HIGH-STRENGTH STEEL PLATE HAVING EXCELLENT FORMABILITY, TOUGHNESS AND WELDABILITY, AND PRODUCTION METHOD OF SAME

TECHNICAL FIELD

The present invention relates to a high-strength steel sheet excellent in formability, toughness and weldability, and a manufacturing method thereof.

BACKGROUND

In recent years, a high-strength steel sheet has been often used in an automobile for reducing a weight of a vehicle body to improve a fuel efficiency and reduce carbon dioxide emission, and absorbing collision energy in an event of collision to ensure protection and safety of a passenger. However, in general, when strength of a steel sheet is increased, the formability (ductility, hole expandability, etc.) decreases to cause the steel sheet to be difficult to process into a complicated shape. Since it is thus not easy to attain both strength and formability (e.g., ductility, hole expandability), various techniques have been proposed so far.

For instance, Patent Literature 1 discloses a technique of improving strength-elongation balance and strength-elongation flange balance in a high-strength steel sheet with tensile strength of 780 MPa or more by having a steel sheet structure include, by a space factor, ferrite in a range from 5 to 50%, residual austenite of 3% or less, and the balance being martensite (an average aspect ratio of 1.5 or more).

Patent Literature 2 discloses a technique of forming a composite structure including ferrite with an average crystal grain diameter of 10 pm or less, martensite of 20 volume % or more, and a second phase in a high-tensile hot-dip galvanized steel sheet, thereby improving corrosion resistance and secondary work brittleness resistance.

Patent Literatures 3 and 8 each disclose a technique of forming a metal structure of a steel sheet in a composite structure of ferrite (soft structure) and bainite (hard structure), thereby securing a high elongation even with a high strength.

Patent Literatures 4 discloses a technique of forming a composite structure in which, in a space factor, ferrite accounts for 5 to 30%, martensite accounts for 50 to 95%, ferrite has an average grain size of a 3-μm-or-less equivalent circle diameter, and martensite has an average grain size of a 6-μm-or-less equivalent circle diameter, thereby improving elongation and elongation flangeability in a high-strength steel sheet.

Patent Literatures 5 discloses a technique of attaining both strength and elongation at a phase interface at which a main phase is a precipitation strengthened ferrite precipitated by controlling a precipitation distribution by a precipitation phenomenon (interphase interfacial precipitation) that occurs mainly due to intergranular diffusion during transformation from austenite to ferrite.

Patent Literature 6 discloses a technique of forming a steel sheet structure in a ferrite single phase and strengthening ferrite with fine carbides, thereby attaining both strength and elongation.

Patent Literature 6 discloses a technique of attaining elongation and hole expandability by setting 50% or more of austenite grains having a required carbon concentration at an interface between austenite grains and ferrite phase, bainite phase, and martensite phase in a high-strength thin steel sheet.

In recent years, high-strength steel with a tensile strength of 590 to 1470 MPa has been used for some parts in order to reduce a weight of an automobile. However, in order to use the high-strength steel with the tensile strength of 590 MPa or more as a steel sheet for automobiles in more parts and achieve further weight reduction, not only formability (e.g., ductility and hole expansion)-strength balance but also a balance between formability and various properties (e.g., toughness and weldability) needs to be improved at the same time.

CITATION LIST
Patent Literature(s)

Patent Literature 1: JP2004-238679A

Patent Literature 2: JP2004-323958A

Patent Literature 3: JP2006-274318A

Patent Literature 4: JP2008-297609A

Patent Literature 5: JP2011-225941A

Patent Literature 6: JP2012-026032A

Patent Literature 7: JP2011-195956A

Patent Literature 8: JP2013-181208A

SUMMARY OF THE INVENTION
Problem(s) to be Solved by the Invention

In light of the demand of improving formability-various properties (e.g., toughness, weldability) balance in addition to improvement in formability-strength balance in a high-strength steel sheet with the tensile strength of 590 MPa or more, an object of the invention is to improve formability-strength-various properties (e.g., toughness, weldability) balance in a high-strength steel sheet (including a galvanized steel sheet, zinc-alloy plated steel sheet, galvannealed steel sheet, and galvannealed alloy steel sheet) with the tensile strength of 590 MPa or more, and to provide a high-strength steel sheet and a manufacturing method thereof to solve this problem.

Means for Solving the Problem(s)

The inventors have diligently studied a solution to the above problem. As a result, the inventors have found that (i) if a microstructure of a material steel sheet (steel sheet for heat treatment) is a lath structure, formation of an Mn-concentrated structure is inhibited in the microstructure, and a required heat treatment is performed, the steel sheet after the heat treatment can have an excellent formability-strength-various properties balance.

The invention has been made based on the above findings, and the gist thereof is as follows.

1. According to an aspect of the invention, a high-strength steel sheet excellent in formability, toughness, and weldability includes a chemical composition including: by mass %,

C in a range from 0.05 to 0.30%, Si in a range from 2.50% or less, Mn in a range from 0.50 to 3.50%, P of 0.100% or less, S of 0.0100% or less, Al in a range from 0.001 to 2.000%, N of 0.0150% or less, O of 0.0050% or less, and the balance consisting of Fe and inevitable impurities,

the steel sheet has a micro structure in a region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from a steel sheet surface, the micro structure including: by volume %, acicular ferrite of 20% or more; martensite of 10% or more; aggregated ferrite of 20% or less; residual austenite of 2.0% or less; and 5% or less of a structure other than a structure including bainite and bainitic ferrite in addition to the above whole structure; and the martensite satisfies a formula (A) below.

$\begin{matrix} [Numerical Formula 1] \\ \sum_{i = 1}^{5} \frac{d_{i}}{{a_{i}}^{1.5}} \leq 10.0 & (A) \end{matrix}$

Herein, d_irepresents an equivalent circle diameter [pm] of the i-th largest island-shaped martensite in the microstructure in a region of ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness), and a_irepresents an aspect ratio of the i-th largest island-shaped martensite in the microstructure in the region of ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness).

2. In the high-strength steel sheet excellent in formability, toughness, and weldability according to the above aspect of the invention, the chemical composition further includes: by mass %, in place of a part of Fe, one or more of Ti of 0.30% or less, Nb of 0.10% or less, and V of 1.00% or less.

3. In the high-strength steel sheet excellent in formability, toughness, and weldability according to the above aspect, the chemical composition further includes: by mass %, in place of a part of Fe, one or more of Cr of 2.00% or less, Ni of 2.00% or less, Cu of 2.00% or less, Mo of 1.00% or less, W of 1.00% or less, B of 0.0100% or less, Sn of 1.00% or less, and Sb of 0.20% or less.

4. In the high-strength steel sheet excellent in formability, toughness, and weldability according to the above aspect, the chemical composition further includes: by mass %, in place of a part of Fe, one or more of Ca, Ce, Mg, Zr, La, Hf, and REM at 0.0100% or less in total.

5. In the high-strength steel sheet excellent in formability, toughness, and weldability according to the above aspect, martensite of the microstructure includes, by volume %, 30% or more of tempered martensite where fine carbides having an average diameter 1.0 μm or less are precipitated with reference to the entire martensite.

6. In the high-strength steel sheet excellent in formability, toughness, and weldability according to the above aspect, the high-strength steel sheet includes a galvanized layer or a zinc alloy plated layer on one surface or both surfaces of the high-strength steel sheet.

7. In the high-strength steel sheet excellent in formability, toughness, and weldability according to the above aspect, the galvanized layer or the zinc alloy plated layer is an alloyed plated layer.

8. A method of manufacturing the high-strength steel sheet according to the above aspect includes:

subjecting a steel piece having the chemical composition according to any one of the above 1 to 4 to hot rolling, completing the hot rolling at a temperature in a range from 850 degrees C. to 1050 degrees C. to provide a steel sheet after the hot rolling;

cooling the steel sheet after the hot rolling from 850 degrees C. to 550 degrees C. at an average cooling rate of at least 30 degrees C. per second, winding the steel sheet at a temperature equal to or less than a Bs point that is a bainite transformation start point defined according to a formula below;

cooling the steel sheet after the hot rolling in a range from the Bs point to a point of (the Bs point −80) degrees C. under conditions satisfying a formula (1) below to provide a hot-rolled steel sheet;

subjecting or not subjecting the hot-rolled steel sheet to cold rolling at a rolling reduction of 10% or less to manufacture a steel sheet for heat treatment;

heating the steel sheet for heat treatment to a temperature in a range from (Ac1+25) degrees C. to an Ac3 point under conditions satisfying a formula (3) below for calculating by dividing an elapsed time in a temperature region from 700 degrees C. to an end point that is a lower one of a maximum heating temperature or (Ac3−20) degrees C. into 10 parts, and retaining the steel sheet for 150 seconds or less in a temperature region from the maximum heating temperature minus 10 degrees C. to the maximum heating temperature;

cooling the steel sheet from a heating retention temperature at an average cooling rate of at least 25 degrees C. per second in a temperature region from 700 degrees C. to 550 degrees C.; and

cooling the steel sheet in a limited range satisfying formulae (4) and (5) for calculating by dividing a dwell time in a temperature region from a start point that is a lower one of 550 degrees C. and a Bs point to 300 degrees C. into 10 parts,

Bs point (degrees C.)=611−33·[Mn]−17·[Cr]

−17·[Ni]−21·[Mo]−11·[Si]

+30·[Al]+(24·[Cr]+15·[Mo]

+5500·[B]+240−[Nb])/(8−[C])

[element]: mass % of each element.

$\begin{matrix} [Numerical Formula 2] \\ (1) \\ \sum_{n = 1}^{8} {5.37 \times 10^{- 1} \cdot (10 n + 925 - Bs - 57 W_{Cr} - 78 W_{Mn} - 39 W_{Si} + 56 W_{Al} - 41 W_{Ni} - {1598 \sqrt{W_{B}})}^{2.5} \cdot \exp (\frac{1.44 \times 10^{4}}{10 n - Bs - 278}) \cdot \exp (- 5.5 W_{Nb} - 2.0 W_{Ti} - 0.2 W_{Cr} - 1.1 W_{Mo}) \cdot Δ {t (n)}^{1 / 3} + 1.81 \times 10^{1} \cdot {(10 n - 5)}^{1.3} \cdot \exp (\frac{1.73 \times 10^{4}}{10 n - Bs - 278}) \cdot \exp (- 1.1 W_{Mo} - 0.6 W_{Cr} - 9.0 \sqrt{W_{B}}) \cdot Δ {t (n)}^{1 / 2}} \leq 1.50 \end{matrix}$

Bs: Bs point (degrees C.)

W_M: a composition of each element (mass %)

Δt(n): an elapsed time (second) from (Bs−10×(n−1)) degrees C. to (Bs−10×n) degrees C. between the cooling after the hot rolling, through winding, and cooling to 400 degrees C.

$\begin{matrix} [Numerical Formula 3] \\ \sum_{n = 1}^{10} 8.65 \times 10^{2} \cdot {(W_{Mn} + 0.51 W_{Cr} + 0.51 W_{Ni} - 0.64 W_{Mo} - 0.33 W_{Si} + 0.90 W_{Al})}^{0.5} \cdot {f_{γ} (n)}^{0.2} \cdot {(1 - f_{γ} (n))}^{1.8} \cdot \exp (- \frac{9.00 \times 10^{3}}{T (n) + 273}) \cdot Δ t^{0.33} \leq 2.0 & (3) \end{matrix}$

Δt: one tenth (second) of the elapsed time,

W_M: a composition of each element (mass %)

fγ(n): an average reverse transformation ratio in the n-th section

T(n): an average temperature in the n-th section

$\begin{matrix} [Numerical Formula 4] \\ \sum_{n = 1}^{10} {1.39 \times 10^{1} \cdot {(Bs - T (n))}^{3} \cdot \exp (- \frac{1.44 \times 10^{4}}{T (n) + 273}) \cdot Δ t^{0.5}} \leq 1.0 & (4) \\ [Numerical Formula 5] \\ \sum_{n = 1}^{10} {1.56 \times 10^{2} \cdot (W_{Si} + 0.9 W_{Al} \cdot {(\frac{T (n)}{550})}^{2} + 0.3 (W_{Cr} + W_{Mo}) \cdot \frac{T (n)}{550}) \cdot \exp (- 6.7 \cdot (1 - \frac{T (n)}{550})) \cdot {(\frac{T (n) - 250}{300})}^{0.5} \cdot {(Bs - T (n))}^{3} \cdot \exp (- \frac{1.44 \times 10^{4}}{T (n) + 273}) \cdot Δ t^{0.5}} \leq 1.0 & (5) \end{matrix}$

Δt: one tenth (second) of the elapsed time

Bs: Bs point (degrees C.)

T(n): an average temperature (degrees C.) in the n-th section

W_M: a composition of each element (mass %)

9. A method of manufacturing the high-strength steel sheet according to the above aspect includes:

cooling the steel sheet from the Bs point to a point of (the Bs point −80) degrees C. under conditions satisfying a formula (1) below to provide a hot-rolled steel sheet;

subjecting or not subjecting the hot-rolled steel sheet to a first cold rolling to manufacture a steel sheet for intermediate heat treatment;

heating the steel sheet for intermediate heat treatment to a temperature equal to or more than (Ac3−20) degrees C. under conditions satisfying a formula (2) below for calculating by dividing an elapsed time in a temperature region from 700 degrees C. to (Ac3−20) degrees C. into 10 parts;

subsequently, cooling the steel sheet for intermediate heat treatment from the heating temperature at an average cooling rate of at least 30 degrees C. per second in a temperature region from 700 degrees C. to 550 degrees C., cooling the steel sheet for intermediate heat at the average cooling rate of at least 20 degrees C. per second in a temperature region from the Bs point to (Bs−80) degrees C., and leaving the steel sheet for intermediate heat from (Bs−80) degrees C. to Ms point for a dwell time of at most 1000 seconds and from the Ms point to (Ms−50) degrees C. at the average cooling rate of at most 100 degrees C. per second to manufacture an intermediate heat-treated steel sheet;

subjecting or not subjecting the cooled intermediate heat-treated steel sheet to a second cold rolling at a rolling reduction of 10% or less to manufacture a steel sheet for heat treatment;

heating the steel sheet for heat treatment to a temperature in a range from (Ac1+25) degrees C. to an Ac3 point under conditions satisfying a formula (3) below for calculating by dividing an elapsed time in a temperature region from 700 degrees C. to an end point that is a lower one of a maximum heating temperature or (Ac3−20) degrees C. into 10 parts, and retaining the steel sheet for heat treatment for 150 seconds or less in a temperature region from the maximum heating temperature minus 10 degrees C. to the maximum heating temperature; and

cooling the steel sheet for heat treatment from a heating retention temperature at an average cooling rate of at least 25 degrees C. per second in a temperature region from 700 degrees C. to 550 degrees C., and cooling the steel sheet for heat treatment in a limited range satisfying formulae (4) and (5) for calculating by dividing a dwell time in a temperature region from a start point that is a lower one of 550 degrees C. and a Bs point to 300 degrees C. into 10 parts,

Bs point (degrees C.)=611−33·[Mn]−17·[Cr]

−17·[Ni]−21·[Mo]−11·[Si]

+30·[Al]+(24·[Cr]+15·[Mo]

+5500·[B]+240−[Nb])/(8−[C])

[element]: mass % of each element.

$\begin{matrix} [Numerical Formula 6] \\ (1) \\ \sum_{n = 1}^{8} {5.37 \times 10^{- 1} \cdot (10 n + 925 - Bs - 57 W_{Cr} - 78 W_{Mn} - 39 W_{Si} + 56 W_{Al} - 41 W_{Ni} - {1598 \sqrt{W_{B}})}^{2.5} \cdot \exp (\frac{1.44 \times 10^{4}}{10 n - Bs - 278}) \cdot \exp (- 5.5 W_{Nb} - 2.0 W_{Ti} - 0.2 W_{Cr} - 1.1 W_{Mo}) \cdot Δ {t (n)}^{1 / 3} + 1.81 \times 10^{1} \cdot {(10 n - 5)}^{1.3} \cdot \exp (\frac{1.73 \times 10^{4}}{10 n - Bs - 278}) \cdot \exp (- 1.1 W_{Mo} - 0.6 W_{Cr} - 9.0 \sqrt{W_{B}}) \cdot Δ {t (n)}^{1 / 2}} \leq 1.50 \end{matrix}$

Bs: Bs point (degrees C.)

W_M: a composition of each element (mass %)

Δt(n): an elapsed time (second) from (Bs−10×(n−1)) degrees C. to (Bs−10×n) degrees C. between the cooling after the hot rolling, through winding, and cooling to 400 degrees C.,

Ms point (degrees C.)=561−474[C]−33·[Mn]

−17·[Cr]−17·[Ni]−21·[Mo]

−11·[Si]+30·[Al]

[element]: mass % of each element

$\begin{matrix} [Numerical Formula 7] \\ \sum_{n = 1}^{10} 5.92 \times 10^{2} \cdot {f_{γ} (n)}^{0.3} \cdot {(1 - f_{γ} (n))}^{1.4} \cdot \exp (- \frac{9.00 \times 10^{3}}{T (n)+273}) \cdot Δ t^{0.5} \leq 1.0 & (2) \end{matrix}$

Δt: one tenth (second) of the elapsed time

f_γ(n): an average reverse transformation ratio in the n-th section

T(n): an average temperature in the n-th section

$\begin{matrix} [Numerical Formula 8] \\ \sum_{n = 1}^{10} 8.65 \times 10^{2} \cdot {(W_{Mn} + 0.51 W_{Cr} + 0.51 W_{Ni} - 0.64 W_{Mo} - 0.33 W_{Si} + 0.90 W_{Al})}^{0.5} \cdot {f_{γ} (n)}^{0.2} \cdot {(1 - f_{γ} (n))}^{1.8} \cdot \exp (- \frac{9.00 \times 10^{3}}{T (n) + 273}) \cdot Δ t^{0.33} \leq 2.0 & (3) \end{matrix}$

Δt: one tenth (second) of the elapsed time,

W_M: a composition of each element (mass %)

fγ(n): an average reverse transformation ratio in the n-th section

T(n): an average temperature in the n-th section

$\begin{matrix} [Numerical Formula 9] \\ \sum_{n = 1}^{10} {1.39 \times 10^{1} \cdot {(Bs - T (n))}^{3} \cdot \exp (- \frac{1.44 \times 10^{4}}{T (n) + 273}) \cdot Δ t^{0.5}} \leq 1.0 & (4) \\ [Numerical Formula 10] \\ \sum_{n = 1}^{10} {1.56 \times 10^{2} \cdot (W_{Si} + 0.9 W_{Al} \cdot {(\frac{T (n)}{550})}^{2} + 0.3 (W_{Cr} + W_{Mo}) \cdot \frac{T (n)}{550}) \cdot \exp (- 6.7 \cdot (1 - \frac{T (n)}{550})) \cdot {(\frac{T (n) - 250}{300})}^{0.5} \cdot {(Bs - T (n))}^{3} \cdot \exp (- \frac{1.44 \times 10^{4}}{T (n) + 273}) \cdot Δ t^{0.5}} \leq 1.0 & (5) \end{matrix}$

Δt: one tenth (second) of the elapsed time

Bs: Bs point (degrees C.)

T(n): an average temperature (degrees C.) in the n-th section

W_M: a composition of each element (mass %)

10. In the method according to the above aspect, the first cold rolling for the steel sheet for heat treatment is performed at the rolling reduction of 80% or less.

11. In the method according to the above aspect, the first cold rolling for the steel sheet for heat treatment is performed at the rolling reduction of more than 10%.

12. The method according to the above aspect further includes a tempering treatment of heating the steel sheet for heat treatment to a temperature in a range from 200 degrees C. to 600 degrees C., after cooling the steel sheet in a limited range satisfying formulae (4) and (5) for calculating by dividing a dwell time in a temperature region from a start point that is a lower one of 550 degrees C. and a Bs point to 300 degrees C. into 10 parts.

13. The method according to the above aspect further includes temper rolling at a rolling reduction of 2.0% or less before the tempering treatment.

14. The manufacturing method of the high-strength steel sheet according to the above aspect includes: immersing the steel sheet in a plating bath including zinc as a main component during dwelling in a range from 550 degrees C. to 300 degrees C. to form a galvanized layer or a zinc alloy plated layer on one surface or both surfaces of the steel sheet.

15. The manufacturing method of the high-strength steel sheet according to the above aspect includes: leaving the steel sheet dwelling in a range from 550 degrees C. to 300 degrees C., cooling the steel sheet to a room temperature, and subsequently forming a galvanized layer or a zinc alloy plated layer by electroplating on one surface or both surfaces of the steel sheet.

16. The manufacturing method of the high-strength steel sheet according to the above aspect includes: immersing the steel sheet in a plating bath including zinc as a main component during the tempering treatment to form a galvanized layer or a zinc alloy plated layer on one surface or both surfaces of the steel sheet.

17. The manufacturing method of the high-strength steel sheet according to the above aspect includes: subjecting the steel sheet to the tempering treatment, cooling the steel sheet to a room temperature, and subsequently forming a galvanized layer or zinc alloy plated layer by electroplating on one surface or both surfaces of the steel sheet.

18. The manufacturing method of the high-strength steel sheet according to the above aspect includes: immersing the steel sheet in a plating bath, subsequently while leaving the steel sheet dwelling from 300 degrees C. to 550 degrees C., heating the galvanized layer or the zinc alloy plated layer to a temperature in a range from 450 degrees C. to 550 degrees C. to perform an alloying treatment on the galvanized layer or the zinc alloy plated layer.

19. The manufacturing method of the high-strength steel sheet according to the above aspect includes: setting a heating temperature of the plated layer or the zinc alloy plated layer to a temperature in a range from 450 degrees C. to 550 degrees C. in the tempering treatment to perform an alloying treatment on the galvanized layer or the zinc alloy plated layer.

According to the above aspects of the invention, a high-strength steel sheet excellent in formability, toughness and weldability can be provided.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 schematically shows a structure of a typical high-strength steel sheet.

FIG. 2 schematically shows a structure of a high-strength steel sheet of the invention.

DESCRIPTION OF EMBODIMENT(S)

In order to manufacture a high-strength steel sheet having excellent toughness and weldability according to an exemplary embodiment of the invention, it is preferable to manufacture a steel sheet for heat treatment (hereinafter, occasionally referred to as a “steel sheet a”) and heat the steel sheet for heat treatment. The steel sheet for heat treatment has a chemical composition including, by mass %, C in a range from 0.05 to 0.30%, Si of 2.50% or less, Mn in a range from 0.50 to 3.50%, P of 0.100% or less, S of 0.010% or less, Al in a range from 0.001 to 2.000%, N of 0.0150% or less, O of 0.0050% or less, and the balance consisting of Fe and inevitable impurities, and

the steel sheet has a microstructure in a region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from a steel sheet surface, the microstructure including: by volume %,

80% or more of a lath structure formed of one or more of martensite or tempered martensite, bainite, and bainitic ferrite;

2.0% or less of an Mn-concentrated structure containing Mn of at least (Mn % of steel sheet)×1.50; and

2.0% or less of coarse aggregated residual austenite.

A high-strength steel sheet (hereinafter, occasionally referred to as “the present steel sheet A”) excellent in formability, toughness, and weldability has a chemical composition including: by mass %, C in a range from 0.05 to 0.30%; Si of 2.50% or less; Mn in a range from 0.50 to 3.50%; P of 0.100% or less; S of 0.010% or less; Al in a range from 0.010 to 2.000%; N of 0.0015% or less; O of 0.0050% or less; and the balance consisting of Fe and inevitable impurities, and

5% or less of a structure other than a structure including bainite and bainitic ferrite in addition to the above whole structure, and

the martensite satisfies a formula (A) below.

$\begin{matrix} [Numerical Formula 11] \\ \sum_{i = 1}^{5} \frac{d_{i}}{{a_{i}}^{1.5}} \leq 10.0 & (A) \end{matrix}$

A high-strength steel sheet excellent in formability, toughness, and weldability of the invention (hereinafter, occasionally referred to as “the present steel sheet A1”) includes a galvanized layer or a zinc alloy plated layer on one surface or both surfaces of the steel sheet A.

In a high-strength steel sheet excellent in formability, toughness, and weldability of the invention (hereinafter, occasionally referred to as “the present steel sheet A2”), the galvanized layer or the zinc alloy plated layer on one surface or both surfaces of the present steel sheet A1 is an alloyed plated layer.

A method (hereinafter, occasionally referred to as “the manufacturing method a1”) of manufacturing the above steel sheet for heat treatment (steel sheet a) includes: subjecting a steel piece having the chemical composition of the steel sheet a to hot rolling, completing the hot rolling at a temperature in a range from 850 degrees C. to 1050 degrees C. to provide a steel sheet after the hot rolling;

cooling the steel sheet after the hot rolling from 850 degrees C. to 550 degrees C., winding the steel sheet at a temperature equal to or less than a Bs point that is a bainite transformation start point defined according to a formula below,

cooling the steel sheet in a range from the Bs point to a point of (the Bs point −80 degrees C.) under conditions satisfying a formula (1) below to provide a hot-rolled steel sheet, and

subjecting or not subjecting the hot-rolled steel sheet to cold rolling with a rolling reduction of 10% or less, so that the steel sheet for heat treatment can be manufactured.

Bs point (degrees C.)=611−33·[Mn]−17·[Cr]

−17−[Ni]−21 ·[Mo]−11·[Si]

+30·[Al]+(24·[Cr]+15·[Mo]

+5500·[B]+240·[Nb])/(8·[C])

[element]: mass % of each element,

$\begin{matrix} [Numerical Formula 12] \\ (1) \\ \sum_{n = 1}^{8} {5.37 \times 10^{- 1} \cdot (10 n + 925 - Bs - 57 W_{Cr} - 78 W_{Mn} - 39 W_{Si} + 56 W_{Al} - 41 W_{Ni} - {1598 \sqrt{W_{B}})}^{2.5} \cdot \exp (\frac{1.44 \times 10^{4}}{10 n - Bs - 278}) \cdot \exp (- 5.5 W_{Nb} - 2.0 W_{Ti} - 0.2 W_{Cr} - 1.1 W_{Mo}) \cdot Δ {t (n)}^{1 / 3} + 1.81 \times 10^{1} \cdot {(10 n - 5)}^{1.3} \cdot \exp (\frac{1.73 \times 10^{4}}{10 n - Bs - 278}) \cdot \exp (- 1.1 W_{Mo} - 0.6 W_{Cr} - 9.0 \sqrt{W_{B}}) \cdot Δ {t (n)}^{1 / 2}} \leq 1.50 \end{matrix}$

In the formula (1), Bs represents the Bs point (degrees C.), W_Mrepresents a chemical composition (mass %) of each elemental species, and Δt(n) represents an elapsed time (second) from (Bs−10× (n−1)) degrees C. to (Bs−10× n) degrees C. in a duration from cooling after hot rolling through winding to cooling to 400 degrees C.

