Hot-stamping formed body

TECHNICAL FIELD OF THE INVENTION

The present invention relates to a hot-stamping formed body. Specifically, the present invention relates to a hot-stamping formed body excellent in strength and toughness applied to a structural member and a reinforcing member of a vehicle or a structure that requires toughness.

Priority is claimed on Japanese Patent Application No. 2019-101984, filed May 31, 2019, the content of which is incorporated herein by reference.

BACKGROUND ART

In recent years, there has been a demand for a reduction in the weight of the vehicle body of a vehicle from the viewpoint of environmental protection and resource saving, and a high strength steel sheet has been increasingly applied to a member for a vehicle. A member for a vehicle is manufactured by press forming. However, with the high-strengthening of a steel sheet, not only is a forming load increased, but also formability decreases. In addition, in a high strength steel sheet, formability into a member having a complex shape becomes a problem. In order to solve such a problem, a hot stamping technique in which press forming is performed after heating to a high temperature in an austenite region where the steel sheet softens has been applied. Hot stamping has attracted attention as a technique that achieves both forming into a member for a vehicle and securing strength by performing a hardening treatment in a die simultaneously with press working.

However, in general, the toughness decreases as the strength of the steel sheet increases. Therefore, when cracks occur during deformation due to a collision, there are cases where the proof stress and absorbed energy required for the member for a vehicle cannot be obtained.

Patent Document 1 discloses a technique in which the crystal orientation difference in bainite is controlled to 5° to 14° by controlling the cooling rate from finish rolling to coiling in a hot rolling step, thereby improving deformability such as stretch flangeability.

Patent Document 2 discloses a technique in which the strength of a specific crystal orientation group among ferrite grains is controlled by controlling manufacturing conditions from finish rolling to coiling in a hot rolling step, thereby improving local deformability.

Patent Document 3 discloses a technique in which a steel sheet for hot stamping is subjected to a heat treatment to form ferrite in the surface layer and thus reduce gaps generated at the interface between ZnO and the steel sheet and the interface between ZnO and a Zn-based plating layer during heating before hot pressing, thereby improving pitting corrosion resistance and the like.

Patent Document 4 discloses a hot-stamping formed body having excellent bendability, which is obtained by laminating surface steel sheets on both sides of a steel sheet.

However, in order to obtain a higher vehicle body weight reduction effect, superior strength and toughness are required.

PRIOR ART DOCUMENT
Patent Document

- [Patent Document 1] PCT International Publication No. WO2016/132545
- [Patent Document 2] Japanese Unexamined Patent Application, First Publication No. 2012-172203
- [Patent Document 3] Japanese Patent No. 5861766
- [Patent Document 4] PCT International Publication No. WO2018/151332

DISCLOSURE OF THE INVENTION
Problems to be Solved by the Invention

In view of the problems of the related art, an object of the present invention is to provide a hot-stamping formed body excellent in strength and toughness.

Means for Solving the Problem

As a result of intensive examinations on a method for solving the above problems, the present inventors have obtained the following findings.

The present inventors found that an effect of suppressing the propagation of cracks can be increased by causing the metallographic structure in a surface layer region, which is a region from the surface of a steel sheet forming a hot-stamping formed body to a position at a depth of 50 μm from the surface, to have one or more of martensite, tempered martensite, and lower bainite as a primary phase, and setting, with respect to the sum of the lengths of grain boundaries having a rotation angle of 57° to 63°, the lengths of grain boundaries having a rotation angle of 49° to 56°, the lengths of grain boundaries having a rotation angle of 4° to 12°, and the lengths of grain boundaries having a rotation angle of 64° to 72° with a <011> direction as a rotation axis among the grain boundaries of grains having a phase of a body-centered structure, the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° to 35% or more, whereby a hot-stamping formed body having better toughness than in the related art is obtained.

The present invention has been made by conducting further examinations based on the above findings, and the gist thereof is as follows.

(1) A hot-stamping formed body according to an aspect of the present invention includes: a steel sheet containing, as a chemical composition, by mass %,

- C: 0.15% or more and less than 0.70%,
- Si: 0.005% to 0.250%,
- Mn: 0.30% to 3.00%,
- sol. Al: 0.0002% to 0.500%,
- P: 0.100% or less,
- S: 0.1000% or less.
- N: 0.0100% or less,
- Nb: 0% to 0.150%,
- Ti: 0% to 0.150%,
- Mo: 0% to 1.000%,
- Cr: 0% to 1.000%,
- B: 0% to 0.0100%,
- Ca: 0% to 0.010%,
- REM: 0% to 0.30%, and
- a remainder consisting of Fe and impurities; and
- a plating layer provided on a surface of the steel sheet, the plating layer having an adhesion amount of 10 g/m²to 90 g/m²and a Ni content of 10 mass % to 25 mass %, and containing a remainder consisting of Zn and impurities,
- in which, in a surface layer region, which is a region from the surface of the steel sheet to a position at a depth of 50 μm from the surface, a metallographic structure has one or more of martensite, tempered martensite, and lower bainite as a primary phase, and with respect to the sum of the lengths of grain boundaries having a rotation angle of 57° to 63°, the lengths of grain boundaries having a rotation angle of 49° to 56°, the lengths of grain boundaries having a rotation angle of 4° to 12°, and the lengths of grain boundaries having a rotation angle of 64° to 72° with a <011> direction as a rotation axis among the grain boundaries of grains having a phase of a body-centered structure, the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° is 35% or more.

(2) The hot-stamping formed body according to (1), may include, as the chemical composition, by mass %, one or two or more selected from the group consisting of:

- Nb: 0.010% to 0.150%;
- Ti: 0.010% to 0.150%;
- Mo: 0.005% to 1.000%;
- Cr: 0.005% to 1.000%;
- B: 0.0005% to 0.0100%;
- Ca: 0.0005% to 0.010%; and
- REM: 0.0005% to 0.30%.

Effects of the Invention

According to the present invention, it is possible to provide a hot-stamping formed body having high strength and having better toughness than in the related art.

EMBODIMENTS OF THE INVENTION

The features of a hot-stamping formed body according to the present embodiment are as follows.

A hot-stamping formed body according to the present embodiment is characterized in that in a surface layer region, which is a region from the surface of a steel sheet forming the hot-stamping formed body to a position at a depth of 50 μm from the surface, the metallographic structure has one or more of martensite, tempered martensite, and lower bainite as a primary phase, and with respect to the sum of the lengths of grain boundaries having a rotation angle of 57° to 63°, the lengths of grain boundaries having a rotation angle of 49° to 56°, the lengths of grain boundaries having a rotation angle of 4° to 12°, and the lengths of grain boundaries having a rotation angle of 64° to 72° with a <011> direction as a rotation axis among the grain boundaries of grains having a phase of a body-centered structure, the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° is set to 35% or more, whereby the propagation of cracks is suppressed.

As a result of intensive examinations, the present inventors found that the above structure is obtained by the following method.

As a first stage, in a hot rolling step, rough rolling is performed in a temperature range of 1,050° C. or higher with a cumulative rolling reduction of 40% or more to promote recrystallization of austenite. Next, a small amount of dislocations are introduced into the austenite after the completion of recrystallization by performing finish rolling with a final rolling reduction of 5% or more and less than 20% in a temperature range of an A₃point or higher. After the finish rolling is ended, cooling is started within 0.5 seconds, and the average cooling rate down to a temperature range of 650° C. or lower is set to 30° C./s or faster. Accordingly, while maintaining the dislocations introduced into the austenite, transformation from the austenite to bainitic ferrite can be started.

Next, austenite is transformed into bainitic ferrite in a temperature range of 550° C. or higher and lower than 650° C. In this temperature range, the transformation into bainitic ferrite tends to be delayed, and in a steel sheet containing 0.15 mass % or more of C, the transformation rate into bainitic ferrite generally becomes slow, and it is difficult to obtain a desired amount of bainitic ferrite. In the present embodiment, in a rolling step, dislocations (strain) are introduced into the surface layer of the steel sheet, and transformation from the austenite into which the dislocations are introduced is caused. Accordingly, the transformation into bainitic ferrite is promoted, and a desired amount of bainitic ferrite can be obtained in the surface layer region of the steel sheet.

In a temperature range of 550° C. or higher and lower than 650° C., slow cooling at an average cooling rate of 1° C./s or faster and slower than 10° C./s is performed to promote the transformation of austenite into bainitic ferrite, whereby the average crystal orientation difference of the grain boundaries of bainitic ferrite can be controlled to 0.4° to 3.0°. Initial bainitic ferrite has grain boundaries having an average crystal orientation difference of 5° or more. However, by performing slow cooling in a temperature range (a temperature range of 550° C. or higher and lower than 650° C.) in which Fe is diffusible, the recovery of dislocations occurs in the vicinity of the grain boundaries of bainitic ferrite, and subgrain boundaries having an average crystal orientation difference of 0.4° to 3.0° are generated. In this case, C in the steel diffuses into the surrounding high angle grain boundaries instead of subgrain boundaries, so that the amount of C segregated in the subgrain boundaries decreases.

Next, by performing cooling in a temperature range of 550° C. or lower at an average cooling rate of 40° C./s or faster, the diffusion of C contained in bainitic ferrite into the subgrain boundaries is suppressed.

As a second stage, a Zn-based plating layer containing 10 to 25 mass % of Ni is formed so that the adhesion amount thereof is 10 to 90 g/m², whereby a steel sheet for hot stamping is obtained.

As a third stage, by controlling the temperature rising rate during hot-stamping heating, the subgrain boundaries having an average crystal orientation difference of 0.4° to 3.0° promote the diffusion of Ni, so that Ni can be contained in the grains of the surface layer of the steel sheet.

In a case of controlling the average heating rate in a hot-stamping forming step to slower than 100°/s, initially, Ni contained in the plating layer diffuses into the steel sheet through the subgrain boundaries of the surface layer of the steel sheet as paths. In this case, the subgrain boundaries having an average crystal orientation difference of 0.4° to 3.0° promote the diffusion of Ni, so that Ni can be contained in the grains of the surface layer of the steel sheet. This is because the boundary segregation of C is suppressed at the subgrain boundaries having an average crystal orientation difference of 0.4° to 3.0°, and the subgrain boundaries effectively function as diffusion paths for Ni.

Next, according to the chemical potential gradient between the subgrain boundaries of the surface layer of the steel sheet and the inside of the grains of the surface layer of the steel sheet, Ni diffuses from the subgrain boundaries into the grains. When the heating temperature reaches the A₃point or higher, the reverse transformation into austenite is completed. In this case, there is a specific crystal orientation relationship between austenite and grains having an average crystal orientation difference of 0.4° to 3.0° inside the grains surrounded by the grain boundaries having an average crystal orientation difference of 5° or more as the primary phase before transformation, so that the crystal orientation of the generated austenite inherits the characteristics of the grains of the primary phase before transformation. During cooling after heat retention and forming in a hot stamping step, when transformation from austenite grains to grains having a phase of a body-centered structure (for example, lower bainite, martensite, and tempered martensite) occurs, the combination of the crystal orientations of such grains is affected by the crystal orientation of austenite before transformation and Ni contained in the surface layer of the steel sheet in a heating step.

By generating the grains having an average crystal orientation difference of 0.4° to 3.0° inside the grains surrounded by the grain boundaries having an average crystal orientation difference of 5° or more in the steel sheet for hot stamping and solid-solubilizing Ni in the grains, the crystal orientations of the grains having a phase of a body-centered structure can be controlled. Specifically, the present inventors found that with respect to the sum of the lengths of grain boundaries having a rotation angle of 57° to 63°, the lengths of grain boundaries having a rotation angle of 49° to 56°, the lengths of grain boundaries having a rotation angle of 4° to 12°, and the lengths of grain boundaries having a rotation angle of 64° to 72° with a <011> direction as a rotation axis among the grain boundaries of the grains having a phase of a body-centered structure, the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° can be controlled to 35% or more. The grain boundaries having a rotation angle of 64° to 72° have the largest grain boundary angles among the grain boundaries of the grains of martensite, tempered martensite, and lower bainite, thereby having a high effect of suppressing the propagation of cracks and suppressing brittle fracture of the steel. As a result, the toughness of the hot-stamping formed body can be improved.

