austenite to provide good ductility and intentionally utilizing relatively hard non-recrystallized ferrite, it is possible to provide the steel sheet with the intended TS, without having to form a large amount of martensite, such as exceeding 25% in area ratio.

Moreover, according to the present disclosure, interfaces between different phases, namely, between polygonal ferrite and martensite, are reduced, making it possible to increase the yield point (YP) and YR of the steel sheet.

To obtain these effects, the area ratio of non-recrystallized ferrite needs to be 8% or more, preferably 10% or more. As used herein, “non-recrystallized ferrite” refers to ferrite that contains strain in the grains with a crystal orientation difference of less than 15°, and that is harder than the above-described polygonal ferrite with high ductility.

In the disclosure, no upper limit is placed on the area ratio of non-recrystallized ferrite, yet a preferred upper limit is around 45%, considering the possibility of increased material anisotropy in the steel sheet surface.

Area Ratio of Martensite: 5% or More and 25% or Less

To achieve TS of 590 MPa or more, the area ratio of martensite needs to be 5% or more. On the other hand, to ensure good ductility, the area ratio of martensite needs to be limited to 25% or less.

According to the disclosure, the area ratios of ferrite (including polygonal ferrite and non-recrystallized ferrite) and martensite can be determined in the following way.

Specifically, a cross section of a steel sheet that is taken in the sheet thickness direction to be parallel to the rolling direction (which is an L-cross section) is polished, then etched with 3 vol.% nital, and ten locations are observed at 2000 times magnification under an SEM (scanning electron microscope), at a position of sheet thickness x 1/4 (which is the position at a depth of one-fourth of the sheet thickness from the steel sheet surface), to capture microstructure micrographs. The captured microstructure micrographs are used to calculate the area ratios of respective phases (ferrite and martensite) for the ten locations using Image-Pro manufactured by Media Cybernetics, the results are averaged, and each average is used as the area ratio of the corresponding phase. In the microstructure micrographs, polygonal ferrite and non-recrystallized ferrite appear as a gray structure (base steel structure), while martensite as a white structure.

According to the disclosure, the area ratios of polygonal ferrite and non-recrystallized ferrite can be determined in the following way. Specifically, low-angle grain boundaries in which the crystal orientation difference is from 2° to less than 15° and large-angle grain boundaries in which the crystal orientation difference is 15° or more are identified using EBSD (Electron Backscatter Diffraction). An IQ Map is then created, considering ferrite that contains low-angle grain boundaries in the grains as non-recrystallized ferrite. Then, low-angle grain boundaries and large-angle grain boundaries are extracted from the created IQ Map at ten locations, respectively, to determine the areas of low-angle grain boundaries and large-angle grain boundaries at the ten locations. Based on the results, the areas of polygonal ferrite and non-recrystallized ferrite are calculated to determine the area ratios of polygonal ferrite and non-recrystallized ferrite for the ten locations. By averaging the results, the above-described area ratios of polygonal ferrite and non-recrystallized ferrite are determined.

Volume Fraction of Retained Austenite: 8% or More

According to the disclosure, the volume fraction of retained austenite needs to be 8% or more, and is preferably 10% or more, to ensure sufficient ductility. According to the disclosure, no upper limit is placed on the area ratio of retained austenite, yet a preferred upper limit is around 40%, considering the risk of formation of increased amounts of unstable retained austenite resulting from insufficient concentration of C, Mn, and the like, which is less effective in improving ductility.

The volume fraction of retained austenite is calculated by determining the x-ray diffraction intensity of a plane of sheet thickness×¼ (which is the plane at a depth of one-fourth of the sheet thickness from the steel sheet surface), which is exposed by polishing the steel sheet surface to a depth of one-fourth of the sheet thickness. Using an incident x-ray beam of MoKa, the intensity ratio of the peak integrated intensity of the {111}, {200}, {220}, and {311} planes of retained austenite to the peak integrated intensity of the {110}, {200}, and {211} planes of ferrite is calculated for all of the twelve combinations, the results are averaged, and the average is used as the volume fraction of retained austenite.

Average Grain Size of Polygonal Ferrite: 6 μm or Less

Refinement of polygonal ferrite grains contributes to improving YP and TS. Thus, to ensure a high YP and a high YR as well as a desired TS, polygonal ferrite needs to have an average grain size of 6 μm or less, and preferably 5 μm or less.

According to the disclosure, no lower limit is placed on the average grain size of polygonal ferrite, yet, from an industrial perspective, a preferred lower limit is around 0.3 μm.

Average Grain Size of Martensite: 3 μm or Less

Refinement of martensite grains contributes to improving bendability and stretch flangeability (hole expansion formability). Thus, to ensure high bendability and high stretch flangeability (high hole expansion formability), the average grain size of martensite needs to be limited to 3 μm or less, and preferably to 2.5 μm or less.

According to the disclosure, no lower limit is placed on the average grain size of martensite, yet, from an industrial perspective, a preferred lower limit is around 0.1 μm.

Average Grain Size of Retained Austenite: 3 μm or Less

Refinement of retained austenite grains contributes to improving ductility, as well as bendability and stretch flangeability (hole expansion formability). Accordingly, to ensure good ductility, bendability, and stretch flangeability (hole expansion formability) of the steel sheet, the average grain size of retained austenite needs to be 3 μm or less, and preferably 2.5 μm or less. According to the disclosure, no lower limit is placed on the average grain size of retained austenite, yet, from an industrial perspective, a preferred lower limit is around 0.1 μm.

The average grain sizes of polygonal ferrite, martensite, and retained austenite are respectively determined by averaging the results from calculating equivalent circular diameters from the areas of polygonal ferrite grains, martensite grains, and retained austenite grains measured with Image-Pro as mentioned above. Polygonal ferrite, non-recrystallized ferrite, martensite, and retained austenite are separated using EBSD, and martensite and retained austenite are identified using an EBSD phase map. In this case, each of the above-described average grain sizes is determined from the measurements for grains with a grain size of 0.01 μm or more. The reason is that grains with a grain size of less than 0.01 μm have no effect on the disclosure.

Average Aspect Ratio of Crystal Grains of each of Polygonal ferrite, Martensite, and Retained Austenite: 2.0 or More and 15.0 or Less

In this disclosure, it is very important to set the average aspect ratio of crystal grains of each of polygonal ferrite, martensite, and retained austenite to 2.0 or more.

A lower aspect ratio of crystal grains indicates that, during retention in heat treatment after cold rolling (cold-rolled sheet annealing), ferrite and austenite recover and recrystallize and then undergo grain growth, resulting in the formation of crystal grains close to equiaxed grains. The ferrite formed here is soft. In the case where cold rolling is omitted or the rolling reduction in cold rolling is less than 30%, on the other hand, the amount of strain applied decreases, so that the formation of polygonal ferrite is suppressed and a microstructure mainly composed of crystal grains with a high aspect ratio results. Such a microstructure composed of crystal grains with a high aspect ratio is hard because it contains a large amount of strain or has parts where the distance between grain boundaries is short, as compared with the above-mentioned microstructure. Therefore, not only the TS is improved, but also the difference in hardness from hard phases such as retained austenite and martensite decreases, and the hole expansion formability is improved without loss of ductility. If the aspect ratio is more than 15.0, the TS increases extremely, and favorable ductility cannot be achieved.

Thus, the average aspect ratio of crystal grains of each of polygonal ferrite, martensite, and retained austenite is limited to 2.0 or more and 15.0 or less. In terms of ductility, the average aspect ratio is more preferably 2.2 or more, and more preferably 2.4 or more.

The aspect ratio of a crystal grain mentioned here is a value obtained by dividing the major axis length of the crystal grain by the minor axis length of the crystal grain. The average aspect ratio of each type of crystal grains can be calculated as follows.

For each of polygonal ferrite grains, martensite grains, and retained austenite grains, the major axis length and minor axis length of each of 30 crystal grains are calculated using the above-mentioned Image-Pro, the major axis length is divided by the minor axis length, and the division results are averaged.

A Value Obtained by Dividing the Mn Content in the Retained Austenite (in mass %) by the Mn Content in the Polygonal Ferrite (in mass %): 2.0 or More

In this disclosure, it is very important that the value obtained by dividing the Mn content in the retained austenite (in mass %) by the Mn content in the polygonal ferrite (in mass %) equals 2.0 or more. The reason is that better ductility requires a larger amount of stable retained austenite with concentrated Mn.

According to the disclosure, no upper limit is placed on the value obtained by dividing the Mn content in the retained austenite (in mass %) by the Mn content in the polygonal ferrite (in mass %), yet a preferred upper limit is around 16.0 from the perspective of ensuring stretch flangeability.

The Mn content in the retained austenite (in mass %) and the Mn content in the polygonal ferrite (in mass %) can be determined in the following way.

Specifically, an EPMA (Electron Probe Micro Analyzer) is used to quantify the distribution of Mn in each phase in a cross section along the rolling direction at a position of sheet thickness×¼. Then, 30 retained austenite grains and 30 ferrite grains are analyzed to determine Mn contents, the results are averaged, and each average is used as the Mn content in the corresponding phase.

In addition to the above-described polygonal ferrite, martensite, and so on, the microstructure according to the disclosure may further include carbides ordinarily found in steel sheets, such as granular ferrite, acicular ferrite, bainitic ferrite, tempered martensite, pearlite, and cementite (excluding cementite in pearlite). Any of these structures may be included as long as the area ratio is 10% or less, without impairing the effect of the disclosure.