The above-described steel sheet for heat treatment (steel sheet a) can be manufactured according to the following manufacturing method (hereinafter, occasionally referred to as a “manufacturing method a2” by using the hot-rolled steel sheet manufactured by the processes of the manufacturing method a1 as a hot-rolled steel sheet.

Specifically, the manufacturing method a2 includes: manufacturing the hot-rolled steel sheet manufactured by the processes of the manufacturing method a1, and subjecting or not subjecting the hot-rolled steel sheet to a first cold rolling to manufacture a steel sheet for intermediate heat treatment;

heating the steel sheet for intermediate heat treatment with the chemical composition of the steel sheet a up to a temperature equal to or more than (Ac3−20) degrees C. under conditions satisfying a formula (2) below, according to which an elapsed time in a temperature region from 700 degrees C. to (Ac3−20) degrees C. is divided into 10 parts,

subsequently, cooling the steel sheet for intermediate heat treatment from the heating temperature at an average cooling rate of at least 30 degrees C. per second in a temperature region from 700 degrees C. to 550 degrees C., cooling the steel sheet for intermediate heat at the average cooling rate of at least 20 degrees C. per second in a temperature region from the Bs point to (Bs−80) degrees C., and leaving the steel sheet for intermediate heat from (Bs−80) degrees C. to an Ms point for a dwell time of at most 1000 seconds and from the Ms point to (Ms −50) degrees C. at the average cooling rate of at most 100 degrees C. per second, subjecting or not subjecting the cooled intermediate heat-treated steel sheet to a second cold rolling at a rolling reduction of 10% or less.

Bs point (degrees C.)=611−33·[Mn]−17·[Cr]

17·[Ni]−21·[Mo]−11·[Si]

+30·[Al]+(24·[Cr]+15·[Mo]

+5500·[B]+240·[Nb])/(8·[C])

Ms point (degrees C.)=561−474[C]−33·[Mn]

−17·[Cr]−17·[Ni]−21·[Mo]

−11·[Si]+30·[Al]

[element]: mass % of each element

$\begin{matrix} [Numerical Formula 13] \\ \sum_{n = 1}^{10} 5.92 \times 10^{2} \cdot {f_{γ} (n)}^{0.3} \cdot {(1 - f_{γ} (n))}^{1.4} \cdot \exp (- \frac{9.00 \times 10^{3}}{T (n)+273}) \cdot Δ t^{0.5} \leq 1.0 & (2) \end{matrix}$

The above formula (2) is a calculation formula of dividing the elapsed time in a temperature region from 700 degrees C. to (Ac3-20) degrees C. in the heating process into 10 parts. Δt represents one tenth (second) of the elapsed time. f_γ(n) represents an average reverse transformation ratio in the n-th section. T(n) represents an average temperature (degrees C.) in the n-th section.

A method of manufacturing the high-strength steel sheet (hereinafter, occasionally referred to as “the present manufacturing method A”) excellent in formability, toughness, and weldability is a method of manufacturing the present steel sheet A.

The method includes: heating the steel sheet a (steel sheet for heat treatment) to a temperature in a range from (Ac1+25) degrees C. to an Ac3 point under conditions satisfying a formula (3) below for calculating by dividing an elapsed time in a temperature region from 700 degrees C. to an end point that is a lower one of a maximum heating temperature or (Ac3−20) degrees C. into 10 parts, and retaining the steel sheet for 150 seconds or less in a temperature region from the maximum heating temperature minus 10 degrees C. to the maximum heating temperature;

cooling the steel sheet from a heating retention temperature at an average cooling rate of at least 25 degrees C. per second in a temperature region from 700 degrees C. to 550 degrees C., and cooling the steel sheet in a limited range satisfying formulae (4) and (5) below for calculating by dividing a dwell time in a temperature region from a start point that is a lower one of 550 degrees C. or the Bs point to 300 degrees C. into 10 parts.

$\begin{matrix} [Numerical Formula 14] \\ \sum_{n = 1}^{10} 8.65 \times 10^{2} \cdot {(W_{Mn} + 0.51 W_{Cr} + 0.51 W_{Ni} - 0.64 W_{Mo} - 0.33 W_{Si} + 0.90 W_{Al})}^{0.5} \cdot {f_{γ} (n)}^{0.2} \cdot {(1 - f_{γ} (n))}^{1.8} \cdot \exp (- \frac{9.00 \times 10^{3}}{T (n) + 273}) \cdot Δ t^{0.33} \leq 2.0 & (3) \end{matrix}$

The above formula (3) is a calculation formula of dividing the elapsed time in a temperature region from 700 degrees C. to an end point, that is, the lower one of the maximum heating temperature or (Ac3−20) degrees C. in the heating process into 10 parts. Δt represents one tenth (second) of the elapsed time. W_Mrepresents a composition (mass %) of each element species. f_γ(n) represents an average reverse transformation ratio in the n-th section. T(n) represents an average temperature (degrees C.) in the n-th section.

$\begin{matrix} [Numerical Formula 15] \\ \sum_{n = 1}^{10} {1.39 \times 10^{1} \cdot {(Bs - T (n))}^{3} \cdot \exp (- \frac{1.44 \times 10^{4}}{T (n) + 273}) \cdot Δ t^{0.5}} \leq 1.0 & (4) \\ [Numerical Formula 16] \\ \sum_{n = 1}^{10} {1.56 \times 10^{2} \cdot (W_{Si} + 0.9 W_{Al} \cdot {(\frac{T (n)}{550})}^{2} + 0.3 (W_{Cr} + W_{Mo}) \cdot \frac{T (n)}{550}) \cdot \exp (- 6.7 \cdot (1 - \frac{T (n)}{550})) \cdot {(\frac{T (n) - 250}{300})}^{0.5} \cdot {(Bs - T (n))}^{3} \cdot \exp (- \frac{1.44 \times 10^{4}}{T (n) + 273}) \cdot Δ t^{0.5}} \leq 1.0 & (5) \end{matrix}$

The formulae (4) and (5) are calculation formulae by dividing the dwell time in the temperature region from the lower one (i.e., start point) of 550 degrees C. and the Bs point to 300 degrees C. into 10 parts. Δt represents one tenth (second) of the elapsed time. Bs represents the Bs point (degrees C.). T(n) represents an average temperature (degrees C.) in each step. W_Mrepresents the composition (mass %) of each elemental species.

A method of manufacturing the high-strength steel sheet (hereinafter, occasionally referred to as “the present manufacturing method A1a”) excellent in formability, toughness, and weldability is a method of manufacturing the present steel sheet A1.

The present manufacturing method Ala includes: immersing the high-strength steel sheet excellent in formability, toughness, and weldability manufactured by the present manufacturing method A in a plating bath including zinc as a main component to form a galvanized layer or a zinc alloy plated layer on one surface or both surfaces of the high-strength steel sheet.

A method of manufacturing the high-strength steel sheet (hereinafter, occasionally referred to as “the present manufacturing method A1 b”) excellent in formability, toughness, and weldability is a method of manufacturing the present steel sheet A1.

The present manufacturing method Alb includes: forming a galvanized layer or a zinc alloy plated layer by electroplating on one surface or both surfaces of the high-strength steel sheet excellent in formability, toughness, and weldability manufactured by the present manufacturing method A.

A method of manufacturing the high-strength steel sheet (hereinafter, occasionally referred to as “the present manufacturing method A2”) excellent in formability, toughness, and weldability is a method of manufacturing the present steel sheet A2.

The present manufacturing method A2 includes: heating the galvanized layer or the zinc alloy plated layer to a temperature in a range from 450 degrees C. to 550 degrees C. in the tempering treatment to perform an alloying treatment on the galvanized layer or the zinc alloy plated layer.

The steel sheet a and the manufacturing methods a1 and a2 thereof, and the present steel sheets A, A1 and A2 and the manufacturing methods A, Ala, Alb, and A2 thereof will be described.

Firstly, reasons for limiting a chemical composition of the steel sheet a and the present steel sheets A, A1, and A2 (hereinafter, occasionally collectively referred to as “the present steel sheet”) will be described. % depicted with the chemical composition means mass %.

Chemical Composition

C is in a range from 0.05 to 0.30%.

C is an element contributing to improving strength and formability. Since an effect obtainable by adding C is not sufficient at less than 0.05% of C, C is defined to be 0.05% or more. C is preferably 0.07% or more, more preferably 0.10% or more.

On the other hand, since weldability is decreased at more than 0.30% of C, C is defined to be 0.30% or less. In order to secure a favorable spot weldability, C is preferably 0.25% or less, more preferably 0.20% or less.

Si is 2.50% or less.

Si is an element contributing to improving strength and formability by making iron carbides finer, however, also embrittling steel. Since a foundry slab becomes embrittled to be susceptible to cracking and weldability is decreased at more than 2.50% of Si, Si is defined to be 2.50% or less. In order to secure impact resistance, Si is preferably 2.20% or less, more preferably 2.00% or less.

When Si is decreased to less than 0.01%, inclusive of the lower limit of 0%, coarse iron carbides are formed during transformation of bainite, thereby decreasing strength and formability. Accordingly, Si is preferably 0.005% or more, more preferably 0.010% or more.

Mn is in a range from 0.50 to 3.50%.

Mn is an element contributing to improving strength by increasing hardenability. When Mn is less than 0.50%, a soft structure is formed during a cooling step of a heat treatment, which makes it difficult to secure a required strength. Accordingly, Mn is defined to be 0.50% or more, preferably 0.80% or more, more preferably 1.00% or more.

On the other hand, when Mn exceeds 5.00%, Mn concentrates on a central part of a foundry slab, so that the foundry slab becomes embrittled to be susceptible to cracking. Moreover, an Mn-concentrated structure of the microstructure of the steel sheet is formed to deteriorate mechanical characteristics. Accordingly, Mn is defined to be 5.00% or less. In order to secure favorable mechanical characteristics and spot weldability, Mn is preferably 3.50% or less, more preferably 3.00% or less.

P is 0.100% or less.

P is an element embrittling steel or embrittling a melted portion generated by spot melting. Since the foundry slab becomes embrittled to be susceptible to cracking at more than 0.100% of P, P is defined to be 0.100% or less. In order to secure a strength of the spot melted portion, P is preferably 0.040% or less, more preferably 0.020% or less.

When P is decreased to less than 0.0001%, inclusive of the lower limit of 0%, a production cost is significantly increased. Accordingly, 0.0001% is a substantive lower limit for a practical steel sheet.

S is 0.0100% or less.

S forms MnS and is an element inhibiting formability such as ductility, hole expandability, elongation flangeability, and bendability. Since formability is significantly deteriorated at more than 0.0100% of S, S is defined to be 0.010% or less. Since S lowers the strength of the spot melted portion to secure a favorable spot weldability, S is preferably 0.007% or less, more preferably 0.005% or less.

When S is decreased to less than 0.0001%, inclusive of the lower limit of 0%, a production cost is significantly increased. Accordingly, 0.0001% is a substantive lower limit for a practical steel sheet.

Al is in a range from 0.001 to 2.000%.

Al functions as a deoxidizing element, however, is also an element embrittling steel and inhibiting spot weldability. Since a sufficient deoxidizing effect cannot be obtained at less than 0.001% of Al, Al is defined to be 0.001% or more, preferably 0.100% or more, more preferably 0.200% or more.

However, when Al exceeds 2.000%, coarse oxides are formed, so that the foundry slab becomes susceptible to cracking. Accordingly, Al is defined to be 2.000% or less. In order to secure a favorable spot weldability, Al is preferably 1.500% or less.

N is 0.0150% or less.

N forms nitrides and is an element inhibiting formability such as ductility, hole expandability, elongation flangeability, and bendability. N is also an element causing generation of blowholes to inhibit weldability during a welding process. Since formability and weldability are deteriorated at more than 0.0150% of N, N is defined to be 0.0150% or less, preferably 0.0100% or less, more preferably 0.0060% or less.

When N is decreased to less than 0.0001%, inclusive of the lower limit of 0%, a production cost is significantly increased. Accordingly, 0.0001% is a substantive lower limit for the steel sheet in practical use.

O is 0.0050% or less.

O forms oxides and is an element inhibiting formability such as ductility, hole expandability, elongation flangeability, and bendability. Since formability is significantly deteriorated at more than 0.0050% of O, O is defined to be 0.0050% or less, preferably 0.0030% or less, more preferably 0.0020% or less.

When O is decreased to less than 0.0001%, inclusive of the lower limit of 0%, a production cost is significantly increased. Accordingly, 0.0001% is a substantive lower limit for the steel sheet in practical use.

The chemical composition of each of the steel sheet a and the present steel sheet may contain the following elements in addition to the above elements in order to improve properties.

Ti is 0.30% or less.

Ti is an element contributing to improving the steel sheet strength by strengthening by precipitates, strengthening by fine grains by inhibiting growth of ferrite crystal grains, and strengthening by dislocation by inhibiting recrystallization. Since a great amount of carbonitrides are precipitated to deteriorate formability at more than 0.30% of Ti, Ti is preferably 0.30% or less, more preferably 0.150% or less.

In order to obtain a sufficient strength-improving effect by Ti, although the lower limit is 0%, Ti is preferably 0.001% or more, more preferably 0.010% or more.

Nb is 0.10% or less.

Nb is an element contributing to improving the steel sheet strength by strengthening by precipitates, strengthening by fine grains by inhibiting growth of ferrite crystal grains, and strengthening by dislocation by inhibiting recrystallization. Since a great amount of carbonitrides are precipitated to deteriorate formability at more than 0.10% of Nb, Nb is preferably 0.10% or less, more preferably 0.06% or less.

In order to obtain a sufficient strength-improving effect by Nb, Nb is preferably 0.001% or more, more preferably 0.005% or more, although the lower limit is 0%.

V is 1.00% or less.

V is an element contributing to improving the steel sheet strength by strengthening by precipitates, strengthening by fine grains by inhibiting growth of ferrite crystal grains, and strengthening by dislocation by inhibiting recrystallization. Since a great amount of carbonitrides are precipitated to deteriorate formability at more than 1.00% of V, V is preferably 1.00% or less, more preferably 0.50% or less.

In order to obtain a sufficient strength-improving effect by V, V is preferably 0.001% or more, more preferably 0.010% or more, although the lower limit is 0%.

Cr is 2.00% or less.

Cr is an element contributing to improving the steel sheet strength by improving hardenability, and the element capable of partially substituting C and/or Mn. Since hot workability is deteriorated to lower productivity at more than 2.00% of Cr, Cr is preferably 2.00% or less, more preferably 1.20% or less.

In order to obtain a sufficient strength-improving effect by Cr, Cr is preferably 0.01% or more, more preferably 0.10% or more, although the lower limit is 0%.

Ni is 2.00%

Ni is an element contributing to improving the steel sheet strength by inhibiting phase transformation at a high temperature, and the element capable of partially substituting C and/or Mn. Since weldability is decreased at more than 2.00% of Ni, Ni is preferably 2.00% or less, more preferably 1.20% or less.

In order to obtain a sufficient strength-improving effect by Ni, Ni is preferably 0.01% or more, more preferably 0.10% or more, although the lower limit is 0%.

Cu is 2.00% or less.

Cu is an element contributing to improving the steel sheet strength by being present as fine grains in steel, and the element capable of partially substituting C and/or Mn. Since weldability is decreased at more than 2.00% of Cu, Cu is preferably 2.00% or less, more preferably 1.20% or less.

In order to obtain a sufficient strength-improving effect by Cu, Cu is preferably 0.01% or more, more preferably 0.10% or more, although the lower limit is 0%.

Mo is 1.00% or less.

Mo is an element contributing to improving the steel sheet strength by inhibiting phase transformation at a high temperature, and the element capable of partially substituting C and/or Mn. Since hot workability is deteriorated to lower productivity at more than 1.00% of Mo, Mo is preferably 1.00% or less, more preferably 0.50% or less.

In order to obtain a sufficient strength-improving effect by Mo, Mo is preferably 0.01% or more, more preferably 0.05% or more, although the lower limit is 0%.

W is 1.00% or less.

W is an element contributing to improving the steel sheet strength by inhibiting phase transformation at a high temperature, and the element capable of partially substituting C and/or Mn. Since hot workability is deteriorated to lower productivity at more than 1.00% of W, W is preferably 1.00% or less, more preferably 0.70% or less.

In order to obtain a sufficient strength-improving effect by W, W is preferably 0.01% or more, more preferably 0.10% or more, although the lower limit is 0%.

B is 0.0100% or less.

B is an element contributing to improving the steel sheet strength by inhibiting phase transformation at a high temperature, and the element capable of partially substituting C and/or Mn. Since hot workability is significantly deteriorated to lower productivity at more than 0.0100% of B, B is preferably 0.0100% or less, more preferably 0.005% or less.

In order to obtain a sufficient strength-improving effect by B, B is preferably 0.0001% or more, more preferably 0.0005% or more, although the lower limit is 0%.

Sn is 1.00% or less.

Sn is an element contributing to improving the steel sheet strength by inhibiting formation of coarse crystal grains. Since the steel sheet sometimes becomes embrittled to be cracked during a rolling process at Sn exceeding 1.00%, Sn is preferably 1.00% or less, more preferably 0.50% or less.

In order to obtain a sufficient effect by adding Sn, Sn is preferably 0.001% or more, more preferably 0.010% or more, although the lower limit is 0%.

Sb is 0.20% or less.

Sb is an element contributing to improving the steel sheet strength by inhibiting formation coarse crystal grains. Since the steel sheet sometimes becomes embrittled to be cracked during a rolling process at Sb exceeding 0.20%, Sb is preferably 0.20% or less, more preferably 0.10% or less.

In order to obtain a sufficient effect by adding Sb, Sb is preferably 0.001% or more, more preferably 0.005% or more, although the lower limit is 0%.

The chemical composition of each of the steel sheet a and the present steel sheet may contain one or more of Ca, Ce, Mg, Zr, La, Hf, and REM as needed.

One or more of Ca, Ce, Mg, Zr, La, Hf, and REM are 0.0100% or less in total.

Ca, Ce, Mg, Zr, La, Hf, and REM are elements contributing to improving formability. Since ductility may be deteriorated when one or more of Ca, Ce, Mg, Zr, La, Hf, and REM exceed 0.0100% in total, one or more of Ca, Ce, Mg, Zr, La, Hf, and REM in total are preferably 0.0100% or less, more preferably 0.0070% or less.

Although the lower limit of the total of one or more of Ca, Ce, Mg, Zr, La, Hf, and REM is 0%, the total is preferably 0.0001% or more, more preferably 0.0010% or more in order to obtain a sufficient effect of improving formability.

It should be noted that REM (Rare Earth Metal) means elements belonging to lanthanoid. Although REM and Ce are often added in a form of misch metal, lanthanoid elements may be inevitably contained other than La and Ce.

In the chemical composition of each of the steel sheet a and the present steel sheet, the balance except for the above elements is Fe and inevitable impurities. The inevitable impurities are elements inevitably mixed from a raw material for steel and/or during a steel production process. As the impurities, H, Na, Cl, Sc, Co, Zn, Ga, Ge, As, Se, Y, Zr, Tc, Ru, Rh, Pd, Ag, Cd, In, Sn, Sb, Te, Cs, Ta, Re, Os, Ir, Pt, Au, and Pb may be contained at 0.010% or less in total.

Next, the microstructure of each of the steel sheet a and the present steel sheet will be described.

Difference Between Structure of Typical High-Strength Steel Sheet and Structure of Present Steel Sheet A

In a typical high-strength steel sheet, segregation of Mn progresses when the steel sheet after casting is subjected to a cooling step in a hot rolling process and a subsequent heat treatment.

As shown in FIG. 1, the structure of the high-strength steel sheet is formed such that coarse-aggregated martensite 2 formed by Mn segregation is formed in an aggregated ferrite 1, whereby a sufficient formability cannot be secured. Accordingly, in the typical high-strength steel sheet, formability is improved by utilizing austenite remaining in the structure.

In contrast, the present steel sheet A is different from the typical high-strength steel sheet in forming a structure, in which an Mn segregation portion is not formed, different from that of the typical high-strength steel sheet by controlling the cooling step in the hot rolling process, the heating step in the cold rolling process, and a temperature rise step in the heat treatment process.

As shown in FIG. 2, the structure of the present steel sheet A is formed such that a structure of acicular ferrite 3 is formed and a martensite region 4 extends in the same direction as the acicular ferrite 3 so as to be interposed therebetween. In the structure of the present steel sheet A, coarse-aggregated martensite derived from Mn segregation is less contained. Thus, a balance between formability and strength is secured by preventing formation of a coarse hard structure and using residual austenite.

Region Defining Microstructure

A microstructure in a region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from the steel sheet surface, the region centering on ¼t (t: sheet thickness) from the steel sheet surface, typifies a microstructure of the entire steel sheet, and exhibits mechanical characteristics (e.g., formability, strength, ductility, toughness, and hole expandability) corresponding to those of the entire steel sheet. In the present steel sheets A, A1, and A2 (hereinafter, collectively referred to as “the present steel sheet A”), the microstructure in the region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from the steel sheet surface is defined.

In order that the microstructure in the region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from the steel sheet surface in the present steel sheet A is made into a required microstructure by heat treatment, a microstructure in a region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from the steel sheet surface is defined same as above in the steel sheet a that is a material of the present steel sheet A.

Firstly, the microstructure in the region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from the steel sheet surface (hereinafter, also referred to as “the microstructure a”) is described. % depicted with the microstructure means volume %.

Microstructure a

80% or More of Lath Structure Including One or More of Martensite or Tempered Martensite, Bainite, and Bainitic Ferrite

The microstructure a is defined as a structure including 80% or more of a lath structure including one or more of martensite or tempered martensite, bainite, and bainitic ferrite. At the lath structure of less than 80%, even when the steel sheet a is subjected to a required heat treatment, a required microstructure cannot be obtained and mechanical characteristics excellent in formability-strength balance cannot be obtained in the present steel sheet A. Accordingly, the lath structure is defined as 80% or more, preferably 90% or more. The lath structure may account for 100%.

An area fraction of the lath structure is obtained by: collecting a test piece from each of the present steel sheet A and the steel sheet a, the test piece having, as an observation surface, a sheet thickness cross section in parallel to a rolling direction of each of the present steel sheet A and the steel sheet a; polishing the observation surface of the test piece and subsequently polishing the observation surface to a mirror surface; and obtaining an area fraction of an area of at least 2.0×10-8 m²in total in at least one view field in the region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from a surface of the test piece in sheet thickness in accordance with Electron Back Scattering Diffraction (EBSD) using Field Emission Scanning Electron Microscope (FE-SEM).

This obtaining of the area fraction depends on an orientation difference that the lath structure has inside. Specifically, a measurement step is set at 0.2 μm, a local orientation difference in surroundings in each of measurement points is mapped by Kernel Average Misorientation (KAM) method, and a 15×15 cut mesh is used to obtain an area by a point counting method.

Since a crystal structure at each measurement point can be obtained by analysis by EBSD, distribution and form of residual austenite are also evaluated by EBSD analysis method using FE-SEM.

Specifically, the EBSD analysis is performed by: collecting a test piece from each of the present steel sheet A and the steel sheet a, the test piece having, as an observation surface, a sheet thickness cross section in parallel to a rolling direction of each of the present steel sheet A and the steel sheet a; polishing the observation surface of the test piece and subsequently removing a strain-affected layer by electrolytic polishing; and setting the measurement step at 0.2 μm in an area of at least an area of at least 2.0×10⁻⁸m²in total in at least one view field in the region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from a surface in sheet thickness.

A residual austenite map is made from data obtained after the measurement. Residual austenite with an equivalent circle diameter of more than 2.0 μm and an aspect ratio of less than 2.5 is extracted to obtain an area fraction.

If the microstructure a is a lath structure, the heat treatment produces fine austenite surrounded by ferrite having the same crystal orientation at a lath boundary and the austenite grows along the lath boundary. The unidirectionally elongated austenite grown along the lath boundary during the heat treatment becomes unidirectionally elongated martensite after the heat treatment, which greatly contributes to work hardening.

The lath structure of the steel sheet a is formed by appropriately adjusting the hot rolling conditions. Formation of the lath structure is described later.

An individual volume % of martensite, tempered martensite, bainite, and bainitic ferrite varies depending on the chemical composition, hot rolling conditions, and cooling conditions of the steel sheet. Although volume % is not particularly limited, but a preferable volume % is described.

Martensite becomes tempered martensite by the heat treatment of the steel sheet for heat treatment described later, and in combination with the existing tempered martensite formed before the heat treatment, contributes to the improvement of the formability-strength balance of the present steel sheet A. On the other hand, since lath martensite is very fine, as the amount of martensite increases, a ratio of unidirectionally elongated martensite present at the ferrite grain boundary increases, and formability is sometimes rather deteriorated. Accordingly, volume % of martensite in the lath structure is preferably 80% or less, more preferably 50% or less.

Tempered martensite is a structure greatly contributing to improving the formability-strength balance of the present steel sheet A. However, sometimes, coarse carbide are formed in the tempered martensite and become isotropic austenite during subsequent heat treatment. Accordingly, volume % of the tempered martensite in the lath structure is preferably 80% or less.

Bainite and bainitic ferrite each are a structure having an excellent formability-strength balance. However, sometimes, coarse carbide are formed in the bainite and become isotropic austenite during subsequent heat treatment. Accordingly, a volume fraction of bainite in the lath structure is preferably 50% or less, more preferably 20% or less.

In the microstructure a, other structures (e.g., pearlite, cementite, aggregated ferrite, and residual austenite) is set at less than 20%.

Since aggregated ferrite does not have austenite nucleation sites in crystal grains, the aggregated ferrite becomes ferrite including no austenite in the microstructure after the heat treatment and does not contribute to improving the strength.

Moreover, aggregated ferrite sometimes does not have a specific crystal orientation relationship with mother phase austenite. When the aggregated ferrite increases, austenite having a crystal orientation significantly different from that of the mother phase austenite is sometimes formed at a boundary between the aggregated ferrite and the mother phase austenite during the heat treatment. Newly formed austenites with different crystal orientations around the ferrite grow isotropically, which does not contribute to improving mechanical characteristics.

The residual austenite in the steel sheet a does not contribute to mechanical characteristics since a part of the residual austenite becomes isotropic during the heat treatment. Moreover, pearlite and cementite are transformed into austenite during the heat treatment and grow isotropically, which does not contribute to improving mechanical characteristics. Accordingly, other structures (e.g., pearlite, cementite, aggregated ferrite, and residual austenite) is set at less than 20%, preferably less than 10%.

In particular, coarse and isotropic residual austenite grows by heating in the heat treatment of the steel sheet for heat treatment to become coarse and isotropic austenite, and becomes coarse and isotropic island-shaped martensite in the subsequent cooling, so that toughness is deteriorated.

Therefore, the volume fraction of coarse aggregated residual austenite having an equivalent circle diameter of more than 2.0 μm and an aspect ratio of less than 2.5, which is a ratio of a long axis to a short axis, is limited to 2.0% or less. The smaller amount of the residual austenite is the better. The residual austenite is preferably 1.5% or less, more preferably 1.0% or less. The residual austenite may be 0.0%.