Hereinafter, the hot-stamping formed body according to the present embodiment and a method of manufacturing the same will be described in detail. First, the reason for limiting the chemical composition of the steel sheet forming the hot-stamping formed body according to the present embodiment will be described. Furthermore, the numerical limit range described below includes a lower limit and an upper limit in the range. Numerical values indicated as “less than” or “more than” do not fall within the numerical range. All % regarding the chemical composition means mass %.

The steel sheet forming the hot-stamping formed body according to the present embodiment contains, as the chemical composition, by mass %, C: 0.15% or more and less than 0.70%, Si: 0.005% to 0.250%, Mn: 0.30% to 3.00%, sol. Al: 0.0002% to 0.500%, P: 0.100% or less, S: 0.1000% or less, N: 0.0100% or less, and a remainder: Fe and impurities.

“C: 0.15% or More and Less than 0.70%”

C is an important element for obtaining a tensile strength of 1,500 MPa or more in the hot-stamping formed body. When the C content is less than 0.15%, martensite is soft and it is difficult to secure a tensile strength of 1,500 MPa or more. Therefore, the C content is set to 0.15% or more. The C content is preferably 0.18% or more, 0.19% or more, more than 0.20%, 0.23% or more, or 0.25% or more. On the other hand, when the C content is 0.70% or more, coarse carbides are generated and fracture is likely to occur, resulting in a decrease in the toughness of the hot-stamping formed body. For this reason, the C content is set to less than 0.70%. The C content is preferably 0.50% or less, 0.45% or less, or 0.40% or less.

“Si: 0.005% to 0.250%”

Si is an element that promotes the phase transformation from austenite into bainitic ferrite. When the Si content is less than 0.005%, the above effect cannot be obtained, and a desired metallographic structure cannot be obtained in the surface layer region of the steel sheet for hot stamping. As a result, a desired microstructure cannot be obtained in the hot-stamping formed body. Therefore, the Si content is set to 0.005% or more. The Si content is preferably 0.010% or more, 0.050% or more, or 0.100% or more. On the other hand, even if Si is contained in an amount of more than 0.250%, the above effect is saturated. Therefore, the Si content is set to 0.250% or less. The Si content is preferably 0.230% or less, or 0.200% or less.

“Mn: 0.30% to 3.00%”

Mn is an element that contributes to an improvement in the strength of the hot-stamping formed body by solid solution strengthening. When the Mn content is less than 0.30%, the solid solution strengthening ability is insufficient and martensite becomes soft, so that it is difficult to obtain a tensile strength of 1,500 MPa or more in the hot-stamping formed body. Therefore, the Mn content is set to 0.30% or more. The Mn content is preferably 0.70% or more, 0.75% or more, or 0.80% or more. On the other hand, when the Mn content exceeds 3.00%, coarse inclusions are generated in the steel and fracture is likely to occur, resulting in a decrease in the toughness of the hot-stamping formed body. Therefore, the Mn content is set to 3.00% or less. The Mn content is preferably 2.50% or less, 2.00% or less, and 1.50% or less.

“P: 0.100% or Less”

P is an element that segregates to the grain boundaries and reduces intergranular strength. When the P content exceeds 0.100%, the intergranular strength significantly decreases, and the toughness of the hot-stamping formed body decreases. Therefore, the P content is set to 0.100% or less. The P content is preferably 0.050% or less, and 0.020% or less. The lower limit of the P content is not particularly limited. However, when the P content is reduced to less than 0.0001%, the dephosphorization cost is increased significantly, which is economically unfavorable. In an actual operation, the P content may be set to 0.0001% or more.

“S: 0.1000% or Less”

S is an element that forms inclusions in the steel. When the S content exceeds 0.1000%, a large amount of inclusions are generated in the steel, and the toughness of the hot-stamping formed body decreases. Therefore, the S content is set to 0.1000% or less. The S content is preferably 0.0050% or less, 0.0030% or less, or 0.0020% or less. The lower limit of the S content is not particularly limited. However, when the S content is reduced to less than 0.00015%, the desulfurization cost is increased significantly, which is economically unfavorable. In an actual operation, the S content may be set to 0.00015% or more.

“sol. Al: 0.0002% to 0.500%”

Al is an element having an action of deoxidizing molten steel and achieving soundness of the steel (suppressing the occurrence of defects such as blowholes in the steel). When the sol. Al content is less than 0.0002%, deoxidation does not sufficiently proceed. Therefore, the sol. Al content is set to 0.0002% or more. The sol. Al content is preferably 0.0010% or more. On the other hand, when the sol. Al content exceeds 0.500%, coarse oxides are generated in the steel, and the toughness of the hot-stamping formed body decreases. Therefore, the sol. Al content is set to 0.500% or less. The sol. Al content is preferably 0.400% or less, 0.200% or less, and 0.100% or less.

N is an impurity element that forms nitrides in the steel and is an element that deteriorates the toughness of the hot-stamping formed body. When the N content exceeds 0.0100%, coarse nitrides are generated in the steel, the toughness of the hot-stamping formed body significantly decreases. Therefore, the N content is set to 0.0100% or less. The N content is preferably 0.0075% or less, and 0.0060% or less. The lower limit of the N content is not particularly limited. However, when the N content is reduced to less than 0.0001%, the denitrification cost is increased significantly, which is economically unfavorable. In an actual operation, the N content may be set to 0.0001% or more.

The remainder of the chemical composition of the steel sheet forming the hot-stamping formed body according to the present embodiment consists of Fe and impurities. Examples of the impurities include elements that are unavoidably incorporated from steel raw materials or scrap and/or in a steelmaking process and are allowed in a range in which the characteristics of the hot-stamping formed body according to the present embodiment are not inhibited.

The steel sheet forming the hot-stamping formed body according to the present embodiment contains substantially no Ni, and the Ni content is less than 0.005%. Since Ni is an expensive element, in the present embodiment, the cost can be kept low compared to a case where Ni is intentionally contained to set the Ni content to 0.005% or more.

The steel sheet forming the hot-stamping formed body according to the present embodiment may contain the following elements as optional elements instead of a portion of Fe. In a case where the following optional elements are not contained, the amount thereof is 0%.

“Nb: 0% to 0.150%”

Nb is an element that contributes to an improvement in the strength of the hot-stamping formed body by solid solution strengthening and thus may be contained as necessary. In a case where Nb is contained, the Nb content is preferably set to 0.010% or more in order to reliably exhibit the above effect. The Nb content is more preferably 0.035% or more. On the other hand, even if Nb is contained in an amount of more than 0.150%, the above effect is saturated. Therefore, the Nb content is preferably set to 0.150% or less. The Nb content is more preferably 0.120% or less.

“Ti: 0% to 0.150%”

Ti is an element that contributes to an improvement in the strength of the hot-stamping formed body by solid solution strengthening and thus may be contained as necessary. In a case where Ti is contained, the Ti content is preferably set to 0.010% or more in order to reliably exhibit the above effect. The Ti content is preferably 0.020% or more. On the other hand, even if Ti is contained in an amount of more than 0.150%, the above effect is saturated. Therefore, the Ti content is preferably set to 0.150% or less. The Ti content is more preferably 0.120% or less.

“Mo: 0% to 1.000%”

Mo is an element that contributes to an improvement in the strength of the hot-stamping formed body by solid solution strengthening and thus may be contained as necessary. In a case where Mo is contained, the Mo content is preferably set to 0.005% or more in order to reliably exhibit the above effect. The Mo content is more preferably 0.010% or more. On the other hand, even if Mo is contained in an amount of more than 1.000%, the above effect is saturated. Therefore, the Mo content is preferably set to 1.000% or less. The Mo content is more preferably 0.800% or less.

“Cr: 0% to 1.000%”

Cr is an element that contributes to an improvement in the strength of the hot-stamping formed body by solid solution strengthening and thus may be contained as necessary. In a case where Cr is contained, the Cr content is preferably set to 0.005% or more in order to reliably exhibit the above effect. The Cr content is more preferably 0.100% or more. On the other hand, even if Cr is contained in an amount of more than 1.000%, the above effect is saturated. Therefore, the Cr content is preferably set to 1.000% or less. The Cr content is more preferably 0.800% or less.

“B: 0% or More and 0.0100% or Less”

B is an element that segregates to improve the grain boundaries and reduces the intergranular strength, so that B may be contained as necessary. In a case where B is contained, the B content is preferably set to 0.0005% or more in order to reliably exhibit the above effect. The B content is preferably 0.0010% or more. On the other hand, even if B is contained in an amount of more than 0.0100%, the above effect is saturated. Therefore, the B content is preferably set to 0.0100% or less. The B content is more preferably 0.0075% or less.

“Ca: 0% to 0.010%”

Ca is an element having an action of deoxidizing molten steel and achieving soundness of the steel. In order to reliably exhibit this action, the Ca content is preferably set to 0.0005% or more. On the other hand, even if Ca is contained in an amount of more than 0.010%, the above effect is saturated. Therefore, the Ca content is preferably set to 0.010% or less.

“REM: 0% to 0.30%”

REM is an element having an action of deoxidizing molten steel and achieving soundness of the steel. In order to reliably exhibit this effect, the REM content is preferably set to 0.0005% or more. On the other hand, even if REM is contained in an amount of more than 0.30%, the above effect is saturated. Therefore, the REM content is preferably set to 0.30% or less.

In the present embodiment, REM refers to a total of 17 elements including Sc, Y, and lanthanoids. In the present embodiment, the REM content refers to the total amount of these elements.

The chemical composition of the steel sheet for hot stamping described above may be measured by a general analytical method. For example, the chemical composition may be measured using inductively coupled plasma-atomic emission spectrometry (ICP-AES). C and S may be measured using a combustion-infrared absorption method, and N may be measured using an inert gas fusion-thermal conductivity method. sol. Al may be measured by ICP-AES using a filtrate obtained by heating and decomposing a sample with an acid. In a case where the steel sheet for hot stamping includes a plating layer on the surface, the chemical composition may be analyzed after removing the plating layer on the surface by mechanical grinding.

Next, the microstructure of the steel sheet forming the hot-stamping formed body according to the present embodiment and the microstructure of the steel sheet forming the steel sheet for hot stamping applied thereto will be described.

“In Surface Layer Region, Which is Region from Surface of Steel Sheet to Position at Depth of 50 μm from Surface, 80% or More by area % of Grains Having Average Crystal Orientation Difference of 0.4° to 3.0° are Included Inside Grains Surrounded by Grain Boundaries Having Average Crystal Orientation Difference of 5° or More”

In the surface layer region of the steel sheet, 80% or more by area % of grains having an average crystal orientation difference of 0.4° to 3.0° are included inside grains surrounded by grain boundaries having an average crystal orientation difference of 5° or more, whereby the subgrain boundaries having an average crystal orientation difference of 0.4° to 3.0° promote the diffusion of Ni during hot-stamping heating, and Ni can be contained in the grains of the surface layer of the steel sheet. As described above, in a method of generating ferrite in the surface layer of a steel sheet in the related art, subgrain boundaries are not formed, so that it is difficult to promote the diffusion of Ni. However, in the steel sheet for hot stamping applied to the hot-stamping formed body according to the present embodiment, since the grains are contained in the surface layer region in 80% or more by area %, Ni can be diffused into the surface layer of the steel sheet by using the subgrain boundaries as diffusion paths of Ni.

In a case of controlling the average heating rate in the hot-stamping forming step to slower than 100° C./s, the subgrain boundaries having an average crystal orientation difference of 0.4° to 3.0° promote the diffusion of Ni, and Ni can be contained in the grains of the surface layer of the steel sheet. Accordingly, with respect to the sum of the lengths of grain boundaries having a rotation angle of 57° to 63°, the lengths of grain boundaries having a rotation angle of 49° to 56°, the lengths of grain boundaries having a rotation angle of 4° to 12°, and the lengths of grain boundaries having a rotation angle of 64° to 72° with a <011> direction as a rotation axis among the grain boundaries of the grains having a phase of a body-centered structure, the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° can be controlled to 35% or more. As a result, the toughness of the hot-stamping formed body can be improved.