We made further investigations on the microstructures of steel sheets upon performing press forming and working.

As a result, it was discovered that there are two types of retained austenite: one transforms to martensite immediately upon the subjection of the steel sheet to press forming or working, while the other persists until the working ratio becomes high enough to cause the retained austenite to eventually transform to martensite, bringing about a TRIP phenomenon (transformation induced plasticity phenomenon). It was also revealed that good elongation can be obtained in a particularly effective way when a large amount of retained austenite transforms to martensite after the working ratio becomes high enough.

Specifically, as a result of collecting samples with good and poor elongation and measuring the quantity of retained austenite by varying the degree of tensile working from 0% to 20%, the working ratio and the quantity of retained austenite showed a tendency as illustrated in FIG. 1. As used herein, “the working ratio” refers to the elongation ratio that is determined from a tensile test performed on a JIS No. 5 test piece sampled from a steel sheet with the tensile direction being perpendicular to the rolling direction of the steel sheet.

It can be seen from FIG. 1 that the samples with good elongation each showed a gentle decrease in the quantity of retained austenite as the working ratio increased.

Accordingly, we further measured the quantity of retained austenite in each sample with TS of 780 MPa after subjection to tensile working with an elongation value of 10%, and examined the effect of the ratio of the quantity of retained austenite after the tensile working to the quantity before the tensile working on the total elongation of the steel sheet. The results are shown in FIG. 2.

It can be seen from FIG. 2 that elongation is good if the value obtained by dividing the volume fraction of retained austenite remaining in a steel after subjection to tensile working with an elongation value of 10% by the volume fraction of retained austenite before the tensile working equals 0.3 or more, but otherwise elongation is poor.

Therefore, it is preferable in the disclosure that the value obtained by dividing the volume fraction of retained austenite remaining in a steel after subjection to tensile working with an elongation value of 10% by the volume fraction of retained austenite before the tensile working equals 0.3 or more. The reason is that this set up may ensure the transformation of sufficient retained austenite to martensite after the working ratio becomes high enough.

The above-described TRIP phenomenon requires retained austenite to be present before performing press forming or working. To cause retained austenite to be present before performing press forming or working, the Ms point (martensite transformation start temperature) which depends on the elements contained in the steel microstructure needs to be as low as approximately 15° C. or lower.

Specifically, in the tensile working with an elongation value of 10% according to the disclosure, a tensile test is performed on a JIS No. 5 test piece sampled from a steel sheet with the tensile direction being perpendicular to the rolling direction of the steel sheet, and the test is interrupted when the elongation ratio reaches 10%, thus applying tensile working with an elongation value of 10% to the test piece.

The volume fraction of retained austenite can be determined in the above-described way.

Upon a detailed study of samples satisfying the above conditions, we discovered that a TRIP phenomenon providing high strain hardenability occurs upon working and even better elongation can be achieved if the C content and the Mn content in the retained austenite satisfy the following relation:

0.09*[Mn]−0.026−0.150≤[C]≤0.09*[Mn]−0.026+0.150

where

[C content] is the C content in the retained austenite in mass %, and

[Mn content] is the Mn content in the retained austenite in mass %.

When the above requirements are met, it is possible to cause a TRIP phenomenon, which is a key factor of improving ductility, to occur intermittently up until the final stage of working performed on the steel sheet, guaranteeing the generation of so-called stable retained austenite.

The C content in the retained austenite (in mass %) can be determined in the following way.

Specifically, an EPMA is used to quantify the distribution of C in each phase in a cross section along the rolling direction at a position of sheet thickness×¼. Then, 30 retained austenite grains are analyzed to determine C contents, the results are averaged, and the average is used as the C content.

Note that the Mn content in the retained austenite (in mass %) can be determined in the same way as the C content in the retained austenite.

The following describes the production conditions.

Steel Slab Heating Temperature: 1100° C. or Higher and 1300° C. or Lower

Precipitates that are present at the time of heating of a steel slab (hereinafter, also referred to simply as a “slab”) will remain as coarse precipitates in the resulting steel sheet, making no contribution to strength. Thus, remelting of any Ti- and Nb-based precipitates formed during casting is required.

In this respect, if a steel slab is heated at a temperature below 1100° C., it is difficult to cause sufficient dissolution of carbides, leading to problems such as an increased risk of trouble during the hot rolling resulting from increased rolling load. Therefore, the steel slab heating temperature is preferably 1100° C. or higher.

In addition, from the perspective of obtaining a smooth steel sheet surface by scaling-off defects in the surface layer of the slab, such as blow hole generation, segregation, and the like, and reducing cracks and irregularities over the steel sheet surface, the steel slab heating temperature is preferably 1100° C. or higher.

If the steel slab heating temperature exceeds 1300° C., however, scale loss increases as oxidation progresses. Therefore, the steel slab heating temperature is preferably 1300° C. or lower. For this reason, the steel slab heating temperature is preferably 1100° C. or higher and 1300° C. or lower. The steel slab heating temperature is further preferably 1150° C. or higher. The steel slab heating temperature is further preferably 1250° C. or lower.

A steel slab is preferably made with continuous casting to prevent macro segregation, yet may be produced with other methods such as ingot casting or thin slab casting. The steel slab thus produced may be cooled to room temperature and then heated again according to a conventional process. Moreover, energy-saving processes are applicable without any problem, such as hot direct rolling or direct rolling in which either a warm steel slab without being fully cooled to room temperature is charged into a heating furnace, or a steel slab is hot rolled immediately after being subjected to heat retaining for a short period. A steel slab is subjected to rough rolling under normal conditions and formed into a sheet bar. When the heating temperature is low, it is preferable to additionally heat the sheet bar using a bar heater or the like prior to finish rolling, from the viewpoint of preventing troubles during the hot rolling.

Finisher delivery temperature in hot rolling: 750° C. or higher and 1000° C. or lower

The heated steel slab is hot rolled through rough rolling and finish rolling to form a hot-rolled sheet. At this point, when the finisher delivery temperature exceeds 1000° C., the amount of oxides (scales) generated suddenly increases and the interface between the steel substrate and oxides becomes rough, which tends to lower the surface quality of the steel sheet after subjection to pickling and cold rolling. In addition, any hot rolling scales persisting after pickling adversely affect the ductility and stretch flangeability of the steel sheet. Moreover, grain size is excessively coarsened, causing surface deterioration in a pressed part during working. On the other hand, if the finisher delivery temperature is below 750° C., rolling load increases and rolling is performed more often with austenite being in a non-recrystallized state. As a result, an abnormal texture develops in the steel sheet, and the final product has a significant planar anisotropy such that the material properties not only become less uniform (the stability as a material decreases), but the ductility itself also deteriorates. Besides, if the finisher delivery temperature in the hot rolling is lower than 750° C. or higher than 1000° C., a microstructure having 8% or more of retained austenite in volume fraction cannot be obtained.

Therefore, the finisher delivery temperature in the hot rolling needs to be 750° C. or higher and 1000° C. or lower. The finisher delivery temperature is preferably 800° C. or higher. The finisher delivery temperature is preferably 950° C. or lower.

Average Coiling Temperature after Hot Rolling: 300° C. or Higher and 750° C. or Lower

When the average coiling temperature after the hot rolling is above 750° C., the grain size of ferrite in the microstructure of the hot-rolled sheet increases, making it difficult to ensure a desired strength of the final-annealed sheet. Besides, when the average coiling temperature after the hot rolling is above 750° C., a microstructure with an average grain size of polygonal ferrite of 6 μm or less, an average grain size of martensite of 3 μm or less, and an average grain size of retained austenite of 3 μm or less cannot be obtained. On the other hand, when the average coiling temperature after the hot rolling is below 300° C., there is an increase in the strength of the hot-rolled sheet and in the rolling load for cold rolling, and the steel sheet suffers malformation. As a result, productivity decreases. Therefore, the average coiling temperature after the hot rolling needs to be 300° C. or higher and 750° C. or lower. The average coiling temperature is preferably 400° C. or higher. The average coiling temperature is preferably 650° C. or lower.

According to the disclosure, finish rolling may be performed continuously by joining rough-rolled sheets during the hot rolling. Rough-rolled sheets may be coiled on a temporary basis. At least part of finish rolling may be conducted as lubrication rolling to reduce the rolling load during the hot rolling. Conducting lubrication rolling in such a manner is effective from the perspective of making the shape and material properties of the steel sheet uniform. In lubrication rolling, the coefficient of friction is preferably 0.10 or more. The coefficient of friction is preferably 0.25 or less.

The hot-rolled sheet thus produced is subjected to pickling. Pickling enables removal of oxides from the steel sheet surface, and is thus important to ensure that the high-strength steel sheet as the final product has good chemical convertibility and sufficient coating quality. The pickling may be performed in one or more batches.

Hot Band Annealing (First Heat Treatment): to Retain in a Temperature Range of [Ac₁Transformation Temperature+20° C.] to [Ac₁Transformation Temperature+120° C.] for 600 s to 21,600 s

In this disclosure, it is very important to retain the steel sheet in a temperature range of [Ac₁transformation temperature+20° C.] to [Ac₁transformation temperature+120° C.] for 600 s to 21,600 s.

