JP2017218672A - High strength cold rolled steel sheet excellent in formability and production method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a high strength cold rolled steel sheet excellent in formability and a production method thereof.SOLUTION: There is provided the high strength cold rolled steel sheet that has component composition containing, by mass%, C:0.05 to 0.25%, Si:over 0% and 3.0% or less, Mn:5.0 to 9.0%, P:over 0% and 0.100% or less, S:over 0% and 0.010% or less, Al:0.001 to 3.0%, Si+Al:0.8 to 3.0%, N:over 0% and 0.0100% or less and the balance iron with inevitable impurity. The high strength cold rolled steel sheet also has a metallographic structure which is composed of, by area ratio, ferrite:40% or more and less than 80%, martensite:less than 25%, retained austenite:20% or more and the balance:less than 10%, and in which low angle grain boundary density in the ferrite is 1.0 to 2.4 μm/μm, average crystal grain size of the retained austenite is 1.5 μm or less and average Mn concentration in the retained austenite is over 9.0 mass%.SELECTED DRAWING: None

Description

  The present invention relates to a high-strength cold-rolled steel sheet excellent in formability used for automobile parts and the like and a method for producing the same.

  Steel sheets used for automotive parts are required to be thin in order to improve fuel efficiency through weight reduction, and high strength steel sheets are required to achieve both thinness and securing of component strength. Yes. Therefore, it is required to increase the tensile strength (TS) of the steel plate to 1180 MPa or more.

  Furthermore, when considering the collision safety, it is also required to increase the yield strength (YS) of the steel plate, and specifically, a steel plate having a YS of 900 MPa or more is required.

  Steel sheets are also required to have excellent formability in order to process into complicated parts. For this reason, a material having a good total elongation (EL) at a strength of TS1180 MPa or more and YS900 MPa or more is desired. Specifically, the product of TS and EL (TS × EL) is 30000 MPa% or more. Things are anxious.

  In addition, steel plates used as automotive parts are generally formed into various shapes after being cut into blanks with a shearing machine, but particularly high-strength steel plates suppress cracking during bending. Is required.

  Specifically, good bendability with R / t of 1.5 or less obtained by dividing the bending radius (R) where cracks occur by the plate thickness (t) is generally required. / T decreases, and particularly in high-strength steel, the shear cut surface is the starting point of fracture during bending, and cracks often occur. For this reason, when bending was performed with the shear cut surface, good bendability expression with an R / t of 1.5 or less that can suppress the generation of cracks from the shear cut surface has been demanded.

  In order to achieve both high strength with TS × EL of 30000 MPa% and high formability, a large amount of retained austenite is introduced into the steel sheet structure, and transformation induced plasticity (TRIP) due to the transformation of the retained austenite to work-induced martensite transformation (TRIP). It is known that it is effective to utilize the effect.

  For example, in Patent Document 1, as the steel sheet structure, the area ratio of martensite to the entire steel sheet structure is 15% or more and 90% or less, the amount of retained austenite is 10% or more and 50% or less, and 50% or more of the martensite is tempered. The area ratio of martensite to the entire steel sheet structure of the tempered martensite is 10% or more, the area ratio of polygonal ferrite to the entire steel sheet structure is 10% or less (including 0%), and the tensile strength is 1470 MPa. As described above, a high-strength steel sheet having a tensile strength × total elongation of 29000 MPa% or more has been disclosed. However, since this steel sheet is not subjected to the structure control for suppressing the breakage of the shear cutting surface starting point, it is assumed that the shear cutting surface starting point breaks when forming an actual part.

  Patent Document 2 discloses a steel plate having a good EL at TS1180 MPa or more and excellent in TS × EL. However, this steel sheet only prescribes the structure fraction of ferrite and does not perform structure control for strengthening ferrite, so it is assumed that it is difficult to develop a high YS of YS 900 MPa or more.

  Patent Document 3 discloses a high-strength steel sheet having TS of 980 MPa or more, TS × EL of 24000 MPa% or more, and also having good bendability of R / t ≦ 1.5, and a manufacturing method thereof. ing. However, since this steel sheet also does not perform ferrite strengthened structure control, it is assumed that it is difficult to achieve a high YS of YS 900 MPa or more and to achieve R / t ≦ 1.5 with the shear cut surface.