In order to obtain the above effect, in the surface layer region of the steel sheet, the grains having an average crystal orientation difference of 0.4° to 3.0° need to be included in 80% or more by area % inside the grains surrounded by the grain boundaries having an average crystal orientation difference of 5° or more. Therefore, in the surface layer region of the steel sheet, the grains having an average crystal orientation difference of 0.4° to 3.0° are included in 80% or more by area % inside the grains surrounded by the grain boundaries having an average crystal orientation difference of 5° or more. The grains having an average crystal orientation difference of 0.4° to 3.0° are included in preferably 85% or more, and more preferably 90% or more.

The microstructure of the center portion of the steel sheet is not particularly limited, but is generally one or more of ferrite, upper bainite, lower bainite, martensite, tempered martensite, residual austenite, iron carbides, and alloy carbides.

The structure can be observed by a general method using a field-emission scanning electron microscope (FE-SEM), an electron back scattering diffraction (EBSD) method, or the like.

Next, a method of measuring the area fraction of the grains having an average crystal orientation difference of 0.4° to 3.0° inside the grains surrounded by the grain boundaries having an average crystal orientation difference of 5° or more will be described.

First, a sample is cut out so that a cross section perpendicular to the surface (sheet thickness cross section) can be observed. The size of the sample depends on a measuring apparatus, but may be set so that a size of about 10 mm can be observed in a rolling direction. The cross section of the sample is polished using #600 to #1500 silicon carbide paper and thereafter mirror-finished using a liquid obtained by dispersing a diamond powder having a particle size of 1 to 6 μm in a diluted solution such as alcohol or pure water. Next, the cross section of the sample is polished at room temperature using colloidal silica containing no alkaline solution for 8 minutes to remove strain introduced into the surface layer of the sample.

At any position in the longitudinal direction of the cross section of the sample, a region having a length of 50 μm from the surface of the steel sheet (the interface between the plating layer and the steel sheet) to a position at a depth of 50 μm from the surface of the steel sheet is measured by an electron back scattering diffraction method at a measurement interval of 0.2 μm to obtain crystal orientation information. For the measurement, an apparatus including a thermal field-emission scanning electron microscope (JSM-7001F manufactured by JEOL Ltd.) and an EBSD detector (DVCS type detector manufactured by TSL) is used. At this time, the degree of vacuum in the apparatus is set to 9.6×10⁻³Pa or less, the acceleration voltage is set to 15 kV, the irradiation current level is set to 13, and the electron beam irradiation time is set to 0.5 sec/point. The obtained crystal orientation information is analyzed using the “Grain Average Misorientation” function installed in the software “OIM Analysis (registered trademark)” attached to the EBSD analyzer. With this function, it is possible to calculate the crystal orientation difference between adjacent measurement points for the grains having a body-centered cubic structure and thereafter obtain the average value (average crystal orientation difference) for all the measurement points in the grains. Regarding the area fraction of the grains having an average crystal orientation difference of 0.4° to 3.0° inside the grains surrounded by the grain boundaries having an average crystal orientation difference of 5° or more, in the obtained crystal orientation information, a region surrounded by grain boundaries having an average crystal orientation difference of 5° or more is defined as a grain, and the area fraction of a region in which the average crystal orientation difference in the grains is 0.4° to 3.0° is calculated by the “Grain Average Misorientation” function. Accordingly, in the surface layer region, the area fraction of the grains having an average crystal orientation difference of 0.4° to 3.0° inside the grains surrounded by the grain boundaries having an average crystal orientation difference of 5° or more is obtained.

“Plating Layer Having Adhesion Amount of 10 g/m²to 90 g/m²and Ni Content of 10 Mass % to 25 Mass % and Containing Remainder Consisting of Zn and Impurities”

The steel sheet for hot stamping applied to the hot-stamping formed body according to the present embodiment has the plating layer having an adhesion amount of 10 g/m²to 90 g/m²and a Ni content of 10 mass % to 25 mass % and containing a remainder consisting of Zn and impurities on the surface of the steel sheet. Accordingly, at the time of hot stamping, the subgrain boundaries having an average crystal orientation difference of 0.4° to 3.0° promote the diffusion of Ni, and Ni can be contained in the grains in the surface layer region of the steel sheet forming the hot-stamping formed body.

When the adhesion amount is less than 10 g/m²or the Ni content in the plating layer is less than 10 mass %, Ni concentrated in the surface layer of the steel sheet is insufficient. Therefore, with respect to the sum of the lengths of grain boundaries having a rotation angle of 57° to 63°, the lengths of grain boundaries having a rotation angle of 49° to 56°, the lengths of grain boundaries having a rotation angle of 4° to 12°, and the lengths of grain boundaries having a rotation angle of 64° to 72° with a <011> direction as a rotation axis among the grain boundaries of the grains having a phase of a body-centered structure, the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° cannot be 35% or more, and the toughness of the hot-stamping formed body cannot be improved.

On the other hand, in a case where the adhesion amount exceeds 90 g/m², or in a case where the Ni content in the plating layer exceeds 25 mass %, Ni is excessively concentrated at the interface between the plating layer and the steel sheet, the adhesion between the plating layer and the steel sheet decreases, and it becomes difficult to supply Ni in the plating layer to the surface layer of the steel sheet, so that a desired microstructure for the hot-stamping formed body after hot stamping cannot be obtained. The adhesion amount of the plating layer is preferably 30 g/m²or more, or 40 g/m²or more. The adhesion amount of the plating layer is preferably 70 g/m²or less, or 60 g/m²or less. The Ni content in the plating layer is preferably 12 mass % or more, or 14 mass % or more. The Ni content in the plating layer is preferably 20 mass % or less, or 18 mass % or less.

The plating adhesion amount and the Ni content in the plating layer are measured by the following methods.

The plating adhesion amount is measured with a test piece collected from any position of the steel sheet for hot stamping according to the test method described in JIS H 0401:2013. Regarding the Ni content in the plating layer, a test piece is collected from any position of the steel sheet for hot stamping according to the test method described in JIS K 0150.2009, and the Ni content at a ½ position of the overall thickness of the plating layer is measured. The obtained Ni content is defined as the Ni content of the plating layer in the steel sheet for hot stamping.

The sheet thickness of the steel sheet for hot stamping is not particularly limited, but is preferably 0.5 to 3.5 mm from the viewpoint of a reduction in the weight of the vehicle body.

Next, a hot-stamping formed body according to the present embodiment, manufactured by using the above-described steel sheet for hot stamping will be described.

“In Surface Layer Region, which is Region from Surface of Steel Sheet to Position at Depth of 50 μm from Surface, Metallographic Structure has One or More of Martensite, Tempered Martensite, and Lower Bainite as Primary Phase, and with Respect to Sum of Lengths of Grain Boundaries Having Rotation Angle of 57° to 63°, Lengths of Grain Boundaries Having Rotation Angle of 49° to 56°, Lengths of Grain Boundaries Having Rotation Angle of 4° to 12°, and Lengths of Grain Boundaries Having Rotation Angle of 64° to 72° with <011> Direction as Rotation Axis Among Grain Boundaries of Grains Having Phase of Body-Centered Structure, Ratio of Lengths of Grain Boundaries Having Rotation Angle of 64° to 72° Is 35% or More”

In the surface layer region of the steel sheet forming the hot-stamping formed body, the metallographic structure is controlled to have martensite, tempered martensite, and lower bainite as the primary phase, and with respect to the sum of the lengths of grain boundaries having a rotation angle of 57° to 63°, the lengths of grain boundaries having a rotation angle of 49° to 56°, the lengths of grain boundaries having a rotation angle of 4° to 12°, and the lengths of grain boundaries having a rotation angle of 64° to 72° with a <011> direction as a rotation axis among the grain boundaries of the grains having a phase of a body-centered structure, the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° is controlled to 35% or more, whereby an effect of suppressing the propagation of cracks is obtained. Accordingly, excellent toughness can be obtained in the hot-stamping formed body. The ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° is preferably 40% or more, 42% or more, or 45% or more. Since the above effect can be obtained as the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° increases, the upper limit thereof is not particularly determined, but may be set to 80% or less, 70% or less, or 60% or less.

In the present embodiment, having martensite, tempered martensite, and lower bainite as the primary phase means that the sum of the area fractions of martensite, tempered martensite, and lower bainite is 85% or more. In addition, the remainder in the microstructure in the present embodiment contains one or more of residual austenite, ferrite, pearlite, granular bainite, and upper bainite. In addition, in the present embodiment, the grains having a phase of a body-centered structure mean grains of which a portion or the entirety is constituted by a phase having crystals of a body-centered structure represented by body-centered cubic crystals, body-centered tetragonal crystals, and the like. Examples of the phase having a body-centered structure include martensite, tempered martensite, or lower bainite.

“Method of Measuring Area Fractions of Martensite, Tempered Martensite, and Lower Bainite”

A sample is cut out from a position 50 mm or more away from the end surface of the hot-stamping formed body so that a cross section (sheet thickness cross section) perpendicular to the surface can be observed. The size of the sample depends on a measuring apparatus, but may be set so that a size of about 10 mm can be observed in a rolling direction.

In a case where a sample cannot be collected from a position 50 mm or more away from the end surface of the hot-stamping formed body because of the shape of the hot-stamping formed body, a sample is collected from a position as far away from the end surface as possible.

The cross section of the sample is polished using #600 to #1500 silicon carbide paper, thereafter mirror-finished using a liquid obtained by dispersing a diamond powder having a particle size of 1 to 6 μm in a diluted solution such as alcohol or pure water, and subjected to nital etching. Next, in the observed section, a region from the surface of the steel sheet (the interface between the plating layer and the steel sheet) to a position at a depth of 50 μm from the surface of the steel sheet is measured as an observed visual field using a thermal field-emission scanning electron microscope (JSM-7001F manufactured by JEOL Ltd.). The area % of martensite, tempered martensite, and lower bainite can be obtained by calculating the sum of the area % of martensite, tempered martensite, and lower bainite.

Tempered martensite is a collection of lath-shaped grains, and is distinguished as a structure in which iron carbides have two or more stretching directions. Lower bainite is a collection of lath-shaped grains, and is distinguished as a structure in which iron carbides have only one stretching direction. Martensite is not sufficiently etched by nital etching and is therefore distinguishable from other etched structures. However, since residual austenite is not sufficiently etched like martensite, the area % of martensite is obtained by obtaining the difference from the area % of residual austenite obtained by a method described later. By calculating the sum of area % of martensite, tempered martensite, and lower bainite, the area fraction of the sum of martensite, tempered martensite, and lower bainite in the surface layer region is obtained.

The area fraction of the remainder in the microstructure is obtained by calculating a value obtained by subtracting the area fraction of the sum of martensite, tempered martensite, and lower bainite from 100%.

The cross section of the sample is polished using #600 to #1500 silicon carbide paper and thereafter mirror-finished using a liquid obtained by dispersing a diamond powder having a particle size of 1 to 6 μm in a diluted solution such as alcohol or pure water. Next, the cross section of the sample is polished at room temperature using colloidal silica containing no alkaline solution for 8 minutes to remove strain introduced into the surface layer of the sample. At any position in the longitudinal direction of the cross section of the sample, a region having a length of 50 μm from the surface of the steel sheet (the interface between the plating layer and the steel sheet) to a position at a depth of 50 μm from the surface of the steel sheet is measured by an electron back scattering diffraction method at a measurement interval of 0.1 μm to obtain crystal orientation information. For the measurement, an apparatus including a thermal field-emission scanning electron microscope (JSM-7001F manufactured by JEOL Ltd.) and an EBSD detector (DVCS type detector manufactured by TSL) is used. At this time, the degree of vacuum in the apparatus is set to 9.6×10⁻⁵Pa or less, the acceleration voltage is set to 15 kV, the irradiation current level is set to 13, and the electron beam irradiation time is set to 0.01 sec/point. The area % of residual austenite, which is an fcc structure, is calculated from the obtained crystal orientation information using the “Phase Map” function installed in the software “OIM Analysis (registered trademark)” attached to the EBSD analyzer, thereby obtaining the area % of residual austenite in the surface layer region.