If the hot band annealing is performed at an annealing temperature below [Ac₁transformation temperature+20° C.] or above [Ac₁transformation temperature+120° C], or if the holding time is shorter than 600 s, concentration of Mn in austenite does not proceed in either case, making it difficult to ensure a sufficient volume fraction of retained austenite after the final annealing. As a result, ductility decreases. Besides, a microstructure in which the value obtained by dividing the Mn content in retained austenite (in mass %) by the Mn content in polygonal ferrite (in mass %) equals 2.0 or more cannot be obtained. On the other hand, if the steel sheet is retained for more than 21,600 s, concentration of Mn in austenite reaches a plateau, and becomes less effective in improving ductility after the final annealing, resulting in a rise in costs.

Therefore, in the hot band annealing (first heat treatment) according to the disclosure, the steel sheet is retained in a temperature range of [Ac₁transformation temperature+20° C.] to [Ac₁transformation temperature+120° C.] for 600 s to 21,600 s.

The above-described heat treatment process may be continuous annealing or batch annealing. After the above-described heat treatment, the steel sheet is cooled to room temperature. The cooling process and cooling rate are not particularly limited, however, and any type of cooling may be performed, including furnace cooling and air cooling in batch annealing and gas jet cooling, mist cooling, and water cooling in continuous annealing. The pickling may be performed according to a conventional process.

Annealing (Second Heat Treatment): to Retain in a Temperature Range of [Ac₁Transformation Temperature+10° C.] to [Ac₁Transformation Temperature+100° C.] for 20 s to 900 s

In this disclosure, it is very important to retain the steel sheet in a temperature range of [Ac₁transformation temperature+10° C.] to [Ac₁transformation temperature+100° C.] for 20 s to 900 s. When the annealing temperature is below [Ac₁transformation temperature+10° C.] or above [Ac₁transformation temperature+100° C], or if the holding time is shorter than 20 s, concentration of Mn in austenite does not proceed in either case, making it difficult to ensure a sufficient volume fraction of retained austenite. As a result, ductility decreases. Besides, a microstructure in which the value obtained by dividing the Mn content in retained austenite (in mass %) by the Mn content in polygonal ferrite (in mass %) equals 2.0 or more cannot be obtained. On the other hand, if the steel sheet is retained for more than 900 s, the area ratio of non-crystallized ferrite decreases and the interfaces between different phases, namely, between ferrite and hard secondary phases (martensite and retained austenite), are reduced, leading to a reduction in both YP and YR. Besides, a microstructure with an average grain size of martensite of 3μm or less and an average grain size of retained austenite of 3 μm or less cannot be obtained.

Rolling Reduction in Cold Rolling: Less than 30%

Cold rolling may be performed after the hot band annealing and before the annealing (second heat treatment). In this case, the rolling reduction needs to be less than 30%. By omitting the cold rolling or performing the cold rolling with a rolling reduction of less than 30%, polygonal ferrite which forms by recrystallization after the heat treatment does not form and a microstructure elongated in the rolling direction remains, and eventually polygonal ferrite, retained austenite, and martensite with a high aspect ratio are obtained. Thus, not only the strength-ductility balance is improved, but also the stretch flangeability (hole expansion formability) is improved. If the rolling reduction is 30% or more, a microstructure having 20% or more and 65% or less of polygonal ferrite in area ratio and a microstructure having an average aspect ratio of crystal grains of each of polygonal ferrite, martensite, and retained austenite of 2.0 or more and 15.0 or less cannot be obtained.

Hot-Dip Galvanizing Treatment

In hot-dip galvanizing treatment according to the disclosure, the steel sheet subjected to the above-described annealing (second heat treatment) is dipped in a galvanizing bath at 440° C. or higher and 500° C. or lower for hot-dip galvanizing. Subsequently, the coating weight on the steel sheet surface is adjusted using gas wiping or the like. Preferably, the hot-dip galvanizing is performed using a galvanizing bath containing 0.10 mass % or more and 0.22 mass % or less of Al.

Moreover, when a hot-dip galvanized layer is subjected to alloying treatment, the alloying treatment may be performed in a temperature range of 450° C. to 600° C. after the above-described hot-dip galvanizing treatment. If the alloying treatment is performed at a temperature above 600° C., untransformed austenite transforms to pearlite, where a desired volume fraction of retained austenite cannot be ensured and ductility degrades. On the other hand, if the alloying treatment is performed at a temperature below 450° C., the alloying process does not proceed, making it difficult to form an alloy layer.

Therefore, when the galvanized layer is subjected to alloying treatment, the alloying treatment is performed in a temperature range of 450° C. to 600° C.

Although other manufacturing conditions are not particularly limited, the series of processes including the annealing, hot-dip galvanizing, and alloying treatment described above may preferably be performed in a continuous galvanizing line (CGL), which is a hot-dip galvanizing line, from the perspective of productivity.

When hot-dip aluminum coating treatment is performed, the steel sheet subjected to the above-described annealing treatment is dipped in an aluminum molten bath at 660° C. to 730° C. for hot-dip aluminum coating treatment. Subsequently, the coating weight is adjusted using gas wiping or the like. If the steel sheet has a composition such that the temperature of the aluminum molten bath falls within the temperature range of [Ac₁transformation temperature+10° C.] to [Ac₁transformation temperature+100° C], the steel sheet is preferably subjected to hot-dip aluminum coating treatment because finer and more stable retained austenite can be formed, and therefore further improvement in ductility can be achieved.

Electrogalvanizing treatment

According to the disclosure, electrogalvanizing treatment may also be performed on the steel sheet after the heat treatment. No particular limitations are placed on the electrogalvanizing treatment conditions, yet the electrogalvanizing treatment conditions are preferably set so that the plated layer has a thickness of 5 μm to 15 μm.

According to the disclosure, the above-described steel sheet, hot-dip galvanized steel sheet, hot-dip aluminum-coated steel sheet, and electrogalvanized steel sheet may be subjected to skin pass rolling for the purposes of straightening, adjustment of roughness on the sheet surface, and the like. The skin pass rolling is preferably performed at a rolling reduction of 0.1% or more. The skin pass rolling is preferably performed at a rolling reduction of 2.0% or less.

When the rolling reduction is less than 0.1%, the skin pass rolling becomes less effective and more difficult to control. Thus, a preferable range for the rolling reduction has a lower limit of 0.1%. On the other hand, when the skin pass rolling is performed at a rolling reduction above 2.0%, the productivity of the steel sheet decreases significantly. Thus, the preferable range for the rolling reduction has an upper limit of 2.0%.

The skin pass rolling may be performed on-line or off-line. Skin pass may be performed in one or more batches to achieve a target rolling reduction.

Moreover, the steel sheet, the hot-dip galvanized steel sheet, the hot-dip aluminum-coated steel sheet, and the electrogalvanized steel sheet according to the disclosure may be subjected to a variety of coating treatment options, such as those using coating of resin, fats and oils, and the like.

EXAMPLES

Steels having the chemical compositions as presented in Table 1, with the balance consisting of Fe and inevitable impurities, were prepared by steelmaking in a converter, and formed into slabs through continuous casting. The slabs thus obtained were formed into a variety of steel sheets, as described below, by varying the conditions as listed in Table 2.

After being hot rolled, each steel sheet was annealed in a temperature range of [Ac₁transformation temperature+20° C.] to [Ac₁transformation temperature+120° C]. After being cold rolled (or without cold rolling), each steel sheet was annealed in a temperature range of [Ac₁transformation temperature+10° C.] to [Ac₁transformation temperature+100° C]. Consequently, a cold-rolled steel sheet (CR) was obtained, and subjected to coating treatment to form a hot-dip galvanized steel sheet (GI), a galvannealed steel sheet (GA), a hot-dip aluminum-coated steel sheet (Al), an electrogalvanized steel sheet (EG), or the like.

Used as hot-dip galvanizing baths were a zinc bath containing 0.19 mass % of Al for hot-dip galvanized steel sheets (GI) and a zinc bath containing 0.14 mass % of Al for galvannealed steel sheets (GA). In either case, the bath temperature was 465° C. and the coating weight per side was 45 g/m²(in the case of both-sided coating). For GA, the Fe concentration in the coating layer was adjusted to be 9 mass % or more and 12 mass % or less. The bath temperature of the hot-dip aluminum molten bath for hot-dip aluminum-coated steel sheets was set at 700° C.

For each of the steel sheets thus obtained, the cross-sectional microstructure, tensile property, hole expansion formability, bendability, and the like were investigated. The results are listed in Tables 3 to 5.

The Ac₁transformation temperature was calculated by:

[Ac₁transformation temperature (° C.)]=751−16*(% C)+11*(% Si)−28*(% Mn)−5.5*(% Cu)−16*(% Ni)+13*(% Cr)+3.4*(% Mo)

where (% C), (% Si), (% Mn), (% Ni), (% Cu), (% Cr), and (% Mo) each represent the content in steel (in mass %) of the element in the parentheses.

Tensile test was performed in accordance with JIS Z 2241 (2011) to measure YP, YR, TS, and EL using JIS No. 5 test pieces, each of which was sampled in a manner that the tensile direction was perpendicular to the rolling direction of the steel sheet. Note that YR is YP divided by TS, expressed as a percentage. In this case, the results were determined to be good when YR 68% and when TS * EL≥24,000 MPa·%. Also, EL was determined to be good when EL≥34% for TS 590 MPa grade, EL≥30% for TS 780 MPa grade, and EL≥24% for TS 980 MPa grade. In this case, a steel sheet of TS 590 MPa grade refers to a steel sheet with TS of 590 MPa or more and less than 780 MPa, a steel sheet of TS 780 MPa grade refers to a steel sheet with TS of 780 MPa or more and less than 980 MPa, and a steel sheet of TS 980 MPa grade refers to a steel sheet with TS of 980 MPa or more and less than 1180 MPa.