2.0% or less of an Mn-concentrated structure containing Mn of at least (Mn % of steel sheet a)×1.50

Even if an Mn-concentrated region in the microstructure is a lath structure, the Mn-concentrated region is preferentially reverse-transformed to austenite during heating in the heat treatment of the steel sheet for heat treatment, and the transformation is unlikely to proceed in the subsequent cooling. Accordingly, residual austenite is likely to be formed. If Mn is less than (Mn % of the steel sheet a)×1.50, it is difficult to form residual austenite, so the standard for Mn concentration is defined at (Mn % of the steel sheet a)×1.50.

In the microstructure a, when the Mn-concentrated structure containing Mn (Mn % of steel sheet a)×1.50 or more exceeds 2.0%, the volume % of the residual austenite exceeds 2.0% in the microstructure of the present steel sheet A. Accordingly, the Mn-concentrated structure in the microstructure a is restricted to 2.0% or less, preferably 1.5% or less, more preferably 1.0% or less.

Next, in the present steel sheet A obtained by applying the heat treatment to the steel sheet a, the microstructure (hereinafter, also referred to as “the microstructure A”) in the region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from the steel sheet surface will be described. % depicted with the microstructure means volume %.

Microstructure A

The microstructure A is a structure mainly formed of acicular ferrite and martensite (including tempered martensite) in which aggregated ferrite is limited to 20% or less (including 0%) and residual austenite is limited to 2.0% or less (including 0%).

20% or More of Acicular Ferrite

When the lath structure of the microstructure a (one or more of martensite or tempered martensite, bainite, and bainitic ferrite: 80% or more) is subjected to the required heat treatment, the lath-shaped ferrite is united into acicular ferrite, and austenite grains unidirectionally elongated are formed at the crystal grain boundary.

Further, when the cooling treatment is performed under predetermined conditions, the austenite unidirectionally elongated becomes a martensite region unidirectionally elongated, thereby improving the formability-strength balance of the microstructure A.

When the volume fraction of the acicular ferrite is less than 20%, a sufficient effect cannot be obtained, an isotropic martensite region is significantly increased, and the formability-strength balance of the microstructure A is deteriorated. Accordingly, the volume fraction of the acicular ferrite is defined as 20% or more. In order to particularly improve the formability-strength balance, the volume fraction of the acicular ferrite is preferably 30% or more.

On the other hand, when the volume fraction of the acicular ferrite exceeds 90%, the volume fraction of martensite is decreased, so that the volume fraction of martensite cannot be made to 10% or more as described later and the strength is significantly lowered. Accordingly, the volume fraction of the acicular ferrite is 90% or less. In order to increase the strength, it is preferable to decrease the volume fraction of the acicular ferrite while increasing the volume fraction of martensite. From this viewpoint, the volume fraction of the acicular ferrite is preferably 75% or less, more preferably 60% or less.

10% or More of Martensite

Martensite is a structure of improving the steel sheet strength. When martensite is less than 10%, a required steel sheet strength cannot be secured in terms of the formability-strength balance. Accordingly, martensite is defined at 10% or more, preferably 20% or more.

On the other hand, when the volume fraction of martensite exceeds 80%, the volume fraction of acicular ferrite cannot arrive at 20% or more as described above to weaken restraint by ferrite, resulting in an isotropic form of the martensite region. Accordingly, the volume fraction of martensite is defined as 80% or less. In order to particularly improve the formability-strength balance, the volume fraction of acicular ferrite is preferably limited to 50% or less, more preferably 35% or less.

30% or More of Tempered Martensite with Precipitated Fine Carbides in Martensite

When martensite is tempered martensite containing fine carbides, resistance of martensite to cracking is significantly improved, and further, martensite also has a sufficient strength, thereby improving the formability-strength balance. In order to obtain this effect, a ratio of tempered martensite containing fine carbides in martensite is preferably 30% or more. The larger ratio of the tempered martensite is preferable. The ratio is more preferably 50% or more and may be 100%.

However, when the tempering excessively proceeds and an average diameter of carbides in martensite exceeds 1.0 μm, the carbides act as a propagation path of crack and rather deteriorates the resistance to cracking.

When the average diameter of carbides is 1.0 μm or less, fracture toughness is not deteriorated, thereby exhibiting the effects of the invention. Since the strength of carbides is lowered when the carbides become large, the average diameter of the carbides is preferably 0.5 μm or less in order to attain both strength and toughness. Although the effects of the invention can be obtained without carbides, it is preferable that martensite contains fine carbides in terms of toughness.

The martensite can be obtained by heating the steel sheet a under predetermined conditions to generate austenite extending in one direction from the lath structure, and then cooling the steel sheet a under predetermined conditions to transform the austenite into martensite. The martensite has such an island-shaped structure that is divided by acicular ferrite and extends in one direction. Since the martensite extends in one direction, the concentration of strain becomes gentle and local cracking is less likely to occur, so that formability is improved.

On the other hand, since coarse and isotropic island-shaped martensite is easily cracked by strain applied, when a density of the martensite is high, brittle fracture at impact is likely to occur, a ductile brittle transition temperature rises significantly to deteriorate toughness.

In order to avoid deterioration of toughness, the size and form of the island-shaped martensite need to satisfy the following formula (A).

$\begin{matrix} [Numerical Formula 17] \\ \sum_{i = 1}^{5} \frac{d_{i}}{{a_{i}}^{1.5}} \leq 10.0 & (A) \end{matrix}$

Here, d_irepresents an equivalent circle diameter [pm] of the i-th largest island-shaped martensite in the microstructure in the region of ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness), and a_irepresents an aspect ratio of the i-th largest island-shaped martensite in the microstructure in the region of ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness). This formula is for evaluating the local cracking occurrence and the risk of connecting the cracks to each other, regarding the island-shaped martensite in which cracks occur preferentially in the initial stage of cracking occurrence and propagation of the cracks. Since initial cracking occurs only in coarse island-shaped martensite, the risk of the initial cracking only needs to be evaluated for relatively large island-shaped martensite. Specifically, in the observation of the microstructure in the exemplary embodiment of the invention, the risk may be evaluated up to the fifth largest island-shaped martensite.

As the size of the island-shaped martensite becomes larger and/or as the aspect ratio becomes smaller, that is, as the martensite is more equiaxed, the value in the left side of the formula becomes larger and toughness is deteriorated. When the value in the left side exceeds 10.0, predetermined characteristics are not exhibited.

As the density of coarse island-shaped martensite increases, the size of the second and subsequent island-shaped martensite increases, and the value on the left side of the formula (A) increases, so that brittle fracture is likely to occur.

As the value of the formula (A) is smaller, local cracking and connection are less likely to occur, and thus, a ductile brittle transition temperature is decreased to preferably improve toughness. A value of the left side of the formula (A) is preferably 7.5 or less, more preferably 5.0 or less.

When the equivalent circle diameter of the largest island-shaped martensite is 1.0 μm or less, all d_iare 1.0 or less and the aspect ratio a_iis always 1.0 or more. Accordingly, the left side of the formula (A) is always 5.0 or less. Therefore, the evaluation of the formula (A) may be omitted when the equivalent circle diameter of the largest island-shaped martensite is 1.0 μm or less.

20% or Less of Aggregated Ferrite

Aggregated ferrite is a structure that competes with acicular ferrite. Since acicular ferrite decreases as aggregated ferrite increases, the volume fraction of aggregated ferrite is limited to 20% or less. The smaller volume fraction of aggregated ferrite is preferable. The volume fraction thereof may be 0%.

2.0% or Less of Residual Austenite

Residual austenite transforms into extremely hard martensite upon impact and acts strongly as a propagation path for brittle fracture. When residual austenite exceeds 2.0%, the absorption energy at the time of brittle fracture is significantly reduced, the progress of fracture cannot be sufficiently suppressed, and toughness is significantly deteriorated. Therefore, residual austenite is defined at 2.0% or less. This is the characteristic of microstructure A. Volume % of residual austenite is preferably 1.6% or less, more preferably 1.2% or less, and may be 0.0%.

Balance: Inevitable Generation Phase

The balance of the microstructure A is bainite, bainitic ferrite and/or an inevitable generation phase. Bainite and bainitic ferrite are structures having an excellent balance between strength and formability, and may be contained in the microstructure as long as a sufficient amount of acicular ferrite and martensite are secured.

If a total of the volume fractions of bainite and bainitic ferrite exceeds 60%, the fraction of acicular ferrite and/or martensite may not be sufficiently obtained. Therefore, the total of the volume fractions of bainite and bainite is preferably 60% or less.

The inevitable generation phase in the balance structure of the microstructure A is pearlite, cementite and the like. As the amount of pearlite and/or cementite increases, ductility decreases and the formability-strength balance decreases. Therefore, the volume fraction of structure other than the above-mentioned all structures (pearlite and/or cementite, etc.) is preferably 5% or less.

By making the microstructure A mainly including the above-mentioned form of ferrite, martensite of 10% or more, and residual austenite of 2% or less, excellent toughness and excellent formability-strength balance can be attained. Therefore, the ductile-brittle transition temperature of the microstructure A reaches −40 degrees C. or less, and the absorption energy after the ductile-brittle transition is equal to or more than (the absorption energy before the ductile-brittle transition)×0.15.

In the above chemical composition, in the spot welded portion of the present steel sheet A having the microstructure A, a cross joint strength can achieve the tensile shear strength×0.25 or more. It is presumed that this is because the form of the microstructure at thermally affected portion at the welding point inherits the form of the acicular ferrite and martensite regions, and the fracture resistance of thermally affected portion is improved.

Here, a method of determining the volume fraction (volume %) of the structure will be described.

A test piece having a sheet thickness cross section parallel to the rolling direction of the steel sheet as the observation surface is collected from each of the present steel sheet A and the steel sheet for heat treatment (steel sheet a). A fraction of the lath structure is obtained by: polishing the observation surface of the test piece and subsequently applying Nital etching to the observation surface; observing an area of at least 2.0×10⁻⁹m²in total in at least one view field in the region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from a surface in sheet thickness using Field Emission Scanning Electron Microscope (FE-SEM); and analyzing an area fraction (area %) of each structure.

Since it is empirically known that the area fraction (area %) Q volume fraction (volume %), the area fraction is used as the volume fraction. The acicular ferrite in the microstructure A refers to ferrite having the aspect ratio of 3.0 or more, which is the ratio of the major axis to the minor axis of the crystal grains, in the observation by FE-SEM. Further, similarly, aggregated ferrite refers to ferrite having the aspect ratio of less than 3.0.

The volume fraction of residual austenite in the microstructure of the present steel sheet A is analyzed by X-ray diffraction. In the region from ⅛t (t: sheet thickness) to ⅜t (t: sheet thickness) from the surface in the sheet thickness of the test piece, the surface parallel to the steel sheet surface is finished to be a mirror surface, and the area fraction of FCC iron is analyzed by X-ray diffraction method. The area fraction is used as the volume fraction of the residual austenite.

The diameter of the carbide contained in the tempered martensite is measured in the same view field as in the measurement of the structure fraction by FE-SEM. In at least one view field, the tempered martensite with a total area of at least 1.0×10⁻¹⁰m²is observed at a magnification of 20,000 times, the equivalent circle diameter is measured for any 30 carbides, and the simple average is regarded as the average diameter of carbides in tempered martensite in the material.

Fine carbides that cannot be detected at a magnification of 20,000 times are ignored in the derivation of the average diameter because such carbides do not act as a propagation path for brittle fracture. Specifically, carbides that are judged to have an equivalent circle diameter of less than 0.1 μm are ignored when calculating the average diameter of carbides.

The present steel sheet A may be a steel sheet having a galvanized layer or a zinc alloy plated layer on one or both surfaces of the steel sheet (the present steel sheet A1), or may be a steel sheet having an alloyed plated layer obtained by alloying the galvanized layer or the zinc alloy plated layer (the present steel sheet A2). Description will be made below.

Galvanized Layer and Zinc Alloy Plated Layer

The plated layer formed on one or both surfaces of the present steel sheet A is preferably a galvanized layer or a zinc alloy plated layer containing zinc as a main component. The zinc alloy plated layer preferably contains Ni as an alloy component.

The galvanized layer and the zinc alloy plated layer are formed by a hot-dip plating method or an electroplating method. When the Al amount of the galvanized layer increases, the adhesion between the steel sheet surface and the galvanized layer decreases. Therefore, the Al amount of the galvanized layer is preferably 0.5 mass % or less. When the galvanized layer is a hot-dip galvanized layer, an Fe amount of the hot-dip galvanized layer is preferably 3.0 mass % or less in order to improve the adhesion between the steel sheet surface and the galvanized layer.

When the galvanized layer is an electrogalvanized layer, an Fe amount of the electrogalvanized layer is preferably 5.0 mass % or less in order to improve corrosion resistance.

The galvanized layer and the zinc alloy plated layer may contain one or more of Ag, B, Be, Bi, Ca, Cd, Co, Cr, Cs, Cu, Ge, Hf, Zr, I, K, La, Li, Mg, Mn, Mo, Na, Nb, Ni, Pb, Rb, Sb, Si, Sn, Sr, Ta, Ti, V, W, Zr, and REM as long as corrosion resistance and formability are not inhibited. Especially, Ni, Al, and Mg are effective for improving corrosion resistance.

Alloyed Plated Layer

The galvanized layer or zinc alloy plated layer is subjected to the alloying treatment to form an alloyed plated layer on the steel sheet surface. When a hot-dip galvanized layer or hot-dip zinc alloy plated layer is subjected to the alloying treatment, an Fe amount of the hot-dip galvanized layer or hot-dip zinc alloy plated layer is preferably in a range from 7.0 to 13.0 mass % in order to improve adhesion between the steel sheet surface and the alloyed plated layer.

The sheet thickness of the present steel sheet A, which is not particularly limited to a specific range of the sheet thickness, is preferably in a range from 0.4 to 5.0 mm in consideration of applicability and productivity. When the sheet thickness is less than 0.4 mm, the shape of the steel sheet is difficult to keep flat and dimensional and shape accuracy is lowered. Accordingly, the sheet thickness is 0.4 mm or more, more preferably 0.8 mm or more.

On the other hand, when the sheet thickness exceeds 5.0 mm, it becomes difficult to control the heating conditions and the cooling conditions during the manufacturing process, and a homogeneous microstructure may not be obtained in the sheet thickness direction. Accordingly, the sheet thickness is preferably 5.0 mm or less, more preferably 4.5 mm or less.

Next, the manufacturing methods a1 and a2 of the steel sheet a, and the manufacturing methods A, A1a, A1 b, and A2 of the invention will be described.

Firstly, the manufacturing method a1 and the manufacturing method a2 of the steel sheet for heat treatment (steel sheet a) that is a material of the present steel sheet A will be described.

The manufacturing method a1 includes:

subjecting a steel piece having the chemical composition of the steel sheet a to hot rolling, completing the hot rolling at a temperature in a range from 850 degrees C. to 1050 degrees C. to provide a steel sheet after the hot rolling,

cooling the steel sheet after the hot rolling at an average cooling rate of at least 30 degrees C. per second in a range from 850 degrees C. to 550 degrees C., winding the steel sheet after the hot rolling at a temperature equal to or less than Bs point that is a bainite transformation start point defined according to a formula below,

cooling the steel sheet in a range from the Bs point to a point of (the Bs point −80 degrees C.) under conditions satisfying a formula (1) below to provide a hot-rolled steel sheet, and

subjecting or not subjecting the hot-rolled steel sheet to cold rolling with a rolling reduction of 10% or less, thereby providing a steel sheet for heat treatment.

Bs point (degrees C.)=611−33·[Mn]−17·[Cr]

−17·[Ni]−21·[Mo]−11·[Si]

+30·[Al]+(24·[Cr]+15·[Mo]

+5500·[B]+240·[Nb])/(8·[C])

[element]: mass % of each element

$\begin{matrix} [Numerical Formula 18] \\ \sum_{n = 1}^{g} {5.37 \times 10^{- 1} \cdot {(10 n + 925 - Bs - 57 W_{Cr} - 78 W_{Mn} - 39 W_{Si} + 56 W_{Al} - 41 W_{Ni} - 1598 \sqrt{W_{B}})}^{2.5} \cdot \exp (\frac{1.44 \times 10^{4}}{10 n - Bs - 278}) \cdot \exp (- 5.5 W_{Nb} - 2.0 W_{Ti} - 0.2 W_{Cr} - 1.1 W_{Mo}) \cdot Δ {t (n)}^{1 / 3} + 1.81 \times 10^{1} \cdot {(10 n - 5)}^{1.3} \cdot \exp (\frac{1.73 \times 10^{4}}{10 n - Bs - 278}) \cdot \exp (- 1.1 W_{Mo} - 0.6 W_{Cr} - 9.0 \sqrt{W_{B}}) \cdot Δ {t (n)}^{1 / 2}} \leq 1.50 & (1) \end{matrix}$

heating the steel sheet for intermediate heat treatment with the chemical composition of the steel sheet a up to a temperature equal to or more than (Ac3−20) degrees C. at an average heating rate satisfying a formula (2) below, according to which an elapsed time in a temperature region from 700 degrees C. to (Ac3−20) degrees C. is divided into 10 parts, subsequently,

cooling the steel sheet for intermediate heat treatment from the heating temperature at an average cooling rate of at least 30 degrees C. per second in a temperature region from 700 degrees C. to 550 degrees C., cooling the steel sheet at the average cooling rate of at least 20 degrees C. per second in a temperature region from the Bs point to (Bs−80) degrees C., leaving the steel sheet from (Bs−80) degrees C. to Ms point for a dwell time of at most 1000 seconds and from the Ms point to (Ms−50) degrees C. at the average cooling rate of at most 100 degrees C. per second (hereinafter, also referred to as the “intermediate heat treatment”), and subjecting or not subjecting the cooled intermediate-heated steel sheet to a second cold rolling at the rolling reduction of 10% or less, thereby manufacturing the steel sheet for heat treatment.

Bs point (degrees C.)=611−33·[Mn]−17·[Cr]

−17−[Ni]−21 ·[Mo]−11·[Si]

+30−[Al]+(24·[Cr]+15·[Mo]

+5500−[B]+240·[Nb])/(8·[C])

Ms point (degrees C.)=561−474[C]−33·[Mn]

−17·[Cr]−17·[Ni]−21·[Mo]

−11·[Si]+30·[Al]

[element]: mass % of each element

$\begin{matrix} [Numerical Formula 19] \\ \sum_{n = 1}^{10} 5.92 \times 10^{2} \cdot {f_{Y} (n)}^{0.3} \cdot {(1 - f_{Y} (n))}^{1.4} \cdot \exp (- \frac{9.00 \times 10^{3}}{T (n) + 273}) \cdot Δ t^{0.5} \leq 1.0 & (2) \end{matrix}$

Process conditions of the manufacturing method a1 will be described.

Hot Rolling

Molten steel having the chemical composition of the steel sheet a is cast according to a typical method such as continuous casting or thin slab casting to manufacture a steel piece intended for hot rolling. When the steel piece is once cooled to the room temperature and then subjected to hot rolling, the heating temperature is preferably in a range from 1080 degrees C. to 1300 degrees C.

When the heating temperature is less than 1080 degrees C., coarse inclusions due to casting do not melt and the hot-rolled steel sheet may crack in the process after hot rolling. Accordingly, the heating temperature is preferably 1080 degrees C. or more, more preferably 1150 degrees C. or more.

When the heating temperature exceeds 1300 degrees C., a large amount of heat energy is required. Accordingly, the heating temperature is preferably 1300 degrees C. or less, more preferably 1230 degrees C. or less. After casting the molten steel, the steel piece in the temperature region from 1080 degrees C. to 1300 degrees C. may be directly subjected to hot rolling.

Hot Rolling Completion Temperature: From 850 Degrees C. to 1050 Degrees C.

Hot rolling is completed at the temperature in a range from 850 degrees C. to 1050 degrees C. When the hot rolling completion temperature is less than 850 degrees C., a rolling reaction force increases and it becomes difficult to stably secure a dimensional accuracy of a shape and a sheet thickness. Therefore, the hot rolling completion temperature is defined as 850 degrees C. or more, preferably 870 degrees C. or more.

On the other hand, when the hot rolling completion temperature exceeds 1050 degrees C., a steel sheet-heating device is required, resulting in an increase in a rolling cost. Therefore, the hot rolling completion temperature is defined as 1050 degrees C. or less, more preferably 1000 degrees C. or less.

Average Cooling Rate From 850 Degrees C. To 550 Degrees C.: At Least 30 Degrees C. Per Second

The steel sheet obtained after the completion of the hot rolling is cooled starting from 850 degrees C. to reach at most 550 degrees C. at the average cooling rate of at least 30 degrees C. per second. When the average cooling rate is less than 30 degrees C. per second, ferrite transformation proceeds and aggregated ferrite is formed not to obtain a sufficient lath structure in the steel sheet a. Therefore, the average cooling rate of the steel sheet, which is obtained after the hot rolling is completed, starting from 850 degrees C. to reach 550 degrees C. is defined as at least 30 degrees C. per second. In order to reduce the aggregated ferrite in the present steel sheet A, the average cooling rate in a range from 850 degrees C. to 550 degrees C. is preferably at least 40 degrees C. per second.

Winding Temperature: Equal to or Less than Bs Point

The steel sheet obtained after the hot rolling is cooled to at most 550 degrees C. at the average cooling rate of at least 30 degrees C. per second in a range from 850 degrees C. to 550 degrees C. and is wound at a temperature equal to or less than the Bs point that is a bainite transformation start point defined according to a formula below.

Bs point (degrees C.)=611−33·[Mn]−17·[Cr]

−17·[Ni]−21·[Mo]−11·[Si]

+30·[Al]+(24·[Cr]+15·[Mo]

+5500·[B]+240−[Nb])/(8−[C])

[element]: mass % of each element.

When the steel sheet obtained after the hot rolling is wound at a temperature higher than the Bs point (degrees C.), ferrite transformation proceeds excessively during winding, and aggregated ferrite is formed to obtain no lath structure in the microstructure. Also, an Mn-concentrated structure is formed at exceeding 2.0 volume %. The winding temperature is preferably equal to or less than (Bs point −80) degrees C.

Temperature History from Bs Point to (Bs Point−80 Degrees C.): Formula (1)

During the period from cooling after hot rolling through winding to cooling, especially in the temperature region from the Bs point to (Bs point −80) degrees C., the bainite transformation tends to proceed locally from some austenite grain boundary, and diffusion of Mn atoms tends to proceed in the temperature region of 400 degrees C. or more. Accordingly, concentration of Mn in the hot-rolled steel sheet from the region where the transformation is completed tends to proceed to the untransformed austenite.

Since the bainite transformation proceeds locally in this hot-rolled steel sheet, untransformed austenite in which Mn is concentrated is also localized, and a part of the concentrated portion of Mn becomes coarse aggregated residual austenite.

The formula (1) represents a tendency of Mn concentration in the temperature region, and is a formula in empirically considering a progress rate of bainite transformation, a rate of Mn concentration, and the degree of uneven distribution of bainite. When the left side of the formula (1) exceeds 1.50, the phase transformation in the hot-rolled steel sheet progresses locally and excessively, and Mn concentration to untransformed austenite progresses excessively, so that the hot-rolled steel sheet has many Mn-concentrated parts and coarse aggregated residual austenite.

Therefore, the value of the formula (1) in the temperature region from the Bs point to (Bs point −80) degrees C. is limited to 1.50 or less. As the value of the formula (1) is smaller, it is more difficult for the Mn concentration to proceed. Therefore, the value of the formula (1) is preferably 1.20 or less, and more preferably 1.00 or less. In the temperature region below (Bs point −80) degrees C., the rate of progress of bainite transformation is sufficiently higher than the rate of Mn concentration, and the concentration of Mn in the untransformed part can be ignored. Moreover, since the bainite transformation also starts from a lot of austenite grain boundaries, the localization of untransformed austenite does not proceed in the hot-rolled steel sheet.

Winding may be performed at the temperature in a range from the Bs point to (Bs point −80 degrees C.). The temperature measurement at that time is performed as follows.

The temperature before winding is measured on the sheet surface at the center of the steel sheet from a vertical direction of the sheet surface. A radiation thermometer is used for the measurement. In the temperature history after winding, a point at the center of the ring-shaped circumferential cross section wound in a coil is defined as a representative point. The temperature history at this representative point is used.

When winding the coil, a contact-type temperature system (thermocouple) is wound around a position corresponding to the representative point, and direct measurement is performed.

Alternatively, heat transfer calculation may be performed to obtain the temperature history of the coil after winding at the representative point. In this case, a radiation thermometer and/or a contact-type temperature system is used for the measurement, and the temperature history on a lateral side and/or a surface of the coil is measured.

$\begin{matrix} [Numerical Formula 20] \\ \sum_{n = 1}^{g} {5.37 \times 10^{- 1} \cdot {(10 n + 925 - Bs - 57 W_{Cr} - 78 W_{Mn} - 39 W_{Si} + 56 W_{Al} - 41 W_{Ni} - 1598 \sqrt{W_{B}})}^{2.5} \cdot \exp (\frac{1.44 \times 10^{4}}{10 n - Bs - 278}) \cdot \exp (- 5.5 W_{Nb} - 2.0 W_{Ti} - 0.2 W_{Cr} - 1.1 W_{Mo}) \cdot Δ {t (n)}^{1 / 3} + 1.81 \times 10^{1} \cdot {(10 n - 5)}^{1.3} \cdot \exp (\frac{1.73 \times 10^{4}}{10 n - Bs - 278}) \cdot \exp (- 1.1 W_{Mo} - 0.6 W_{Cr} - 9.0 \sqrt{W_{B}}) \cdot Δ {t (n)}^{1 / 2}} \leq 1.50 & (1) \end{matrix}$

The above formula (1) is used for a calculation in the temperature region from the Bs point to (Bs point −80) degrees C. in a duration from cooling after hot rolling through winding to cooling. In the formula (1), Bs represents the Bs point (degrees C.), W_Mrepresents the composition (mass %) of each elemental species, and Δt(n) represents the elapsed time (seconds) from (Bs−10×(n−1)) degrees C. to (Bs−10×n) degrees C. 1 to 8 are assigned for n in the calculation. However, since the diffusion rate of Mn is low and the concentration of Mn does not proceed in the temperature region of 400 degrees C. or less, the calculation using the subsequent n is not included in the total when (Bs−10×n) degrees C. is below 400 degrees C. For instance, when Bs is 455 degrees C., the formula (1) indicates the total of the calculation using from n=1 to n=6.

As the cooling rate in the temperature region from the Bs point to (Bs point −80) degrees C. is higher, the value of the formula (1) becomes smaller, thereby inhibiting the concentration of Mn. However, when the steel sheet wound in a coil is cooled rapidly, the shape of the steel sheet collapses, making it difficult to temper and pickle the steel sheet. Accordingly, the average cooling rate after winding the steel sheet in a coil is preferably equal to or less than 10 degrees C. per second. From the viewpoint of the shape of the steel sheet, it is preferable to allow the coil after winding to cool as long as the formula (1) can be satisfied.