JP 2011-184756 A JP 2012-237054 A JP 2013-76162 A

  Therefore, the object of the present invention is the above desired level, that is, the tensile strength (TS) is 1180 MPa or more, the yield strength (YS) is 900 MPa or more, TS × total elongation (EL) is 30000 MPa% or more, and the shear cut surface An object of the present invention is to provide a high-strength cold-rolled steel sheet excellent in formability that can satisfy R / t of 1.5 or less, and a method for producing the same.

The high-strength cold-rolled steel sheet of the present invention is
C: 0.05 mass% or more and 0.25 mass% or less,
Si: more than 0% by mass and 3.0% by mass or less,
Mn: 5.0% by mass or more and 9.0% by mass or less,
P: more than 0% by mass and 0.100% by mass or less,
S: more than 0% by mass and 0.010% by mass or less,
Al: 0.001 mass% or more and 3.0 mass% or less,
Si + Al: 0.8 mass% or more and 3.0 mass% or less,
N: more than 0% by mass and 0.0100% by mass or less, and the balance: iron and inevitable impurities,
Having a component composition of
Ferrite: 40 area% or more and less than 80 area%,
Martensite: less than 25 area%,
Retained austenite: 20 area% or more, and the remainder: less than 10 area% of the metal structure,
The low-angle grain boundary density in the ferrite is 1.0 μm / μm ² or more and 2.4 μm / μm ² or less,
The residual austenite has an average crystal grain size of 1.5 μm or less, and
The average Mn concentration in the retained austenite is more than 9.0% by mass.

The high-strength cold-rolled steel sheet of the present invention is
Cr: 0.01% by mass or more and 0.20% by mass or less,
Mo: 0.01% by mass or more and 0.20% by mass or less,
Cu: 0.01% by mass or more and 0.20% by mass or less,
It is preferable to further contain one or more selected from the group consisting of Ni: 0.01% by mass to 0.20% by mass and B: 0.00001% by mass to 0.02% by mass. .

The high-strength cold-rolled steel sheet of the present invention is
Ca: 0.0005 mass% or more and 0.01 mass% or less,
It is preferable to further contain one or more selected from the group consisting of Mg: 0.0005 mass% to 0.01 mass% and REM: 0.0001 mass% to 0.01 mass%. .

The manufacturing method of the high-strength cold-rolled steel sheet of the present invention is
C: 0.05 mass% or more and 0.25 mass% or less,
Si: more than 0% by mass and 3.0% by mass or less,
Mn: 5.0% by mass or more and 9.0% by mass or less,
P: more than 0% by mass and 0.100% by mass or less,
S: more than 0% by mass and 0.010% by mass or less,
Al: 0.001 mass% or more and 3.0 mass% or less,
Si + Al: 0.8 mass% or more and 3.0 mass% or less,
N: more than 0% by mass and 0.0100% by mass or less, and the balance: iron and inevitable impurities,
A step of hot rolling a steel material having a component composition of:
A first step of cooling the steel sheet after the hot rolling step to room temperature;
Annealing the steel material after the first cooling step under conditions of a temperature of 400 ° C. or more and less than Ac1, a holding time of 0.5 hours or more and 72 hours or less;
Cold rolling the steel after the annealing step at a rolling reduction of 25% or more and 80% or less;
A step of heating the steel material after the cold rolling step at an average speed of 3.0 ° C./second or more;
The steel sheet after the temperature raising step is soaked under a condition of a first holding temperature [(Ac1 + Ac3) / 2-30] ° C. or higher and [(Ac1 + Ac3) / 2 + 10] ° C. or lower and a first holding time of 0 second or longer and 300 seconds or shorter. The first step;
A second step of cooling the steel material after the first soaking step at an average rate of 1.0 ° C./second or more from the first holding temperature;
The steel sheet after the second cooling step is subjected to a second holding temperature [(Ac1 + Ac3) / 2-90] ° C. to [(Ac1 + Ac3) / 2-50] ° C. and a second holding time of 120 seconds to 600 seconds. A second step of soaking,
And a third step of cooling the steel plate after the second soaking step.