“Method of Measuring Ratio of Lengths of Grain Boundaries Having Rotation Angle of 64° to 72°”

With respect to the sum of the lengths of grain boundaries having a rotation angle of 57° to 63°, the lengths of grain boundaries having a rotation angle of 49° to 56°, the lengths of grain boundaries having a rotation angle of 4° to 12°, and the lengths of grain boundaries having a rotation angle of 64° to 72° with a <011> direction as a rotation axis among the grain boundaries of the grains having a phase of a body-centered structure including martensite, tempered martensite, and lower bainite, the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° is obtained by the following method.

First, a sample is cut out from any position of the hot-stamping formed body so that a cross section (sheet thickness cross section) perpendicular to the surface can be observed. The size of the sample depends on a measuring apparatus, but may be set so that a size of about 10 mm can be observed in a rolling direction.

At any position in the longitudinal direction of the cross section of the sample, a region having a length of 50 μm from the surface of the steel sheet (the interface between the plating layer and the steel sheet) to a position at a depth of 50 μm from the surface of the steel sheet is measured by an electron back scattering diffraction method at a measurement interval of 0.1 μm to obtain crystal orientation information. For the measurement, an apparatus including a thermal field-emission scanning electron microscope (JSM-7001F manufactured by JEOL Ltd.) and an EBSD detector (DVCS type detector manufactured by TSL) is used. At this time, the degree of vacuum in the apparatus is set to 9.6×10⁻⁵Pa or less, the acceleration voltage is set to 15 kV, the irradiation current level is set to 13, and the electron beam irradiation time is set to 0.01 sec/point. With respect to the sum of the lengths of grain boundaries having a rotation angle of 57° to 63°, the lengths of grain boundaries having a rotation angle of 49° to 56°, the lengths of grain boundaries having a rotation angle of 4° to 12°, and the lengths of grain boundaries having a rotation angle of 64° to 72° with a <011> direction as a rotation axis among the grain boundaries of the grains having a phase of a body-centered structure, the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° is calculated from the obtained crystal orientation information using the “Inverse Pole Figure Map” and “Axis Angle” functions installed in the software “OIM Analysis (registered trademark)” attached to the EBSD analyzer. In these functions, for the grain boundaries of the grains having a phase of a body-centered structure, the sum of the lengths of the grain boundaries can be calculated by designating a specific rotation angle with any crystal direction as a rotation axis. For all the grains included in the measurement region, the <011> direction of the grains having a phase of a body-centered structure is designated as the rotation axis, rotation angles of 57° to 63°, 490 to 56°, 4° to 12°, and 64° to 72° are input, the sum of the lengths of these grain boundaries is calculated, and the ratio of the grain boundaries of 64° to 72° is obtained.

“Plating Layer Having Adhesion Amount of 10 g/m²to 90 g/m²and Ni Content of 10 Mass % to 25 Mass % and Containing Remainder Consisting of Zn and Impurities”

The hot-stamping formed body according to the present embodiment has a plating layer having an adhesion amount of 10 g/m²to 90 g/m²and a Ni content of 10 mass % to 25 mass % and containing a remainder consisting of Zn and impurities on the surface of the steel sheet.

When the adhesion amount is less than 10 g/m²or the Ni content in the plating layer is less than 10 mass %, the amount of Ni concentrated in the surface layer region of the steel sheet is small, and a desired metallographic structure cannot be obtained in the surface layer region after hot stamping. On the other hand, in a case where the adhesion amount exceeds 90 g/m², or in a case where the Ni content in the plating layer exceeds 25 mass %, Ni is excessively concentrated at the interface between the plating layer and the steel sheet, the adhesion between the plating layer and the steel sheet decreases, and Ni in the plating layer is less likely to diffuse into the surface layer region of the steel sheet, so that a desired metallographic structure cannot be obtained in the hot-stamping formed body.

The adhesion amount of the plating layer is preferably 30 g/m²or more, or 40 g/m²or more. The adhesion amount of the plating layer is preferably 70 g/m²or less, or 60 g/m²or less. The Ni content in the plating layer is preferably 12 mass % or more, or 14 mass % or more. The Ni content in the plating layer is preferably 20 mass % or less, or 18 mass % or less.

The plating adhesion amount of the hot-stamping formed body and the Ni content in the plating layer are measured by the following methods.

The plating adhesion amount is measured with a test piece collected from any position of the hot-stamping formed body according to the test method described in JIS H 0401:2013. Regarding the Ni content in the plating layer, a test piece is collected from any position of the hot-stamping formed body according to the test method described in JIS K 0150:2009, and the Ni content at a ½ position of the overall thickness of the plating layer is measured, thereby obtaining the Ni content of the plating layer in the hot-stamping formed body.

Next, a preferred manufacturing method of the hot-stamping formed body according to the present embodiment. First, a method of manufacturing the steel sheet for hot stamping applied to the hot-stamping formed body according to the present embodiment will be described.

“Rough Rolling”

A steel piece (steel) to be subjected to hot rolling may be a steel piece manufactured by an ordinary method, and may be, for example, a steel piece manufactured by a general method such as a continuously cast slab or a thin slab caster. It is preferable that the steel having the above-described chemical composition is subjected to hot rolling, and in a hot rolling step, subjected to rough rolling with a cumulative rolling reduction of 40% or more in a temperature range of 1,050° C. or higher. In a case where the rolling is performed at a temperature of lower than 1,050° C. or in a case where the rough rolling is ended at a cumulative rolling reduction of less than 40%, recrystallization of austenite is not promoted, and transformation into bainitic ferrite occurs while excessive dislocations are included in the subsequent step, so that in the surface layer region of the steel sheet for hot stamping, the ratio of grains having an average crystal orientation difference of 0.4° to 3.0° inside grains surrounded by grain boundaries having an average crystal orientation difference of 5° or more cannot be 80% or more by area %.

“Finish Rolling”

Next, it is preferable to perform finish rolling with a final rolling reduction of 5% or more and less than 20% in a temperature range of an A₃point or higher. In a case where rolling is performed at a temperature lower than the A₃point, or in a case where the finish rolling is ended at a final rolling reduction of 20% or more, transformation into bainitic ferrite occurs while excessive dislocations are included in austenite, and the average crystal orientation difference of bainitic ferrite becomes too large, so that grains having an average crystal orientation difference of 0.4° to 3.0° are not generated. Furthermore, when the finish rolling is ended at a final rolling reduction of less than 5%, the amount of dislocations introduced into austenite is reduced, transformation from austenite into bainitic ferrite is delayed, so that in the surface layer region of the steel sheet for hot stamping, the ratio of grains having an average crystal orientation difference of 0.4° to 3.0° inside grains surrounded by grain boundaries having an average crystal orientation difference of 5° or more cannot be 80% or more by area %. The A₃point is represented by Expression (1).

A₃point=850+10×(C+N)×Mn+350×Nb+250×Ti+40×B+10×Cr+100×Mo (1)

Here, the element symbol in Expression (1) indicates the amount of the corresponding element by mass %, and 0 is substituted in a case where the corresponding element is not contained.

“Cooling”

It is preferable that cooling is started within 0.5 seconds after the finish rolling is completed, and the average cooling rate down to a temperature range of 650° C. or lower is set to 30° C./s or faster. In a case where the time from the end of the finish rolling to the start of the cooling exceeds 0.5 seconds, or in a case where the average cooling rate down to the temperature range of 650° C. or lower is slower than 30° C./s, the dislocations introduced into austenite are recovered, and in the surface layer region of the steel sheet for hot stamping, the ratio of grains having an average crystal orientation difference of 0.4° to 3.0° inside grains surrounded by grain boundaries having an average crystal orientation difference of 5° or more cannot be 80% or more by area %.

It is preferable that after performing cooling to a temperature range of 650° C. or lower, slow cooling is performed in a temperature range of 550° C. or higher and lower than 650° C. at an average cooling rate of 1° C./s or faster and slower than 10° C./s. When slow cooling is performed in a temperature range of 650° C. or higher, phase transformation from austenite to ferrite occurs, and a desired metallographic structure cannot be obtained in the surface layer region of the steel sheet for hot stamping. When slow cooling is performed in a temperature range of lower than 550° C., the yield strength of austenite before transformation is high, so that grains having a large crystal orientation difference are likely to be formed adjacent to each other in bainitic ferrite in order to relax the transformation stress. Therefore, grains having an average crystal orientation difference of 0.4° to 3.0° are not generated inside grains surrounded by grain boundaries having an average crystal orientation difference of 5° or more. When the average cooling rate in the above temperature range is slower than 1° C./s, C contained in bainitic ferrite segregates to subgrain boundaries, and Ni in the plating layer cannot diffuse into the surface layer of the steel sheet in a hot-stamping heating step. When the average cooling rate in the above temperature range is 10° C./s or faster, dislocation recovery does not occur near the grain boundaries of bainitic ferrite, and grains having an average crystal orientation difference of 0.4° to 3.0° are not generated inside grains surrounded by grain boundaries having an average crystal orientation difference of 5° or more. Therefore, the average cooling rate in the above temperature range is more preferably set to slower than 5° C./s.

It is preferable that after performing slow cooling to 550° C., cooling is performed in a temperature range of 550° C. or lower at an average cooling rate of 40° C./s or faster. When cooling is performed at an average cooling rate of slower than 40° C./s, C contained in bainitic ferrite segregates to subgrain boundaries, and Ni in the plating layer cannot diffuse into the surface layer of the steel sheet in the hot-stamping heating step. The cooling may be performed down to a temperature range of 350° C. to 500° C.

“Plating Application”

Using the hot-rolled steel sheet as it is or after being subjected to a softening heat treatment or cold rolling, a plating layer having an adhesion amount of 10 g/m²to 90 g/m²and a Ni content of 10 mass % to 25 mass %, and containing a remainder consisting of Zn and impurities is formed. Accordingly, a steel sheet for hot stamping is obtained. In the manufacturing of the steel sheet for hot stamping, a known manufacturing method such as pickling or temper rolling may be included before the plating is applied. In a case where cold rolling is performed before the plating is applied, the cumulative rolling reduction in the cold rolling is not particularly limited, but is preferably set to 30% to 70% from the viewpoint of shape stability of the steel sheet.

In addition, in softening annealing before the plating is applied, the heating temperature is preferably set to 760° C. or lower from the viewpoint of protecting the microstructure of the surface layer of the steel sheet. When tempering is performed at a temperature higher than 760° C., in the surface layer region, the area % of grains having an average crystal orientation difference of 0.4° to 3.0° inside grains surrounded by grain boundaries having an average crystal orientation difference of 5° or more cannot be 80% or more, and as a result, a hot-stamping formed body having a desired metallographic structure cannot be obtained. Therefore, in a case where tempering needs to be performed before the plating is applied due to a high C content or the like, softening annealing is performed at a temperature of 760° C. or lower.

The hot-stamping formed body according to the present embodiment is manufactured by performing heating the above steel sheet for hot stamping in a temperature range of 500° C. to the A₃point with an average heating rate of slower than 100° C./s, thereafter performing hot-stamping forming so that the elapsed time from the start of the heating to the forming is 200 to 400 seconds, and cooling the formed body to room temperature.

In addition, in order to adjust the strength of the hot-stamping formed body, a softened region may be formed by tempering a partial region or the entire region of the hot-stamping formed body at a temperature of 200° C. to 500° C.

In a case where heating is performed in a temperature range of 500° C. to the A₃point with an average heating rate of slower than 100° C./s, with respect to the sum of the lengths of grain boundaries having a rotation angle of 57° to 63°, the lengths of grain boundaries having a rotation angle of 49° to 56°, the lengths of grain boundaries having a rotation angle of 4° to 12°, and the lengths of grain boundaries having a rotation angle of 64° to 72° with a <011> direction as a rotation axis among the grain boundaries of the grains having a phase of a body-centered structure, the ratio of the lengths of the grain boundaries having a rotation angle of 64° to 72° can be controlled to 35% or more. Accordingly, the toughness of the hot-stamping formed body can be increased. The average heating rate at the above temperature range is preferably slower than 80° C./s. The lower limit is not particularly limited. However, in an actual operation, setting the lower limit of the average heating rate to slower than 0.01° C./s causes an increase in the manufacturing cost. Therefore, the lower limit may be set to 0.01° C./s.