In particular, when the above formula (1) is not satisfied in the cooling process in the temperature region from the Bs point to (Bs point −80) degrees C., the bainite transformation starts locally from some austenite grain boundaries and aggregated untransformed austenite remains in the steel sheet a, resulting in aggregated residual austenite. The value of the formula (1) in the temperature region is preferably 1.20 or less, and more preferably 1.00 or less.

Tempering of Hot-Rolled Steel Sheet

Since the wound hot-rolled steel sheet has high strength, the hot-rolled steel sheet may be subjected to a tempering treatment at an appropriate temperature and time in order to increase productivity in a cutting process before a final heat treatment.

In the manufacturing method a1, the hot-rolled steel sheet may be cold-rolled with the rolling reduction of 10% or less to provide a steel sheet for heat treatment. However, when the rolling reduction at cold rolling exceeds 10%, the grain boundaries of the lath structure are excessively distorted. When the steel sheet is heated here, a part of the lath structure is recrystallized during heating to become aggregated ferrite, so that acicular ferrite cannot be obtained by the heat treatment.

Process conditions of the manufacturing method a2 will be described.

Hot-Rolled Steel Sheet Further Subjected to Cold Rolling and Heat Treatment

The manufacturing method a2 includes: subjecting or not subjecting the hot-rolled steel sheet manufactured by the same steps as those of the manufacturing steps of the hot-rolled steel sheet according to the above manufacturing method a1: to the cold rolling (hereinafter, sometimes referred to as the “first cold rolling”) to manufacture the steel sheet for the intermediate heat treatment; to the heat treatment (hereinafter, sometimes referred to as the “intermediate heat treatment”) for suppressing the cold rolling from affecting the structure; and as needed, for instance, further to the cold rolling with the rolling reduction of 10% or less (hereinafter, sometimes referred to as a “second cold rolling”) to manufacture the steel sheet a. The hot-rolled steel sheet to be subjected to the first cold rolling and the intermediate heat treatment may be any hot-rolled steel sheet having the chemical composition of the steel sheet a and manufactured according to the same process as the hot-rolled steel sheet manufacturing process of the manufacturing method a1. Since the following intermediate heat treatment is performed, the rolling reduction for the first cold rolling can be more than 10%.

The hot-rolled steel sheet may be pickled at least once before the intermediate heat treatment. When oxides on the surface of the hot-rolled steel sheet are removed and cleaned by pickling, plating properties of the steel sheet are improved.

The hot-rolled steel sheet after pickling is subjected or not subjected to the first cold rolling before the intermediate heat treatment to obtain a steel sheet for intermediate heat treatment. The first cold rolling improves the shape and dimensional accuracy of the steel sheet. However, if the total rolling reduction exceeds 85%, the ductility of the steel sheet decreases and the steel sheet may crack during the cold rolling. Therefore, the total rolling reduction is preferably 80% or less, more preferably 75% or less.

When the cold rolling with the rolling reduction exceeding 10% is applied to the lath structure, the grain boundaries of the lath structure are excessively distorted. When the steel sheet is heated here, a part of the lath structure is recrystallized during heating to become aggregated ferrite, so that acicular ferrite cannot be obtained by the heat treatment. When the cold rolling with the rolling reduction exceeding 10% is performed to obtain a steel sheet having the required sheet thickness and/or shape, a heat treatment for obtaining a lath structure is required prior to the heat treatment for obtaining acicular ferrite.

When the total rolling reduction is less than 0.05%, the shape and dimensional accuracy of the steel sheet do not improve, and the steel sheet temperature becomes non-uniform during the subsequent heat treatment and cooling treatment, resulting in a reduced ductility and a poor appearance of the steel sheet. Therefore, the total rolling reduction is preferably 0.05% or more, more preferably 0.10% or more. The total rolling reduction is preferably 20% or more in order to make the structure finer by recrystallization in the subsequent heat treatment process. When the rolling reduction in the cold rolling is 10% or less as described above, the following heat treatment may or may not be performed thereafter, and in that case, the manufacturing method is equivalent to that of the manufacturing method a1.

When the hot-rolled steel sheet is cold-rolled, the steel sheet may be heated before rolling or between rolling passes. This heating softens the steel sheet, reduces the rolling reaction force during rolling, and improves the shape and dimensional accuracy of the steel sheet. The heating temperature is preferably 700 degrees C. or less. When the heating temperature exceeds 700 degrees C., a part of the microstructure becomes aggregated austenite, Mn segregation proceeds, and a coarse aggregated Mn concentrated region is formed. Therefore, the structure of the steel sheet a falls out of the predetermined structure, and the structure is not suitable as the steel sheet for heat treatment.

This aggregated Mn-concentrated region becomes untransformed austenite and remains aggregated even in a firing process, and an aggregated and coarse hard structure is formed in the steel sheet, resulting in deterioration in ductility. When the heating temperature is less than 300 degrees C., a sufficient softening effect cannot be obtained. Accordingly, the heating temperature is preferably 300 degree C. or more. The pickling may be performed before or after the heating.

Steel-sheet-heating temperature: (Ac3−20) degrees C. or more

Temperature region with limited heating rate: from 700 degrees C. to (Ac3−20) degrees C.

Heating in above temperature region: Formula (2) below

The cold-rolled steel sheet (also the hot-rolled steel sheet may be used) is heated to (Ac3-20) degrees C. or more. When the steel-sheet-heating temperature (i.e., the heating temperature of the steel sheet) is less than (Ac3−20) degrees C., coarse ferrite remains during heating and isotropically grows to form aggregated ferrite during the subsequent cooling, resulting in a significant decline of mechanical characteristics of the high-strength steel sheet of the invention. Therefore, the steel-sheet-heating temperature is defined as (Ac3−20) degrees C. or more, preferably (Ac3−15) degrees C. or more, more preferably (Ac3+5) degrees C. or more.

Further, Ac3 and later-described Ac1 of the invention are obtained by: cutting out small pieces from the steel sheet before various heat treatments; removing an oxide layer on the surface of the steel sheet by polishing or pickling with hydrochloric acid, subsequently heating the small pieces up to 1200 degrees C. at the heating rate of 10 degrees C. per second in a vacuum environment of 10⁻¹MPa or less; and measuring a volume change behavior during heating using a laser displacement meter.

The upper limit of the steel-sheet-heating temperature is not particularly specified, but from the viewpoint of inhibiting the coarsening of crystal grains and reducing the heating cost, the upper limit is 1050 degrees C., and 1000 degrees C. or less is preferable.

Regarding the treatment time, a dwell time in the section from (maximum heating temperature −10) degrees C. to the maximum heating temperature may be short and may be less than 1 second, but if it is cooled immediately after heating, temperature unevenness may occur inside the steel sheet to deteriorate the shape of the steel sheet. Therefore, the treatment time is preferably 1 second or more.

On the other hand, if the dwell time in this temperature section becomes excessively long, the structure may become coarse and toughness of the final product may be deteriorated. From this viewpoint, the dwell time is preferably 10000 seconds or less. Since prolonging the dwell time increases the heat treatment cost, the dwell time is preferably 1000 seconds or less.

In heating, the steel sheet (the steel sheet for intermediate heat treatment) is heated under conditions satisfying the formula (2) below in a temperature region from 700 degrees C. to (Ac3−20) degrees C. By this heating, a base structure for forming the microstructure of the steel sheet a into a lath structure can be formed.

If the formula (2) is not satisfied, Mn segregation proceeds during heating, a coarse aggregated Mn-concentrated region is formed, and the mechanical characteristics after the heat treatment are deteriorated. The heating conditions need to satisfy the formula (2). The value of the formula (2) is preferably limited to 0.8 or less.

$\begin{matrix} [Numerical Formula 21] \\ \sum_{n = 1}^{10} 5.92 \times 10^{2} \cdot {f_{Y} (n)}^{0.3} \cdot {(1 - f_{Y} (n))}^{1.4} \cdot \exp (- \frac{9.00 \times 10^{3}}{T (n) + 273}) \cdot Δ t^{0.5} \leq 1.0 & (2) \end{matrix}$

The above formula (2) is a formula expressing the Mn concentration behavior in a region where a BCC phase represented by ferrite and an FCC phase represented by austenite coexist. As the value on the left side of the formula is larger, Mn is more concentrated. The reverse transformation rate f_γ(n) during heating can be obtained by cutting out small pieces from the material before the heat treatment, performing a heat treatment test in advance, and measuring a volume expansion behavior during heating.

Average Cooling Rate From 700 Degrees C. To 550 Degrees C.: At Least 30 Degrees C. Per Second

The steel sheet for intermediate heat treatment (cold-rolled steel sheet or hot-rolled steel sheet) is heated up to (Ac3−20) degrees C. or more, and subsequently, cooled at the average cooling rate of at least 30 degrees C. per second in the temperature region from 700 degrees C. to 550 degrees C. When the average cooling rate is less than 30 degrees C. per second, ferrite transformation proceeds and coarse aggregated ferrite is formed, so that the lath structure cannot be obtained in the steel sheet a. The average cooling rate is preferably at least 40 degrees C. per second. Although a desired steel sheet for heat treatment can be obtained without setting the upper limit of the cooling rate, at most 200 degrees C. per second is preferable from the viewpoint of cost.

Average Cooling Rate From Bs Point To (Bs-80) Degrees C.: At Least 20 Degrees C. Per Second

In the cooling process in the manufacturing method a2, the particle diameter of a mother phase is finer than that in the cooling process in the manufacturing method a1, and the transformation is likely to proceed at or less than the Bs point. Since the time required for transformation is short, Mn concentration is unlikely to occur, but on the other hand, transformation in the temperature region proceeds locally even in the heat treatment, so that aggregated untransformed austenite tends to remain. From the latter point of view, the cooling rate at or less than the Bs point in the manufacturing method a2 has a smaller tolerance than that in the manufacturing method a1.

When the average cooling rate is less than 20 degrees C. per second in the cooling process in the temperature region from the Bs point to (Bs point −80) degrees C., the bainite transformation starts locally from some austenite grain boundaries and aggregated untransformed austenite remains, resulting in aggregated residual austenite. Therefore, the average cooling rate is set at at least 20 degrees C. per second in the above temperature region. The average cooling rate is preferably at least 30 degrees C. per second. Although a desired steel sheet for heat treatment can be obtained without setting the upper limit of the cooling rate, at most 200 degrees C. per second is preferable from the viewpoint of cost.

Dwell Time From (Bs-80) Degrees C. To Ms Point: 1000 Seconds or Less

In the manufacturing method a2, the particle diameter of the mother phase is fine, and transformation easily proceeds at or less than the Bs point as compared with the manufacturing method a1. Therefore, if the dwell time from (Bs-80) degrees C. to the Ms point is long, bainite transformation locally progresses, and aggregated untransformed austenite may remain, resulting in aggregated residual austenite. The dwell time referred to here also includes a time during which the temperature is maintained within the temperature region of (Bs−80) degrees C. to the Ms point by reheating, isothermal maintenance, or the like.

Therefore, the dwell time is limited to 1000 degrees C. or less in the above temperature region. The dwell time is preferably 500 seconds or less, further preferably 200 seconds or less. The shorter dwell time is preferable. However, since a very large cooling rate is required to allow less than 1 second of the dwell time, 1 second or more is preferable from the viewpoint of cost.

Average Cooling Rate From Ms Point To (Ms-50) Degrees C.: At Most 100 Degrees C. Per Second

In the manufacturing method a2, the cooling rate is high and a lot of untransformed regions remain at the time of reaching the Ms point as compared with the manufacturing method a1. Therefore, if the cooling rate from the Ms point to (Ms −50) degrees C. is excessively high, aggregated untransformed austenite is likely to remain.

The average cooling rate from the Ms point to (Ms −50) degrees C. is limited to at most 100 degrees C. per second in order to sufficiently proceed with the martensitic transformation from the Ms point to (Ms −50) degrees C. and reduce untransformed austenite. The average cooling rate in the above temperature region is preferably at most 70 degrees C. per second, and more preferably at most 40 degrees C. per second.

By controlling the average cooling rate within this range, untransformed austenite can be sufficiently transformed into martensite and its fraction can be reduced. Therefore, generation of coarse aggregated residual austenite is reducible.

The lower cooling rate is preferable in the above temperature region. However, a large-scale heating device is required to make the cooling rate less than 0.1 degrees C. per second. Therefore, the cooling rate is preferably at least 0.1 degrees C. per second from the viewpoint of cost.

Ms point (degrees C.)=561−474[C]−33·[Mn]

−17·[Cr]−17·[Ni]−21·[Mo]

−11·[Si]+30·[Al]

In the manufacturing method a2, the intermediate heat-treated steel sheet after cooling of the intermediate heat treatment may be subjected to a second cold rolling with a rolling reduction of 10% or less, the intermediate heat-treated steel sheet after cooling may be pickled, or the intermediate heat-treated steel sheet after cooling may be tempered to the extent that Mn concentration in the carbide does not proceed.

Further, after the same heat treatment as the above intermediate heat treatment is performed without performing the first cold rolling, the second cold rolling with a rolling reduction of 10% or less may be performed. Alternatively, the hot-rolled steel sheet after being subjected to the same heat treatment as the above intermediate heat treatment may be pickled. Alternatively, the hot-rolled steel sheet after being subjected to the same heat treatment as the above intermediate heat treatment may be tempered to the extent that the Mn concentration to carbide does not proceed. However, since the above intermediate heat treatment is not performed after the second cold rolling, when the rolling reduction at the second cold rolling exceeds 10%, grain boundaries of the lath structure are excessively distorted in the same manner as in the first cold rolling. When the steel sheet is heated here, a part of the lath structure is recrystallized during heating to become aggregated ferrite, so that acicular ferrite cannot be obtained by the heat treatment.

Next, the manufacturing methods A, A1a, A1 b, and A2 of the invention will be described.

The present manufacturing method A is a manufacturing method of the present steel sheet A using the steel sheet for heat treatment (steel sheet a) manufactured by the method a1 or a2 of the invention.

The present manufacturing method A includes: heating the steel sheet for heat treatment to a temperature in a range from (Ac1+25) degrees C. to an Ac3 point under conditions satisfying a formula (3) below for calculating by dividing an elapsed time in a temperature region from 700 degrees C. to an end point that is a lower one of a maximum heating temperature or (Ac3−20) degrees C. into 10 parts, and retaining the steel sheet for 150 seconds or less in a temperature region from the maximum heating temperature minus 10 degrees C. to the maximum heating temperature;

The present manufacturing method A1a is a manufacturing method of the present steel sheet A1.

The present manufacturing method A1a includes: immersing the high-strength steel sheet excellent in formability, toughness, and weldability manufactured by the present manufacturing method A in a plating bath including zinc as a main component to form a galvanized layer or a zinc alloy plated layer on one surface or both surfaces of the high-strength steel sheet.

The present manufacturing method A1b is a manufacturing method of the present steel sheet A1.

The present manufacturing method A1b includes: forming a galvanized layer or a zinc alloy plated layer by electroplating on one surface or both surfaces of the high-strength steel sheet excellent in formability, toughness, and weldability manufactured by the present manufacturing method A.

The present manufacturing method A2 is a manufacturing method of the present steel sheet A2.

Process conditions of the manufacturing method A will be described.

Steel-sheet-heating temperature: (Ac1+25) degrees C. to Ac3 point

Temperature region with limited heating rate: from 700 degrees C. to (Ac3−20) degrees C.

Heating conditions: Formula (3) below

The steel sheet a is heated from (Ac+25) degrees C. to Ac3 point. For heating, in the temperature region from 700 degrees C. to (Ac3−20) degrees C., the average heating rate of at least 1 degree C. per second or the heating conditions satisfying the formula (3) below are set.

When the steel-sheet-heating temperature is less than (Ac1+25) degrees C., it is concerned that cementite in the steel sheet may remain undissolved to deteriorate mechanical characteristics. Accordingly, the steel-sheet-heating temperature is determined to be equal to or more than (Ac1+25) degrees C., preferably equal to or more than (Ac1+40) degrees C.

On the other hand, the upper limit of the steel-sheet-heating temperature is determined to be equal to or less than Ac3 point. When the steel-sheet-heating temperature exceeds the Ac3 point, the lath structure of the steel sheet a is not inherited, which makes it difficult to obtain acicular ferrite. Moreover, since acicular ferrite is not obtained, martensite is shaped to be coarse, aggregated and island-shaped martensite.

Accordingly, when the steel-sheet-heating temperature exceeds the Ac3 point, properties required for the steel sheet of the invention cannot be achieved. When the steel-sheet-heating temperature approaches the Ac3 point, a majority of the microstructure becomes austenite and the lath structure disappears. Accordingly, in order to inherit the lath structure of the steel sheet a and further improve the mechanical characteristics, the steel-sheet-heating temperature is preferably equal to or less than (Ac3−10) degrees C., more preferably equal to or less than (Ac3−20) degrees C.

When the temperature history in the temperature region from 700 degrees C. to (Ac3−20) degrees C. in the heating step does not satisfy the formula (3), a lot of coarse and aggregated martensite is formed in the microstructure of the present steel sheet A, thereby not satisfying the formula (A) to deteriorate toughness. Accordingly, the temperature history in the temperature region in the heating step is determined to meet the heating conditions satisfying the formula (3).

In order to reduce the amount of coarse and aggregated martensite and sufficiently improve toughness, it is further preferable to limit the value of the left side of the formula (3) to 1.5 or less.

$\begin{matrix} [Numerical Formula 22] \\ \sum_{n = 1}^{10} 8.65 \times 10^{2} \cdot {(W_{Mn} + 0.51 W_{Cr} + 0.51 W_{Ni} - 0.64 W_{Mo} - 0.33 W_{Si} + 0.90 W_{Al})}^{0.5} \cdot {f_{Y} (n)}^{0.5} \cdot {(1 - f_{Y} (n))}^{1.8} \cdot \exp (- \frac{9.00 \times 10^{3}}{T (n) + 273}) \cdot Δ t^{0.33} \leq 2.0 & (3) \end{matrix}$

The formula (3) is an empirical formula in consideration of the generation frequency, stabilization behavior and growth rate of isotropic austenite grains caused by reverse transformation. In the formula (3), a term containing the chemical composition represents the generation frequency of the isotropic austenite grains. As the term becomes larger, more isotropic austenite grains are formed. When the formed isotropic austenite is chemically unstable, other acicular austenite encroaches on the formed isotropic austenite or the formed isotropic austenite is transformed into a phase other than martensite in the subsequent heat treatment, so that formation of coarse isotropic austenite is inhibited and toughness is not impaired. On the other hand, when concentration of alloy elements into isotropic austenite progresses during heating, the isotropic austenite is chemically stabilized and remains untransformed until a low temperature, and is transformed into martensite during cooling to impair toughness.

As the reverse transformation ratio represented by f_γ(n) is smaller, a driving force applied to distribution of the alloy elements is increased. Alternatively, as the temperature becomes higher, atomic diffusion becomes more active and a distribution rate of the alloy elements is higher.

The isotropic austenite grows at the driving force increased especially in a region where the reverse transformation ratio is large, whereas the isotropic austenite can grow more without being affected by the surrounding acicular austenite in a region where the reverse transformation ratio is smaller.

From the above viewpoint, the empirical formula in which coefficients and indexes of the formula consisting of the chemical composition, reverse transformation rate, temperature and time are organized is the formula (3). As the value of the formula (3) is smaller, formation of the isotropic and coarse martensite is more inhibited.

Heating Retention Temperature Region: From Maximum Heating Temperature Minus 10 Degrees C. To Maximum Heating Temperature

Heating retention time: 150 seconds or less

The steel sheet a is heated under the above conditions and retained for 150 seconds or less at the temperature in the temperature region from the maximum heating temperature minus 10 degrees C. to the maximum heating temperature. When the heating retention time exceeds 150 seconds, the microstructure may become austenite and the lath structure may disappear. Accordingly, the heating retention time is defined as 150 seconds or less, preferably 120 seconds or less.

Temperature Region With Limited Cooling Rate: From 700 Degrees C. To 550 Degrees C.

Average Cooling Rate: At Least 25 Degrees C. Per Second

When the average cooling rate is less than 25 degrees C. per second, acicular ferrite excessively grows to become aggregated ferrite, resulting in an excessively low fraction of acicular ferrite. Moreover, since aggregated ferrite are also newly formed in addition to growth of acicular ferrite, a fraction of aggregated ferrite is increased.

Therefore, the average cooling rate is defined as at least 25 degrees C. per second, preferably at least 35 degrees C. per second, more preferably at least 40 degrees C. per second in the temperature region from 700 degrees C. to 550 degrees C.

The upper limit of the average cooling rate is not particularly determined. Excessively increasing the cooling rate requires special equipment and a refrigerant, which increases the cost and makes it difficult to control the cooling stop temperature. Therefore, it is preferable to keep the cooling rate at at most 200 degrees C. per second.

In the calculation in the formulae (4) and (5), the dwell time in the temperature region from the lower one (i.e., start point) of 550 degrees C. and the Bs point to 300 degrees C. is divided into 10 parts.

The steel sheet a, which has been cooled at the average cooling rate of at least 25 degrees C. per second in the temperature region from 700 degrees C. to 550 degrees C., is limited to the range satisfying the formulae (4) and (5) for calculating by dividing the dwell time in the temperature region from the lower one (i.e., start point) of 550 degrees C. and the Bs point to 300 degrees C. into 10 parts.

Unless the formulae (4) and (5) are not satisfied, bainite transformation and/or pearlite transformation excessively progresses and untransformed austenite is consumed, so that a sufficient amount of martensite cannot be obtained. Therefore, the left side of the formula (4) is limited to 1.0 or less.

In order to sufficiently obtain untransformed austenite in terms of high strength, the left side of the formula (4) is preferably 0.8 or less, further preferably 0.6 or less.

When the formula (5) is not satisfied although the formula (4) is satisfied, it is concerned that carbon may be excessively concentrated in untransformed austenite to generate residual austenite. By limiting the left side of the formula (5) to 1.0 or less, concentration of carbons to untransformed austenite is restricted, so that the majority of the untransformed austenite can be transformed into martensite in the subsequent cooling process. In order to reduce residual austenite, the left side of the formula (5) is preferably 0.8 or less, further preferably 0.6 or less.

$\begin{matrix} [Numerical Formula 23] \\ \sum_{n = 1}^{10} {1.39 \times 10^{1} \cdot {(Bs - T (n))}^{3} \cdot \exp (- \frac{1.44 \times 10^{4}}{T (n) + 273}) Δ t^{0.5}} \leq 1.0 & (4) \\ [Numerical Formula 24] \\ \sum_{n = 1}^{10} {1.56 \times 10^{2} \cdot (W_{Si} + 0.9 W_{Al} \cdot {(\frac{T (n)}{550})}^{2} + 0.3 (W_{Cr} + W_{Mo}) \cdot \frac{T (n)}{550}) \cdot \exp (- 6.7 \cdot (1 - \frac{T (n)}{550})) \cdot {(\frac{T (n) - 250}{300})}^{0.5} \cdot {(Bs - T (n))}^{3} \cdot \exp (- \frac{1.44 \times 10^{4}}{T (n) + 273}) \cdot Δ t^{0.5}} \leq 1.0 & (5) \end{matrix}$

The formula (4) is an index for evaluating a progress degree of bainite transformation in this temperature region. When the formula (4) is not satisfied, bainite transformation excessively progresses. The term consisting of the supercooling degree from Bs in the formula (4) represents a driving force of the bainite transformation, and increases as the temperature decreases. Meanwhile, the exponential function term represents a progress rate of bainite transformation by a thermal activation mechanism, and increases as the temperature rises.

The formula (5) is an index showing a behavior of carbide formation from untransformed austenite in the temperature region. When the formula (5) is not satisfied, a large amount of pearlite and/or iron carbides are formed from untransformed austenite, the untransformed austenite is excessively consumed, and a sufficient amount of martensite cannot be obtained. Since carbons are concentrated in untransformed austenite along with bainite transformation and carbides are easily formed, the left side of the formula (5) becomes larger as the term consisting of Bs and the temperature common to the formula (4) becomes larger, which increases a risk of forming carbides. The exponential function term that is not common to the formula (4) represents the rate of carbide formation by thermal activation mechanism. The exponential function term increases as the temperature rises. The term consisting of other chemical compositions and temperatures represents the driving force of forming carbides, and increases as the temperature decreases or decreases by adding elements (Si, Al, Cr, Mo) inhibiting formation of carbides.

When both of the formula (4) and the formula (5) are satisfied, a sufficient amount of untransformed austenite remains until after dwelling in the temperature region and an amount of solid solution carbon in the untransformed austenite remains in an appropriate range, a sufficient amount of martensite can be obtained by subsequent cooling.

When the average cooling rate from 300 degrees C. to the room temperature is excessively low, carbons may be distributed from partially formed martensite to untransformed austenite, and austenite may remain. From this viewpoint, the average cooling rate in the above temperature region is preferably at least 0.1 degrees C. per second, and more preferably at least 0.5 degrees C. per second.

In the manufacturing method A, the wound steel sheet may be subjected to skin pass rolling with a rolling reduction of 2.0% or less. By subjecting the wound steel sheet to skin pass rolling with a rolling reduction of 2.0% or less, the material, shape, and dimensional accuracy of the steel sheet can be improved.

Further, in the production method A of the invention, the wound steel sheet may be tempered by being heated to a temperature in a range from 200 degrees C. to 600 degrees C. Toughness of martensite can be improved by this tempering. When the tempering temperature is less than 200 degrees C., toughness of martensite is not sufficiently improved. Therefore, the tempering temperature is preferably 200 degrees C. or more, more preferably 300 degrees C. or more.

On the other hand, when the tempering temperature exceeds 600 degrees C., austenite may be decomposed into carbides and the lath structure may disappear. Therefore, the tempering temperature is preferably 600 degrees C. or less, more preferably 550 degrees C. or less. The tempering time is not particularly limited to a specific range. The tempering time may be appropriately set according to the chemical composition and the heat history of the steel sheet.

When the tempering time is excessively long, a tempering embrittlement phenomenon may occur in which coarse carbides are formed in the tempered martensite to embrittle the steel sheet. Therefore, the tempering time is preferably 10000 seconds or less. In order to avoid the embrittlement, the tempering time is more preferably 3600 seconds or less, further preferably 1000 seconds or less.

When the tempering time is excessively short, temperature unevenness may occur inside the steel sheet and the shape of the steel sheet may be deteriorated. Therefore, the tempering time is preferably 1 second or more. In order to sufficiently obtain the toughness improving effect by the tempering, the tempering time is preferably 3 seconds or more, and more preferably 6 seconds or more.

Further, in the manufacturing method A of the invention, the tempering may be performed after the skin pass rolling, and conversely, the skin pass rolling may be performed after the tempering. Alternatively, the skin pass rolling may be performed before and after the tempering.