Bend test was performed according to the V-block method specified in JIS Z 2248 (1996). Each steel sheet was visually observed under a stereoscopic microscope for cracks on the outside of the bent portion, and the minimum bending radius without cracks was used as the limit bending radius R. In this case, the bendability of the steel sheet was determined to be good if the following condition was satisfied: limit bending radius R at 90° V-bending/t≤1.5 (where t is the thickness of the steel sheet).

Hole expansion test was performed in accordance with JIS Z 2256 (2010). Each of the steel sheets obtained was cut to a size of 100 mm * 100 mm, and a hole of 10 mm in diameter was drilled through each sample with clearance 12%±1%. Then, each steel sheet was clamped into a die having an inner diameter of 75 mm with a blank holding force of 9 tons (88.26 kN). In this state, a conical punch of 60° was pushed into the hole, and the hole diameter at the crack initiation limit was measured. Then, to evaluate hole expansion formability, the maximum hole expansion ratio (%) was calculated by:

Maximum hole expansion ratio λ(%)={(D_f-D₀)/D₀}*100

where D_fis a hole diameter at the time of occurrence of cracking (mm) and D₀is an initial hole diameter (mm).

In this case, the maximum hole expansion ratio was determined to be good when λ≥34% for TS 590 MPa grade, λ≥30% for TS 780 MPa grade, and λ≥25% for TS 980 MPa grade.

The sheet passage ability during hot rolling was determined to be low when it was considered that the risk of troubles, such as malformation during hot rolling due to increased rolling load, would increase because, for example, the hot-rolling finisher delivery temperature was low and rolling would be performed more often with austenite being in a non-crystallized state, or rolling would be performed in an austenite-ferrite dual phase region. The sheet passage ability during cold rolling was determined to be low when it was considered that the risk of troubles, such as malformation during cold rolling due to increased rolling load, would increase because, for example, the coiling temperature during hot rolling was low and the hot-rolled sheet had a steel microstructure in which low-temperature transformation phases, such as bainite and martensite, were dominantly present.

The surface characteristics of each final-annealed sheet were determined to be poor when defects such as blow hole generation and segregation on the surface layer of the slab could not be scaled-off, cracks and irregularities on the steel sheet surface increased, and a smooth steel sheet surface could not be obtained. The surface characteristics of each final-annealed sheet were also determined to be poor when the amount of oxides (scales) generated suddenly increased, interfaces between the steel substrate and oxides were roughened, and the surface quality after pickling and cold rolling degraded, or when hot-rolling scales persisted at least in part after pickling.

In this case, productivity was evaluated according to the lead time costs, including: (1) malformation of a hot-rolled sheet occurred; (2) a hot-rolled sheet requires straightening before proceeding to the subsequent steps; and (3) a prolonged holding time during the annealing treatment. The productivity was determined to be “high” when none of (1) to (3) applied and “low” when any of (1) to (3) applied.

Tensile working was performed in accordance with JIS Z 2241 (2011) using JIS No. 5 test pieces, each of which was sampled in a manner that the tensile direction was perpendicular to the rolling direction of the steel sheet. A value was obtained by dividing the volume fraction of retained austenite remaining in each steel sheet after subjection to tensile working with an elongation value of 10% by the volume fraction of retained austenite before the working (10% application). The volume fraction of retained austenite was measured in accordance with the above procedure.

The measurement results are also listed in Table 4.

The C content in the retained austenite (in mass %) and the Mn content in the retained austenite (in mass %) were measured in accordance with the above procedure.

The measurement results are also listed in Table 4.

TABLE 1

Chemical composition (mass %)