  Here, Ac1 and Ac3 in the manufacturing method of the high-strength cold-rolled steel sheet according to the present invention are the temperature at which the formation of austenite starts and the temperature at which the transformation from ferrite to austenite is completed, respectively, using the cold-rolled sheet. A temperature rise test is performed under the condition of a temperature rise rate of 3.0 ° C./second, and the temperature obtained experimentally by measuring the shrinkage associated with austenite formation.

  According to the present invention, while restricting the amount of hard martensite introduced, the high-strength ferrite is used as a parent phase, and the retained austenite is increased in its crystal grain size and Mn concentration while increasing its fraction to the limit. By controlling to an appropriate range, the desired high level TS, YS and TS × EL, and a high strength cold-rolled steel sheet excellent in formability, which has a good R / t with a shear cut surface, and its A manufacturing method can be provided.

  The present inventors have intensively studied to solve the above problems. As a result, in order to have a high strength cold-rolled steel sheet with a desired high YS, TS × EL, and good R / t while maintaining the shear cut surface, while restricting the amount of hard martensite introduced, It has been found that it is effective to use strengthened ferrite as a parent phase, and to control the crystal grain size and the ease of deformation-induced martensite transformation while increasing the fraction of retained austenite to the limit.

  In other words, the ferrite in the cold-rolled cold-rolled sheet is suppressed by softening due to recrystallization in the annealing process, and a recovery structure having high strength and appropriate ductility is obtained. , YS is 900 MPa or higher and TS is 1180 MPa or higher. In addition, by increasing the strength of ferrite, which is a soft phase, the uniformity of strength in the microstructure with the retained austenite that is transformed into hard martensite by deformation induced by deformation is improved, and the origin of fracture is dispersed, Further, the progress of the crack between the soft phase and the hard phase can be suppressed, and the occurrence of cracks during bending can be suppressed even with the shear cut surface. The degree of recovery organization and recrystallization of ferrite is expressed by the low-angle grain boundary density in the ferrite, and high strength of the ferrite can be realized by appropriately controlling the low-angle grain boundary density.

  Furthermore, by refining the retained austenite and dispersing the fine retained austenite, the hard martensite after the processing-induced martensite transformation can be finely dispersed. In addition, the development between the soft phase and the hard phase of the cracks can be suppressed, and the occurrence of cracks during bending can be suppressed even with the shear cut surface.

  TS × EL improvement effect utilizing transformation-induced plasticity of retained austenite can be maximized by moderately suppressing the processing-induced martensitic transformation of retained austenite in the early stage of deformation and transforming in large quantities in the middle and later stages of deformation. It has been known.

  In this cold-rolled steel sheet, the concentration of strain on the ferrite in the early stage of deformation is relaxed due to the strengthening by the recovery structure of ferrite, and the strain tends to enter the retained austenite. In particular, it is important to stabilize the retained austenite more than before.

  In order to stabilize retained austenite, it is particularly effective to concentrate C and Mn. However, in this cold-rolled steel sheet, the amount of C added is limited in order to suppress excessive introduction of martensite. In addition to crystallization, the concentration of Mn to retained austenite is extremely important.

  As a result of further investigation based on the above findings, the present inventors have completed the present invention.

  Hereinafter, the metal structure characterizing the high-strength cold-rolled steel sheet according to the present invention (hereinafter also referred to as “the present steel sheet”) will be described first.

[Metal structure of the steel sheet of the present invention]
The steel sheet of the present invention has a metal structure of ferrite: 40 area% or more and less than 80 area%, martensite: less than 25 area%, residual austenite: 20 area% or more, and the balance: less than 10 area%, The low-angle grain boundary density is 1.0 μm / μm ² or more and 2.4 μm / μm ² or less, the average crystal grain size of the residual austenite is 1.5 μm or less, and the average Mn concentration in the residual austenite is It is characterized by being over 9.0% by mass.