In addition, the elapsed time from the start of the heating to the forming (hot-stamping forming) is preferably set to 200 to 400 seconds. When the elapsed time from the start of the heating to the forming is shorter than 200 seconds or longer than 400 seconds, there may be cases where a desired metallographic structure cannot be obtained in the hot-stamping formed body.

The holding temperature at the time of hot stamping is preferably set to the A₃point+10° C. to the A₃point+150° C. The average cooling rate after the hot stamping is preferably set to 10° C./s or faster.

EXAMPLES

Next, examples of the present invention will be described. The conditions in the examples are one example of conditions adopted to confirm the feasibility and effects of the present invention, and the present invention is not limited to this one example of conditions. The present invention can adopt various conditions as long as the object of the present invention is achieved without departing from the gist of the present invention.

Steel pieces manufactured by casting molten steels having the chemical compositions shown in Tables 1 to 4 were subjected to hot rolling, cold rolling, and plating under the conditions shown in Tables 5, 7, 9, and 11 to obtain steel sheets for hot stamping shown in Tables 6, 8, 10, and 12. The obtained steel sheets for hot stamping were subjected to hot-stamping forming by heat treatments shown in Tables 13, 15, 17, and 19 to obtain hot-stamping formed bodies. Furthermore, for some of the hot-stamping formed bodies, a portion of the hot-stamping formed body was irradiated with a laser to be tempered, thereby forming a partially softened region. The tempering temperature by laser irradiation was set to 200° C. to 500° C. Tables 14, 16, 18, and 20 show the microstructure and mechanical properties of the obtained hot-stamping formed bodies.

The underlines in the tables indicate those outside the range of the present invention, those deviating from preferable manufacturing conditions, and those having characteristic values that are not preferable.

TABLE 1

Chemical composition (mass %) of base steel sheet,

Steel
remainder consisting of Fe and impurities

No.
C
Si
Mn
P
S
sol.A1
N
Note

1
0.16
0.250
1.10
0.006
0.0020
0.030
0.0026
Invention Steel

2
0.44
0.250
1.80
0.010
0.0090
0.400
0.0040
Invention Steel

3
0.23
0.250
1.20
0.010
0.0100
0.030
0.0050
Invention Steel

4

0.08

0.220
0.81
0.008
0.0009
0.044
0.0026
Comparative Steel

5
0.16
0.150
0.71
0.011
0.0006
0.043
0.0037
Invention Steel

6
0.31
0.250
0.80
0.015
0.0011
0.041
0.0039
Invention Steel

7
0.36
0.180
0.81
0.005
0.0005
0.045
0.0037
Invention Steel

8
0.44
0.250
0.71
0.015
0.0007
0.034
0.0042
lnvention Steel

9
0.67
0.190
0.71
0.014
0.0003
0.037
0.0035
Invention Steel

10

0.78

0.250
0.90
0.014
0.0011
0.031
0.0026
Comparative Steel

11
0.36

0.002

0.86
0.005
0.0003
0.041
0.0032
Comparative Steel

12
0.38
0.007
0.83
0.005
0.0011
0.050
0.0030
Invention Steel

13
0.37
0.210
0.72
0.011
0.0007
0.030
0.0041
Invention Steel

14
0.37
0.240
0.90
0.015
0.0007
0.047
0.0037
Invention Steel

15
0.37
0.150

0.15

0.005
0.0003
0.035
0.0030
Comparative Steel

16
0.44
0.170
0.44
0.007
0.0005
0.049
0.0029
Invention Steel

17
0.36
0.240
0.82
0.010
0.0011
0.035
0.0038
invention Steel

18
0.37
0.180
1.29
0.007
0.0010
0.030
0.0028
invention Steel

19
0.37
0.150
1.99
0.009
0.0005
0.035
0.0042
Invention Steel

20
0.38
0.170
2.89
0.007
0.0005
0.046
0.0037
Invention Steel

21
0.38
0.150

3.15

0.012
0.0009
0.036
0.0042
Comparative Steel

22
0.38
0.240
0.82
0.0004
0.0007
0.045
0.0026
Invention Steel

23
0.36
0.160
0.90
0.009
0.0006
0.030
0.0038
Invention Steel

24
0.36
0.150
0.77
0.094
0.0010
0.043
0.0033
Invention Steel

25
0.37
0.190
0.84

0.123

0.0010
0.033
0.0032
Comparative Steel

26
0.36
0.200
0.75
0.009
0.00015
0.047
0.0045
Invention Steel

27
0.37
0.150
0.81
0.013
0.0003
0.031
0.0029
Invention Steel

28
0.37
0.190
0.89
0.008
0.0022
0.044
0.0032
Invention Steel

29
0.36
0.230
0.80
0.007
0.0900
0.049
0.0030
Invention Steel

30
0.36
0.190
0.72
0.006

0.1334

0.045
0.0025
Comparative Steel

TABLE 2

Chemical composition (mass %)

of base steel sheet, remainder

Steel
consisting of Fe and impurities
A₃

No.
Nb
Ti
Mo
Cr
B
Ca
REM
(° C.)
Note

1

0.130

865
Invention Steel

2

0.03
858
Invention Steel

3

0.020

0.200

860
Invention Steel

4

851
Comparative Steel

5

851
Invention Steel

6

853
Invention Steel

7

853
Invention Steel

8

853
Invention Steel

9

855
Invention Steel

10

857
Comparative Steel

11

853
Comparative Steel

12

853
Invention Steel

13

853
Invention Steel

14

853
Invention Steel

15

851
Comparative Steel

16

852
Invention Steel

17

853
Invention Steel

18

855
Invention Steel

19

857
Invention Steel

20

861
Invention Steel

21

862
Comparative Steel

22

853
Invention Steel

23

853
Invention Steel

24

853
Invention Steel

25

853
Comparative Steel

26

853
Invention Steel

27

853
Invention Steel

28

853
Invention Steel

29

853
Invention Steel

30

853
Comparative Steel

TABLE 3

Chemical composition (mass %) of base steel sheet,

Steel
remainder consisting of Fe and impurities

No.
C
Si
Mn
P
S
sol.A1
N
Note

31
0.38
0.230
0.79
0.013
0.0008

0.0001

0.0027
Comparative Steel

32
0.38
0.160
0.85
0.010
0.0009
0.0003
0.0033
Invention Steel

33
0.35
0.200
0.72
0.014
0.0007
0.003
0.0042
Invention Steel

34
0.37
0.160
0.73
0.006
0.0006
0.031
0.0026
Invention Steel

35
0.35
0.240
0.83
0.009
0.0008
0.494
0.0034
Invention Steel

36
0.37
0.240
0.84
0.011
0.0007

0.581

0.0040
Comparative Steel

37
0.37
0.220
0.89
0.007
0.0007
0.035
0.0001
Invention Steel

38
0.38
0.150
0.89
0.009
0.0008
0.038
0.0073
invention Steel

39
0.38
0.190
0.71
0.007
0.0007
0.039
0.0090
Invention Steel

40
0.36
0.210
0.73
0.008
0.0003
0.035

0.0160

Comparative Steel

41
0.37
0.230
0.87
0.009
0.0006
0.031
0.0025
Invention Steel

42
0.36
0.170
0.70
0.009
0.0009
0.046
0.0030
Invention Steel

43
0.37
0.220
0.73
0.008
0.0004
0.033
0.0038
Invention Steel

44
0.37
0.230
0.90
0.009
0.0011
0.044
0.0044
Invention Steel

45
0.35
0.170
0.89
0.011
0.0007
0.043
0.0028
Invention Steel

46
0.36
0.170
0.88
0.007
0.0004
0.031
0.0033
Invention Steel

47
0.36
0.210
0.80
0.005
0.0003
0.037
0.0035
invention Steel

48
0.37
0.200
0.78
0.009
0.0010
0.031
0.0026
Invention Steel

49
0.38
0.160
0.82
0.015
0.0009
0.031
0.0041
Invention Steel

50
0.36
0.230
0.77
0.011
0.0008
0.043
0.0038
Invention Steel

51
0.35
0.160
0.70
0.005
0.0006
0.047
0.0026
Invention Steel

52
0.37
0.250
0.83
0.006
0.0010
0.033
0.0039
Invention Steel

53
0.37
0.150
0.70
0.015
0.0008
0.031
0.0044
Invention Steel

54
0.36
0.230
0.86
0.005
0.0003
0.050
0.0044
Invention Steel

55
0.36
0.160
0.74
0.015
0.0006
0.034
0.0044
Invention Steel

56
0.36
0.160
0.78
0.015
0.0006
0.037
0.0039
Invention Steel

57
0.36
0.190
0.80
0.010
0.0006
0.034
0.0027
Invention Steel

58
0.18
0.210
1.29
0.006
0.0020
0.030
0.0026
Invention Steel

59
0.21
0.220
1.31
0.006
0.0020
0.030
0.0028
Invention Steel

60
0.23
0.200
1.30
0.006
0.0020
0.030
0.0030
Invention Steel

61
0.25
0.190
1.28
0.006
0.0020
0.030
0.0029
Invention Steel

TABLE 4

Chemical composition (mass %) of base steel

Steel
sheet remainder consisting of Fe and impurities
A₃

No.
Nb
Ti
Mo
Cr
B
Ca
REM
(° C.)
Note

31

853
Comparative Steel

32

853
Invention Steel

33

853
Invention Steel

34

853
Invention Steel

35

853
Invention Steel

36

853
Comparative Steel

37

853
Invention Steel

38

853
Invention Steel

39

853
Invention Steel

40

853
Comparative Steel

41
0.012

857
Invention Steel

42
0.032

864
Invention Steel

43
0.120

895
Invention Steel

44

0.013

857
Invention Steel

45

0.036

862
Invention Steel

46

0.140

888
Invention Steel

47

0.006

854
Invention Steel

48

0.012

854
Invention Steel

49

0.980

951
Invention Steel

50

0.006

853
Invention Steel

51

0.009

853
Invention Steel

52

0.960

863
Invention Steel

53

0.0006

853
Invention Steel

54

0.0011

853
Invention Steel

55

0.0090

853
Invention Steel

56

0.008

853
Invention Steel

57

0.28
853
Invention Steel

58

0.017
0.120
0.207

871
Invention Steel

59

0.130

866
Invention Steel

60

0.121

865
Invention Steel

61

0.020
0.119
0.200

872
Invention Steel

TABLE 5

Hot rollnig

Cooling

Heat

Average
Average
Average

treat-

cooling
cooling
cooling
Cold
ment

rate up to
rate at
rate in
rolling
before

Rough rolling
Finish rolling

temperature
550° C. or
temperature
Cumu-
plating

Rolling
Cumulative
Rolling
Final
Cooling
range
higher and
range of
lative
Heating

Steel
temper-
rolling
temper-
rolling
start
of 650° C.
lower than
550° C.
rolling
temper-

Steel
sheet
ature
reduction
ature
reduction
time
or lower
650° C.
or lower
reduction
ature