Steel sample ID
C
Si
Mn
P
S
N
Ti
Al
Nb
B
Ni
Cr
V
Mo

A
0.111
0.34
3.55
0.023
0.0022
0.0037
0.035
—
—
—
—
—
—
—

B
0.156
0.65
3.91
0.028
0.0019
0.0035
0.038
—
—
—
—
—
—
—

C
0.170
1.24
4.11
0.024
0.0023
0.0033
0.035
—
—
—
—
—
—
—

D
0.070
1.25
3.51
0.027
0.0020
0.0031
0.033
—
—
—
—
—
—
—

E
0.155
0.80
3.78
0.031
0.0019
0.0035
0.033
—
—
—
—
—
—
—

F
0.141
0.05
3.80
0.021
0.0025
0.0032
0.015
—
—
—
—
—
—
—

G
0.198
0.87
3.78
0.025
0.0020
0.0041
0.022
—
—
—
—
—
—
—

H
0.166
0.74
2.87
0.025
0.0020
0.0034
0.035
—
—
—
—
—
—
—

I
0.160
0.52
3.91
0.028
0.0025
0.0031
0.041
—
—
—
—
—
—
—

IA
0.030
0.42
3.55
0.027
0.0021
0.0031
0.041
—
—
—
—
—
—
—

IB
0.152
3.00
3.87
0.028
0.0020
0.0032
0.042
—
—
—
—
—
—
—

IC
0.115
0.52
2.60
0.021
0.0021
0.0035
0.035
—
—
—
—
—
—
—

ID
0.156
0.51
2.99
0.001
0.0019
0.0034
0.035
—
—
—
—
—
—
—

IE
0.151
0.34
3.01
0.100
0.0021
0.0029
0.036
—
—
—
—
—
—
—

IF
0.152
0.36
3.15
0.031
0.0001
0.0035
0.038
—
—
—
—
—
—
—

IG
0.118
0.51
3.00
0.034
0.0200
0.0031
0.039
—
—
—
—
—
—
—

IH
0.124
0.45
3.25
0.025
0.0022
0.0005
0.041
—
—
—
—
—
—
—

II
0.147
0.48
3.45
0.031
0.0023
0.0100
0.041
—
—
—
—
—
—
—

IJ
0.142
0.35
3.69
0.028
0.0018
0.0031
0.005
—
—
—
—
—
—
—

IK
0.145
0.41
3.57
0.029
0.0025
0.0032
0.200
—
—
—
—
—
—
—

IL
0.148

4.22

3.87
0.031
0.0025
0.0035
0.042
—
—
—
—
—
—
—

IM
0.115
0.55
3.45
0.031
0.0019
0.0034

0.210

—
—
—
—
—
—
—

J

0.010

0.52
3.21
0.031
0.0021
0.0031
0.039
—
—
—
—
—
—
—

K
0.199

4.51

2.51
0.028
0.0025
0.0038
0.024
—
—
—
—
—
—
—

L
0.186
1.01

2.25

0.025
0.0025
0.0034
0.025
—
—
—
—
—
—
—

M
0.181
0.78
3.80
0.022
0.0021
0.0038

0.001

—
—
—
—
—
—
—

N
0.205
0.89
3.51
0.024
0.0029
0.0038
0.033
0.45
—
—
—
—
—
—

O
0.200
1.02
3.78
0.028
0.0025
0.0034
0.033
—
0.042
—
—
—
—
—

P
0.191
0.83
3.54
0.027
0.0024
0.0041
0.035
—
—
0.0015
—
—
—
—

Q
0.210
1.01
3.57
0.029
0.0023
0.0032
0.021
—
—
—
0.312
—
—
—

R
0.212
0.55
4.11
0.029
0.0022
0.0031
0.025
—
—
—
—
0.355
—
—

S
0.225
0.78
3.76
0.031
0.0023
0.0032
0.023
—
—
—
—
—
0.035
—

T
0.201
0.98
3.29
0.031
0.0022
0.0041
0.035
—
—
—
—
—
—
0.329

U
0.202
1.32
3.12
0.025
0.0025
0.0033
0.041
—
—
—
—
—
—
—

V
0.189
1.02
3.55
0.026
0.0029
0.0034
0.045
—
—
—
—
—
—
—

W
0.190
0.88
3.45
0.025
0.0025
0.0035
0.033
—
—
—
—
—
—
—

X
0.199
0.78
3.52
0.026
0.0025
0.0033
0.035
—
0.047
—
—
—
—
—

Y
0.208
0.51
3.23
0.029
0.0027
0.0041
0.036
—
0.032
—
—
—
—
—

Z
0.204
0.29
3.65
0.027
0.0019
0.0031
0.034
—
0.038
—
—
—
—
—

AA
0.199
1.01
3.87
0.025
0.0025
0.0037
0.037
—
—
—
—
—
—
—

AB
0.210
1.28
4.02
0.029
0.0029
0.0041
0.033
—
—
—
—
—
—
—

AC
0.199
1.11
4.09
0.031
0.0021
0.0035
0.033
—
—
—
—
—
—
—

AD
0.188
0.81
3.54
0.028
0.0020
0.0039
0.026
—
—
—
—
—
—
—

Ac₁transformation

Chemical composition (mass %)
temperature

Steel sample ID
Cu
Sn
Sb
Ta
Ca
Mg
REM
(° C.)
Remarks

A
—
—
—
—
—
—
—
654
Conforming steel

B
—
—
—
—
—
—
—
646
Conforming steel

C
—
—
—
—
—
—
—
647
Conforming steel

D
—
—
—
—
—
—
—
665
Conforming steel

E
—
—
—
—
—
—
—
651
Conforming steel

F
—
—
—
—
—
—
—
643
Conforming steel

G
—
—
—
—
—
—
—
652
Conforming steel

H
—
—
—
—
—
—
—
676
Conforming steel

I
—
—
—
—
—
—
—
645
Conforming steel

IA
—
—
—
—
—
—
—
656
Conforming steel

IB
—
—
—
—
—
—
—
673
Conforming steel

IC
—
—
—
—
—
—
—
670
Conforming steel

ID
—
—
—
—
—
—
—
670
Conforming steel

IE
—
—
—
—
—
—
—
668
Conforming steel

IF
—
—
—
—
—
—
—
664
Conforming steel

IG
—
—
—
—
—
—
—
671
Conforming steel

IH
—
—
—
—
—
—
—
663
Conforming steel

II
—
—
—
—
—
—
—
657
Conforming steel

IJ
—
—
—
—
—
—
—
649
Conforming steel

IK
—
—
—
—
—
—
—
653
Conforming steel

IL
—
—
—
—
—
—
—
687
Comparative steel

IM
—
—
—
—
—
—
—
659
Comparative steel

J
—
—
—
—
—
—
—
667
Comparative steel

K
—
—
—
—
—
—
—
727
Comparative steel

L
—
—
—
—
—
—
—
696
Comparative steel

M
—
—
—
—
—
—
—
650
Comparative steel

N
—
—
—
—
—
—
—
659
Conforming steel

O
—
—
—
—
—
—
—
653
Conforming steel

P
—
—
—
—
—
—
—
658
Conforming steel

Q
—
—
—
—
—
—
—
654
Conforming steel

R
—
—
—
—
—
—
—
643
Conforming steel

S
—
—
—
—
—
—
—
651
Conforming steel

T
—
—
—
—
—
—
—
668
Conforming steel

U
0.259
—
—
—
—
—
—
674
Conforming steel

V
—
0.006
—
—
—
—
—
660
Conforming steel

W
—
—
—
0.005
—
—
—
661
Conforming steel

X
—
—
—
—
—
—
—
658
Conforming steel

Y
—
—
0.007
—
—
—
—
663
Conforming steel

Z
—
—
—
0.008
—
—
—
649
Conforming steel

AA
—
—
—
—
0.0021
—
—
651
Conforming steel

AB
—
—
—
—
—
0.0021
—
649
Conforming steel

AC
—
—
—
—
—
—
0.0028
646
Conforming steel

AD
—
—
—
—
—
—
—
658
Conforming steel

Underline: outside range according to present disclosure

TABLE 2

Finisher
Average
hot-rolled sheet heat treatment

Steel
Slab heating
delivery
coiling
Heat treatment
Heat treatment

sample
temperature
temperature
temperature
temperature
time

No.
ID
(° C.)
(° C.)
(° C.)
(° C.)
(s)

1
A
1230
900
540
703
18000

2
B
1240
890
500
688
20000

3
C
1200
890
600
690
15000

4
C
1100
890
600
690
20000

5
C
1300
880
580
700
21000

6
C
1200
750
600
690
20000

7
C
1200
1000
680
710
18000

8
C
1150
880
300
690
19000

9
C
1180
870
750
690
20000

10
C
1180
870
600
670
19000

11
C
1190
860
550
760
18000

12
C
1200
850
600
690
600

13
C
1210
850
540
680
17000

14
C
1200
890
540
680
17000

15
C
1250
870
660
690
19000

16
C
1220

700

540
690
20000

17
C
1230

1100
490
690
10000

18
C
1240
860

850

690
7000

19
C
1250
870
510

500

16000

20
C
1240
880
490

850

17000

21
C
1250
890
570
690
300

22
C
1250
890
600
690
19000

23
C
1240
890
600
690
20000

24
C
1230
860
610
690
19000

25
C
1230
860
610
690
6000

26
C
1240
880
590
690
6000

27
C
1210
880
560
690
10000

28
C
1230
860
560
690
16000

29
C
1200
890
570
690
20000

30
D
1240
860
530
696
18000

31
E
1240
890
520
689
6000

32
F
1250
900
550
690
18000

33
G
1240
890
590
687
7000

34
H
1260
860
560
715
9000

35
I
1240
920
600
691
15000

36
IA
1250
890
600
700
15000

37
IB
1250
890
600
710
18000

38
IC
1240
890
560
750
18000

39
ID
1230
880
570
700
18000

40
IE
1250
890
580
710
19000

41
IF
1240
860
560
710
18000

42
IG
1230
860
560
710
18000

43
IH
1250
860
570
715
18000

44
II
1250
870
600
712
18000

45
IJ
1250
890
580
720
18000

46
IK
1230
880
580
690
18000

47
IL
1240
870
590
710
18000

48
IM
1250
870
570
710
18000

49

J

1220
860
630
717
17000

50

K

1210
870
620
764
20000

51

L

1240
840
570
729
19000

52
M
1250
830
540
688
5000

53
N
1260
850
580
684
6000

54
O
1270
870
540
695
15000

55
P
1220
900
520
695
18000

56
Q
1260
840
600
696
19000

57
R
1270
830
560
683
14000

58
S
1240
880
620
690
8000

59
T
1250
820
600
700
8000

60
U
1250
850
530
715
15000

61
V
1240
920
570
692
13000

62
W
1230
910
500
705
10000

63
X
1250
890
590
695
16000

64
Y
1260
900
520
702
9000

65
Z
1250
880
540
686
18000

66
AA
1260
900
520
686
9000

67
AB
1250
880
540
694
15000

68
AC
1260
860
530
686
6000

69
AD
1250
870
540
696
8000

70
B
1230
890
550
695
10000

71
B
1250
870
530
698
8000

Annealing treatment

Rolling reduction
Heat treatment
Heat treatment

in cold rolling
temperature
time

No.
(%)
(° C.)
(s)
Type*
Remarks

1
27.6
688
500
CR
Example

2
27.6
673
300
CR
Example

3
28.6
675
350
GA
Example

4
28.6
680
500
CR
Example

5
28.6
680
350
CR
Example

6
22.2
675
350
CR
Example

7
29.6
690
400
GA
Example

8
28.6
675
400
GA
Example

9
25.9
690
400
CR
Example

10
25.9
700
350
CR
Example

11
28.6
690
500
CR
Example

12
25.0
680
500
GA
Example

13
25.0
740
500
GA
Example

14
22.2
680
20
GA
Example

15
28.6
670
900
CR
Example

16
28.6
675
250
CR
Comparative Example

17
27.6
675
350
CR
Comparative Example

18
29.6
675
800
CR
Comparative Example

19
25.9
675
700
EG
Comparative Example

20
25.0
675
500
CR
Comparative Example

21
27.6
675
600
CR
Comparative Example

22
10.3
675
550
CR
Example

23
0.0
675
550
CR
Example

24

57.5

675
650
CR
Comparative Example

25

36.4

675
650
CR
Comparative Example

26
28.6

520

750
CR
Comparative Example

27
29.6

850

400
Al
Comparative Example

28
28.6
675
2
CR
Comparative Example

29
28.6
675
1500
CR
Comparative Example

30
27.6
688
600
CR
Example

31
27.6
674
700
GI
Example

32
24.1
675
500
CR
Example

33
25.0
672
550
Al
Example

34
28.6
700
540
CR
Example

35
28.6
676
290
GA
Example

36
28.6
680
650
GA
Example

37
28.6
690
650
CR
Example

38
28.6
710
550
CR
Example

39
28.6
700
600
CR
Example

40
28.6
700
600
GA
Example

41
28.6
690
600
GA
Example

42
28.6
690
650
CR
Example

43
28.6
690
650
CR
Example

44
28.6
680
600
CR
Example

45
28.6
690
550
CR
Example

46
28.6
710
580
GA
Example

47
28.6
710
600
GA
Comparative Example

48
28.6
680
600
GA
Comparative Example

49
25.9
702
300
GI
Comparative Example

50
29.6
749
200
EG
Comparative Example

51
29.6
714
280
CR
Comparative Example

52
28.6
673
360
EG
Comparative Example

53
21.4
669
370
GI
Example

54
28.6
680
400
CR
Example

55
28.6
680
300
GA
Example

56
27.6
681
320
CR
Example

57
28.6
668
300
EG
Example

58
27.6
675
300
Al
Example

59
29.6
685
200
GI
Example

60
29.6
700
250
GI
Example

61
28.6
677
280
GI
Example

62
27.6
690
250
EG
Example

63
22.2
680
300
Al
Example

64
25.0
687
340
GA
Example

65
28.6
671
600
G1
Example

66
29.6
671
500
Al
Example

67
29.6
679
500
CR
Example

68
29.6
671
350
CR
Example

69
28.6
692
400
CR
Example

70
25.9
657
200
CR
Example

71
28.6
658
180
CR
Example

Underline: outside range according to present disclosure

*CR: cold-rolled steel sheet (no coating), GI: hot-dip galvanized steel sheet (no galvannealing), GA: galvannealed steel sheet Al: hot-dip aluminum-coated steel sheet, EG: electrogalvanized steel sheet