<Ferrite: 40 area% or more and less than 80 area%>
The steel sheet of the present invention has desired mechanical properties in combination with transformation-induced plasticity of retained austenite by forming a recovery structure having ferrite as a main phase and having both high strength and ductility. In the steel sheet of the present invention, when the area ratio of ferrite in the metal structure is less than 40%, not only the ductility of the matrix phase is insufficient, but also the Mn concentration concentrated in the austenite is lowered, so that the EL is lowered. On the other hand, if the ferrite in the metal structure is 80 area% or more, TS cannot be secured. A preferable lower limit of ferrite in the metal structure is 45 area%, and a preferable upper limit is 75 area%.

<Martensite: Less than 25% by area>
In the steel sheet of the present invention, when martensite is contained in the metal structure in an area of 25 area% or more, in addition to lowering of EL, fracture starting from martensite occurs at the shear cut surface, and bendability is lowered. The upper limit of martensite in the metal structure is preferably 22 area%, more preferably 20 area%. In the present invention, “martensite” means a combination of both “as-quenched martensite” and “tempered martensite”.

<Residual austenite: 20 area% or more>
In addition to ferrite as a parent phase, residual austenite is introduced as a second phase. Residual austenite has the effect of enhancing TS, EL, and also bendability by transformation induced martensite transformation. In order to obtain good mechanical properties, it is necessary to introduce the retained austenite by 20 area% or more. The lower limit of retained austenite in the metal structure is preferably 25 area%, more preferably 30%.

<Balance: less than 10 area%>
Even if the steel sheet of the present invention contains a total of less than 10 area% of pearlite, bainite and cementite as the remaining structure other than the ferrite, martensite and retained austenite, the effects of the present invention can be obtained. In order to decrease the upper limit, the upper limit of the total of the remaining structures in the metal structure is preferably 5 area%.

<Low-angle grain boundary density in ferrite: 1.0 μm / μm ² or more and 2.4 μm / μm ² or less>
The steel sheet of the present invention has a high strength of ferrite that yields preferentially by making it a recovery structure in which low-angle grain boundaries are introduced at a density of 1.0 μm / μm ² or more and 2.4 μm / μm ² in ferrite, High YS. In addition, while this recovered structure contributes to the increase in TS, it has an appropriate ductility and does not decrease EL. Furthermore, when the retained austenite is transformed into a hard structure by processing-induced martensite transformation, the strength of the ferrite is increased, so that the uniformity of strength in the microstructure is improved, the starting point of fracture is dispersed, The progress between the soft phase / hard phase of the crack can be suppressed, and the occurrence of cracks during bending can be suppressed even with the shear cut surface. When the low-angle grain boundary density in the ferrite is less than 1.0 μm / μm ² , the recrystallization of the ferrite proceeds, and YS, TS, and bendability deteriorate. On the other hand, when the low-angle grain boundary density in the ferrite exceeds 2.4 μm / μm ² , the recovery of the ferrite does not proceed sufficiently, and the processed ferrite remains and the EL decreases. A preferable lower limit of the low-angle grain boundary density in the ferrite is 1.1 μm / μm ² , and a preferable upper limit is 2.2 μm / μm ² .

<Average crystal grain size of retained austenite: 1.5 μm or less>
By making the average crystal grain size of retained austenite 1.5 μm or less and finely dispersing it, crack generation on the shear cut surface is suppressed, and bendability is improved. When the average crystal grain size of the retained austenite exceeds 1.5 μm, a part of the retained austenite is transformed into coarse martensite when it is cut by a shearing machine, and cracks are generated. The upper limit of the average crystal grain size of retained austenite is preferably 1.4 μm, and more preferably 1.3 μm.

<Average Mn concentration in retained austenite: more than 9.0% by mass>
By increasing the average Mn concentration in the retained austenite to more than 9.0% by mass, the stability against deformation of the retained austenite is increased, the processing-induced martensite transformation in the early stage of deformation is moderately suppressed, and a large amount of transformation occurs in the middle to late stages of deformation. To improve TS × EL. When the average Mn concentration in the retained austenite is 9.0% by mass or less, TS × EL decreases. The lower limit of the average Mn concentration in the retained austenite is preferably 9.5% by mass, more preferably 10.0% by mass.