Galvanized Layer and Zinc Alloy Plated Layer

A galvanized layer or a zinc alloy plated layer is formed on one surface or both surfaces of the present steel sheet A by the manufacturing method Ala and the manufacturing method Alb of the invention. The plating method is preferably a hot-dip galvanizing method or an electroplating method.

Process Conditions of the Manufacturing Method A1a Will be Described.

In the manufacturing method A1a of the invention, the present steel sheet A is immersed in a plating bath including zinc as a main component to form a galvanized layer or a zinc alloy plated layer on one surface or both surfaces of the present steel sheet A.

Temperature of Plating Bath

The temperature of the plating bath is preferably from 450 degrees C. to 470 degrees C. When the temperature of the plating bath is less than 450 degrees C., the viscosity of the plating solution increases, it becomes difficult to control the thickness of the plated layer accurately, and the appearance of the steel sheet is impaired. Therefore, the temperature of the plating bath is preferably 450 degrees C. or more. On the other hand, when the temperature of the plating bath exceeds 470 degrees C., a large amount of fume is formed from the plating bath and the working environment is deteriorated to lower the work safety. Therefore, the temperature of the plating bath is preferably 470 degrees C. or less.

The temperature of the present steel sheet A immersed in the plating bath is preferably in a range from 400 degrees C. to 530 degrees C. When the temperature of the steel sheet is less than 400 degrees C., a large amount of heat is required to stably maintain the temperature of the plating bath at 450 degrees C. or more, and the plating cost increases. Therefore, the temperature of the steel sheet is preferably 400 degrees C. or more, more preferably 430 degrees C. or more.

On the other hand, when the temperature of the steel sheet exceeds 530 degrees C., a large amount of heat must be removed to keep the temperature of the plating bath stable at 470 degrees C. or less, thereby increasing the plating cost. Therefore, the temperature of the steel sheet is preferably 530 degrees C. or less, more preferably 500 degrees C. or less.

Composition of Plating Bath

The plating bath mainly contains zinc and preferably has an effective Al amount of 0.01 to 0.30 mass % which is obtained by subtracting the entire Fe amount from the entire Al amount. When the effective Al amount of the galvanizing bath is less than 0.01 mass %, Fe excessively invades into the galvanized layer or the zinc alloy plated layer, and the plating adhesion is lowered. Therefore, the effective Al amount of the galvanizing bath is 0.01 mass % or more, more preferably 0.04 mass % or more.

On the other hand, when the effective Al amount of the galvanizing bath exceeds 0.30 mass %, Al oxides are excessively formed at the interface between the base iron and the galvanized layer or the zinc alloy plated layer, and the plating adhesion is significantly deteriorated. Therefore, the effective Al amount of the galvanizing bath is preferably 0.30 mass % or less. Since the Al oxides hinder movement of Fe atoms and Zn atoms to inhibit formation of the alloy phase in the subsequent alloying treatment, the effective Al amount of the plating bath is more preferably 0.20 mass % or less.

The plating bath may contain one or more of Ag, B, Be, Bi, Ca, Cd, Co, Cr, Cs, Cu, Ge, Hf, Zr, I, K, La, Li, Mg, Mn, Mo, Na, Nb, Ni, Pb, Rb, Sb, Si, Sn, Sr, Ta, Ti, V, W, Zr, and REM in order to improve corrosion resistance and formability.

The adhesion amount of plating is adjusted by pulling the steel sheet out of the plating bath and then spraying a high-pressure gas mainly including nitrogen on the surface of the steel sheet to remove excessive plating solution.

Process conditions of the manufacturing method A1 b will be described.

In the manufacturing method A1b, a galvanized layer or a zinc alloy plated layer is formed on one surface or both surfaces of the present steel sheet A by electroplating.

Electroplating

In the manufacturing method A1b, a galvanized layer or a zinc alloy plated layer is formed on one surface or both surfaces of the present steel sheet A under typical electroplating conditions.

Alloying of Galvanized Layer and Zinc Alloy Plated Layer

In the manufacturing method A2, it is preferable to heat a galvanized layer or a zinc alloy plated layer, which is formed on one surface or both surfaces of the present steel sheet A by the manufacturing method A1a or the manufacturing method A1 b, to a temperature in a range from 450 degrees C. to 550 degrees C. for alloying. The heating time is preferably in a range from 2 to 100 seconds.

When the heating temperature is less than 450 degrees C. or the heating time is less than 2 seconds, alloying does not proceed sufficiently and the plating adhesion is not improved. Therefore, it is preferable that the heating temperature is 450 degrees C. or more and the heating time is 2 seconds or more.

On the other hand, when the heating temperature exceeds 550 degrees C. or the heating time exceeds 100 seconds, alloying excessively proceeds and the plating adhesion is lowered. Therefore, it is preferable that the heating temperature is 550 degrees C. or less and the heating time is 100 seconds or less.

EXAMPLES

Next, Examples of the invention will be described. Conditions used in Examples are exemplarily adopted for checking the feasibility and effect of the invention. The invention is not limited to the exemplary conditions. Various conditions are applicable to the invention as long as the conditions are not contradictory to the gist of the invention and are compatible with an object of the invention.

Example 1: Manufacture of Steel Sheet for Heat Treatment

Steel pieces were manufactured by casting molten steel with the chemical compositions shown in Tables 1 and 2. Next, the steel pieces were subjected to hot rolling under conditions shown in Tables 3 and 4.

TABLE 1

Chemical
Chemical component (mass %)

component
C
Si
Mn
P
S
Al
N
O
Ti
Nb
V
Cr
Ni
Cu

A
0.148
0.82
2.50
0.009
0.0022
0.037
0.0025
0.0009

Example

B
0.085
0.43
1.87
0.012
0.0047
0.182
0.0056
0.0007
0.008
0.010

0.18

Example

C
0.201
1.63
2.31
0.006
0.0030
0.079
0.0013
0.0015

Example

D
0.058
0.21
1.56
0.012
0.0055
0.071
0.0064
0.0018
0.067

Example

E
0.264
0.35
1.29
0.009
0.0010
0.038
0.0075
0.0008

Example

F
0.221
0.86
2.10
0.013
0.0011
0.201
0.0028
0.0016

Example

G
0.149
0.02
2.80
0.014
0.0020
0.022
0.0056
0.0006

0.053

Example

H
0.138
0.56
3.32
0.009
0.0016
0.860
0.0037
0.0013

Example

I
0.137
0.05
2.85
0.011
0.0017
1.165
0.0031
0.0016

0.063

Example

J
0.194
0.16
2.09
0.013
0.0017
0.075
0.0027
0.0014

0.14
Example

K
0.096
0.71
1.68
0.019
0.0028
0.133
0.0048
0.0017
0.162

Example

L
0.077
1.44
2.17
0.016
0.0019
0.076
0.0047
0.0013

0.067

Example

M
0.107
2.24
1.05
0.002
0.0001
0.098
0.0050
0.0013

0.15
0.22

Example

N
0.199
1.47
0.88
0.042
0.0006
0.031
0.0055
0.0009

1.06

Example

O
0.137
2.05
0.57
0.033
0.0041
0.013
0.0037
0.0008

1.23
0.32
Example

P
0.146
1.91
0.84
0.016
0.0071
0.029
0.0051
0.0003

0.207

Example

Q
0.068
1.64
1.94
0.017
0.0014
0.228
0.0043
0.0016
0.011
0.021

Example

R
0.124
0.74
1.33
0.009
0.0012
0.002
0.0058
0.0017

0.64

Example

S
0.133
0.82
1.84
0.003
0.0051
0.080
0.0044
0.0003
0.115

Example

T
0.122
0.35
2.36
0.001
0.0048
0.084
0.0108
0.0003
0.023

Example

U
0.128
0.18
2.84
0.008
0.0059
1.710
0.0026
0.0008

Example

V
0.124
1.32
1.23
0.006
0.0030
0.018
0.0030
0.0007

0.030

0.31

Example

W
0.136
0.28
1.52
0.003
0.0022
0.082
0.0026
0.0015
0.043

Example

X
0.188
0.31
2.08
0.019
0.0037
0.005
0.0028
0.0017

Example

Y
0.163
0.99
1.94
0.023
0.0036
0.041
0.0031
0.0013

Example

Z
0.191
1.83
1.36
0.018
0.0079
0.097
0.0027
0.0013

Example

AA

0.034

0.94
1.99
0.009
0.0062
0.036
0.0060
0.0009

Comparative

AB

0.357

0.93
2.05
0.008
0.0063
0.073
0.0071
0.0003

Comparative

AC
0.167

3.05

1.96
0.010
0.0074
0.089
0.0027
0.0004

Comparative

AD
0.162
0.88

6.11

0.011
0.0063
0.059
0.0049
0.0015

Comparative

AE
0.167
0.87

0.31

0.008
0.0017
0.052
0.0061
0.0018

Comparative

AF
0.164
0.93
2.01

0.115

0.0061
0.098
0.0075
0.0011

Comparative

AG
0.169
0.89
1.96
0.009

0.0214

0.089
0.0056
0.0008

Comparative

AH
0.158
0.91
2.03
0.010
0.0010

2.222

0.0027
0.0007

Comparative

AI
0.158
0.78
1.90
0.011
0.0010
0.076

0.0218

0.0014

Comparative

AJ
0.171
0.94
2.05
0.011
0.0011
0.014
0.0071

0.0195

Comparative

AK
0.148
0.81
2.49
0.013
0.0009
0.009
0.0034
0.0009

Example

AL
0.200
1.62
2.31
0.010
0.0013
0.083
0.0024
0.0012

Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 2

Chemical
Chemical component (mass %)
Temperature (° C.)

component
Mo
B
W
Ca
Ce
Mg
Zr
La
REM
Sn
Sb
Bs point
Ms point

A

521
400
Example

B
0.09
0.0004

0.0008

560
455
Example

C

519
374
Example

D

0.0013

575
482
Example

E

566
391
Example

F

538
384
Example

G

530
398
Example

H

521
406
Example

I

551
436
Example

J

0.0017

543
401
Example

K

552
456
Example

L

0.0014

552
439
Example

M

553
448
Example

N

565
404
Example

O

549
434
Example

P

563
444
Example

Q

0.0033

578
454
Example

R

0.0009

564
439
Example

S

544
431
Example

T

0.0009

532
424
Example

U
0.13

566
453
Example

V

0.0022

558
442
Example

W
0.28

558
440
Example

X

0.0005

0.0013

541
400
Example

Y

0.14

537
410
Example

Z

0.0029

549
408
Example

M

536
470

Comparative

AB

535
316

Comparative

AC

515
386

Comparative

AD

401
275

Comparative

AE

593
464

Comparative

AF

537
410

Comparative

AG

539
409

Comparative

AH

601
476

Comparative

AI

542
417

Comparative

AJ

533
402

Comparative

AK

0.109

521
400
Example

AL

0.051
519
374
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 3

Hot rolling conditions

Rolling
Average

Heating
completion
cooling
Winding
Bs—winding

Hot-rolled
Chemical
temperature
temperature
rate 1
temperature
temperature
Bs
Left side of

steel sheet
component
° C.
° C.
° C./sec
° C.
° C.
° C.
Formula (1)

1
A
1220
874
49
490
31
521
0.68
Example

2
A
1175
930

<1

607

−86
521
0.82

Comparative

3
B
1220
922
54
491
69
560
1.05
Example

5
C
1195
868
47

529

−10
519
0.66

Comparative

6
C
1210
988
54
515
4
519
0.74
Example

7
D
1200
942
45
501
74
575
1.03
Example

8
D
1205
928
32
545
30
575
1.42
Example

9
E
1195
980
44
545
21
566

1.83

Comparative

10
E
1210
978
44
506
60
566
1.05
Example

11
F
1245
922
45
533
5
538
1.18
Example

12
F
1265
918
46
98
440
538
0.00
Example

13
G
1215
868
54
515
15
530
0.81
Example

14
G
1240
974
44
488
42
530
0.45
Example

15
H
1190
920
51
498
23
521
0.57
Example

16
H
1245
920
39
520
1
521
0.78
Example

17
I
1210
870
60
526
25
551
0.67
Example

18
I
1235
876
32
512
39
551
1.31
Example

19
J
1235
936
50
523
20
543
0.44
Example

20
J
1210
990
55
492
51
543
0.69
Example

21
K
1190
932
42
535
17
552
0.70
Example

22
K
1205
986
37
521
31
552
1.02
Example

23
L
1200
970
41
523
29
552
1.00
Example

24
L
1210
922
39
490
62
552
0.55
Example

25
M
1245
884
54
526
27
553
1.14
Example

26
M
1240
986
56
500
53
553
0.85
Example

27
N
1210
880
49
533
32
565
1.09
Example

28
N
1175
886
52
500
65
565
0.53
Example

29
O
1175
936
44
528
21
549
1.17
Example

30
O
1180
878
39
539
10
549
1.01
Example

31
P
1190
932
42
512
51
563
0.96
Example

32
P
1190
882
46
529
34
563

1.63

Comparative

33
Q
1200
866
36
538
40
578
0.61
Example

34
Q
1180
866
41
501
77
578
0.43
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 4

Hot rolling conditions

Rolling
Average

Heating
completion
cooling
Winding
Bs—winding

Hot-rolled
Chemical
temperature
temperature
rate 1
temperature
temperature
Bs
Left side of

steel sheet
component
° C.
° C.
° C./sec
° C.
° C.
° C.
Formula (1)

35
R
1175
936
56
492
72
564
0.69
Example

36
R
1225
932
39
491
73
564
0.12
Example

37
S
1235
980
42
509
35
544
0.80
Example

38
S
1180
884
53
525
19
544
1.17
Example

39
T
1245
992
36
503
29
532
0.78
Example

40
T
1200
986
41
501
31
532
0.23
Example

41
U
1180
966
53
532
34
566
1.45
Example

42
U
1240
978
43
537
29
566
1.04
Example

43
V
1260
974
39
532
26
558
1.15
Example

44
V
1200
992
49
509
49
558
0.84
Example

45
W
1175
986
55
506
52
558
0.79
Example

46
W
1235
918
41
545
13
558
1.25
Example

47
X
1265
966
53
524
17
541
0.71
Example

48
X
1235
928
43
499
42
541
0.73
Example

49
Y
1255
992
48
507
30
537
0.85
Example

50
Y
1235
922
57

541

−4

537
1.01

Comparative

51
Z
1245
932
45
519
30
549
1.10
Example

52
Z
1175
880
46
390
159
549
0.00
Example

53

AA

1200
934
58
526
10
536
1.00

Comparative

54

AB

1260
994
44
512
23
535
0.91

Comparative

55

AC

Test was terminated due to being cracked during casting process.

Comparative

56

AD

Test was terminated due to being cracked during casting process.

Comparative

57

AE

1255
886
54
505
88
593
1.12

Comparative

58

AF

Test was terminated due to being cracked during casting process.

Comparative

59

AG

1205
936
54
504
35
539
0.85

Comparative

60

AH

Test was terminated due to being cracked during casting process.

Comparative

61

AI

1255
928
46
492
50
542
0.67

Comparative

62

AJ

1175
892
50
511
22
533
0.71

Comparative

63
AK
1220
907
47
485
36
521
0.63
Example

64
AL
1205
956
51
505
14
519
0.64
Example

65
I
1225
917

22

533
18
551
1.01

Comparative

66
K
1200
913

17

525
27
552
1.05

Comparative

67
O
1195
900
9
524
25
549
1.11

Comparative

68
W
1215
925

11

530
28
558
1.12

Comparative

※A value with underline indicates that the value is out of the scope of the invention.

The hot-rolled steel sheets were treated under conditions shown in Tables 5 to 9 to provide steel sheets for heat treatment.

Examples with an indication of “to manufacturing method A” in Tables 5 to 9 are manufacturing examples by the manufacturing method a1 (without the intermediate heat treatment). The hot-rolled steel sheets with the mark “-” for the cold rolling ratio 2 were directly used as the steel sheets for heat treatment. For instance, a hot-rolled steel sheet 10 was directly used as a steel sheet 10 for heat treatment. Moreover, the steel sheets with the indication of “to manufacturing method A” in Tables 5 to 9 and with numerical values entered in the cold rolling ratio 2 were used as steel sheets for heat treatment after subjecting the hot-rolled steel sheets to cold rolling with the rolling reduction of the cold rolling ratio 2.

On the other hand, Examples with the indication of the intermediate heat treatment conditions in Tables 5 to 9 are manufacturing examples by the manufacturing method a2 (with the intermediate heat treatment). The cold rolling ratio 1 is a rolling ratio in the first cold rolling. The cold rolling ratio 2 is a rolling ratio in the second cold rolling. When each rolling ratio is denoted by the mark “-”, the corresponding cold rolling was not performed.

TABLE 5

Intermediate heat treatment

Maxi-

Maxi-
mum

Steel

mum
heating

sheet
Hot-

Cold
Left
heating
temper-

Cold
Plate

for heat
rolled

rolling
side of
temper-
ature—

Cooling
Cooling
Dwell
Cooling
rolling
thick-

treat-
steel
Chemical
ratio 1
Formula
ature
Ac3
Ac3
rate 1
rate 2
time
rate 3
ratio 2
ness
Bs
Ms

ment
sheet
component
%
(2)
° C.
° C.
° C.
° C./sec
° C./sec
sec
° C./sec
° C.
mm
° C.
° C.

1a
1
A
to manufacturing method A
3.2
3.0
521
400
Example

1b
1
A
40
0.83
860
23
837
103
62
195
54
—
1.8
521
400
Example

1c
1
A
40

1.15

853
16
837
58
28
56
26
—
1.8
521
400

Com-

parative

1d
1
A
40
0.83

812

−25
837
41
30
69
22
—
1.8
521
400

Com-

parative

1e
1
A
—
0.69
862
17
845
47
43
344
16
1.4
3.0
521
400
Example

2a

2

A
to manufacturing method A
—
2.0
521
400

Com-

parative

3a
3
B
to manufacturing method A
1.4
2.4
560
455
Example

3b
3
B
—
0.75
876
14
862
37
29
54
42
4.5
2.4
560
455
Example

3c
3
B
67
0.54
885
19
866
52
29
24
9
0.7
0.8
560
455
Example

5a

5

C
to manufacturing method A
1.7
3.1
519
374

Com-

parative

6a
6
C
60
0.78
830
−17
847
65
28
47
11
2.3
1.2
519
374
Example

6b
6
C
to manufacturing method A
2.4
3.0
519
374
Example

7a
7
D
0.5
0.51
865
7
858
62
32
27
12
3.4
4.5
575
482
Example

7b
7
D
to manufacturing method A
0.5
4.5
575
482
Example

8a
8
D
70
0.83
890
28
862
43
32
46
6
2.9
0.9
575
482
Example

8b
8
D
to manufacturing method A
0.3
3.0
575
482
Example

9c

9

E
to manufacturing method A
0.6
2.4
566
391

Com-

parative

10
10
E
to manufacturing method A
—
2.1
566
391
Example

11
11
F
to manufacturing method A
2.8
1.8
538
384
Example

12
12
F
to manufacturing method A
2.7
2.3
538
384
Example

13
13
G
to manufacturing method A
3.3
3.2
530
398
Example

14
14
G
to manufacturing method A
2.7
3.0
530
398
Example

15
15
H
to manufacturing method A
0.2
2.3
521
406
Example

16
16
H
to manufacturing method A
2.4
2.7
521
406
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 6

Intermediate heat treatment

Maxi-

Maxi-
mum

Steel

mum
heating

sheet
Hot-

Cold
Left
heating
temper-

Cold
Plate

for heat
rolled

rolling
side of
temper-
ature—

Cooling
Cooling
Dwell
Cooling
rolling
thick-

treat-
steel
Chemical
ratio1
Formula
ature
Ac3
Ac3
rate 1
rate 2
time
rate 3
ratio 2
ness
Bs
Ms

ment
sheet
component
%
(2)
° C.
° C.
° C.
° C./sec
° C./sec
sec
° C./sec
° C.
mm
° C.
° C.

17
17
I
to manufacturing method A
3.7
2.4
551
436
Example

18a
18
I
50
0.79
960
25
935
34
26
166

151
—
1.2
551
436

Com-

parative

18b
18
I
50
0.83
928
−7
935
80
33
36
4
0.5
1.2
551
436
Example

18c
18
I
75
0.81
944
19
925
58
43
525
14
1.7
0.6
551
436
Example

19a
19
J
25
0.79
815
1
814
103
32
328
32
—
3.0
543
401
Example

19b
19
J
to manufacturing method A
3.7
4.0
543
401
Example

20a
20
J
8
0.38
833
14
819
37
60
51
29
—
2.0
543
401
Example

20b
20
J
to manufacturing method A
—
2.1
543
401
Example

21a
21
K
6
0.88
873
7
866
85
59
41
15
6.5
2.0
552
456
Example

21b
21
K
to manufacturing method A
1.3
2.1
552
456
Example

22a
22
K
15
0.91
860
−4
864
57
59
22
6
3.4
1.8
552
456
Example

23
23
L
to manufacturing method A
2.7
2.2
552
439
Example

24a
24
L
60
0.88
880
10
870
44
46
15
15
2.4
2.0
552
439
Example

24b
24
L
60
0.81

816

−54
870
83
48
30
5
2.4
2.0
552
439

Com-

parative

24c
24
L
to manufacturing method A
3.1
5.0
552
439
Example

25a
25
M
73
0.88
950
8
942
97
32
32
15
2.6
0.8
553
448
Example

25b
25
M
73
0.83
951
9
942
39

10

40
32
2.7
0.8
553
448

Com-

parative

25c
25
M
to manufacturing method A
6.2
3.0
553
448
Example

26
26
M
to manufacturing method A
1.6
2.5
553
448
Example

27a
27
N
37
0.64
870
10
860
101
60
16
27
3.5
1.9
565
404
Example

27b
27
N
37
0.55
870
10
860
54
33

1279

14
2.6
1.9
565
404

Com-

parative

27c
27
N
to manufacturing method A
0.3
3.0
565
404
Example

28
28
N
to manufacturing method A
3.7
3.0
565
404
Example

29
29
O
to manufacturing method A
8.7
3.5
549
434
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 7

Intermediate heat treatment

Maxi-

Maxi-
mum

Steel

mum
heating

sheet
Hot-

Cold
Left
heating
temper-

Cold
Plate

for heat
rolled

rolling
side of
temper-
ature—

Cooling
Cooling
Dwell
Cooling
rolling
thick-

treat-
steel
Chemical
ratio 1
Formula
ature
Ac3
Ac3
rate 1
rate 2
time
rate 3
ratio 2
ness
Bs
Ms

ment
sheet
component
%
(2)
° C.
° C.
° C.
° C./sec
° C./sec
sec
° C./sec
° C.
mm
° C.
° C.

30a
30
O
80
0.79
873
15
858
79
29
45
12
1.6
0.8
549
434
Example

30b
30
O
50
0.80
880
16
864
38
28
348
46
3.3
2.0
549
434
Example

30c
30
O
50
0.79
879
15
864
8
33
58
4
0.6
2.0
549
434

Com-

parative

31
31
P
to manufacturing method A
—
1.8
563
444
Example

32d

32

P
to manufacturing method A
—
2.0
563
444

Com-

parative

33a
33
Q
50
0.90
935
15
920
61
33
152
3
0.7
1.5
578
454
Example

33b
33
Q
to manufacturing method A
1.5
3.0
578
454
Example

34a
34
Q
50
0.75
928
12
916
38
28
60
4
3.3
1.5
578
454
Example

34b
34
Q
to manufacturing method A
3.6
3.0
578
454
Example

35a
35
R
50
0.77
940
92
848
105
29
22
6
—
1.2
564
439
Example

35b
35
R
to manufacturing method A
—
2.4
564
439
Example

36a
36
R
50
0.84
843
−4
847
78
28
399
14
0.1
1.0
564
439
Example

36b
36
R
to manufacturing method A
1.4
2.0
564
439
Example

37a
37
S
0.6
0.66
875
25
850
103
60
319
25
6.1
3.0
544
431
Example

37b
37
S
to manufacturing method A
3.4
3.0
544
431
Example

38a
38
S
13
0.76
840
−13
853
57
32
42
11
3.3
3.5
544
431
Example

38b
38
S
to manufacturing method A
3.8
4.0
544
431
Example

39a
39
T
25
0.67
850
16
834
63
47
19
29
2.6
3.0
532
424
Example

39b
39
T
to manufacturing method A
3.3
4.0
532
424
Example

40a
40
T
25
0.80
860
27
833
46
31
53
13
3.4
1.2
532
424
Example

40b
40
T
to manufacturing method A
3.6
1.6
532
424
Example

41a
41
U
75
0.94
1012
22
990
47
29
330
19
3.9
0.6
566
453
Example

41b
41
U
to manufacturing method A
6.4
2.4
566
453
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 8

Intermediate heat treatment

Maxi-

Maxi-
mum

Steel

mum
heating

sheet
Hot-

Cold
Left
heating
temper-

Cold
Plate

for heat
rolled

rolling
side of
temper-
ature—

Cooling
Cooling
Dwell
Cooling
rolling
thick-

treat-
steel
Chemical
ratio 1
Formula
ature
Ac3
Ac3
rate 1
rate 2
time
rate 3
ratio 2
ness
Bs
Ms

ment
sheet
component
%
(2)
° C.
° C.
° C.
° C./sec
° C./sec
sec
° C./sec
° C.
mm
° C.
° C.

42a
42
U
75
0.83
990
3
987
40
60
23
16
3.6
0.6
566
453
Example

42b
42
U
to manufacturing method A
2.8
2.4
566
453
Example

43a
43
V
70
0.84
919
51
868
97
32
41
10
2.1
2.1
558
442
Example

43b
43
V
to manufacturing method A
2.7
7.0
558
442
Example

44a
44
V
70
0.87
860
−4
864
101
32
65
5
—
0.9
558
442
Example

44b
44
V
to manufacturing method A
—
3.0
558
442
Example

45a
45
W
50
0.83
871
25
846
66
31
308
6
3.4
1.0
558
440
Example

45b
45
W
to manufacturing method A
2.7
2.0
558
440
Example

46a
46
W
50
0.78
831
−9
840
67
33
24
14
0.5
1.0
558
440
Example

47a
47
X
60
0.69
824
14
810
39
62
18
10
3.0
1.2
541
400
Example

47b
47
X
60
0.64
825
15
810
61
30
41
28
3.6
1.2
541
400
Example

47c
47
X
40
0.68
820
8
812
38
5
47
3
3.5
1.8
541
400

Com-

parative

47d
47
X
to manufacturing method A
—
3.0
541
400
Example

48a
48
X
40
0.56
825
11
814
37
28
56
6
—
1.2
541
400
Example

48b
48
X
to manufacturing method A
1.5
2.0
541
400
Example

49a
49
Y
50
0.83
850
4
846
43
24
325
11
4.4
0.9
537
410
Example

49b
49
Y
to manufacturing method A
4.4
1.8
537
410
Example

50b

50

Y
to manufacturing method A
0.4
3.0
537
410

Com-

parative

51a
51
Z
72
0.80
891
7
884
57
33
192
14
3.5
1.1
549
408
Example

51b
51
Z
to manufacturing method A
3.3
3.9
549
408
Example

52a
52
Z
50
0.93
895
9
886
62
33
52
5
0.3
1.0
549
408
Example

52b
52
Z
to manufacturing method A
3.3
2.0
549
408
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 9

Intermediate heat treatment

Maxi-

Maxi-
mum

Steel

mum
heating

sheet
Hot-

Cold
Left
heating
temper-

Cold
Plate

for heat
rolled

rolling
side of
temper-
ature—

Cooling
Cooling
Dwell
Cooling
rolling
thick-

treat-
steel
Chemical
ratio 1
Formula
ature
Ac3
Ac3
rate 1
rate 2
time
rate 3
ratio 2
ness
Bs
Ms

ment
sheet
component
%
(2)
° C.
° C.
° C.
° C./sec
° C./sec
sec
° C./sec
° C.
mm
° C.
° C.