No.
No
(° C.)
(%)
(° C.)
(%)
(sec)
(° C./s)
(°C./s)
(° C./s)
(%)
(° C.)
Note

1
1
1080
40
889
8
0.4
40
33
28
40
Absent
Comparative Steel

2
2
1100
40
970
30
0.3
40
11
30
40
Absent
Comparative Steel

3
3
1143
46
886
12
0.4
47
6
59
49
770
Comparative Steel

4
4
1099
49
905
11
0.4
48
5
60
59
Absent
Comparative Steel

5
5
1149
58
885
9
0.4
41
6
54
45
Absent
Invention Steel

6
6
1123
46
915
8
0.4
51
6
59
51
Absent
Invention Steel

7
7
1141
40
908
12
0.2
40
6
62
49
Absent
Invention Steel

8
8
1090
48
896
12
0.4
49
6
62
12
Absent
Invention Steel

9
9
1099
57
886
11
0.2
47
6
48
58
Absent
Invention Steel

10
10
1143
46
884
10
0.2
53
5
46
60
Absent
Comparative Steel

11
11
1128
51
890
10
0.3
40
6
60
49
Absent
Comparative Steel

12
12
1142
42
902
9
0.3
52
7
60
56
Absent
Invention Steel

13
13
1145
54
909
12
0.4
47
5
55
53
Absent
Invention Steel

14
14
1137
40
894
9
0.2
54
6
58
40
Absent
Invention Steel

15
15
1101
45
904
9
0.3
44
7
55
52
Absent
Comparative Steel

16
16
1121
57
881
9
0.4
43
5
46
58
Absent
Invention Steel

17
17
1103
46
915
11
0.4
44
5
50
44
Absent
Invention Steel

18
18
1130
53
892
11
0.4
43
6
59
43
Absent
Invention Steel

19
19
1095
55
908
10
0.2
52
7
65
59
Absent
Invention Steel

20
20
1136
59
885
8
0.3
48
4
65
51
Absent
Invention Steel

21
21
1107
41
881
10
0.3
50
6
49
42
Absent
Comparative Steel

22
22
1123
44
888
12
0.4
43
4
63
58
Absent
Invention Steel

23
23
1123
44
888
11
0.3
55
7
46
49
Absent
Invention Steel

24
24
1080
51
884
10
0.2
48
5
57
50
Abseil
Invention Steel

25
25
1120
43
918
10
0.3
43
6
48
60
Absent
Comparative Steel

26
26
1124
48
888
8
0.4
50
4
58
60
Absent
Invention Steel

27
27
1078
49
892
10
0.3
40
7
62
51
Absent
Invention Steel

28
28
1127
47
892
12
0.2
51
5
62
46
Absent
Invention Steel

29
29
1101
58
887
11
0.4
53
4
50
47
Absent
Invention Steel

30
30
1112
56
909
10
0.2
47
5
56
46
Absent
Comparative Steel

TABLE 6

Steel sheet for hot stamping

Grains having

average crystal

Plating
Ni content
orientation

Steel
adhesion
in plating
difference of 0.4°
Sheet

Steel
sheet
amount
layer
to 3.0°
thickness

No.
No.
(g/m²)
(mass %)
(area %)
(mm)
Note

1
1
41
15

30

1.6
Comparative Steel

2
2
53
12

25

1.6
Comparative Steel

3
3
40
12
3
1.6
Comparative Steel

4
4
56
15
86
1.6
Comparative Steel

5
5
50
14
87
1.4
Invention Steel

6
6
41
15
90
1.6
Invention Steel

7
7
54
17
89
1.8
Invention Steel

8
8
57
15
88
1.6
Invention Steel

9
9
40
16
89
1.9
Invention Steel

10

10
53
17
89
1.5
Comparative Steel

11

11
48
12

46

1.8
Comparative Steel

12
12
58
16
82
1.4
Invention Steel

13
13
48
17
84
1.6
Invention Steel

14
14
46
14
89
1.6
Invention Steel

15

15
58
10
92
1.7
Comparative Steel

16
16
51
17
89
1.4
Invention Steel

17
17
43
11
85
1.8
Invention Steel

18
18
52
12
93
1.6
Invention Steel

19
19
50
13
89
1.6
Invention Steel

20
20
45
11
93
1.9
Invention Steel

21

21
45
14
91
1.5
Comparative Steel

22
22
60
14
86
2.0
Invention Steel

23
23
47
15
91
1.9
Invention Steel

24
24
60
15
87
1.7
Invention Steel

25

25
58
13
87
1.4
Comparative Steel

26
26
60
15
87
1.8
Invention Steel

27
27
52
12
86
2.0
Invention Steel

28
28
50
10
86
1.4
Invention Steel

29
29
53
15
88
1.5
Invention Steel

30

30
51
11
90
1.5
Comparative Steel

TABLE 7

Hot rolling

Cooling

Average
Average
Average

Heat

cooling
cooling
cooling
Cold
treatment

rate up to
rate at
rate in
rolling
before

Rough rolling
Finish rolling
Cool-
temperature
550° C. or
temperature
Cumu-
plating

Rolling
Cumulative
Rolling
Final
ing
range of
higher and
range of
lative
Heating

Steel
temper-
rolling
temper-
rolling
start
650° C.
lower than
550° C.
rolling
temper-

Steel
sheet
ature
reduction
ature
reduction
time
or lower
650° C.
or lower
reduction
ature

No.
No.
(° C.)
(%)
(° C.)
(%)
(sec)
(° C./s)
(° C./s)
(° C./s)
(%)
(° C.)
Note

31

31
1108
46
902
10
0.4
40
6
45
49
Absent
Comparative Steel

32
32
1136
60
918
8
0.2
54
5
45
48
Absent
Invention Steel

33
33
1128
56
895
12
0.2
41
6
57
43
Absent
Invention Steel

34
34
1127
54
914
10
0.3
51
4
48
48
Absent
Invention Steel

35
35
1118
47
881
10
0.3
51
4
64
57
Absent
Invention Steel

36

36
1081
40
904
9
0.3
42
6
49
44
Absent
Comparative Steel

37
37
1103
52
881
11
0.2
53
6
52
57
Absent
Invention Steel

38
38
1081
41
889
9
0.2
53
7
56
59
Absent
Invention Steel

39
39
1085
50
891
12
0.2
42
6
45
57
Absent
Invention Steel

40

40
1073
53
901
10
0.2
53
4
45
60
Absent
Comparative Steel

41
41
1128
55
917
12
0.2
50
7
53
57
Absent
Invention Steel

42
42
1142
41
893
9
0.4
48
7
62
57
Absent
Invention Steel

43
43
1090
54
890
12
0.2
53
7
49
54
Absent
Invention Steel

44
44
1080
58
891
9
0.4
40
7
46
56
Absent
Invention Steel

45
45
1126
53
890
10
0.2
52
6
50
42
Absent
Invention Steel

46
46
1093
60
913
11
0.2
44
6
65
53
Absent
Invention Steel

47
47
1136
52
882
12
0.2
54
6
57
52
Absent
Invention Steel

48
48
1079
49
917
11
0.4
42
5
53
45
Absent
Invention Steel

49
49
1112
57
892
8
0.3
41
4
64
45
Absent
Invention Steel

50
50
1094
45
886
10
0.4
41
6
48
56
Absent
Invention Steel

51
51
1121
51
896
12
0.2
52
7
47
57
Absent
Invention Steel

52
52
1070
52
913
11
0.2
46
6
61
55
Absent
Invention Steel

53
53
1109
56
910
11
0.4
47
4
45
43
Absent
Invention Steel

54
54
1080
58
901
11
0.4
49
6
60
45
Absent
Invention Steel

55
55
1129
42
903
8
0.4
49
7
55
54
Absent
Invention Steel

56
56
1098
40
919
9
0.3
43
5
58
52
Absent
Invention Steel

57
57
1079
57
887
12
0.4
50
7
57
52
Absent
Invention Steel

TABLE 8

Steel sheet for hot stamping

Grains having

average crystal

Plating
Ni content
orientation

Steel
adhesion
in plating
difference of 0.4°
Sheet

Steel
sheet
amount
layer
to 3.0°
thickness

No.
No.
(g/m²)
(mass %)
(area %)
(mm)
Note

31

31
46
16
90
1.5
Comparative Steel

32
32
40
16
87
2.0
Invention Steel

33
33
43
13
92
1.8
Invention Steel

34
34
46
16
85
1.6
Invention Steel

35
35
51
14
92
1.4
Invention Steel

36

36
47
13
90
1.5
Comparative Steel

37
37
52
12
92
1.6
Invention Steel

38
38
46
17
86
1.5
Invention Steel

39
39
60
16
91
1.9
Invention Steel

40

40
60
17
88
1.8
Comparative Steel

41
41
45
15
91
1.7
Invention Steel

42
42
58
15
86
1.5
Invention Steel

43
43
59
12
85
1.7
Invention Steel

44
44
45
17
86
1.9
Invention Steel

45
45
42
17
86
1.5
Invention Steel

46
46
58
16
91
1.8
Invention Steel

47
47
42
14
88
1.8
Invention Steel

48
48
48
13
86
1.7
Invention Steel

49
49
58
12
87
2.0
Invention Steel

50
50
42
10
86
1.4
Invention Steel

51
51
51
15
88
1.4
Invention Steel

52
52
60
10
91
1.9
Invention Steel

53
53
49
11
88
1.7
Invention Steel

54
54
40
16
87
1.6
Invention Steel

55
55
54
10
85
1.9
Invention Steel

56
56
44
14
90
2.0
Invention Steel

57
57
46
17
87
1.8
Invention Steel

TABLE 9

Hot rolling

Cooling

Average
Average
Average

Heat

cooling
cooling
cooling
Cold
treatment

rate up to
rate at
rate in
rolling
before

Rough rolling
Finish rolling
Cool-
temperature
550° C. or
temperature
Cumu-
plating

Rolling
Cumulative
Rolling
Final
ing
range of
higher and
range of
lative
Heating

Steel
temper-
rolling
temper-
rolling
start
650° C.
lower than
550° C.
rolling
temper-

Steel
sheet
ature
reduction
ature
reduction
time
or lower
650° C.
or lower
reduction
ature