  Hereinafter, the method for evaluating the metal structure will be described.

[Area ratio of retained austenite and its average crystal grain size, and average Mn concentration in retained austenite]
After polishing the plate thickness cross section perpendicular to the rolling direction of the steel plate and corroding it with the Picral solution to reveal the metal structure, the shot is taken for the area of plate thickness / 4 as representative of the whole steel plate structure. An image with a magnification of 10000 is taken with respect to 10 fields of approximately 10 μm × 12 μm region with a key field emission scanning electron microscope (hereinafter referred to as FE-SEM). In particular, the area ratio and the average crystal grain size converted from the area of each grain to the equivalent circle diameter are calculated for each field of view using the image analysis software for the area that is corroded and observed with black contrast as retained austenite. The average value for 10 visual fields is defined as the area ratio of retained austenite and its average crystal grain size. In addition, at the time of photographing 10 fields, the Mn concentration (mass%) of one retained austenite grain is measured by energy dispersive X-ray spectroscopy (EDS) using FE-SEM in each field, and each perimeter 10 measurement points are averaged. The average Mn concentration (mass%) in the retained austenite is calculated.

[Each area ratio of ferrite, martensite and remaining structure]
After the plate thickness cross section perpendicular to the rolling direction of the steel plate is polished and corroded with 3% nital liquid to reveal the metal structure, the region of plate thickness / 4 is roughly 10 μm × 12 μm by FE-SEM. An image with a magnification of 10000 is taken for 10 fields of view, and when the remaining structure such as bainite or pearlite is included, the total area ratio of the remaining structure is obtained in the same manner as the area ratio of residual austenite. On the other hand, since it is difficult to distinguish between ferritic and as-quenched martensite in the steel as-annealed structure, the temperature range in which only cementite precipitation occurs in the as-quenched martensite with no change in the structure fraction. (For example, hold at 300 ° C. for 30 minutes), the steel is corroded with 3% nital liquid, and the structure is similarly observed, and ferrite (black region) and martensite (region where carbide is precipitated) are observed. Calculate the ratio. 100− (area ratio of retained austenite + total area ratio of remaining structure) is multiplied by the ratio of ferrite to obtain the area ratio (%) of ferrite in the metal structure. Multiply 100- (area ratio of retained austenite + total area ratio of remaining structure) by the ratio of martensite to obtain the area ratio (%) of martensite in the metal structure.

[Low-angle grain boundary density in ferrite]
Polishing the thickness cross section perpendicular to the rolling direction of the steel sheet, and stepping on the visual field of approximately 20 μm × 20 μm area by electron backscatter diffraction imaging (EBSD) using FE-SEM for the area of thickness / 4 Measure at an interval of 0.05 μm, calculate the total length of the low-inclination grain boundaries in the analysis software, limited to the ferrite region, and divide by the area of the ferrite region to reduce the small-inclination grain boundary density (μm / μm ² ) is calculated. Note that a low-angle grain boundary is defined as a region where the crystal orientation rotation between adjacent measurement points is 1 ° or more and less than 15 °. Further, in the EBSD measurement principle, martensite may be included in the ferrite region. However, since the martensite area ratio in the present invention is sufficiently smaller than the ferrite area ratio, the low-angle grain boundary density in the ferrite is low. Even if it does not distinguish at the time of calculation of this, it becomes a parameter | index which shows the recovery organization of a ferrite.

  Next, the component composition which comprises this invention steel plate is demonstrated.

[Component composition of the steel sheet of the present invention]
C (carbon): 0.05% by mass or more and 0.25% by mass or less C, together with Mn, contributes to an increase in the retained austenite fraction as an austenite stabilizing element and an improvement in the stability of the retained austenite with respect to processing. In order to effectively exhibit such an action, C needs to be contained by 0.05% by mass or more. However, if the C content exceeds 0.25%, hard martensite is excessively generated in the final annealing, and the weldability deteriorates. The minimum with preferable C content is 0.10 mass%, and a preferable upper limit is 0.20 mass%.