53
53

AA

to manufacturing method A
0.6
2.5
536
470

Example

54
54

AB

to manufacturing method A
5.3
2.5
535
316

Example

55
55

AC

Test was terminated due to being cracked during casting process.

Example

56
56

AD

Test was terminated due to being cracked during casting process.

Example

57
57

AE

to manufacturing method A
3.7
2.5
593
464

Example

58
58

AF

Test was terminated due to being cracked during casting process.

Example

59
59

AG

to manufacturing method A
1.3
2.5
539
409

Example

60
60

AH

Test was terminated due to being cracked during casting process.

Example

61
61

AI

to manufacturing method A
0.6
2.5
542
417

Example

62
62

AJ

to manufacturing method A
2.4
2.5
533
402

Example

63
63
AK
40
0.79
870
32
838
100
59
180
25
0.2
1.8
521
400
Com-

parative

64
64
AL
60
0.75
840
6
834
62
30
50
15
0.3
1.2
519
374
Com-

parative

65

65

I
to manufacturing method A
3.4
2.4
551
436

Example

66

66

K
to manufacturing method A
2.6
2.1
552
456

Example

67

67

O
to manufacturing method A
3.5
4.0
549
434

Example

68

68

W
to manufacturing method A
2.6
2.0
558
440

Example

1f
1
A
to manufacturing method A

40
1.8
521
400

Example

3d
3
B
—
0.75
876
14
862
37
29
54
42

16
2.1
560
455

Example

※A value with underline indicates that the value is out of the scope of the invention.

Tables 10 to 14 show microstructures of the obtained steel sheets for heat treatment. In the microstructures, M refers to martensite, tempered M represents tempered martensite, B refers to bainite, BF refers to bainitic ferrite, aggregated α refers to aggregated ferrite, and residual γ refers to residual austenite.

TABLE 10

Steel sheet for heat treatment

Volume fraction

Steel
Hot-

Lath structure

Coarse
Mn-

sheet
rolled

Tempered

Aggregated
Residual

aggregated
concentrated

for heat
steel
Chemical
M
M
B
BF
SUM
α
γ
Others
residual γ
region

treatment
sheet
component
%
%
%
%
%
%
%
%
%
%

1a
1
A
1
13
49
25
88
12
0.1
0
0.0
0.2
Example

1b
1
A
40
0
34
17
91
7
0
2
0.0
0.5
Example

1c
1
A
45
7
25
19
96
0
1
3
0.5

4

Comparative

1d
1
A
21
0
15
28

64

36

0
0
0.0
1

Comparative

1e
1
A
32
0
35
17
84
13
0.3
3
0.0
0.4
Example

2a
2
A
0
0
0
0
0

78

0

22
0.0

6

Comparative

3a
3
B
0
6
67
20
93
7
0.1
0
0.0
0.6
Example

3b
3
B
49
0
30
6
85
12
0
3
0.0
0.4
Example

3c
3
B
51
0
32
7
90
9
0
1
0.0
0.4
Example

5a
5
C
8
3
10
47

68

26

5
1
1.6

4

Comparative

6a
6
C
34
20
10
20
84
13
0.7
2
0.0
0.6
Example

6b
6
C
8
2
41
33
84
16
0.4
0
0.0
0.5
Example

7a
7
D
45
0
36
3
84
15
0.1
1
0.0
0.3
Example

7b
7
D
5
6
71
8
90
8
0.0
2
0.0
0.5
Example

8a
8
D
47
0
38
4
89
9
0.1
2
0.0
0.9
Example

8b
8
D
2
0
83
0
85
14
1.0
0
0.3
1.6
Example

9c
9
E
0
0
80
7
87
3
4
6

2.9

5

Comparative

10
10
E
2
15
65
4
86
13
0.0
1
0.0
0.4
Example

11
11
F
7
13
23
45
88
9
0.7
2
0.0
0.5
Example

12
12
F
26
54
0
14
94
4
0.0
2
0.0
0.0
Example

13
13
G
5
0
67
25
97
0
0.0
3
0.0
0.3
Example

14
14
G
0
0
99
0
99
0
0.5
1
0.0
0.6
Example

15
15
H
17
0
38
42
97
3
0.0
0
0.0
0.0
Example

16
16
H
8
5
54
25
92
7
0.8
0
0.0
0.3
Example

※A value with underline indicates that the value is out of the favorable scope of the invention.

TABLE 11

Steel sheet for heat treatment

Volume fraction

Steel
Hot-

Lath structure

Coarse
Mn-

sheet
rolled

Tempered

Aggregated
Residual

aggregated
concentrated

for heat
steel
Chemical
M
M
B
BF
SUM
α
γ
Others
residual γ
region

treatment
sheet
component
%
%
%
%
%
%
%
%
%
%

17
17
I
0
0
90
5
95
3
0.0
2
0.0
0.0
Example

18a
18
I
27
0
29
39
95
1
4
0

3.0

0.4

Comparative

18b
18
I
51
0
38
10
99
0
0
1
0.0
0.6
Example

18c
18
I
34
0
57
8
99
0
0
1
0.0
0.4
Example

19a
19
J
32
0
53
4
89
10
0
1
0.0
0.6
Example

19b
19
J
6
0
78
0
84
16
0.0
0
0.0
0.0
Example

20a
20
J
39
5
35
2
81
16
0
3
0.0
0.1
Example

20b
20
J
8
7
76
0
91
7
0.3
2
0.0
0.5
Example

21a
21
K
44
0
31
12
87
11
0
2
0.0
0.6
Example

21b
21
K
4
0
55
26
85
14
0.3
1
0.0
0.5
Example

22a
22
K
49
0
26
11
86
12
0.1
2
0.0
0.9
Example

23
23
L
14
5
4
65
88
10
1.1
1
0.2
1.0
Example

24a
24
L
51
0
14
20
85
14
0.7
0
0.0
0.7
Example

24b
24
L
18
2
16
1

37

63

0
0
0.0
0

Comparative

24c
24
L
10
0
26
54
90
9
0.1
1
0.0
0.1
Example

25a
25
M
41
0
5
43
89
9
0
2
0.0
0.7
Example

25b
25
M
27
3
5
48
83
12
5
0

3.5

1.5

Comparative

25c
25
M
13
0
5
66
84
13
1.4
2
0.2
1.3
Example

26
26
M
7
12
15
55
89
10
0.8
0
0.0
0.7
Example

27a
27
N
44
0
17
25
86
11
0.4
3
0.0
0.3
Example

27b
27
N
12
0
1
83
96
0
4
0
0.5

3

Comparative

27c
27
N
6
9
25
43
83
17
0.4
0
0.0
0.6
Example

28
28
N
16
0
0
81
97
3
0.1
0
0.0
0.1
Example

29
29
O
2
0
13
73
88
6
1.6
4
1.3
1.4
Example

※A value with underline indicates that the value is out of the favorable scope of the invention.

TABLE 12

Steel sheet for heat treatment

Volume fraction

Steel
Hot-

Lath structure

Coarse
Mn-

sheet
rolled

Tempered

Aggregated
Residual

aggregated
concentrated

for heat
steel
Chemical
M
M
B
BF
SUM
α
γ
Others
residual γ
region

treatment
sheet
component
%
%
%
%
%
%
%
%
%
%

30a
30
O
36
0
13
49
98
0
0.6
1
0.0
0.7
Example

30b
30
O
15
0
12
57
84
14
0
2
0.0
0.7
Example

30c
30
O
12
0
15
14

41

58

0
1
0.0
1

Comparative

31
31
P
2
0
13
70
85
13
0.8
1
0.0
0.9
Example

32d
32
P
12
15
11
51
89
3
7
1

4.1

6

Comparative

33a
33
Q
38
0
18
35
91
8
0
1
0.0
1
Example

33b
33
Q
5
0
31
56
92
6
0.0
2
0.0
0.0
Example

34a
34
Q
43
0
14
26
83
15
0
2
0.0
0.4
Example

34b
34
Q
15
0
11
69
95
4
0.1
1
0.0
0.2
Example

35a
35
R
49
0
31
13
93
5
0
2
0.0
0.5
Example

35b
35
R
0
32
45
12
89
10
0.0
1
0.0
0.5
Example

36a
36
R
0
23
45
18
86
12
0
2
0.0
1
Example

36b
36
R
8
0
72
5
85
13
0.0
2
0.0
0.0
Example

37a
37
S
33
0
42
19
94
3
0
3
0.0
0.2
Example

37b
37
S
2
13
65
10
90
8
0.5
2
0.2
0.3
Example

38a
38
S
35
15
23
11
84
14
0.1
2
0.0
0.5
Example

38b
38
S
1
32
43
16
92
7
0.2
1
0.0
0.7
Example

39a
39
T
55
0
40
5
100
0
0
0
0.0
0.2
Example

39b
39
T
9
27
34
24
94
6
0.0
0
0.0
0.3
Example

40a
40
T
49
0
36
6
91
7
0
2
0.0
0.7
Example

40b
40
T
36
11
25
13
85
15
0.0
0
0.0
0.0
Example

41a
41
U
35
0
46
4
85
13
0.1
2
0.0
0.8
Example

41b
41
U
2
0
93
0
95
4
0.7
0
0.5
1.1
Example

※A value with underline indicates that the value is out of the favorable scope of the invention.

TABLE 13

Steel sheet for heat treatment

Volume fraction
Coarse
Mn-

Steel sheet

Lath structure
Aggregated
Residual

aggregated
concentrated

for heat
Hot-rolled
Chemical
M
Tempered M
B
BF
SUM
α
γ
Others
residual γ
region

treatment
steel sheet
component
%
%
%
%
%
%
%
%
%
%

42a
42
U
50
0
33
3
86
12
0
2
0.0
0.5
Example

42b
42
U
5
5
68
12
90
10
0.0
0
0.0
1.1
Example

43a
43
V
0
61
37
0
98
2
0.3
0
0.0
0.6
Example

43b
43
V
2
0
83
0
85
13
1.0
1
0.0
1.3
Example

44a
44
V
30
0
32
20
82
16
1
1
0.3
0.9
Example

44b
44
V
10
4
67
11
92
7
0.2
1
0.0
0.3
Example

45a
45
W
25
6
46
6
83
14
1
2
0.2
0.8
Example

45b
45
W
2
23
55
9
89
11
0.0
0
0.0
0.3
Example

46a
46
W
45
0
34
4
83
16
0.1
1
0.0
0.7
Example

47a
47
X
47
0
30
4
81
18
0.1
1
0.0
0.4
Example

47b
47
X
44
0
34
5
83
16
0.1
1
0.0
0.5
Example

47c
47
X
12
0
31
38
81
13
6
0

3.0

0.9

Comparative

47d
47
X
9
0
70
9
88
12
0.0
0
0.0
0.5
Example

48a
48
X
34
0
51
4
89
11
0.1
0
0.0
0.3
Example

48b
48
X
9
11
40
26
86
14
0.0
0
0.0
0.2
Example

49a
49
Y
0
31
35
22
88
10
0
2
0.0
0.5
Example

49b
49
Y
2
20
53
18
93
6
0.9
0
0.3
0.7
Example

50b
50
Y
0
0
35
25

60

30

3
7
1.3

4

Comparative

51a
51
Z
28
0
14
39
81
16
0.3
3
0.0
0.3
Example

51b
51
Z
14
4
67
0
85
13
0.5
2
0.1
0.6
Example

52a
52
Z
44
0
16
32
92
8
0
0
0.0
1
Example

52b
52
Z
7
63
13
5
88
10
0.0
2
0.0
0.0
Example

※A value with underline indicates that the value is out of the favorable scope of the invention.

TABLE 14

Steel sheet for heat treatment

Volume fraction
Coarse
Mn-

Steel sheet

Lath structure
Aggregated
Residual

aggregated
concentrated

for heat
Hot-rolled
Chemical
M
Tempered M
B
BF
SUM
α
γ
Others
residual γ
region

treatment
steel sheet
component
%
%
%
%
%
%
%
%
%
%

53
53

AA

0
0
1
5
6

93

0
1
0.0
0

Comparative

54
54

AB

3
5
54
33
95
2
1
2
0.2
1

Comparative

55
55

AC

Test was terminated due to being cracked during casting process.

Comparative

56
56

AD

Test was terminated due to being cracked during casting process.

Comparative

57
57

AE

6
0
0
10

16

72

1

11

0.3
6

Comparative

58
58

AF

Test was terminated due to being cracked during casting process.

Comparative

59
59

AG

18
5
35
27
85
8
0
7
0.0
0

Comparative

60
60

AH

Test was terminated due to being cracked during casting process.

Comparative

61
61

AI

9
7
54
18
88
7
1
4
0.0
1

Comparative

62
62

AJ

16
0
46
30
92
5
1
2
0.2
0

Comparative

63
63
AK
32
0
35
21
88
11
0.3
1
0.0
0.3
Example

64
64
AL
35
20
10
19
84
14
0.2
2
0.0
0.6
Example

65

65

I
5
0
41
17

63

37

0
0
0.0
0

Comparative

66

66

K
10
0
63
0

73

25

1
1
0.2
1

Comparative

67

67

O
15
0
8
25

48

45

6
1
1.3
1.5

Comparative

68

68

W
0
0
60
7

67

33

0
0
0.0
1.4

Comparative

1f
1
A
0
0
0
0
0
15
0

85

0.0
0.2

Comparative

3d
3
B
29
0
15
6

50

13
0

37

0.0
0.4

Comparative

※A value with underline indicates that the value is out of the scope of the invention.

Example 2: Manufacture of High-Strength Steel Sheet

By subjecting the steel sheets for heat treatment shown in Tables 10 to 14 to heat treatment (final heat treatment) under the conditions shown in Tables 15 to 20, high-strength steel sheets having excellent formability, toughness, and weldability can be obtained.

TABLE 15

Final heat treatment

Heating

Max-

Ac3-

Max-
imum

Max-

imum
heating

imum

Steel

Left
heating
tem-

heating

sheet
Hot-
Chem-
side of
tem-
per-

tem-

Dwell

Ex-
for heat
rolled
ical
For-
per-
ature-

per-

time

peri-
treat-
steel
com-
mula
ature
Ac1
Ac1
ature
Ac3
1

ment
ment
sheet
ponent
(3)
° C.
° C.
° C.
° C.
° C.
sec

1
1a
1
A
1.0
788
72
716
40
828
91

2
1a
1
A

2.3

771
55
716
57
828
108

3
1b
1
A
1.0
762
43
719
76
838
92

4
1b
1
A
1.2

733

14

719
105
838
104

5
1b
1
A
1.0

845

126
719

−7

838
94

6

1c

1
A
1.2
808
86
722
27
835
57

7

1d

1
A
0.8
795
75
720
43
838
44

8
1e
1
A
0.9
761
47
714
79
840
106

9
1e
1
A
1.5
791
77
714
49
840
42

10
2a
2
A
0.8
813
95
718
25
838
106

16
3a
3
B
1.1
788
61
727
78
866
62

17
3a
3
B
0.8
821
94
727
45
866
60

18
3h
3
B
1.2
841
116
725
20
861
90

19
3h
3
B
0.8
834
109
725
27
861
73

20
3c
3
B
0.8
829
108
721
41
870
60

21
3c
3
B
0.8
804
83
721
66
870
88

24

5a

5
C
1.0
786
55
731
60
846
45

28
6a
6
C
1.1
808
72
736
38
846
87

29
6b
6
C
0.9
776
40
736
70
846
72

30
7a
7
D
0.8
829
110
719
29
858
101

31
7b
7
D
1.0
828
119
709
32
860
48

32
8a
8
D
1.7
816
94
722
42
858
71

33
8b
8
D
1.1
779
54
725
74
853
105

Final heat treatment

Tempering

treatment

Cooling

Skin

Average

Average
Skin

pass

cooling
Left
Left
cooling
pass
Tem

rolling

Ex-
rate 1
side of
side of
rate 2
rolling
per-

after

peri-
° C./
Formula
Formula
° C./s
rate
ature
Time
tempering

ment
sec
(4)
(5)
ec
%
° C.
sec
%

1
105
0.32
0.22
1
—
345
27
0.4
Example

2
62
0.29
0.19
26
—
—
—
—

Comparative

3
83
0.55
0.38
2
0.1
360
1089
0.1
Example

4
91
0.38
0.26
16
—
—
—
—

Comparative

5
46
0.14
0.09
6
0.3
—
—
—

Comparative

6
57
0.50
0.34
9
—
—
—
—

Comparative

7
40
0.24
0.16
19
0.2
—
—
—

Comparative

8
99
0.64
0.44
6
—
288
192
—
Example

9
100
0.58
0.40
14
0.7
—
—
—
Example

10
39
0.25
0.17
2
—
—
—
—

Comparative

16
45
0.51
0.30
9
0.2
236
4
0.2
Example

17
44
0.87

1.08

9
—
—
—
—

Comparative

18
39
0.26
0.15
8
0.1
—
—
—
Example

19

13

0.53
0.31
22
0.1
—
—
—

Comparative

20
60
0.84
0.49
9
1.8
—
—
—
Example

21
103

1.38

0.82
4
1.8
—
—
—

Comparative

24
42
0.22
0.07
5
—
—
—
—

Comparative

28
68
0.29
0.09
1
0.8
—
—
—
Example

29
41
0.77
0.26
4
1.1
—
—
—
Example

30
46
0.31
0.36
14
0.1
310
50
0.8
Example

31
100
0.71
0.93
77
0.7
—
—
—
Example

32
47
0.43
0.71
7
—
340
36
0.2
Example

33
87
0.50
0.66
1
—
—
—
—
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 16

Final heat treatment

Heating

Max-

Ac3-

Max-
imum

Max-

imum
heating

imum

Steel

Left
heating
tem-

heating

sheet
Hot-
Chem-
side of
tem-
per-

tem-

Dwell

Ex-
for heat
rolled
ical
For-
per-
ature-

per-

time

peri-
treat-
steel
com-
mula
ature
Ac1
Ac1
ature
Ac3
1

ment
ment
sheet
ponent
(3)
° C.
° C.
° C.
° C.
° C.
sec

36
9c
9
E
0.9
760
43
717
55
815
60

37
10
10
E
1.2
773
55
718
45
818
58

38
11
11
F
0.9
772
42
730
70
842
42

39
12
12
F
1.4
812
83
729
34
846
60

40
13
13
G
1.2
768
62
706
40
808
72

41
14
14
G
0.9
747
47
700
63
810
58

42
15
15
H
0.9
794
89
705
76
870
57

43
16
16
H
1.2
773
70
703
92
865
90

44
17
17
I
1.2
881
165
716
53
934
101

45
18a
18
I
0.8
898
187
711
40
938
102

46
18b
18
I
0.8
835
121
714
98
933
47

47
18c
18
I
1.0
870
159
711
64
934
88

49
19a
19
J
0.8
731
44
687
83
814
88

50
19a
19
J
1.0

709

22

687
105
814
102

51
19b
19
J
1.0
790
111
679
28
818
44

52
19b
19
J
0.8
786
107
679
32
818

516

53
20a
20
J
1.1
740
53
687
74
814
60

54
206
20
J
0.9
798
113
685
14
812
77

55
21a
21
K
1.6
772
63
709
94
866
109

56
21b
21
K
1.2
840
127
713
26
866
63

57
22a
22
K
1.2
823
116
707
47
870
57

59
23
23
L
1.0
848
135
713
22
870
92

60
23
23
L
1.0
826
113
713
44
870
63

Final heat treatment

Tempering

treatment

Cooling

Skin

Average

Average
Skin

pass

cooling
Left
Left
cooling
pass
Tem

rolling

Ex-
rate 1
side of
side of
rate 2
rolling
per-

after

peri-
° C./
Formula
Formula
° C./
rate
ature
Time
tempering

ment
sec
(4)
(5)
sec
%
° C.
sec
%

36
88
0.29
0.29
2
0.1
—
—
—

Comparative

37
37
0.86
0.70
21
—
—
—
—
Example

38
83
0.74
0.43
28
—
—
—
—
Example

39
47
0.76
0.38
8
—
—
—
—
Example

40
99
0.02
0.41
3
—
—
—
—
Example

41
43
0.01
0.18
4
0.3
327
224
—
Example

42
44
0.63
0.32
26
0.8
260
18
0.7
Example

43
40
0.89
0.45
4
0.1
—
—
—
Example

44
90
0.69
0.43
17
—
—
—
—
Example

45
91
0.55
0.33
8
0.3
—
—
—

Comparative

46
45
0.95
0.51
19

371
4
—
Example

47
69
0.76
0.45
16
—
—
—
—
Example

49
40
0.30
0.61
7
0.3
—
—
—
Example

50
102
0.29
0.65
7
0.1
—
—
—

Comparative

51
38
0.38
0.82
7
1.7
—
—
—
Example

52
46
0.23
0.48
8
—
—
—
—

Comparative

53
72
0.07
0.17
15
—
—
—
—
Example

54
75
0.23
0.49
4
0.3
—
—
—
Example

55
38
0.82
0.42
26
—
—
—
—
Example

56
56
0.61
0.31
3
—
350
32
1.2
Example

57
102
0.87
0.49
8
—
312
7
0.2
Example

59
39
0.45
0.33
7
—
—
—
—
Example

60
43

1.54

0.39
2
—
—
—
—

Comparative

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 17

Final heat treatment

Heating

Max-

Ac3-

Max-
imum

Max-

imum
heating

imum

Steel

Left
heating
tem-

heating

sheet
Hot-
Chem-
side of
tem-
per-

tem-

Dwell

Ex-
for heat
rolled
ical
For-
per-
ature-

per-

time

peri-
treat-
steel
com-
mula
ature
Ac1
Ac1
ature
Ac3
1

ment
ment
sheet
ponent
(3)
° C.
° C.
° C.
° C.
° C.
sec

61
24a
24
L
0.9
794
93
701
71
865
89

62
24a
24
L
0.8
772
71
701
93
865
56

63

24b

24
L
0.8
777
67
710
89
866
46

64
24c
24
L
0.8
788
72
716
84
872
44

65
25a
25
M
0.9
880
128
752
62
942
59

66

25b

25
M
1.1
880
130
750
53
933
90

67
25c
25
M
0.9
899
154
745
36
935
73

68
26
26
M
1.2
897
142
755
43
940
89

69
27a
27
N
0.9
798
45
753
62
860
71

70

27b

27
N
1.0
800
50
750
61
861
87

71
27c
27
N
1.0
822
72
750
38
860
45

72
27c
27
N
1.1
857
107
750
3
860
47

73
28
28
N
0.8
813
60
753
47
860
64

74
29
29
O
1.0
796
82
714
72
868
109

75
30a
30
O
0.8
817
107
710
46
863
43

76
30a
30
O
1.1
840
130
710
23
863
59

77
30b
30
O
0.9
804
90
714
66
870
77

78

30c

30
O
0.9
770
59
711
93
863
48

80
31
31
P
1.1
885
142
743
27
912
62

85

32d

32
P
1.0
835
102
733
67
902
63

86
33a
33
Q
1.0
832
105
727
88
920
60

87
33h
33
Q
1.2
890
163
727
32
922
60

88
34a
34
Q
0.9
876
141
735
44
920
94

Final heat treatment

Tempering

treatment

Cooling

Skin

Average

Average
Skin

pass

cooling
Left
Left
cooling
pass
Tem

rolling

Ex-
rate 1
side of
side of
rate 2
rolling
per-

after

peri-
° C./
Formula
Formula
° C./
rate
ature
Time
tempering

ment
sec
(4)
(5)
sec
%
° C.
sec
%

61
47
0.32
0.13
26
—
—
—
—
Example

62

23

0.81
0.22
5
0.7
—
—
—

Comparative

63
46
0.70
0.23
28
0.1
—
—
—

Comparative

64
38
0.62
0.21
12
0.1
—
—
—
Example

65
43
0.47
0.08
12
0.2
—
—
—
Example

66
55
0.37
0.06
24
—
—
—
—

Comparative

67
41
0.44
0.07
11
—
514
6
—
Example

68
107
0.76
0.13
11
—
—
—
—
Example

69
44
0.89
0.21
8
—
—
—
—
Example

70
46
0.88
0.19
8
0.3
—
—
—

Comparative

71
106
0.36
0.07
13
—
436
24
0.1
Example

72
47
0.89
0.21
9
—
—
—
—
Example

73
55
0.78
0.21
29
0.6
—
—
—
Example

74
40
0.72
0.14
7
—
—
—
—
Example

75
39
0.43
0.12
4
—
—
—
—
Example

76
71
0.49
0.10
12
—
—
—
—
Example

77
103
0.85
0.17
17
0.7
421
18
1.2
Example

78
39
0.87
0.20
6
—
—
—
—

Comparative

80
61
0.72
0.17
14
—
—
—
—
Example

85
38
0.66
0.20
2
—
—
—
—

Comparative

86
54
0.75
0.28
18
1.1
—
—
—
Example

87
106
0.93
0.33
16
—
—
—
—
Example

88
47
0.54
0.21
4
—
216
5663
0.2
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 18