No.
No.
(° C.)
(%)
(° C.)
(%)
(sec)
(° C./s)
(° C./s)
(° C./s)
(%)
(° C.)
Note

7
58
990
57
894
11
0.3
52
4
48
60
Absent
Comparative Steel

7
59
1065
52
891
10
0.2
43
7
60
46
Absent
Invention Steel

7
60
1133

36

911
11
0.3
47
7
52
55
Absent
Comparative Steel

7
61
1084
42
896
12
0.3
42
4
54
49
Absent
Invention Steel

7
62
1113
45

790

10
0.2
48
4
48
48
Absent
Comparative Steel

7
63
1126
53
839
12
0.2
41
6
47
53
Absent
Invention Steel

7
64
1074
51
914
3
0.2
40
5
53
47
Absent
Comparative Steel

7
65
1086
45
917
6
0.4
45
5
49
45
Absent
Invention Steel

7
66
1074
58
915
9
0.3
46
6
63
50
Absent
Invention Steel

7
67
1149
49
892
17
0.2
54
6
65
57
Absent
Invention Steel

7
68
1100
57
890

26

0.4
51
5
56
59
Absent
Comparative Steel

7
69
1090
52
908
8
0.3
49
5
48
49
Absent
Invention Steel

7
70
1119
46
914
9
0.4
55
7
57
43
Absent
Invention Steel

7
71
1096
58
909
10

0.7

51
5
51
57
Absent
Comparative Steel

7
72
1075
48
883
10
0.4

26

4
56
55
Absent
Comparative Steel

7
73
1081
55
905
12
0.4
33
4
55
43
Absent
Invention Steel

7
74
1118
47
895
8
0.4
49
6
62
47
Absent
Invention Steel

7
75
1130
49
912
11
0.2
44
0.6
54
52
Absent
Comparative Steel

7
76
1093
49
885
11
0.2
42
2
64
44
Absent
Invention Steel

7
77
1141
51
906
11
0.2
52
5
57
44
Absent
Invention Steel

7
78
1147
58
882
10
0.4
47
9
55
57
Absent
Invention Steel

7
79
1144
51
916
8
0.4
41

13
45
55
Absent
Comparative Steel

7
80
1096
51
896
9
0.3
41
7

34

41
Absent
Comparative Steel

7
81
1094
50
886
12
0.3
50
7
41
47
Absent
Invention Steel

7
82
1107
51
919
10
0.4
41
5
59
49
Absent
Invention Steel

7
83
1087
54
910
9
0.4
43
5
50
0
Absent
Invention Steel

7
84
1078
55
913
12
0.2
46
4
64
40
711
Invention Steel

7
85
1089
43
904
12
0.3
44
6
62
58
Absent
Invention Steel

7
86
1109
49
896
9
0.2
51
5
61
48
Absent
Invention Steel

7
87
1149
52
898
8
0.4
53
6
46
45
Absent
Invention Steel

7
88
1141
47
895
8
0.2
51
6
65
57
Absent
Invention Steel

7
89
1096
49
906
10
0.4
52
5
56
43
Absent
Invention Steel

7
90
1107
51
916
9
0.4
41
4
55
47
Absent
Invention Steel

7
91
1087
51
886
12
0.2
41
5
64
44
Absent
Invention Steel

7
92
1078
50
913
10
0.2
46
4
62
41
Absent
Invention Steel

TABLE 10

Steel sheet for hot stamping

Grains having

average crystal

Plating
Ni content
orientation

Steel
adhesion
in plating
difference of 0.4°
Sheet

Steel
sheet
amount
layer
to 3.0°
thickness

No.
No.
(g/m²)
(mass %)
(area %)
(mm)
Note

7
58
58
17

66

1.8
Comparative Steel

7
59
54
17
82
1.8
Invention Steel

7
60
59
11

56

1.4
Comparative Steel

7
61
41
16
82
1.9
Invention Steel

7
62
54
14

61

1.4
Comparative Steel

7
63
51
13
84
1.9
Invention Steel

7
64
42
13

57

1.6
Comparative Steel

7
65
43
17
83
1.4
Invention Steel

7
66
44
11
85
1.4
Invention Steel

7
67
49
10
82
1.5
Invention Steel

7
68
44
17

68

1.5
Comparative Steel

7
69
43
11
86
1.7
Invention Steel

7
70
60
10
82
1.4
Invention Steel

7
71
52
11

58

1.5
Comparative Steel

7
72
55
11

59

1.9
Comparative Steel

7
73
42
17
82
1.8
Invention Steel

7
74
45
15
84
1.7
Invention Steel

7
75
51
10

74

2.0
Comparative Steel

7
76
42
17
82
1.9
Invention Steel

7
77
50
14
81
1.4
Invention Steel

7
78
45
17
83
1.7
Invention Steel

7
79
54
15

28

1.6
Comparative Steel

7
80
45
10

76

1.4
Comparative Steel

7
81
40
10
81
2.0
Invention Steel

7
82
52
10
83
2.0
Invention Steel

7
83
49
12
86
1.4
Invention Steel

7
84
40
12
90
1.6
Invention Steel

7
85
50
13
85
1.9
Invention Steel

7
86
40
17
82
1.7
Invention Steel

7
87
52
10
83
1.5
Invention Steel

7
88
49
11
85
1.7
Invention Steel

7
89
55
11
82
1.4
Invention Steel

7
90
45
15
84
1.8
Invention Steel

7
91
45
17
83
1.9
Invention Steel

7
92
45
10
90
1.7
Invention Steel

TABLE 11

Hot rolling

Cooling

Average
Average
Average

Heat

cooling
cooling
cooling
Cold
treatment

rate up to
rate at
rate in
rolling
before

Rough rolling
Finish rolling
Cool-
temperature
550° C. or
temperature
Cumu-
plating

Rolling
Cumulative
Rolling
Final
ing
range of
higher and
range of
lative
Heating

Steel
temper-
rolling
temper-
rolling
start
650° C.
lower than
550° C.
rolling
temper-

Steel
sheet
ature
reduction
ature
reduction
time
or lower
650° C.
or lower
reduction
ature

No.
No.
(° C.)
(%)
(° C.)
(%)
(sec)
(° C./s)
(° C./s)
(° C./s)
(%)
(° C.)
Note

58
93
1150
57
917
11
0.3
47
6
47
45
Absent
Invention Steel

59
94
1131
46
890
10
0.2
48
5
49
45
Absent
Invention Steel

60
95
1110
48
908
10
0.2
40
6
56
45
Absent
Invention Steel

61
96
1108
55
883
12
0.2
54
5
57
45
Absent
Invention Steel

7
97
1099
47
906
8
0.3
49
3
55
45
Absent
Invention Steel

7
98
1088
47
919
10
0.4
55
2
62
45
Absent
Invention Steel

7
99
1103
51
913
12
0.2
51
2
54
45
Absent
Invention Steel

7
100
1098
50
895
9
0.2
43
3
51
45
Absent
Invention Steel

TABLE 12

Steel sheet for hot stamping

Grains having

average crystal

Plating
Ni content
orientation

Steel
adhesion
in plating
difference of 0.4°
Sheet

Steel
sheet
amount
layer
to 3.0°
thickness

No.
No.
(g/m²)
(mass %)
(area %)
(mm)
Note

58
93
49
11
90
1.4
Invention Steel

59
94
40
13
82
1.4
Invention Steel

60
95
49
10
85
1.4
Invention Steel

61
96
45
10
84
1.6
Invention Steel

7
97
45
11
95
1.4
Invention Steel

7
98
51
17
94
1.6
Invention Steel

7
99
50
14
96
1.6
Invention Steel

7
100
52
15
95
1.4
Invention Steel

TABLE 13

Heat treatment step during hot stamping

Elapsed time

Average

from start of

Steel

heating
Holding
heating to
Tempering
Partially

Steel
sheet
Manufacturing
rate
temperature
forming
temperature
softened

No.
No.
No.
(° C./s)
(° C.)
(s)
(° C.)
region
Note

1
1
A1
43
911
287
Absent
Absent
Comparative Steel

2
2
A2
48
908
272
Absent
Absent
Comparative Steel

3
3
A3
43
913
244
Absent
Absent
Comparative Steel

4
4
A4
39
893
288
Absent
Absent
Comparative Steel

5
5
A5
53
920
285
Absent
Absent
Invention Steel

6
6
A6
41
890
240
Absent
Absent
Invention Steel

7
7
A7
39
913
280
Absent
Absent
Invention Steel

8
8
A8
46
893
347
Absent
Absent
Invention Steel

9
9
A9
39
894
320
480
Absent
Invention Steel

10

10

A10
52
919
283
Absent
Absent
Comparative Steel

11

11

A11
56
903
322
Absent
Absent
Comparative Steel

12
12
A12
46
890
346
Absent
Absent
Invention Steel

13
13
A13
55
903
321
Absent
Absent
Invention Steel

14
14
A14
47
910
357
Absent
Absent
Invention Steel

15

15

A15
45
899
304
Absent
Absent
Comparative Steel

16
16
A16
47
907
289
Absent
Absent
Invention Steel

17
17
A17
43
915
243
Absent
Absent
Invention Steel

18
18
A18
54
906
287
Absent
Absent
Invention Steel

19
19
A19
54
917
358
Absent
Absent
Invention Steel

20
20
A20
51
909
305
Absent
Absent
Invention Steel

21

21

A21
33
894
277
Absent
Absent
Comparative Steel

22
22
A22
45
919
268
Absent
Absent
Invention Steel

23
23
A23
34
902
317
Absent
Absent
Invention Steel

24
24
A24
50
891
323
Absent
Absent
Invention Steel

25

25

A25
31
900
276
Absent
Absent
Comparative Steel

26
26
A26
60
917
273
Absent
Absent
Invention Steel

27
27
A27
49
908
317
Absent
Absent
Invention Steel

28
28
A28
54
892
332
Absent
Absent
Invention Steel

29
29
A29
42
891
249
Absent
Absent
Invention Steel

30

30

A30
40
899
255
Absent
Absent
Comparative Steel

TABLE 14

Microstructure of hot-stamping formed body

Martensite,
Ratio of lengths of grain
Mechanical properties

Plating

tempered
boundaries having rotation

Impact

Steel

adhesion
Ni content in
martensite, and
angle of 64° to 72° with <011>
Tensile
value at

Steel
sheet
Manufacturing
amount
plating layer
lower bainite
direction as rotation axis
strength
−60° C.

No.
No.
No.
(g/m²)
(mass %)
(area %)
(%)
(MPa)
(J/cm²)
Note

1
1
A1
41
15
92

25

2052
8
Comparative Steel

2
2
A2
53
12
97

21

2006
6
Comparative Steel

3
3
A3
40
12
93
4
2124
3
Comparative Steel

4
4
A4
56
15

47

42
972
46
Comparative Steel

5
5
A5
50
14
95
45
1620
38
Invention Steel

6
6
A6
41
15
94
44
1929
31
Invention Steel

7
7
A7
54
17
90
42
2011
28
Invention Steel

8
8
A8
57
15
94
43
2520
21
Invention Steel

9
9
A9
40
16
95
41
2580
23
Invention Steel

10

10

A10
53
17
96
42
2791
3
Comparative Steel

11

11

A11
48
12
90

29

2100

15

Invention Steel

12
12
A12
58
16
89
37
2144
26
Invention Steel

13
13
A13
48
17
88
41
2106
28
Invention Steel

14
14
A14
46
14
96
51
2017
30
Invention Steel

15

15

A15
58
10

44

42

1420

38
Comparative Steel

16
16
A16
51
17
87
45
2519
22
Invention Steel

17
17
A17
43
11
89
36
1890
27
Invention Steel

18
18
A18
52
12
89
39
1899
26
Invention Steel

19
19
A19
50
13
87
37
1910
28
hivention Steel

20
20
A20
45
11
92
41
1530
21
Invention Steel

21

21

A21
45
14
91
44
1540
3
Comparative Steel

22
22
A22
60
14
97
45
2087
31
Invention Steel

23
23
A23
47
15
91
44
2016
28
Invention Steel

24
24
A24
60
15
97
38
2070
22
Invention Steel

25

25

A25
58
13
92
42
2070

14

Comparative Steel

26
26
A26
60
15
94
44
2106
33
Invention Steel

27
27
A27
52
12
92
38
2119
31
Invention Steel

28
28
A28
50
10
91
39
2104
25
Invention Steel

29
29
A29
53
15
95
37
2049
22
Invention Steel

30

30

A30
51
11
87
45
2068

16

Comparative Steel

TABLE 15

Heat treatment step during hot stamping

Elapsed time

Average

from start of

Steel

heating
Holding
heating to
Tempering
Partially

Steel
sheet
Manufacturing
rate
temperature
forming
temperature
softened

No.
No.
No.
(° C./s)
(° C.)
(s)
(° C.)
region
Note

31

31

A31
52
896
349
Absent
Absent
Comparative Steel

32
32
A32
42
917
329
Absent
Absent
Invention Steel

33
33
A33
47
909
256
Absent
Absent
Invention Steel

34
34
A34
36
896
356
Absent
Absent
Invention Steel

35
35
A35
35
908
269
Absent
Absent
Invention Steel

36

36

A36
46
915
286
Absent
Absent
Comparative Steel

37
37
A37
42
914
263
Absent
Absent
Invention Steel

38
38
A38
45
917
256
Absent
Absent
Invention Steel

39
39
A39
57
897
295
Absent
Absent
Invention Steel

40

40

A40
52
903
329
Absent
Absent
Comparative Steel

41
41
A41
38
906
260
Absent
Absent
Invention Steel

42
42
A42
47
899
337
Absent
Absent
Invention Steel

43
43
A43
43
905
350
Absent
Absent
Invention Steel

44
44
A44
36
896
341
Absent
Absent
Invention Steel

45
45
A45
47
917
259
Absent
Absent
Invention Steel

46
46
A46
42
920
343
Absent
Absent
Invention Steel

47
47
A47
53
892
317
Absent
Absent
Invention Steel

48
48
A48
41
897
256
Absent
Absent
Invention Steel

49
49
A49
31
895
320
Absent
Absent
Invention Steel

50
50
A50
38
916
331
Absent
Absent
Invention Steel

51
51
A51
51
908
315
Absent
Absent
Invention Steel

52
52
A52
52
891
254
Absent
Absent
Invention Steel

53
53
A53
33
920
265
Absent
Absent
Invention Steel

54
54
A54
36
905
322
Absent
Absent
Invention Steel

55
55
A55
41
918
307
Absent
Absent
Invention Steel

56
56
A56
33
894
254
Absent
Absent
Invention Steel

57
57
A57
60
898
317
Absent
Absent
Invention Steel

TABLE 16

Microstructure of hot-stamping formed body

Martensite,
Ratio of lengths of grain
Mechanical properties

Plating

tempered
boundaries having rotation

Impact

Steel

adhesion
Ni content in
martensite, and
angle of 64° to 72° with <011>
Tensile
value at

Steel
sheet
Manufacturing
amount
plating layer
lower bainite
direction as rotation axis
strength
−60° C.