Si (silicon): more than 0% by mass to 3.0% by mass or less Si is useful as a solid solution strengthening element for ferrite and contributes to high YS and high TS while minimizing the decrease in EL. When excessively added, the local ductility is lowered, and particularly, the crack generation at the shear cut surface is promoted and the bendability is lowered. Therefore, the upper limit of the Si content is set to 3.0% by mass. The lower limit of the Si content is preferably 0.05% by mass, and more preferably 0.1% by mass. The upper limit of the Si content is preferably 1.5% by mass, more preferably 0.5% by mass.

Mn (manganese): 5.0% by mass or more and 9.0% by mass or less Mn contributes to an increase in the fraction of retained austenite as an austenite stabilizing element and an improvement in the stability of the retained austenite with respect to processing. In order to effectively exhibit such an action, it is necessary to contain 5.0% by mass or more. However, if it exceeds 9.0% by mass, recovery of ferrite is suppressed, and a structure having poor ductility affected by processing remains. The minimum with preferable Mn content is 6.0 mass%, and a preferable upper limit is 8.5 mass%.

P (phosphorus): more than 0% by mass and 0.100% by mass or less P is inevitably present as an impurity element, and if it exceeds 0.100% by mass, EL deteriorates. The upper limit with preferable P content is 0.03 mass%.

S (sulfur): more than 0% by mass and 0.010% by mass or less S is also an element that inevitably exists as an impurity element, forms sulfide-based inclusions such as MnS, and lowers EL as a starting point of cracking. is there. For this reason, the upper limit of S content is 0.010 mass%, Preferably it restrict | limits to 0.005 mass%.

Al (aluminum): 0.001% by mass or more and 3.0% by mass or less Al is used as a deoxidizing material, but if its content is less than 0.001% by mass, a sufficient steel cleaning effect can be obtained. On the other hand, if the Al content exceeds 3.0% by mass, the steel is embrittled, causing steel piece cracking during casting. The lower limit of the Al content is preferably 0.5% by mass, more preferably 0.8% by mass, and the upper limit of the Al content is preferably 2.8% by mass, more preferably 2. 5% by mass.

Si + Al: 0.8 mass% or more and 3.0 mass% or less By containing Si and / or Al, the ferrite-austenite two-phase region expands to the high temperature side, and the two-phase region temperature at which the optimum austenite fraction is obtained is increased. Therefore, when the soaking is carried out at a high temperature in the first soaking step, the austenite fraction is controlled, and at the same time, the recovery structure of ferrite is promoted. Further, the amount of Mn concentrated in the austenite when the temperature is soaked at a low temperature in the second soaking step is increased. If the total content of Si and Al (hereinafter also referred to as “Si + Al total content”) is less than 0.8% by mass, the two-phase region temperature at which the optimum austenite fraction is obtained is too low, and thus ferrite does not recover sufficiently. In addition, the Mn concentration in the retained austenite also decreases. On the other hand, when the total content of Si + Al exceeds 3.0% by mass, the steel is embrittled, so that the bendability is lowered and the steel piece is cracked during casting. The lower limit of the total Si + Al content is preferably 0.9% by mass, more preferably 1.0% by mass, and the upper limit of the total Si + Al content is preferably 2.9% by mass, more preferably 2.8% by mass.

N (nitrogen): more than 0% by mass and 0.0100% by mass or less N is also inevitably present as an impurity element, reduces elongation due to strain aging, and bonds with Al to precipitate as coarse nitride, so shear cutting Causes surface destruction. Accordingly, the N content is desirably as low as possible, and the upper limit is 0.0100% by mass, preferably limited to 0.006% by mass or less.

  The steel sheet of the present invention basically contains the above components, and the balance is substantially iron and unavoidable impurities, but can contain the following permissible components as long as the effects of the present invention are not impaired.