TABLE 3

Rolling

Volume
Average

Steel
reduction in
Area ratio
Area ratio
Area ratio
fraction of
grain size
Aspect ratio of

sample
cold rolling
of F
of F′
of M
RA
(μm)
crystal grains

No.
ID
(%)
(%)
(%)
(%)
(%)
F
M
RA
F
M
RA
Balance
Remarks

1
A
27.6
64.9
8.0
6.3
13.1
4.9
2.6
2.4
4.3
3.5
4.2
BF, P, θ
Example

2
B
27.6
55.2
9.2
10.6
19.2
4.3
1.7
1.8
4.5
4.0
4.3
BF, P, θ
Example

3
C
28.6
42.5
16.9
13.5
24.6
3.2
1.0
1.1
4.4
4.1
4.3
BF, P, θ
Example

4
C
28.6
45.1
8.5
13.5
22.5
4.2
2.1
1.2
4.5
4.1
4.2
BF, P, θ
Example

5
C
28.6
42.1
9.2
12.6
23.4
4.1
2.0
1.1
4.8
4.0
4.3
BF, P, θ
Example

6
C
22.2
42.5
10.2
15.4
22.1
3.2
1.9
1.3
4.5
4.1
4.3
BF, P, θ
Example

7
C
29.6
43.1
9.8
12.5
20.6
3.0
1.8
2.1
4.4
4.2
4.2
BF, P, θ
Example

8
C
28.6
42.5
9.1
14.1
25.1
3.5
1.3
2.2
5.1
4.5
4.3
BF, P, θ
Example

9
C
25.9
41.6
9.1
13.8
22.6
3.6
1.5
2.5
4.8
4.2
4.1
BF, P, θ
Example

10
C
25.9
38.1
10.1
12.8
22.4
3.8
2.0
1.2
4.5
4.1
4.1
BF, P, θ
Example

11
C
28.6
50.6
11.2
14.1
23.5
5.0
2.1
1.3
4.5
4.2
4.2
BF, P, θ
Example

12
C
25.0
32.1
17.2
17.8
24.8
4.5
2.3
1.5
4.7
4.0
4.2
BF, P, θ
Example

13
C
25.0
46.9
12.1
12.9
25.1
3.9
1.5
1.5
4.8
4.0
4.3
BF, P, θ
Example

14
C
22.2
41.0
11.2
14.1
22.6
5.0
1.9
1.6
4.7
4.1
4.4
BF, P, θ
Example

15
C
28.6
42.6
12.5
16.5
23.9
4.1
2.1
1.4
4.8
4.1
4.1
BF, P, θ
Example

16
C
28.6
55.2
10.2
12.8
7.1
3.9
1.5
1.6
4.4
4.2
4.5
BF, P, θ
Comparative Example

17
C
27.6
60.8
10.8
13.4
7.4
4.1
1.8
1.4
3.5
4.0
4.2
BF, P, θ
Comparative Example

18
C
29.6
55.9
10.3
12.5
18.6

7.8

4.2

4.1

5.5
4.1
4.5
BF, P, θ
Comparative Example

19
C
25.9
59.1
10.4
15.4
6.4
5.4
1.8
1.7
4.4
4.3
4.4
BF, P, θ
Comparative Example

20
C
25.0
59.3
12.1
16.8
6.9
5.2
1.5
1.4
4.6
4.4
4.1
BF, P, θ
Comparative Example

21
C
27.6
50.2
11.4
14.9
6.2
5.1
1.6
1.5
4.7
4.4.
4.3
BF, P, θ
Comparative Example

22
C
10.3
40.1
9.3
10.4
18.5
4.2
2.1
2.0
5.8
4.8
4.1
BF, P, θ
Example

23
C
0.0
45.3
9.3
10.4
18.5
4.2
2.1
2.0
8.1
4.2
4.1
BF, P, θ
Example

24
C

57.5

70.0

10.8
8.0
8.0

6.5

2.7
2.9

1.4

1.4

1.5

BF, P, θ
Comparative Example

25
C

36.4

65.5

10.8
8.5
8.1
5.1
2.7
2.9

1.9

1.8

1.9

BF, P, θ
Comparative Example

26
C
28.6
55.8
10.4
18.1
6.2
4.5
2.3
2.1
3.8
4.2
4.3
BF, P, θ
Comparative Example

27
C
29.6
53.8
10.9
17.1
6.5
4.6
2.1
2.4
4.2
4.5
4.6
BF, P, θ
Comparative Example

28
C
28.6
54.2
11.2
18.5
6.3
4.2
2.3
2.2
3.9
4.0
4.7
BF, P, θ
Comparative Example

29
C
28.6
58.2

1.2

8.4
23.4
5.6

4.1

3.9

4.1
3.8
4.1
BF, P, θ
Comparative Example

30
D
27.6
50.1
9.8
10.4
18.4
4.2
1.8
1.8
4.2
4.2
5.0
BF, P, θ
Example

31
E
27.6
52.1
10.1
10.6
16.8
4.1
1.5
1.9
4.5
4.4
4.2
BF, P, θ
Example

32
F
24.1
50.1
9.8
10.9
19.2
3.9
1.9
1.8
4.5
4.7
4.4
BF, P, θ
Example

33
G
25.0
64.5
8.1
8.5
12.8
5.1
2.7
2.3
4.4
4.8
4.3
BF, P, θ
Example

34
H
28.6
63.1
8.5
8.8
13.8
4.8
2.5
2.2
4.6
4.6
4.3
BF, P, θ
Example

35
I
28.6
64.7
8.0
8.8
13.5
4.6
2.4
2.4
4.7
4.5
4.2
BF, P, θ
Example

36
IA
28.6
64.8
8.5
8.5
12.6
5.1
2.5
1.8
4.5
4.5
4.2
BF, P, θ
Example

37
IB
28.6
65.0
9.1
8.5
13.5
5.5
2.6
1.5
4.5
4.5
4.3
BF, P, θ
Example

38
IC
28.6
64.8
8.1
8.9
14.0
5.1
2.4
2.2
4.4
4.6
4.1
BF, P, θ
Example

39
ID
28.6
55.1
9.1
10.1
18.1
4.9
2.1
1.9
4.2
4.2
4.2
BF, P, θ
Example

40
IE
28.6
52.0
9.2
10.2
15.6
4.6
2.2
2.0
4.4
4.1
4.3
BF, P, θ
Example

41
IF
28.6
54.0
9.8
10.1
15.7
4.2
2.3
2.1
4.2
4.6
4.2
BF, P, θ
Example

42
IG
28.6
53.1
8.7
10.2
16.8
4.5
2.1
2.2
4.5
4.3
4.1
BF, P, θ
Example

43
IH
28.6
59.1
10.1
10.5
17.2
5.1
2.5
1.9
4.1
4.2
4.4
BF, P, θ
Example

44
II
28.6
60.1
8.9
10.5
18.1
4.9
2.4
1.5
4.5
4.1
4.1
BF, P, θ
Example

45
IJ
28.6
58.1
9.5
10.9
15.4
4.6
2.5
1.8
4.7
4.2
4.5
BF, P, θ
Example

46
IK
28.6
61.2
8.5
11.1
16.9
4.5
2.4
1.5
4.6
4.1
4.3
BF, P, θ
Example

47
IL
28.6

66.1

8.0
10.5
10.2
5.6
2.0
1.9
4.1
4.1
4.1
BF, P, θ
Comparative Example

48
IM
28.6
63.5
12.5
14.5
9.0
4.0
2.1
2.1
4.5
4.5
4.2
BF, P, θ
Comparative Example

49
J
25.9
65.0
8.9
3.8
3.6

7.4

0.6
0.5
4.3
4.4
4.2
BF, P, θ
Comparative Example

50
K
29.6
50.4
18.4
15.4
6.8
5.4

3.9

3.8

4.4
4.1
4.1
BF, P, θ
Comparative Example

51
L
29.6
60.3
13.2
15.9
6.2
5.8

4.5

3.9

4.4
4.1
4.1
BF, P, θ
Comparative Example

52
M
28.6
50.3

2.2

11.4
13.2

7.1

4.1

4.0

4.2
4.1
3.9
BF, P, θ
Comparative Example

53
N
21.4
55.1
10.4
11.4
18.4
4.2
1.6
1.9
4.3
4.2
4.1
BF, P, θ
Example

54
O
28.6
54.2
10.5
9.8
17.4
4.3
1.7
1.4
4.2
4.3
4.2
BF, P, θ
Example

55
P
28.6
55.7
10.1
10.5
19.5
4.1
1.4
1.5
3.9
4.3
4.6
BF, P, θ
Example

56
Q
27.6
56.1
10.3
10.8
19.6
4.3
1.7
1.6
4.0
4.2
4.3
BF, P, θ
Example

57
R
28.6
65.0
8.2
7.5
12.8
5.1
2.5
2.3
3.9
4.1
4.5
BF, P, θ
Example

58
S
27.6
64.8
8.1
8.2
12.4
4.8
2.4
2.1
4.3
4.2
4.3
BF, P, θ
Example

59
T
29.6
60.9
8.0
7.2
14.2
4.6
2.3
2.1
4.2
4.5
4.4
BF, P, θ
Example

60
U
29.6
63.9
8.1
7.6
13.5
4.5
2.4
2.5
4.4
4.2
4.5
BF, P, θ
Example

61
V
28.6
65.0
8.7
7.5
12.9
4.8
2.1
2.4
4.0
4.1
4.7
BF, P, θ
Example

62
W
27.6
64.9
8.0
6.8
13.2
4.7
2.3
2.1
3.9
3.9
4.1
BF, P, θ
Example

63
X
22.2
50.7
10.4
10.2
18.4
4.1
1.6
1.7
3.7
3.1
4.2
BF, P, θ
Example

64
Y
25.0
62.8
10.5
10.6
15.0
4.5
1.7
1.8
3.9
4.2
4.4
BF, P, θ
Example

65
Z
28.6
55.5
9.8
9.8
20.1
4.2
1.8
1.6
4.2
4.2
4.3
BF, P, θ
Example

66
AA
29.6
50.8