No.
No.
No.
(g/m²)
(mass %)
(area %)
(%)
(MPa)
(J/cm²)
Note

31

31

A31
46
16
91
44
2147

13

Comparative Steel

32
32
A32
40
16
88
37
2067
23
Invention Steel

33
33
A33
43
13
96
36
2064
26
Invention Steel

34
34
A34
46
16
90
38
2139
29
Invention Steel

35
35
A35
51
14
95
45
2125
21
Invention Steel

36

36

A36
47
13
91
43
2025

17

Comparative Steel

37
37
A37
52
12
95
39
2025
29
Invention Steel

38
38
A38
46
17
96
39
2090
25
Invention Steel

39
39
A39
60
16
88
40
2015
23
Invention Steel

40

40

A40
60
17
94
42
2048

12

Comparative Steel

41
41
A41
45
15
96
36
2218
30
Invention Steel

42
42
A42
58
15
89
41
2185
25
Invention Steel

43
43
A43
59
12
97
45
2193
22
Invention Steel

44
44
A44
45
17
87
43
2213
27
Invention Steel

45
45
A45
42
17
95
36
2250
20
Invention Steel

46
46
A46
58
16
94
44
2129
22
Invention Steel

47
47
A47
42
14
88
43
2206
27
Invention Steel

48
48
A48
48
13
87
45
2152
30
Invention Steel

49
49
A49
58
12
87
45
2181
26
Invention Steel

50
50
A50
42
10
88
36
2199
26
Invention Steel

51
51
A51
51
15
88
39
2143
28
Invention Steel

52
52
A52
60
10
88
41
2182
28
Invention Steel

53
53
A53
49
11
88
37
2008
26
Invention Steel

54
54
A54
40
16
95
43
2068
31
Invention Steel

55
55
A55
54
10
93
43
2082
31
Invention Steel

56
56
A56
44
14
97
43
2066
33
Invention Steel

57
57
A57
46
17
94
39
2070
32
Invention Steel

TABLE 17

Heat treatment step during hot stamping

Elapsed time

Average

from start of

Steel

heating
Holding
heating to
Tempering
Partially

Steel
sheet
Manufacturing
rate
temperature
forming
temperature
softened

No.
No.
No.
(° C./s)
(° C.)
(s)
(° C.)
region
Note

7

58

A58
57
912
304
Absent
Absent
Comparative Steel

7
59
A59
47
910
296
Absent
Absent
Invention Steel

7

60

A60
43
894
256
Absent
Absent
Comparative Steel

7
61
A61
45
907
322
Absent
Absent
Invention Steel

7

62

A62
38
900
269
Absent
Absent
Comparative Steel

7
63
A63
57
912
336
Absent
Absent
Invention Steel

7

64

A64
59
890
339
Absent
Absent
Comparative Steel

7
65
A65
46
913
246
Absent
Absent
Invention Steel

7
66
A66
57
894
267
Absent
Absent
Invention Steel

7
67
A67
46
893
312
Absent
Absent
Invention Steel

7

68

A68
42
900
326
Absent
Absent
Comparative Steel

7
69
A69
60
913
286
Absent
Absent
Invention Steel

7
70
A70
42
903
343
Absent
Absent
Invention Steel

7

71

A71
52
903
241
Absent
Absent
Comparative Steel

7

72

A72
49
920
290
Absent
Absent
Comparative Steel

7
73
A73
38
903
253
Absent
Absent
Invention Steel

7
74
A74
60
912
342
Absent
Absent
Invention Steel

7

75

A75
54
896
250
Absent
Absent
Comparative Steel

7
76
A76
38
894
278
Absent
Absent
Invention Steel

7
77
A77
55
909
318
Absent
Absent
Invention Steel

7
78
A78
46
896
336
Absent
Absent
Invention Steel

7

79

A79
43
898
297
Absent
Absent
Comparative Steel

7

80

A80
49
918
360
Absent
Absent
Comparative Steel

7
81
A81
48
920
321
Absent
Absent
Invention Steel

7
82
A82
36
901
342
Absent
Absent
Invention Steel

7
83
A83
40
911
260
Absent
Absent
Invention Steel

7
84
A84
55
915
303
Absent
Absent
Invention Steel

7
85
A85
2
892
302
Absent
Absent
Invention Steel

7
86
A86
11
914
354
Absent
Absent
Invention Steel

7
87
A87
52
901
326
Absent
Absent
Invention Steel

7
88
A88
91
912
343
Absent
Absent
Invention Steel

7
89
A89
41

790

264
Absent
Absent
Comparative Steel

7
90
A90
58

1009
305
Absent
Absent
Comparative Steel

7
91
A91
36
918
336
180
Absent
Invention Steel

7
92
A92
47
904
251
Absent
Present
Invention Steel

TABLE 18

Microstructure of hot-stamping formed body

Martensite,
Ratio of lengths of grain
Mechanical properties

Plating

tempered
boundaries having rotation

Impact

Steel

adhesion
Ni content in
martensite, and
angle of 64° to 72° with <011>
Tensile
value at

Steel
sheet
Manufacturing
amount
plating layer
lower bainite
direction as rotation axis
strength
−60° C.

No.
No.
No.
(g/m²)
(mass %)
(area %)
(%)
(MPa)
(J/cm²)
Note

7

58

A58
58
17
97

16

2086

16

Comparative Steel

7
59
A59
54
17
93
36
2014
23
Invention Steel

7

60

A60
59
11
92

15

2133

17

Comparative Steel

7
61
A61
41
16
95
44
2015
24
Invention Steel

7

62

A62
54
14
91

12

2119

13

Comparative Steel

7
63
A63
51
13
91
40
2035
27
Invention Steel

7

64

A64
42
13
87

17

2123

18

Invention Steel

7
65
A65
43
17
87
42
2061
22
Invention Steel

7
66
A66
44
11
96
39
2092
28
Invention Steel

7
67
A67
49
10
91
39
2022
20
Invention Steel

7

68

A68
44
17
88

21

2057

15

Invention Steel

7
69
A69
43
11
96
36
2119
23
Invention Steel

7
70
A70
60
10
90
43
2044
22
Invention Steel

7

71

A71
52
11
94

19

2086

17

Comparative Steel

7

72

A72
55
11
96

22

2129

18

Comparative Steel

7
73
A73
42
17
93
44
2114
28
Invention Steel

7
74
A74
45
15
87
44
2112
26
Invention Steel

7

75

A75
51
10
90

12

2111

17

Comparative steel

7
76
A76
42
17
88
38
2040
23
Invention Steel

7
77
A77
50
14
90
41
2056
29
Invention Steel

7
78
A78
45
17
92
42
2124
27
Invention Steel

7

79

A79
54
15
97

14

2075

11

Comparative Steel

7

80

A80
45
10
87

31

2138

16

Comparative Steel

7
81
A81
40
10
89
43
2074
25
Invention Steel

7
82
A82
52
10
90
49
2025
32
Invention Steel

7
83
A83
49
12
89
45
2094
21
Invention Steel

7
84
A84
40
12
94
36
2068
22
Invention Steel

7
85
A85
50
13
87
55
2108
35
Invention Steel

7
86
A86
40
17
90
51
2118
33
Invention Steel

7
87
A87
52
10
90
41
2007
30
Invention Steel

7
88
A88
49
11
89
36
2143
26
Invention Steel

7
89
A89
55
11
91
6
2094
8
Comparative Steel

7
90
A90
45
15
95
7
2066

14

Comparative Steel

7
91
A91
45
17
88
43
2125
22
Invention Steel

7
92
A92
45
10
88
42
2025
26
Invention Steel

TABLE 19

Heat treatment step during hot stamping

Elapsed time

Average

from start of

Steel

heating
Holding
heating to
Tempering
Partially

Steel
sheet
Manufacturing
rate
temperature
forming
temperature
softened

No.
No.
No.
(° C./s)
(° C.)
(s)
(° C.)
region
Note

58
93
A93
38
912
312
Absent
Absent
Invention Steel

59
94
A94
46
900
286
Absent
Absent
Invention Steel

60
95
A95
42
912
290
Absent
Absent
Invention Steel

61
96
A96
38
920
250
Absent
Absent
Invention Steel

7
97
A97
55
912
278
Absent
Absent
Invention Steel

7
98
A98
43
913
336
Absent
Absent
Invention Steel

7
99
A99
40
915
321
Absent
Absent
Invention Steel

7
100
A100
39
912
281
Absent
Absent
Invention Steel

TABLE 20

Microstructure of hot-stamping formed body

Martensite,
Ratio of lengths of grain
Mechanical properties

Plating

tempered
boundaries having rotation

Impact

Steel

adhesion
Ni content in
martensite, and
angle of 64° to 72° with <011>
Tensile
value at

Steel
sheet
Manufacturing
amount
plating layer
lower bainite
direction as rotation axis
strength
−60° C.

No.
No.
No.
(g/m²)
(mass %)
(area %)
(%)
(MPa)
(J/cm²)
Note

58
93
A93
42
14
96
45
1620
38
Invention Steel

59
94
A94
54
11
95
44
1591
35
Invention Steel

60
95
A95
40
11
94
41
1578
38
Invention Steel

61
96
A96
49
10
91
43
1599
32
Invention Steel

7
97
A97
40
11
90
59
2091
31
Invention Steel

7
98
A98
49
17
93
62
2101
29
Invention Steel

7
99
A99
55
12
91
66
2077
28
Invention Steel

7
100
A100
45
10
92
63
2061
34
Invention Steel

The microstructure of the steel sheets for hot stamping and the hot-stamping formed bodies was measured by the above-mentioned measurement methods. The mechanical properties of the hot-stamping formed bodies were evaluated by the following methods.

“Tensile Strength”

The tensile strength of the hot-stamping formed body was obtained in accordance with the test method described in JIS Z 2241:2011 by producing a No. 5 test piece described in JIS Z 2201:2011 from any position in the hot-stamping formed body.

“Toughness”

The toughness was evaluated by a Charpy impact test at −60° C. The toughness was evaluated by collecting a sub-size Charpy impact test piece from any position of the hot-stamping formed body and obtaining an impact value at −60° C. according to the test method described in JIS Z 2242:2005.

In a case where the tensile strength was 1,500 MPa or more and the impact value at −60° C. was 20 J/cm²or more was determined to be an invention example as being excellent in strength and toughness. In a case where any one of the above two performances was not satisfied, the case was determined to be a comparative example.

In the invention examples of Tables 14, 16, 18, and 20, the remainder in the microstructure contained one or more of residual austenite, ferrite, pearlite, granular bainite, and upper bainite.

Referring to Tables 14, 16, 18, and 20, it can be seen that a hot-stamping formed body in which the chemical composition, the plating composition, and the microstructure are within the ranges of the present invention has excellent strength and toughness.

On the other hand, it can be seen that a hot-stamping formed body in which any one or more of the chemical composition and the microstructure deviates from the present invention is inferior in one or more of strength and toughness.

INDUSTRIAL APPLICABILITY

According to the present invention, it is possible to provide a hot-stamping formed body having high strength and having better toughness than in the related art is obtained.

Number	Name	Date	Kind
20150027596	Miyoshi et al.	Jan 2015	A1
20170306437	Nakagawa et al.	Oct 2017	A1
20180023162	Sugiura et al.	Jan 2018	A1
20190390295	Nakagawa et al.	Dec 2019	A1
20200230681	Toda et al.	Jul 2020	A1

Number	Date	Country
2 684 985	Jan 2014	EP
2012-172203	Sep 2012	JP
2012197505	Oct 2012	JP
5861766	Feb 2016	JP
10-2014-0128409	Nov 2014	KR
10-2017-0056696	May 2017	KR
WO 2016132545	Aug 2016	WO
WO 2018151332	Aug 2018	WO
WO 2018179839	Oct 2018	WO

Hot-stamping formed body

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