Cr (chromium): 0.01 mass% or more and 0.20 mass% or less,
Mo (molybdenum): 0.01 mass% or more and 0.20 mass% or less,
Cu (copper): 0.01 mass% or more and 0.20 mass% or less,
Ni (nickel): 0.01% by mass or more and 0.20% by mass or less, and B: 0.00001% by mass or more and 0.02% by mass or less, one selected from the group consisting of 1 or 2 or more The element is an element useful as a steel strengthening element. In order to effectively exhibit such an action, Cr, Mo, Cu and Ni are each 0.01% by mass or more (more preferably 0.05% by mass or more), and B is 0.00001% by mass or more (more The content is preferably 0.0001% by mass or more). However, even if these elements are contained excessively, the above effects are saturated and economically useless, so Cr, Mo, Cu and Ni are each 0.20% by mass or less (more preferably 0.15%). It is recommended to limit B to 0.02 mass% or less (more preferably 0.01 mass% or less, and still more preferably 0.006 mass% or less).

Ca (calcium): 0.0005 mass% or more and 0.01 mass% or less,
Mg (magnesium): 0.0005 mass% or more and 0.01 mass% or less, and REM (rare earth element): one or more selected from the group consisting of 0.0001 mass% or more and 0.01 mass% or less Moreover, these elements are elements effective in controlling the form of sulfide in steel and improving workability. Here, as REM used for this invention, Sc (scandium), Y (yttrium), a lanthanoid, etc. are mentioned. In order to effectively exhibit the above action, Ca and Mg are each 0.0005% by mass or more (more preferably 0.001% by mass or more), and REM is 0.0001% by mass or more (more preferably 0.0002% by mass). % Or more) is recommended. However, even if these elements are contained in excess, the above effects are saturated and economically wasteful, so that each is 0.01% by mass or less (more preferably, Ca and Mg are 0.003% by mass or less, It is recommended to limit the REM to 0.006% by mass or less.

Remainder The steel sheet of the present invention contains Fe (iron) and unavoidable impurities as the remainder in addition to the elements described above. Examples of the inevitable impurities include Sn (tin), As (arsenic), Pb (lead), and the like.

[Method for producing high-strength cold-rolled steel sheet according to the present invention]
The method for producing a high-strength cold-rolled steel sheet according to the present invention includes a hot rolling step, a first cooling step, an annealing step, a cold rolling step, a temperature raising step, a first soaking step, a second cooling step, and a second soaking step. A heat process and a 3rd cooling process are provided. Hereinafter, each step will be described.

<Hot rolling process>
In this step, a steel material having the above component composition is hot-rolled. Hot rolling conditions are not particularly limited. For example, a cast steel material such as a slab is directly charged into a heating furnace, or once cooled to room temperature, charged into a heating furnace, soaked, and hot-rolled.

<First cooling step>
In this step, the steel sheet after the hot rolling step is cooled to room temperature. Although cooling conditions are not specifically limited, For example, the steel plate after a hot rolling process is wound and cooled, and it is set as a hot rolled coil (hot rolled plate).

  Under normal hot rolling conditions and room temperature cooling conditions, the hot-rolled sheet has a uniform martensite structure in the component composition system of the steel sheet of the present invention.

<Annealing process>
In this step, the hot-rolled sheet as the steel material after the first cooling step is annealed under conditions of a temperature of 400 ° C. or higher and less than Ac1, and a holding time of 0.5 hour or more and 72 hours or less.
The hot-rolled sheet is annealed and softened under the predetermined conditions before the cold rolling process described later, and the metal structure is made a cementite structure finely dispersed with recrystallized ferrite. By recrystallizing the parent phase, a large amount of dislocations is introduced into the ferrite by cold rolling, and two-stage soaking (hereinafter referred to as “final”) by a first soaking process and a second soaking process described later. High-strength recovery structure can be obtained by annealing). Moreover, the average particle diameter of a retained austenite can be refined by final annealing by finely dispersing cementite. In addition, when not performing an annealing process, not only a desired structure | tissue will not be obtained after the last annealing process but since the intensity | strength of a hot-rolled sheet is too high, the cold rolling process mentioned later becomes impossible substantially. When annealing is performed with Ac1 or more, coarse austenite grains are generated and remain in the structure after the final annealing step, so that the residual austenite becomes coarse and a desired average crystal grain size cannot be obtained. On the other hand, when the annealing temperature is less than 400 ° C. or when the holding time is less than 0.5 hour, the recrystallization of ferrite does not proceed sufficiently, and the cold rolling process cannot be performed substantially. If the holding time is longer than 72 hours, coarse cementite is dispersed at a low density, and the retained austenite is coarsened in the final annealing, so that a desired average crystal grain size cannot be obtained. The annealing means is not particularly limited, but it is preferable to use a batch furnace because it requires soaking for a long time of 0.5 hours to 72 hours. Moreover, you may perform pickling before an annealing process. The annealing temperature is preferably 420 ° C. as the lower limit, more preferably 440 ° C., and (Ac1-10) ° C. as the upper limit. The holding time of the annealing temperature is preferably 1 hour as a lower limit, more preferably 3 hours, and preferably 60 hours and more preferably 50 hours as an upper limit.