Final heat treatment

Heating

Max-

Ac3-

Max-
imum

Max-

imum
heating

imum

Steel

Left
heating
tem-

heating

sheet
Hot-
Chem-
side of
tem-
per-

tem-

Dwell

Ex-
for heat
rolled
ical
For-
per-
ature-

per-

time

peri-
treat-
steel
com-
mula
ature
Ac1
Ac1
ature
Ac3
1

ment
ment
sheet
ponent
(3)
° C.
° C.
° C.
° C.
° C.
sec

89
34a
34
Q
1.0
870
135
735
50
920
105

90
34b
34
Q
1.1
895
170
725
24
919
109

91
35a
35
R
1.0
790
65
725
58
848
89

92
35a
35
R
1.1

860

135
725

−12
848
87

93
35b
35
R
0.8
812
92
720
30
842
107

94
36a
36
R
0.9
785
55
730
65
850
75

95
36b
36
R
1.3
799
77
722
51
850
58

96
37a
37
S
1.2
771
64
707
79
850
103

97
37a
37
S
1.8
764
57
707
86
850
56

98
37b
37
S
1.0
820
116
704
31
851
61

99
37b
37
S
0.8
735
31
704
116
851
109

100
38a
38
S
1.0
781
79
702
64
845
89

101
38b
38
S
1.1
787
81
706
61
848
75

102
39a
39
T
0.9
805
121
684
29
834
102

103
39b
39
T
0.8
808
118
690
30
838
57

104
40a
40
T
1.1
818
145
673
16
834
62

105
40b
40
T
1.1
796
106
690
44
840
74

106
41a
41
U
1.9
896
150
746
94
990
72

107
41b
41
U
1.2
890
140
750
90
980
56

108
41b
41
U
0.9
897
147
750
83
980
58

109
42a
42
U
1.1
920
184
736
65
985
90

110
42b
42
U
0.8
911
166
745
77
988
75

111
43a
43
V
1.4
843
126
717
25
868
105

Final heat treatment

Tempering

treatment

Cooling

Skin

Average

Average
Skin

pass

cooling
Left
Left
cooling
pass
Tem

rolling

Ex-
rate 1
side of
side of
rate 2
rolling
per-

after

peri-
° C./
Formula
Formula
° C./
rate
ature
Time
tempering

ment
sec
(4)
(5)
sec
%
° C.
sec
%

89
6
0.33
0.11
28
—
—
—
—

Comparative

90
38
0.84
0.24
4
—
—
—
—
Example

91
89
0.59
0.31
25
0.3
—
—
—
Example

92
89
0.48
0.25
22
—
—
—
—

Comparative

93
88
0.89
0.38
13
0.2
325
1979
—
Example

94
85
0.85
0.41
18
0.1
420
105
0.2
Example

95
47
0.70
0.38
2
0.3
—
—
—
Example

96
54
0.37
0.23
22
0.1
—
—
—
Example

97
86
0.64
0.35
23
—
—
—
—
Example

98
85
0.75
0.38
17
—
363
16
0.2
Example

99
70
0.83
0.47
3
—
—
—
—
Example

100
72
0.67
0.34
11
0.2
455
10
—
Example

101
83
0.68
0.51
19
—
—
—
—
Example

102
100
0.34
0.42
5
—
379
112
0.2
Example

103
42
0.23
0.27
25
0.1
298
80
0.1
Example

104
56
0.46
0.62
14
0.1
—
—
—
Example

105
55
0.71
0.94
1
0.2
—
—
—
Example

106
44
0.66
0.19
2
0.8
—
—
—
Example

107
41
0.92
0.25
19
—
—
—
—
Example

108
76
0.64
0.32
7
—
—
—
—
Example

109
40
0.46
0.21
18
0.3
252
17
0.3
Example

110
43
0.36
0.18
7
—
—
—
—
Example

111
42
0.47
0.19
126
—
—
—
—
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 19

Final heat treatment

Heating

Max-

Ac3-

Max-
imum

Max-

imum
heating

imum

Steel

Left
heating
tem-

heating

sheet
Hot-
Chem-
side of
tem-
per-

tem-

Dwell

Ex-
for heat
rolled
ical
For-
per-
ature-

per-

time

peri-
treat-
steel
com-
mula
ature
Ac1
Ac1
ature
Ac3
1

ment
ment
sheet
ponent
(3)
° C.
° C.
° C.
° C.
° C.
sec

112
43a
43
V
1.1
823
106
717
45
868
61

113
43b
43
V
1.2
809
79
730
49
858
58

114
44a
44
V
1.1
845
122
723
22
867
59

115
44a
44
V
1.1
798
75
723
69
867
143

116
44b
44
V
1.1
803
88
715
67
870
63

117
45a
45
W
0.9
816
116
700
30
846
73

118
45b
45
W
1.2
792
92
700
54
846
57

119
46a
46
W
1.2
797
92
705
45
842
106

121
47a
47
X
1.1
753
69
684
57
810
109

122
47b
47
X
0.8
790
100
690
20
810
87

123

47c

47
X
0.9
726
43
683
82
808
102

124
47d
47
X
1.2
737
47
690
65
802
136

125
48a
48
X
1.1
749
66
683
62
811
76

126
48a
48
X
1.0
777
94
683
34
811
103

127
48b
48
X
1.2
790
100
690
20
810
42

128
49a
49
Y
0.9
778
72
706
78
856
124

129
49b
49
Y
1.2
803
87
716
37
840
71

131
50b

50

Y
0.8
823
103
720
23
846
94

132
51a
51
Z
0.9
792
53
739
92
884
59

133
51a
51
Z
1.0
855
116
739
29
884
90

134
51b
51
Z
1.5
793
49
744
87
880
56

135
52a
52
Z
1.0
775
35
740
95
870
86

136
52b
52
Z
0.9
800
65
735
85
885
105

Final heat treatment

Tempering

treatment

Cooling

Skin

Average

Average
Skin

pass

cooling
Left
Left
cooling
pass
Tem

rolling

Ex-
rate 1
side of
side of
rate 2
rolling
per-

after

peri-
° C./
Formula
Formula
° C./
rate
ature
Time
tempering

ment
sec
(4)
(5)
sec
%
° C.
sec
%

112
40
0.67
0.24
26
—
—
—
—
Example

113
41
0.60
0.23
23
0.3
320
638
—
Example

114
58
0.76
0.21
124
—
405
135
0.1
Example

115
84
0.30
0.08
2
—
—
—
—
Example

116
45
0.88
0.31
8
0.2
—
—
—
Example

117
83
0.71
0.61
26
—
320
50
—
Example

118
70
0.88
0.78
3
0.1
—
—
—
Example

119
59
0.14
0.12
11
0.2
271
126
—
Example

121
31
0.41
0.56
5
0.7
—
—
—
Example

122
60
0.31
0.47
18
0.3
450
2
1.2
Example

123
38
0.33
0.43
9
—
—
—
—

Comparative

124
61
0.28
0.39
1
—
—
—
—
Example

125
39
0.19
0.34
29
—
—
—
—
Example

126
42
0.87

1.05

4
1.8
—
—
—

Comparative

127
92
0.35
0.62
15
1.7
—
—
—
Example

128
41
0.32
0.31
14
0.3
—
—
—
Example

129
45
0.72
0.55
5
—
381
24
—
Example

131
105
0.45
0.37
19
0.1
—
—
—

Comparative

132
38
0.23
0.13
12
—
471
40
—
Example

133
99
0.92
0.52
26
—
—
—
—
Example

134
106
0.44
0.30
25
1.8
—
—
—
Example

135
47
0.68
0.43
14
0.1
—
—
—
Example

136
72
0.44
0.27
4
1.3
399
27
1.8
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 20

Final heat treament

Heating

Max-

Ac3-

Max-
imum

Max-

imum
heating

imum

Steel

Left
heating
tem-

heating

sheet
Hot-
Chem-
side of
tem-
per-

tem-

Dwell

Ex-
for heat
rolled
ical
For-
per-
ature-

per-

time

peri-
treat-
steel
com-
mula
ature
Ac1
Ac1
ature
Ac3
1

ment
ment
sheet
ponent
(3)
° C.
° C.
° C.
° C.
° C.
sec

137
53
53

AA

1.0
784
43
741
88
872
90

138
54
54

AB

0.9
761
54
707
41
802
104

139
55
55

AC

140
56
56

AD

141
57
57

AE

1.2
867
132
735
61
928
109

142
58
58

AF

143
59
59

AG

0.9
813
109
704
31
844
106

144
60
60

AH

145
61
61

AI

1.2
768
65
703
78
846
104

146
62
62

AJ

1.1
757
55
702
81
838
92

147
63
63
AK
1.1
798
79
719
40
838
45

148
64
64
AL
0.9
810
57
753
50
860
60

149
65

65

I
0.8
860
144
716
75
935
74

150
66

66

K
1.1
798
94
704
70
868
109

151
67

67

O
1.2
844
132
712
23
867
43

152
68

68

W
1.0
817
115
702
28
845
101

153

1f

1
A
1.1
790
77
713
34
824
81

154

3d

3
B
1.1
840
120
720
27
867
75

Final heat treatment

Tempering

treatment

Cooling

Skin

Average

Average
Skin

pass

cooling
Left
Left
cooling
pass
Tem

rolling

Ex-
rate 1
side of
side of
rate 2
rolling
per-

after

peri-
° C./
Formula
Formula
° C./
rate
ature
Time
tempering

ment
sec
(4)
(5)
sec
%
° C.
sec
%

137
41
0.48
0.23
19
—
—
—
—

Comparative

138
46
0.54
0.26
18
—
—
—
—

Comparative

139

Comparative

140

Comparative

141
47
0.92
0.24
2
—
—
—
—

Comparative

142

Comparative

143
40
0.44
0.23
17
—
—
—
—

Comparative

144

Comparative

145
41
0.39
0.22
3
—
—
—
—

Comparative

146
72
0.43
0.17
8
—
—
—
—

Comparative

147
80
0.55
0.39
13
0.2
—
—
—
Example

148
55
0.75
0.23
27
0.1
—
—
—
Example

149
85
0.19
0.12
7
—
—
—
—

Comparative

150
41
0.83
0.47
27
0.1
—
—
—

Comparative

151
46
0.89
0.24
25
—
—
—
—

Comparative

152
44
0.36
0.33
7
0.6
—
—
—

Comparative

153
95
0.31
0.17
5
—
—
—
—

Comparative

154
41
0.23
0.22
10
—
—
—
—

Comparative

※A value with underline indicates that the value is out of the scope of the invention.

Some of the steel sheets for heat treatment were subjected to the plating treatment under conditions shown in Table 21 in addition to the heattreatment shown in Tables 15 to 20. In Table 21, GA represents an alloyed hot-dip galvanized steel sheet, GI represents a non-alloyed hot-dip galvanized steel sheet, and EG represents an electroplated steel sheet.

TABLE 21

Hot dip galvanizing

Plating
Steel
Effective

Steel
Hot-

bath
sheet
amount of
Alloying treatment

sheet
rolled

temper-
temper-
Al in
Temper-

Experi-
for heat
steel
Chemical

ature
ature
plating bath
ature
Time

ment
treatment
sheet
component
Surface
° C.
° C.
%
° C.
sec

3
1b
1
A
GA
453
437
0.09
561
12
Example

9
1e
1
A
GI
459
449
0.25
—
—
Example

20
3c
3
B
GI
456
451
0.13
—
—
Example

31
7b
7
D
EG
—
—
—
—
—
Example

32
8a
8
D
GI
456
461
0.21
—
—
Example

54
20b
20
J
GA
458
440
0.07
561
5
Example

55
21a
21
K
GI
464
471
0.25
—
—
Example

67
25c
25
M
GA
466
472
0.07
514
6
Example

72
27c
27
N
GA
461
454
0.07
550
35
Example

75
30a
30
O
GA
452
453
0.12
549
12
Example

87
33b
33
Q
GA
464
461
0.07
494
19
Example

91
35a
35
R
GI
452
468
0.20
—
—
Example

93
35b
35
R
EG
—
—
—
—
—
Example

94
36a
36
R
GA
461
446
0.12
560
23
Example

99
37b
37
S
EG
—
—
—
—
—
Example

100
38a
38
S
GA
456
457
0.12
508
28
Example

102
39a
39
T
GI
459
459
0.28
—
—
Example

103
39b
39
T
EG
—
—
—
—
—
Example

106
41a
41
U
GA
466
449
0.08
532
24
Example

116
44b
44
V
EG
—
—
—
—
—
Example

118
45b
45
W
GI
456
461
0.09
—
—
Example

119
46a
46
W
EG
—
—
—
—
—
Example

121
47a
47
X
GA
452
459
0.10
555
14
Example

125
48a
48
X
GA
453
458
0.11
571
17
Example

132
51a
51
Z
GA
454
444
0.04
471
40
Example

※A value with underline indicates that the value is out of the scope of the invention.

Tables 22 to 27 show microstructures and properties of the obtained high-strength steel sheets. In the microstructures, acicular α represents acicular ferrite, aggregated α represents aggregated ferrite, M represents martensite, tempered M represents tempered martensite, B represents bainite, BF represents bainitic ferrite, and residual γ represents residual austenite.

TABLE 22

High-strength steel sheet

Mechanical

Microstructure fraction

characteristics

(Perc-

Average

Left

Steel
Hot-

Aci-
Aggre-

entage of

Re-

Left
diameter of

side of
Impact
Spot

sheet
rolled
Chemical

cular
gated

Tem-

sidual

side of
carbides in

Formula
characteristics
weldability

Experi-
for heat
steel
com-

α
α
M
pered M)
B
BF
γ
Others
Formula
Tempered M
TS
El
λ
(6) ×
T_TR
E_B/
E_C
E_T
E_C/

ment
treatment
sheet
ponent
Plating
%
%
%
%
%
%
%
%
(A)
μm
MPa
%
%
10⁶
° C.
E_RT
kN
kN
E_T

1
1a
1
A
—
57
7
24
67
8
4
0.1
0
5.9
0.4
961
19
51
4.0
−90
0.29
20.7
46.2
0.45
Example

2
1a
1
A
—
47
5
37
12
6
3
1.1
0

12.8

0.2
1207
14
42
3.8
−20

0.10

19.8
47.2
0.42

Comparative

3
1b
1
A
GA
44
3
30
100
10
12
1.0
0
8.1
0.7
969
19
55
4.3
−70
0.31
9.3
24.0
0.39
Example

4
1b
1
A
—
26
1
39
21
13
8
0.7

12
6.2
0.1
748
18
27

1.9

−50
0.28
6.8
18.9
0.36

Comparative

5
1b
1
A
—
0

43

22
0
25
10
0.3
0

10.9

—
962
15
24

2.2

−30

0.10

5.0
18.6

0.27

Comparative

6

1c

1
A
—
65
0
19
0
12
0

4.0

0
6.5
—
1054
19
32
3.7
−40

0.08

7.7
20.3
0.38

Comparative

7

1d

1
A
—

14

51

15
0
9
10
0.6
0

10.8

—
873
18
22

2.2

−20
0.24
5.5
18.8

0.29

Comparative

8
1e
1
A
—
43
5
26
55
8
15
1.0
2
5.8
0.2
948
17
62
3.9
−40
0.33
18.1
43.0
0.42
Example

9
1e
1
A
GI
54
8
19
0
8
9
0.6
1
8.4
—
927
18
56
3.8
−40
0.29
22.5
51.0
0.44
Example

10
2a

2

A
—
0

53

16
0
13
14

3.5

1

11.1

—
906
18
28

2.6

20
0.35
5.1
21.2

0.24

Comparative

16
3a
3
B
—
48
4
32
36
8
7
0.5
1
7.2
<0.1
892
18
66
3.9
−70
0.31
13.2
28.8
0.46
Example

17

3a
3
B
—
57
5
3
0
11
12
1.4

11
<5.0
—

563

28
61

2.9

—
—
—
—
—

Comparative

18
3b
3
B
—
61
11
23
0
2
1
0.4
2
6.0
—
931
17
61
3.8
−60
0.34
15.3
33.9
0.45
Example

19

3b
3
B
—

18

46

18
0
10
7
0.9
0
8.1
—
894
18
28

2.5

−40
0.26
10.1
31.7

0.32

Comparative

20
3c
3
B
GI
63
7
14
0
1
12
0.9
2
5.9
—
705
25
72
4.0
−40
0.30
2.9
5.9
0.48
Example

21

3c
3
B
—
46
5
11
0
0
33

5.4

0
7.1
—
713
34
32
3.6
−50

0.12

2.4
5.9
0.41

Comparative

24
5a

5

C
—

10

61

14
0
0
10

4.8

0

11.5

—
1124
16
15

2.3

10

0.12

13.7
42.8

0.32

Comparative

28
6a
6
C
—
59
9
29
0
2
0
0.5
I
4.8
—
1372
11
48
3.9
−60
0.31
5.9
16.8
0.35
Example

29
6b
6
C
—
40
8
39
8
3
10
0.4
0
5.0
0.1
1334
12
41
3.7
−40
0.23
19.7
56.2
0.35
Example

30
7a
7
D
—
54
13
16
54
9
6
0.6
1
6.7
0.4
667
24
83
3.8
−60
0.27
31.8
72.4
0.44
Example

31
7b
7
D
EG
50
6
12
0
11
18
1.0
2
5.2
—
625
28
76
3.8
−50
0.22
25.2
58.8
0.43
Example

32
8a
8
D
GI
53
7
11
62
15
13
1.0
0
8.2
0.4
590
27
97
3.8
−60
0.22
3.5
7.5
0.47
Example

33
8b
8
D
—
47
6
12
0
13
20
1.4
0
4.8
—
650
25
83
3.8
−60
0.19
14.0
34.5
0.41
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 23

High-strength steel sheet

Mechanical

Microstructure fraction

characteristics

(Perc-

Average

Left

Steel
Hot-

Aci-
Aggre-

entage of

Re-

Left
diameter of

side of
Impact
Spot

sheet
rolled
Chemical

cular
gated

Tem-

sidual

side of
carbides in

Formula
characteristics
weldability

Experi-
for heat
steel
com-

α
α
M
pered M)
B
BF
γ
Others
Formula
Tempered M
TS
El
λ
(6) ×
T_TR
E_B/
E_C
E_T
E_C/

ment
treatment
sheet
ponent
Plating
%
%
%
%
%
%
%
%
(A)
μm
MPa
%
%
10⁶
° C.
E_RT
kN
kN
E_T

36
9c
9
E
—
32
8
25
10
20
11

2.5

2

11.5
0.2
1208
16
29
3.6

−20

0.08

10.5
30.1
0.35

Comparative

37
10
10
E
—
54
9
10
0
2
23
0.6
1
<5.0
—
842
20
58
3.7
−50
0.26
11.9
30.6
0.39
Example

38
11
11
F
—
46
3
23
0
10
17
0.5
1
5.8
—
1091
15
49
3.8
−70
0.22
10.2
24.3
0.42
Example

39
12
12
F
—
66
3
20
0
4
7
0.1
0
9.2
—
1150
15
47
4.0
−80
0.35
13.1
30.7
0.43
Example

40
13
13
G
—
63
0
24
0
13
0
0.1
0
6.5
—
1095
16
48
4.0
−50
0.30
21.6
51.5
0.42
Example

41
14
14
G
—
54
0
38
63
8
0
0.0
0
7.3
0.3
1150
13
67
4.1
−60
0.33
21.7
51.6
0.42
Example

42
15
15
H
—
58
2
22
39
8
8
0.7
1
7.7
0.2
937
18
61
4.0
−80
0.20
16.0
36.4
0.44
Example

43
16
16
H
—
49
4
22
0
2
20
0.8
2
7.7
—
901
20
51
3.9
−60
0.32
16.0
41.2
0.39
Example

44
17
17
I
—
70
2
15
0
2
8
0.7
2
6.5
—
888
19
63
4.0
−80
0.30
14.3
31.1
0.46
Example

45
18a
18
I
—
75
0
14
17
6
4
1.3
0

12.0
<0.1
763
26
45
3.7

−10

0.28
4.4
11.2
0.39

Comparative

46
18b
18
I
—
61
0
19
54
0
18
1.5
1
7.8
0.5
923
17
73
4.1
−70
0.23
5.6
13.5
0.42
Example

47
18c
18
I
—
72
0
14
0
3
9
0.4
2
5.5
—
894
19
67
4.2
−80
0.21
2.8
5.8
0.47
Example

49
19a
19
J
—
36
5
24
0
19
15
0.3
1
4.5
—
1067
15
49
3.7
−40
0.25
16.5
41.1
0.40
Example

50

19a
19
J
—
27
2
25
0
22
13
0.4

11
6.9
—
816
12
16

1.1

−40
0.27
15.4
40.4
0.38

Comparative

51
19b
19
J
—
55
14
13
0
12
6
0.2
0
5.7
—
1004
19
36
3.6
−50
0.22
28.2
71.8
0.39
Example

52

19b
19
J
—

15

33
32
8
19
1
0.0
0

11.5
0.1
1270
10
18

1.9

10
0.32
20.6
68.8

0.30

Comparative

53
20a
20
J
—
46
7
39
20
6
1
0.1
1
6.0
0.4
1363
11
46
3.8
−60
0.22
10.6
27.8
0.38
Example

54
20b
20
J
GA
70
6
12
0
8
1
0.6
2
6.2
—
1013
18
44
3.8
−80
0.20
15.4
31.7
0.49
Example

55
21a
21
K
GI
46
6
24
0
4
17
0.8
2
9.1
—
796
22
57
3.7
−70
0.21
9.6
23.1
0.42
Example

56
21b
21
K
—
47
14
11
72
12
15
0.6
0
7.8
0.5
686
29
55
3.9
−70
0.33
11.5
26.2
0.44
Example

57
22a
22
K
—
62
9
14
43
1
11
1.2
2
6.5
0.1
765
23
67
4.0
−70
0.24
11.0
25.2
0.44
Example

59
23
23
L
—
71
9
14
0
3
2
0.7
0
8.1
—
803
25
44
3.8
−70
0.32
16.1
32.4
0.50
Example

60

23
23
L
—
65
8
11
0
2
10

3.0

1
<5.0
—
638
34
42
3.6
−60

0.12

12.5
24.6
0.51

Comparative

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 24

High-strength steel sheet

Mechanical

Microstructure fraction

characteristics

(Perc-

Average

Left

Steel
Hot-

Aci-
Aggre-

entage of

Re-

Left
diameter of

side of
Impact
Spot

sheet
rolled
Chemical

cular
gated

Tem-

sidual

side of
carbides in

Formula
characteristics
weldability

Experi-
for heat
steel
com-

α
α
M
pered M)
B
BF
γ
Others
Formula
Tempered M
TS
El
λ
(6) ×
T_TR
E_B/
E_C
E_T
E_C/

ment
treatment
sheet
ponent
Plating
%
%
%
%
%
%
%
%
(A)
μm
MPa
%
%
10⁶
° C.
E_RT
kN
kN
E_T

61
24a
24
L
—
52
8
35
41
3
1
0.5
1
6.6
0.3
904
16
74
3.7
−80
0.34
11.6
25.9
0.45
Example

62

24a
24
L
—

14

30

34
18
9
12
1.3
0
8.2
0.6
910
14
28

2.0

−40
0.21
7.1
24.6

0.29

Comparative

63

24b

24
L
—
6

81

6
0
7
0
0.2
0

10.5
—
654
31
37

3.2

−20

0.10

8.2
25.7

0.32

Comparative

64
24c
24
L
—
53
6
32
10
3
4
0.5
2
4.6
0.4
838
18
75
3.8
−60
0.26
38.2
84.8
0.45
Example

65
25a
25
M
—
65
7
25
0
1
1
0.8
0
5.2
—
999
20
40
4.0
−60
0.24
3.6
7.8
0.47
Example

66

25b

25
M
—
49
12
12
0
0
25
1.6
0

13.1
—
704
25
61
3.6
−10
0.31
2.5
6.4
0.39

Comparative

67
25c
25
M
GA
63
11
22
100
2
1
1.1
0
6.5
0.9
933
21
51
4.3
−60
0.22
24.9
53.5
0.47
Example

68
26
26
M
—
64
8
24
0
1
2
0.8
0
6.8
—
976
18
48
3.8
−70
0.18
17.2
33.7
0.51
Example

69
27a
27
N
—
47
6
34
0
2
10
0.4
I
7.6
—
1292
13
39
3.8
−60
0.24
9.5
23.4
0.41
Example

70

27b

27
N
—
47
0
24
15
15
12
1.1
I

11.0
0.3
867
22
42
3.6
10
0.25
10.0
23.3
0.43

Comparative

71
27c
27
N
—
58
11
27
100
1
0
0.6
2
5.2
0.7
1237
14
49
4.3
−70
0.21
21.8
53.6
0.41
Example

72
27c
27
N
GA
57
17
23
0
0
1
0.7
1
6.0
—
1261
15
31
3.7
−50
0.30
21.8
53.5
0.41
Example

73
28
28
N
—
59
2
29
0
2
5
0.7
2
6.1
—
1329
13
39
3.9
−70
0.20
26.3
61.0
0.43
Example

74
29
29
O
—
52
4
36
15
2
3
1.6
1
5.0
0.1
1137
16
38
3.8
−40
0.25
25.0
62.6
0.40
Example

75
30a
30
O
GA
67
0
28
0
2
2
1.0
0
5.2
—
1151
15
44
3.9
−60
0.27
4.1
8.2
0.50
Example

76
30a
30
O
—
77
0
19
0
2
1
0.8
0
5.0
—
1072
19
36
4.0
−80
0.24
4.0
8.7
0.46
Example

77
30b
30
O
—
58
8
26
92
1
4
1.4
2
5.5
0.4
1020
19
47
4.2
−80
0.18
11.2
23.9
0.47
Example

78

30c

30
O
—
0

76

12
12
0
11
1.2
0

10.3
0.2
750
18
12

1.3

−30

0.12

5.5
18.5

0.30

Comparative

80
31
31
P
—
68
11
17
0
1
2
1.1
0
6.4
—
1140
17
37
4.0
−50
0.23
11.7
24.9
0.47
Example

85
32d

32

P
—
43
0
18
0
14
19

5.6

0

11.4
—
660
35
47
4.1
−20

0.12

9.0
21.4
0.42

Comparative

86
33a
33
Q
—
54
5
30
0
2
8
1.3
0
6.0
—
799
22
61
3.9
−50
0.18
7.3
17.5
0.42
Example

87
33b
33
Q
GA
73
5
15
0
0
6
0.4
1
5.2
—
753
24
65
4.0
−50
0.30
19.3
42.2
0.46
Example

88
34a
34
Q
—
64
12
16
56
3
4
0.6
0
6.0
0.3
681
29
58
3.9
−60
0.29
7.7
16.4
0.47
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 25

High-strength steel sheet

Mechanical

Microstructure fraction

characteristics

(Perc-

Average

Left

Steel
Hot-

Aci-
Aggre-

entage of

Re-

Left
diameter of

side of
Impact
Spot

sheet
rolled
Chemical

cular
gated

Tem-

sidual

side of
carbides in

Formula
characteristics
weldability

Experi-
for heat
steel
com-

α
α
M
pered M)
B
BF
γ
Others
Formula
Tempered M
TS
El
λ
(6) ×
T_TR
E_B/
E_C
E_T
E_C/

ment
treatment
sheet
ponent
Plating
%
%
%
%
%
%
%
%
(A)
μm
MPa
%
%
10⁶
° C.
E_RT
kN
kN
E_T

89
34a
34
Q
—

15

43
17
0
13
10
0.4
2
8.6
—
730
23
31

2.5

−40
0.24
4.9
15.4

0.32

Comparative

90
34b
34
Q
—
77
4
12
0
1
4
1.0
1
<5.0
—
756
25
61
4.1
−60
0.21
20.1
43.8
0.46
Example

91
35a
35
R
GI
53
3
27
0
6
10
0.6
0
7.1
—
1025
17
51
4.0
−60
0.32
6.2
13.8
0.45
Example

92
35a
35
R
—
0

36
25
15
15
23
0.9
0

12.5
0.4
961
13
26

2.0

−30

0.06

2.9
12.2

0.24

Comparative

93
35b
35
R
EG
66
7
15
100
1
10
1.3
0
6.8
0.2
818
23
60
4.2
−70
0.22
15.9
32.2
0.49
Example