10.6
10.6
19.4
3.9
1.9
1.5
4.1
4.1
4.2
BF, P, θ
Example

67
AB
29.6
52.1
10.1
9.6
18.4
4.1
1.7
1.5
4.2
4.5
4.6
BF, P, θ
Example

68
AC
29.6
52.9
9.9
10.3
18.2
4.2
1.6
1.8
4.4
4.5
4.7
BF, P, θ
Example

69
AD
28.6
51.2
11.1
12.1
19.6
3.9
1.4
1.6
4.3
4.3
4.1
BF, P, θ
Example

70
B
25.9
48.0
10.1
11.2
18.4
4.5
1.9
1.7
4.1
4.2
4.2
BF, P, θ
Example

71
B
28.6
50.5
10.5
10.8
19.1
4.6
1.8
1.8
3.9
4.4
4.4
BF, P, θ
Example

Underline: outside range according to present disclosure

F: polygonal ferrite,

F′: non-recrystallized ferrite,

BF: bainitic ferrite,

RA: retained austenite,

M: martensite,

P: pearlite,

θ: carbide (such as cementite)

TABLE 4

Value obtained

by dividing RA

remaining volume

Average

fraction after

Mn content
0.09 × (Mn
0.09 × (Mn

10% tensile

Average
Average
in RA/
content in
content in

working by

Steel
Mn content
Mn content
Average
RA) − 0.026 −
RA) − 0.026 +
C content
RA volume

sample
in RA
in F
Mn content
0.150
0.150
in RA
fraction before

No.
ID
(mass %)
(mass %)
in F
(mass %)
(mass %)
(mass %)
working
Remarks

1
A
6.89
2.84
2.43
0.444
0.744
0.63
0.77
Example

2
B
7.68
3.02
2.54
0.515
0.815
0.71
0.81
Example

3
C
8.22
3.08
2.67
0.564
0.864
0.75
0.68
Example

4
C
7.88
2.87
2.75
0.533
0.833
0.75
0.65
Example

5
C
8.02
2.88
2.78
0.546
0.846
0.75
0.68
Example

6
C
7.55
3.01
2.51
0.504
0.804
0.78
0.74
Example

7
C
8.01
3.01
2.66
0.545
0.845
0.68
0.74
Example

8
C
7.89
3.05
2.59
0.534
0.834
0.74
0.65
Example

9
C
7.99
2.98
2.68
0.543
0.843
0.78
0.68
Example

10
C
7.75
2.99
2.59
0.522
0.822
0.75
0.71
Example

11
C
7.98
3.01
2.65
0.542
0.842
0.75
0.64
Example

12
C
5.87
2.89
2.03
0.352
0.652
0.62
0.51
Example

13
C
7.89
2.89
2.73
0.534
0.834
0.76
0.71
Example

14
C
7.99
3.05
2.62
0.543
0.843
0.74
0.72
Example

15
C
7.84
3.01
2.60
0.530
0.830
0.76
0.74
Example

16
C
7.45
2.79
2.67
0.495
0.795
0.43
0.25
Comparative Example

17
C
7.35
2.89
2.54
0.486
0.786
0.65
0.42
Comparative Example

18
C
6.89
2.97
2.32
0.444
0.744
0.63
0.51
Comparative Example

19
C
5.41
3.57

1.52

0.311
0.611
0.50
0.39
Comparative Example

20
C
5.32
3.67

1.45

0.303
0.603
0.49
0.52
Comparative Example

21
C
5.26
3.68

1.43

0.297
0.597
0.49
0.44
Comparative Example

22
C
7.48
2.99
2.50
0.497
0.797
0.69
0.69
Example

23
C
7.48
2.99
2.50
0.497
0.797
0.69
0.69
Example

24
C
7.55
2.75
2.75
0.504
0.804
0.79
0.19
Comparative Example

25
C
7.32
2.75
2.66
0.483
0.783
0.79
0.19
Comparative Example

26
C
5.67
3.64

1.56

0.334
0.634
0.29
0.22
Comparative Example

27
C
5.54
3.75

1.48

0.323
0.623
0.46
0.46
Comparative Example

28
C
5.28
3.87

1.36

0.299
0.599
0.49
0.53
Comparative Example

29
C
8.26
2.67
3.09
0.567
0.867
0.76
0.39
Comparative Example

30
D
7.54
2.89
2.61
0.503
0.803
0.69
0.71
Example

31
E
7.32
2.78
2.63
0.483
0.783
0.62
0.75
Example

32
F
7.84
2.97
2.64
0.530
0.830
0.72
0.64
Example

33
G
6.95
2.85
2.44
0.450
0.750
0.62
0.69
Example

34
H
7.08
2.76
2.57
0.461
0.761
0.63
0.70
Example

35
I
6.85
2.66
2.58
0.441
0.741
0.61
0.74
Example

36
IA
7.55
3.15
2.40
0.504
0.804
0.55
0.48
Example

37
IB
7.15
2.58
2.77
0.468
0.768
0.52
0.55
Example

38
IC
4.51
1.55
2.91
0.230
0.530
0.51
0.38
Example

39
ID
6.95
3.15
2.21
0.450
0.750
0.61
0.68
Example

40
IE
7.10
3.21
2.21
0.463
0.763
0.58
0.70
Example

41
IF
6.88
3.01
2.29
0.443
0.743
0.58
0.74
Example

42
IG
7.15
3.21
2.23
0.468
0.768
0.61
0.74
Example

43
IH
6.99
2.89
2.42
0.453
0.753
0.62
0.75
Example

44
II
7.15
2.97
2.41
0.468
0.768
0.65
0.76
Example

45
IJ
7.10
2.88
2.47
0.463
0.763
0.58
0.81
Example

46
IK
7.02
2.78
2.53
0.456
0.756
0.58
0.56
Example

47
IL
6.87
3.10
2.22
0.442
0.742
0.55
0.25
Comparative Example

48
IM
6.55
3.15
2.08
0.414
0.714
0.35
0.21
Comparative Example

49
J
6.45
2.79
2.31
0.405
0.705
0.38
0.24
Comparative Example

50
K
7.29
2.87
2.54
0.480
0.780
0.67
0.52
Comparative Example

51
L
3.40
2.08

1.63

0.130
0.430
0.30
0.43
Comparative Example

52
M
7.28
2.89
2.52
0.479
0.779
0.65
0.46
Comparative Example

53
N
7.59
2.98
2.55
0.507
0.807
0.70
0.62
Example

54
O
7.64
2.85
2.68
0.512
0.812
0.65
0.68
Example

55
P
7.49
2.89
2.59
0.498
0.798
0.69
0.74
Example

56
Q
7.39
2.98
2.48
0.489
0.789
0.63
0.84
Example

57
R
6.58
2.75
2.39
0.416
0.716
0.59
0.86
Example

58
S
6.87
2.81
2.44
0.442
0.742
0.58
0.81
Example

59
T
6.89
2.74
2.51
0.444
0.744
0.63
0.75
Example

60
U
6.99
2.65
2.64
0.453
0.753
0.61
0.78
Example

61
V
6.48
2.71
2.39
0.407
0.707
0.55
0.74
Example

62
W
6.78
2.68
2.53
0.434
0.734
0.59
0.76
Example

63
X
7.85
2.89
2.72
0.531
0.831
0.69
0.79
Example

64
Y
7.46
2.79
2.67
0.495
0.795
0.66
0.83
Example

65
Z
7.59
2.68
2.83
0.507
0.807
0.68
0.74
Example

66
AA
7.36
2.89
2.55
0.486
0.786
0.63
0.78
Example

67
AB
7.56
2.78
2.72
0.504
0.804
0.67
0.77
Example

68
AC
7.54
2.79
2.70
0.503
0.803
0.64
0.68
Example

69
AD
7.94
2.91
2.73
0.539
0.839
0.70
0.72
Example

70
B
7.24
3.24
2.23
0.476
0.776
0.45
0.29
Example

71
B
7.18
3.28
2.19
0.470
0.770
0.46
0.28
Example

Underline: outside range according to present disclosure

F: polygonal ferrite,

F′: non-recrystallized ferrite,

BF: bainitic ferrite,

RA: retained austenite,

M: martensite,

P: pearlite,

θ: carbide (such as cementite)