94
36a
36
R
GA
51
6
24
100
4
13
1.5
1
6.6
0.5
838
22
55
4.0
−80
0.23
4.6
10.3
0.44
Example

95
36b
36
R
—
56
9
20
0
5
8
0.0
2
9.1
—
865
20
56
3.8
−70
0.22
11.7
27.1
0.43
Example

96
37a
37
S
—
49
1
38
16
9
3
0.3
0
5.5
<0.1
1116
14
54
3.8
−50
0.30
19.6
43.4
0.45
Example

97
37a
37
S
—
48
1
31
0
7
13
0.4
0
9.3
—
1077
14
60
3.8
−50
0.33
20.5
49.9
0.41
Example

98
37b
37
S
—
69
6
14
69
2
8
0.9
0
4.9
0.3
834
21
66
4.1
−80
0.30
19.0
44.4
0.43
Example

99
37b
37
S
EG
30
2
39
0
5
23
0.8
0
7.6
—
1002
14
66
3.6
−40
0.31
18.4
44.7
0.41
Example

100
38a
38
S
GA
51
7
26
100
4
10
1.0
1
5.8
0.6
895
21
54
4.1
−60
0.27
26.7
61.3
0.44
Example

101
38b
38
S
—
61
4
15
0
7
12
0.6
0
6.4
—
858
19
70
4.0
−70
0.22
25.2
59.4
0.42
Example

102
39a
39
T
GI
75
0
14
76
6
3
0.2
2
6.2
0.4
844
19
77
4.1
−80
0.32
22.9
50.8
0.45
Example

103
39b
39
T
EG
74
5
15
46
5
1
0.1
0
6.6
0.1
938
17
69
4.1
−90
0.23
32.4
64.9
0.50
Example

104
40a
40
T
—
65
6
12
0
8
8
0.8
0
<5.0
—
760
24
61
3.9
−70
0.26
6.0
13.8
0.44
Example

105
40b
40
T
—
48
11
11
0
10
19
0.7
0
7.7
—
682
29
52
3.7
−50
0.30
7.5
18.0
0.41
Example

106
41a
41
U
GA
60
9
23
0
1
6
1.0
0
9.6
—
955
19
47
3.8
−50
0.32
2.2
5.5
0.41
Example

107
41b
41
U
—
62
3
26
0
1
7
1.3
0
5.8
—
1083
15
57
4.0
−80
0.22
14.6
35.6
0.41
Example

108
41b
41
U
—
61
3
27
0
3
5
1.4
0
5.2
—
1094
17
40
3.9
−80
0.25
17.3
37.5
0.46
Example

109
42a
42
U
—
60
10
22
33
3
3
0.4
2
4.8
0.3
1015
16
58
3.9
−70
0.35
2.5
5.8
0.43
Example

110
42b
42
U
—
62
8
23
0
4
2
1.0
0
6.9
—
1012
17
50
3.9
−70
0.23
18.7
40.2
0.46
Example

111
43a
43
V
—
76
2
17
0
2
2
0.9
0
8.5
—
988
16
61
3.9
−80
0.21
15.3
33.6
0.46
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 26

High-strength steel sheet

Mechanical

Microstructure fraction

characteristics

(Perc-

Average

Left

Steel
Hot-

Aci-
Aggre-

entage of

Re-

Left
diameter of

side of
Impact
Spot

sheet
rolled
Chemical

cular
gated

Tem-

sidual

side of
carbides in

Formula
characteristics
weldability

Experi-
for heat
steel
com-

α
α
M
pered M)
B
BF
γ
Others
Formula
Tempered M
TS
El
λ
(6) ×
T_TR
E_B/
E_C
E_T
E_C/

ment
treatment
sheet
ponent
Plating
%
%
%
%
%
%
%
%
(A)
μm
MPa
%
%
10⁶
° C.
E_RT
kN
kN
E_T

112
43a
43
V
—
69
2
20
0
3
5
0.5
1
6.7
—
962
15
81
4.0
−60
0.21
12.8
28.9
0.44
Example

113
43b
43
V
—
60
9
22
76
4
3
1.2
1
5.4
0.3
945
18
60
4.1
−60
0.32
62.1
153.0
0.41
Example

114
44a
44
V
—
65
14
15
100
1
2
1.3
2
4.8
0.4
873
25
45
4.3
−70
0.19
4.8
9.6
0.50
Example

115
44a
44
V
—
50
9
36
0
3
1
0.8
0
7.1
—
1115
16
40
3.8
−40
0.22
3.3
8.3
0.40
Example

116
44b
44
V
EG
56
5
27
0
2
9
1.1
0
7.3
—
945
18
53
3.8
−70
0.30
22.9
49.6
0.46
Example

117
45a
45
W
—
58
11
16
39
4
10
0.7
0
5.9
0.2
816
25
45
3.9
−50
0.20
4.4
9.5
0.47
Example

118
45b
45
W
GI
56
7
11
0
8
15
0.7
2
4.6
—
771
24
53
3.7
−60
0.32
9.9
23.2
0.42
Example

119
46a
46
W
EG
56
11
28
45
4
1
0.4
0
8.3
0.1
1133
15
46
3.9
−60
0.32
4.2
9.4
0.45
Example

121
47a
47
X
GA
50
13
16
0
13
7
0.4
1
7.7
—
1003
15
59
3.7
−40
0.22
4.9
12.2
0.40
Example

122
47b
47
X
—
66
13
11
48
7
2
0.2
1
3.9
0.8
905
20
54
4.0
−90
0.21
5.6
13.6
0.41
Example

123

47c

47
X
—
46
16
13
0
20
2
1.5
1

11.7
—
768
25
44
3.5
0
0.23
7.0
17.4
0.40

Comparative

124
47d
47
X
—
47
5
29
0
16
3
0.4
0
4.7
—
1165
15
39
3.7
−50
0.31
15.6
39.4
0.40
Example

125
48a
48
X
GA
51
7
25
0
12
3
0.4
2
5.4
—
1142
15
43
3.8
−40
0.34
5.4
13.3
0.41
Example

126

48a
48
X
—
66
9
0
—
6
7
0.8

11
—
—

526

29
56

2.6

—
—
—
—
—

Comparative

127
48b
48
X
—
62
12
13
0
10
3
0.4
0
5.7
—
1000
20
37
3.8
−50
0.35
9.2
22.9
0.40
Example

128
49a
49
Y
—
55
6
26
0
10
3
0.4
0
5.5
—
1217
14
42
3.9
−70
0.34
4.4
9.8
0.45
Example

129
49b
49
Y
—
60
5
18
66
4
11
1.1
1
4.6
0.2
936
19
57
4.1
−80
0.31
8.7
20.9
0.42
Example

131
50b

50

Y
—

12

33

32
0
2
17

4.4

0
9.0
—
1020
13
6

1.0

10

0.13

10.0
35.6

0.28

Comparative

132
51a
51
Z
GA
42
8
41
100
7
2
0.2
0
7.8
0.5
1217
11
70
3.9
−70
0.25
5.0
12.4
0.40
Example

133
51a
51
Z
—
59
13
13
0
4
11
0.3
0
5.9
—
925
20
43
3.7
−60
0.27
5.0
12.5
0.40
Example

134
51b
51
Z
—
45
5
35
23
8
6
0.7
0
8.7
0.1
1193
12
60
3.8
−50
0.19
25.4
66.9
0.38
Example

135
52a
52
Z
—
24
3
34
0
17
20
1.4
1
4.9
—
1110
14
47
3.5
−40
0.30
4.3
11.1
0.38
Example

136
52b
52
Z
—
49
4
35
89
6
6
0.2
0
7.6
0.2
1231
12
61
4.0
−80
0.23
12.1
28.9
0.42
Example

※A value with underline indicates that the value is out of the scope of the invention.

TABLE 27

High-strength steel sheet

Mechanical

Microstructure fraction

characteristics

(Perc-

Average

Left

Steel
Hot-

Aci-
Aggre-

entage of

Re-

Left
diameter of

side of
Impact
Spot

sheet
rolled
Chemical

cular
gated

Tem-

sidual

side of
carbides in

Formula
characteristics
weldability

Experi-
for heat
steel
com-

α
α
M
pered M)
B
BF
γ
Others
Formula
Tempered M
TS
El
λ
(6) ×
T_TR
E_B/
E_C
E_T
E_C/

ment
treatment
sheet
ponent
Plating
%
%
%
%
%
%
%
%
(A)
μm
MPa
%
%
10⁶
° C.
E_RT
kN
kN
E_T

137
53
53

AA

—
0

93

3
0
0
3
0.0
1
<5.0
—

465

33
105

3.4

—
—
—
—
—

Comparative

138
54
54

AB

—
29
2
51
0
15
2
1.0
0
9.5
—
1860
11
12

3.1

−40
0.22
3.1
30.7

0.10

Comparative

139
55
55

AC

—
Test was terminated due to being

Test was terminated due to being

Comparative

cracked during casting process.

cracked during casting process.

140
56
56

AD

—
Test was terminated due to being

Test was terminated due to being

Comparative

cracked during casting process.

cracked during casting process.

141
57
57

AE

—
7
53
6
0
15
7

4.1

8
<5.0
—

562

25
67

2.7

—
—
—
—
—

Comparative

142
58
58

AF

—
Test was terminated due to being

Test was terminated due to being

Comparative

cracked during casting process.

cracked during casting process.

143
59
59

AG

—
43
13
27
0
5
10
0.0
2
6.9
—
1031
7
10

0.73

—
—
—
—
—

Comparative

144
60
60

AH

—
Test was terminated due to being

Test was terminated due to being

Comparative

cracked during casting process.

cracked during casting process.

145
61
61

AI

—
36
10
35
0
9
8
1.3
1
6.4
—
1112
11
13

1.5

—
—
—
—
—

Comparative

146
62
62

AJ

—
52
9
24
15
13
0
0.0
2
6.7
0.1
965
9
10
0.85
—
—
—
—
—

Comparative

147
63
63
AK
—
51
11
19
0
6
12
1.1
0
7.4
—
984
17
61
4.1
−50
0.31
19.5
48.0
0.41
Example

148
64
64
AL
—
55
9
27
0
2
5
1.0
1
5.2
—
1402
11
39
3.7
−50
0.28
6.2
15.8
0.39
Example

149
65

65

I
—

18

40

23
10
12
6
1.2
0

12.5
0.1
851
23
25

2.9

10

0.11

6.9
31.4

0.22

Comparative

150
66

66

K
—

16

59

17
0
2
5
1.4
0

11.0
—
713
25
34

2.8

−20
0.23
5.3
22.3

0.24

Comparative

151
67

67

O
—
8

67

12
0
0
12
1.3
0

10.8
—
684
29
28

2.7

−10
0.19
14.6
46.9

0.31

Comparative

152
68

68

W
—

15

48

13
0
9
9
1.4
3
9.2
—
874
15
36

2.3

0

0.09

6.8
20.5

0.33

Comparative

153

1f

1
A
—
0

59

24
0
11
4
1.0
1
7.9
—
933
17
31

2.7

−40
0.24
13.8
41.2

0.33

Comparative

154

3d

3
B
—

17

52

21
0
6
1
0.8
2
8.2
—
888
15
29

2.1

−40
0.23
10.2
32.3

0.32

Comparative

※A value with underline indicates that the value is out of the scope of the invention.

A tensile test and a hole expansion test were performed in order to evaluate the strength and the formability. The tensile test was performed in accordance with JIS Z 2241. A test piece was a No. 5 test piece described in JIS Z 2201. A tensile axis was in line with a width direction of the steel sheet. The hole expansion test was performed in accordance with JIS Z 2256. In a high-strength steel sheet with TS of 590 MPa or more, when a formula (6) below consisting of the maximum tensile strength TS (MPa), total elongation El (%), and hole expandability λ(%) was satisfied, the steel sheet was judged to have excellent formability-strength balance.

TS^1.5×El×λ^0.5≥3.5×10⁶ (6)

The steel sheets not having sufficient strength and formability-strength balance in the tensile test and the hole expansion test were not subjected to the subsequent Charpy test and spot welded joint evaluation test.

Charpy impact test was conducted in order to evaluate toughness. When a thickness of a steel sheet was less than 2.5 mm, as a test piece, a laminated Charpy test piece was used. The laminated Charpy test piece was obtained by laminating the steel sheets until a total thickness thereof exceeds 5.0 mm, fastening the laminated steel sheets with bolts, and giving a V notch of 2-mm depth thereto. Other conditions were in accordance with JIS Z 2242.

When a ductile-brittle transition temperature T_TRat which a brittle fracture surface ratio was 50% or more was −40 degrees C. or less, and a ratio E_B/E_RTof shock absorption energy E_Bafter brittle transition to shock absorption energy E_RTat the room temperature was 0.15 or more, the steel sheet was judged to have an excellent toughness. Here, the ductility-brittle transition temperature T_TRis a temperature at which the brittle fracture surface ratio reaches 50%. The shock absorption energy E_Bafter the brittle transition refers to absorption energy at the time of having dropped to a flat level in response to the decrease in the shock test temperature.

In order to evaluate weldability, a shear test and a cross tensile test were performed on a spot welded joint. The shear test was performed in accordance with JIS Z 3136. The cross tensile test was performed in accordance with JIS Z 3137. The joint to be evaluated was created by stacking two target steel sheets, adjusting a welding current so that the diameter of a molten portion was 4.0 times the square root of the sheet thickness, and performing spot welding. When a ratio E_C/E_Tof the joint strength E_Tin the shear test and the joint strength E_Cin the cross tensile test was 0.35 or more, the steel sheet was judged to have an excellent weldability.

The steel sheets for heat treatment 1c, 1d, 1f, 2a, 3d, 5a, 9c, 18a, 24b, 25b, 27b, 30c, 32d, 47c, 50b, 53 to 62, 65, 66, 67, and 68 are examples of the steel sheet for heat treatment that does not satisfy the requirements for manufacturing the steel sheet A. Experimental Examples 6, 7, 10, 24, 36, 45, 63, 66, 70, 78, 85, 123, 131, 137 to 146, and 149 to 154 in which the above steel sheets for heat treatment were subjected to the heat treatment did not exhibit sufficient properties.

The steel sheets 65 to 68 for heat treatment are examples of a steel sheet in which the average cooling rate in a range from 850 degrees C. to 550 degrees C. was low, the microstructure of the hot-rolled steel sheet had a few lath structures, and aggregated ferrite. For this reason, in Experimental Examples 149 to 152 in which the respective steel sheets 65 to 68 were subjected to the heat treatment, acicular ferrite was not sufficiently obtained and a large amount of aggregated ferrite was present, resulting in deterioration in strength-formability balance, toughness, and weldability.

The steel sheets 5a and 50b for heat treatment are examples of a steel sheet in which a winding temperature after hot rolling was excessively high, and the microstructure of the hot-rolled steel sheet had a few lath structure and a wide Mn-concentrated region. For this reason, in Experimental Examples 24 and 131 in which the respective steel sheets 5a and 50b were subjected to the heat treatment, acicular ferrite was not sufficiently obtained, residual austenite of more than 2% was present, and a lot of coarse, aggregated island-shaped martensite was present, resulting in deterioration in strength-formability balance, toughness, and weldability.

The steel sheets 9c and 32d for heat treatment are examples of a steel sheet in which the temperature change of the steel sheet in the temperature region from the Bs point after hot rolling to (Bs−80) degrees C. did not satisfy the formula (1). The microstructure of the hot-rolled steel sheet contained a wide Mn-concentrated region and further had a coarse and aggregated residual austenite. Therefore, in Experimental Examples 36 and 85 in which the respective steel sheets 9c and 32d were subjected to the heat treatment, each steel sheet excessively containing residual austenite was obtained, resulting in deterioration in toughness.

The steel sheet 2a for heat treatment is an example of a steel sheet in which a winding temperature after hot rolling was excessively high, and the microstructure of the hot-rolled steel sheet did not contain the lath structure and contained a wide Mn-concentrated region. For this reason, in Experimental Example 10 in which the steel sheet 2a was subjected to the heat treatment, acicular ferrite was not obtained and a structure containing a large amount of residual austenite was obtained, resulting in deterioration in strength-formability balance, toughness, and weldability.

The steel sheet 1c for heat treatment is an example of a steel sheet in which the steel sheet temperature history in the temperature region of 700 degrees C. to (Ac3−20) degrees C. in the heating process did not satisfy the formula (2) at the manufacture of the steel sheet a by subjecting the hot-rolled steel sheet to the heat treatment. An excessive Mn-concentrated region was formed in the steel sheet 1c. Therefore, in Experimental Example 6 in which the steel sheet 1c was subjected to the heat treatment, the obtained steel sheet excessively contained residual austenite, resulting in deterioration in toughness.

The steel sheets 1d and 24b for heat treatment are examples of the steel sheet a in which the maximum heating temperature was excessively low at the manufacture of the steel sheet a by cold-rolling the hot-rolled steel sheet at a rolling reduction of more than 10% and subjecting the steel sheet for intermediate heat treatment to the intermediate heat treatment. A sufficient lath structure was not obtained in the steel sheets 1d and 24b. Therefore, in Experimental Examples 7 and 63 in which the respective steel sheets 1d and 24b were subjected to the heat treatment, a sufficient acicular ferrite was not obtained to deteriorate the strength-formability balance and weldability, and toughness was also deteriorated since coarse aggregated martensite increased as the acicular ferrite decreased.

The steel sheet 30c for heat treatment is an example of the steel sheet a in which the cooling rate in a range from 700 degrees C. to 550 degrees C. was excessively small at the manufacture of the steel sheet a by cold-rolling the hot-rolled steel sheet at a rolling reduction of more than 10% and subjecting the steel sheet for intermediate heat treatment to the intermediate heat treatment. A sufficient lath structure was not obtained in the steel sheet 30c. Therefore, in Experimental Example 78 in which the steel sheet 30c was subjected to the heat treatment, a sufficient acicular ferrite was not obtained to deteriorate the strength-formability balance and weldability, and toughness was also deteriorated since coarse aggregated martensite increased as the acicular ferrite decreased.

The steel sheets 25b and 47c for heat treatment are examples of the steel sheet a in which the cooling rate in a range from the Bs point to (Bs point −80) degrees C. was excessively small at the manufacture of the steel sheet a by cold-rolling the hot-rolled steel sheet at a rolling reduction of more than 10% and subjecting the steel sheet for intermediate heat treatment to the intermediate heat treatment, in which the microstructure of the hot-rolled steel sheet had coarse and aggregated residual austenite. Therefore, in Experimental Examples 66 and 123 in which the respective steel sheets 25b and 47c were subjected to the heat treatment, a lot of coarse and aggregated martensite were formed, resulting in deterioration in toughness.

The steel sheet 27b for heat treatment is an example in which the dwell time in a temperature region from (Bs point −80) degrees C. to Ms point was excessively long in the manufacture of the steel sheet a by cold-rolling the hot-rolled steel sheet at a rolling reduction of more than 10% and subjecting the steel sheet for intermediate heat treatment to the intermediate heat treatment, in which the microstructure of the hot-rolled steel sheet had coarse and aggregated residual austenite. Therefore, in Experimental Example 70 in which the steel sheet 27b was subjected to the heat treatment, a lot of coarse and aggregated martensite was formed, resulting in deterioration in toughness.

The steel sheet 18a for heat treatment is an example of a steel sheet in which the cooling rate in a range from the Ms point to (Ms point −50) degrees C. was excessively high in the manufacture of the steel sheet a by cold-rolling the hot-rolled steel sheet at a rolling reduction of more than 10% and subjecting the steel sheet for intermediate heat treatment to the intermediate heat treatment, in which the microstructure of the hot-rolled steel sheet had coarse and aggregated residual austenite. Therefore, in Experimental Example 70 in which the steel sheet 18a was subjected to the heat treatment, a lot of coarse and aggregated martensite were formed, resulting in deterioration in toughness.

In the manufacture of the steel sheet a by subjecting the hot-rolled steel sheet to the cold rolling, the steel sheets 1f and 3d for heat treatment were subjected to the cold rolling at the rolling reduction of more than 10%, however, not subjected to the intermediate heat treatment after the cold rolling, so that a sufficient lath structure was not obtained. Therefore, in Experimental Examples 153 and 154 in which the steel sheets 1f and 3d were subjected to the heat treatment, a sufficient acicular ferrite was not obtained to deteriorate the strength-formability balance and weldability, and weldability became inferior.

In each of Experimental Examples 2, 4, 5, 17, 19, 21, 50, 52, 60, 62, 89, 92, and 126, the steel sheet for heat treatment (steel sheet a) having a predetermined alloy structure was used, but the heat treatment conditions fell outside the range of the invention, so that sufficient characteristics were not obtained.

In Experimental Example 2, the temperature history did not satisfy the formula (3) in the heating step when the steel sheet 1a for heat treatment was subjected to the heat treatment, and the obtained steel sheet had a lot of coarse and aggregated martensite, which did not satisfy the formula (A), resulting in deterioration in toughness.

In Experimental Examples 4 and 50 where the respective steel sheets 1 b and 19a for heat treatment were subjected to the heat treatment, the maximum heating temperature was excessively low in the heating step, so that a large amount of cementite remained undissolved and, consequently, a sufficient strength-formability balance was not obtained.

In Experimental Examples 5 and 92 where the respective steel sheets 1 b and 35a for heat treatment were subjected to the heat treatment, the maximum heating temperature in the heating step was excessively high, so that sufficient acicularferrite was not obtained to deteriorate the strength-formability balance and weldability, and toughness was also deteriorated since coarse aggregated martensite increased as the acicular ferrite decreased.

In Experimental Example 52 where the steel sheet 19b for heat treatment was subjected to the heat treatment, the retention time at the maximum heating temperature in the heating step was excessively long, so that a sufficient amount of acicular ferrite was not obtained to deteriorate the strength-formability balance and weldability, and toughness was also deteriorated since coarse aggregated martensite increased as the acicular ferrite decreased.

In Experimental Examples 19, 62 and 89 where the respective steel sheets 3b, 24a and 34a for heat treatment were subjected to the heat treatment, the average cooling rate for cooling from 700 degrees C. to 550 degrees C. in the cooling step was excessively low. Since acicular ferrite was decreased, the strength-formability balance and weldability were deteriorated.

In Experimental Examples 21 and 60 where the steel sheets 3c and 23 for heat treatment were subjected to the heat treatment, the formula (4) was not satisfied in the cooling step. Since bainite transformation proceeded excessively to concentrate carbons in untransformed austenite, a large amount of residual austenite was present in the steel sheet after the heat treatment, resulting in deterioration of toughness.

In Experimental Examples 17 and 126 where the steel sheets 3a and 48a for heat treatment were subjected to the heat treatment, the formula (5) was not satisfied in the cooling step. Since pearlite was excessively formed, a sufficient amount of martensite was not obtained, resulting in a significant deterioration in strength.

Among the steel sheets whose properties are shown in Tables 22 to 29, the steel sheets except for the above steel sheets in Comparatives are high-strength steel sheets having excellent formability, toughness, and weldability satisfying the conditions of the invention.

In particular, in Experimental Examples 1, 3, 8, 16, 30, 32, 41, 42, 46, 56, 57, 67, 71, 77, 88, 93, 94, 98, 100, 102, 103, 109, 113, 114, 117, 119, 122, 129, 132, and 136, the steel sheets for heat treatment were subjected to an appropriate heat treatment to cause martensitic transformation, and, subsequently, subjected to the tempering treatment to make martensite tough tempered-martensite. Thus properties were significantly improved.

In Experimental Examples 31, 99, and 116, the high-strength steel sheets after the heat treatment were subjected to electroplating. In Experimental Example 119, the steel sheet after the tempering treatment was subjected to electroplating. In Experimental Examples 93 and 103, the steel sheets after the heat treatment were subjected to electroplating, and subsequently, subjected to the tempering treatment.

Experimental Examples 9, 32 and 55 each show a high-strength hot-dip galvanized steel sheet obtained by immersing the steel sheet in a zinc bath immediately after dwelling from 550 degrees C. to 300 degrees C., and subsequently cooling the steel sheet to the room temperature in the heat treatment process. In particular, in Experimental Example 32, the steel sheet after being cooled to the room temperature was further subjected to the tempering treatment.

Experimental Examples 20, 91, 102 and 118 each show a high-strength hot-dip galvanized steel sheet obtained by, in the heat treatment process, cooling the steel sheet from 700 degrees C. to 550 degrees C. and subsequently immersing the steel sheet in a zinc bath immediately before dwelling in a range from 550 degrees C. to 300 degrees C. In particular, in Experimental Example 102, the steel sheet after being cooled to the room temperature was further subjected to the tempering treatment.

Experimental Examples 3, 54 and 121 each show a high-strength galvannealed steel sheet obtained by, in the heat treatment process, immersing the steel sheet in a zinc bath immediately after dwelling in a range from 550 degrees C. to 300 degrees C., further heating the steel sheet for the alloying treatment, and subsequently cooling the steel sheet to the room temperature. In particular, in Experimental Example 3, the steel sheet after being cooled to the room temperature was further subjected to the tempering treatment.

Experimental Examples 72, 75, 94 and 125 each show a high-strength galvannealed steel sheet obtained by, in the heat treatment process, cooling the steel sheet from 700 degrees C. to 550 degrees C., subsequently immersing the steel sheet in a zinc bath immediately before dwelling in a range from 550 degrees C. to 300 degrees C., and further heating the steel sheet for the alloying treatment. In particular, in Experimental Example 94, the steel sheet after being cooled to the room temperature was further subjected to the tempering treatment.

Experimental Examples 87, 100 and 106 each show a high-strength galvannealed steel sheet obtained by, in the heat treatment process, immersing the steel sheet in a zinc bath during dwelling in a range from 550 degrees C. to 300 degrees C., and further heating the steel sheetforthe alloying treatment. In particular, in Experimental Example 100, the steel sheet after being cooled to the room temperature was further subjected to the tempering treatment.

Experimental Examples 67 and 132 each show a high-strength hot-dip galvannealed steel sheet obtained by immersing the steel sheet in a zinc bath during the heating in the tempering treatment, and subsequently, performing the alloying treatment and the tempering treatment at the same time.

As described above, according to the invention, a high-strength steel sheet excellent in formability, toughness and weldability can be provided. Since the high-strength steel sheet of the invention is a steel sheet suitable for a significant weight reduction in an automobile, the invention is highly applicable to the steel sheet manufacturing industry and the automobile industry.

EXPLANATION OF CODES

- 1 . . . aggregated ferrite, 2 . . . martensite, 3 . . . acicular ferrite, 4 . . . martensite region.

HIGH-STRENGTH STEEL PLATE HAVING EXCELLENT FORMABILITY, TOUGHNESS AND WELDABILITY, AND PRODUCTION METHOD OF SAME

Information

Publication Number

Date Filed

Date Published

Inventors

Original Assignees

CPC

International Classifications

Abstract

Description

Claims

PCT Information