TABLE 5

Steel
Sheet
Sheet passage
Sheet passage
Surface

sample
thickness
ability during
ability during
characteristics of

No.
ID
(mm)
hot rolling
cold rolling
final-annealed sheet
Productivity

1
A
2.1
Good
Good
Good
Good

2
B
2.1
Good
Good
Good
Good

3
C
2.0
Good
Good
Good
Good

4
C
2.0
Good
Good
Good
Good

5
C
2.0
Good
Good
Good
Good

6
C
2.1
Good
Good
Good
Good

7
C
1.9
Good
Good
Good
Good

8
C
2.0
Good
Good
Good
Good

9
C
2.0
Good
Good
Good
Good

10
C
2.0
Good
Good
Good
Good

11
C
2.0
Good
Good
Good
Good

12
C
2.1
Good
Good
Good
Good

13
C
2.1
Good
Good
Good
Good

14
C
2.1
Good
Good
Good
Good

15
C
2.0
Good
Good
Good
Good

16
C
2.0
Poor
Poor
Poor
Poor

17
C
2.1
Good
Poor
Poor
Poor

18
C
1.9
Good
Good
Good
Good

19
C
2.0
Good
Poor
Good
Good

20
C
2.1
Good
Good
Good
Good

21
C
2.1
Good
Poor
Good
Good

22
C
2.6
Good
Good
Good
Good

23
C
2.8
Good
Good
Good
Good

24
C
1.7
Good
Good
Good
Good

25
C
2.1
Good
Good
Good
Good

26
C
2.0
Good
Good
Good
Good

27
C
1.9
Good
Good
Good
Poor

28
C
2.0
Good
Good
Good
Good

29
C
2.0
Good
Good
Good
Good

30
D
2.1
Good
Good
Good
Good

31
E
2.1
Good
Good
Good
Good

32
F
2.2
Good
Good
Good
Good

33
G
2.1
Good
Good
Good
Good

34
H
2.0
Good
Good
Good
Good

35
I
2.0
Good
Good
Good
Good

36
IA
2.0
Good
Good
Good
Good

37
IB
2.0
Good
Good
Good
Good

38
IC
2.0
Good
Good
Good
Good

39
ID
2.0
Good
Good
Good
Good

40
IE
2.0
Good
Good
Good
Good

41
IF
2.0
Good
Good
Good
Good

42
IG
2.0
Good
Good
Good
Good

43
IH
2.0
Good
Good
Good
Good

44
II
2.0
Good
Good
Good
Good

45
IJ
2.0
Good
Good
Good
Good

46
IK
2.0
Good
Good
Good
Good

47
IL
2.0
Good
Good
Good
Good

48
IM
2.0
Good
Good
Good
Good

49
J
2.0
Good
Good
Good
Good

50
K
1.9
Good
Good
Poor
Good

51
L
1.9
Good
Good
Good
Good

52
M
2.0
Good
Good
Good
Good

53
N
2.2
Good
Good
Good
Good

54
O
2.0
Good
Good
Good
Good

55
P
2.0
Good
Good
Good
Good

56
Q
2.1
Good
Good
Good
Good

57
R
2.0
Good
Good
Good
Good

58
S
2.1
Good
Good
Good
Good

59
T
1.9
Good
Good
Good
Good

60
U
1.9
Good
Good
Good
Good

61
V
2.0
Good
Good
Good
Good

62
W
2.1
Good
Good
Good
Good

63
X
2.1
Good
Good
Good
Good

64
Y
2.1
Good
Good
Good
Good

65
Z
2.0
Good
Good
Good
Good

66
AA
1.9
Good
Good
Good
Good

67
AB
1.9
Good
Good
Good
Good

68
AC
1.9
Good
Good
Good
Good

69
AD
2.0
Good
Good
Good
Good

70
B
2.0
Good
Good
Good
Good

71
B
2.0
Good
Good
Good
Good

YP
YR
TS
EL
TS × EL

λ

No.
(MPa)
(%)
(MPa)
(%)
(MPa · %)
R/t
(%)
Remarks

1
515
79.2
650
38.2
24830
0.1
61
Example

2
691
85.1
812
35.1
28501
0.2
52
Example

3
996
97.8
1018
31.4
31965
0.5
40
Example

4
990
97.9
1011
32.0
32352
0.5
49
Example

5
950
96.4
985
31.5
31028
0.5
52
Example

6
950
96.5
984
31.4
30898
0.5
51
Example

7
960
95.8
1002
35.1
35170
0.5
52
Example

8
950
96.3
987
32.6
32176
0.5
51
Example

9
940
94.9
990
35.1
34749
0.5
49
Example

10
950
94.1
1010
33.1
33431
0.5
52
Example

11
950
94.8
1002
31.2
31262
0.5
55
Example

12
980
97.5
1005
31.8
31959
0.5
56
Example

13
900
91.5
984
31.5
30996
0.5
52
Example

14
910
91.9
990
31.4
31086
0.5
51
Example

15
950
95.0
1000
32.1
32100
0.5
51
Example

16
695
82.7
840
21.9
18396
1.5
25
Comparative Example

17
689
83.5
825
22.4
18480
1.4
30
Comparative Example

18
501
91.3
549
28.4
15592
1.1
28
Comparative Example

19
699
82.8
844
22.5
18990
0.5
44
Comparative Example

20
691
80.3
861
23.5
20234
0.5
43
Comparative Example

21
663
80.9
820
23.7
19434
0.5
42
Comparative Example

22
653
76.8
850
35.9
30515
0.6
56
Example

23
649
76.7
846
35.9
30371
0.5
56
Example

24
659
79.4
830
21.6
17928
1.9
22
Comparative Example

25
654
79.7
821
21.6
17734
1.5
22
Comparative Example

26
697
80.1
870
21.5
18705
0.5
31
Comparative Example

27
705
82.0
860
20.6
17716
0.5
41
Comparative Example

28
694
79.0
878
20.9
18350
0.5
40
Comparative Example

29
488
58.8
830
36.2
30046
1.3
25
Comparative Example

30
693
84.0
825
34.9
28793
0.2
41
Example

31
661
77.6
852
32.8
27946
0.4
45
Example

32
702
82.8
848
35.1
29765
0.2
46
Example

33
518
79.7
650
37.8
24570
0.1
59
Example

34
512
81.4
629
38.6
24279
0.1
65
Example

35
519
82.6
628
38.9
24429
0.1
65
Example

36
510
85.7
595
41.0
24395
0.5
60
Example

37
610
93.8
650
38.0
24700
0.5
62
Example

38
550
92.0
598
42.0
25116
0.5
58
Example

39
600
91.9
653
38.0
24814
0.5
55
Example

40
580
93.1
623
40.2
25045
0.5
56
Example

41
560
88.9
630
39.1
24633
0.5
60
Example

42
550
88.3
623
38.6
24048
0.5
55
Example

43
510
85.4
597
42.5
25373
0.5
52
Example

44
560
82.4
680
35.8
24344
0.5
55
Example

45
560
86.2
650
39.7
25805
0.5
50
Example

46
650
82.5
788
32.1
25295
0.5
56
Example

47
660
84.0
786
30.1

23659

0.5
55
Comparative Example

48
660
83.7
789

21.4

16885

0.5
53
Comparative Example

49
330
60.6
545
31.9
17386
0.1
63
Comparative Example

50
905
75.7
1195
15.8
18881
1.3
12
Comparative Example

51
631
76.0
830
20.8
17264
0.8
37
Comparative Example

52
499
59.1
845
28.9
24421
1.0
15
Comparative Example

53
674
81.2
830
36.4
30212
0.2
40
Example

54
661
77.7
851
35.8
30466
0.3
45
Example

55
709
87.5
810
35.9
29079
0.4
51
Example

56
710
89.0
798
36.4
29047
0.2
48
Example

57
505
80.8
625
39.4
24625
0.1
53
Example

58
531
83.0
640
39.5
25280
0.1
58
Example

59
501
83.4
601
41.2
24761
0.1
55
Example

60
534
78.1
684
37.5
25650
0.1
65
Example

61
550
83.5
659
36.9
24317
0.1
55
Example

62
545
82.1
664
36.7
24369
0.1
59
Example

63
726
83.5
869
34.8
30241
0.2
48
Example

64
709
82.5
859
35.1
30151
0.4
45
Example

65
710
85.5
830
36.4
30212
0.3
50
Example

66
678
82.6
821
36.9
30295
0.4
47
Example

67
661
81.1
815
34.8
28362
0.3
53
Example

68
702
84.9
827
35.2
29110
0.3
44
Example

69
785
79.2
991
32.6
32307
0.3
42
Example

70
591
74.6
792
31.5
24948
0.5
40
Example

71
598
75.3
794
30.8
24455
0.5
41
Example

From above, it can be seen that the steel sheets according to the disclosure each exhibited TS of 590 MPa or more and YR of 68% or more, and are thus considered as high-strength steel sheets having excellent formability and high yield ratio and hole expansion formability. In contrast, the comparative examples are inferior in terms of at least one of YR, TS, EL, λ, or R/t.

INDUSTRIAL APPLICABILITY

According to the disclosure, it becomes possible to manufacture high-strength steel sheets with excellent formability and high yield ratio and hole expansion formability that exhibit TS of 590 MPa or more and YR of 68% or more and that satisfy the condition of TS * EL≥24,000 MPa·%. Steel sheets according to the disclosure are highly beneficial in industrial terms, because they can improve fuel efficiency when applied to, for example, automobile structural parts, by a reduction in the weight of automotive bodies.

STEEL SHEET, COATED STEEL SHEET, AND METHODS FOR MANUFACTURING SAME

Information

Publication Number

Date Filed

Date Published

Inventors

Original Assignees

CPC

International Classifications

Abstract

Description

Claims

Priority Claims (1)

PCT Information