<Cold rolling process>
In this step, the steel material after the annealing step is cold-rolled (hereinafter also referred to as “cold rolling”) at a rolling reduction rate (hereinafter also referred to as “cold rolling rate”) of 25% or more and 80% or less. Get.
A large amount of dislocations is introduced into the recrystallized ferrite produced by annealing by cold rolling, and recovery-structured ferrite having a desired small-angle grain boundary density is produced by subsequent final annealing. When the cold rolling rate is less than 25%, the low-inclined grain boundary density decreases, and YS, TS, and bendability decrease. On the other hand, cold rolling with a cold rolling rate exceeding 80% is substantially difficult. The lower limit of the cold rolling rate is preferably 30%, the upper limit is preferably 75%, and more preferably 70%.

<Temperature raising process>
In this step, the steel material after the cold rolling step is heated at an average speed of 3.0 ° C./second or more.

<First soaking process>
In this step, the steel sheet after the temperature raising step is subjected to a first holding temperature [(Ac1 + Ac3) / 2-30] ° C. to [(Ac1 + Ac3) / 2 + 10] ° C. and a first holding time of 0 second to 300 seconds. Soak up.

<Second cooling step>
In this step, the steel material after the first soaking step is cooled at an average rate of 1.0 ° C./second or more from the first holding temperature.

<Second soaking process>
In this step, the steel sheet after the second cooling step is subjected to the second holding temperature [(Ac1 + Ac3) / 2-90] ° C. or higher and [(Ac1 + Ac3) / 2-50] ° C. or lower, the second holding time 120 seconds to 600 seconds or less. Soaking under the conditions of

<Temperature increase at an average rate of 3.0 ° C./second or more>
The temperature is increased at an average rate of 3.0 ° C./second or more in order to suppress recrystallization of the ferrite and ensure a low-angle grain boundary density in the ferrite. When the average speed is less than 3.0 ° C./second, the low-inclination grain boundary density in the ferrite decreases, and YS, TS, and bendability decrease. The upper limit of the average speed is not particularly limited. As a minimum of average speed, 4.0 ° C / second is preferred and 5.0 ° C / second is more preferred.

<First holding temperature [(Ac1 + Ac3) / 2-30] ° C. or higher and [(Ac1 + Ac3) / 2 + 10] ° C. or lower and first holding time of 0 second to 300 seconds>
By performing the first soaking (first soaking) step in the ferrite-austenite two-phase region, particularly on the high temperature side, the reverse transformation to austenite proceeds with finely dispersed cementite as the core, and C is concentrated. Finely dispersed austenite grains are obtained. At the same time, the ferrite is recovered and organized. When the first holding temperature is less than [(Ac1 + Ac3) / 2-30] ° C., the amount of austenite produced is insufficient, resulting in a decrease in the retained austenite fraction and insufficient recovery of ferrite. The low-angle grain boundary density increases, and TS and EL decrease. On the other hand, when the first holding temperature is higher than [(Ac1 + Ac3) / 2 + 10] ° C., the amount of austenite to be generated becomes excessive, the ferrite fraction is lowered, and the C concentration in the austenite is lowered, so that the retained austenite fraction is reduced. The martensite fraction becomes excessive and the EL and bendability decrease. On the other hand, if the holding time is longer than 300 seconds, recrystallization of the ferrite proceeds, the low-angle grain boundary density in the ferrite is lowered, and YS, TS, and bendability are lowered. The first holding time of 0 second means that the second soaking at the next low temperature (second stage) at the moment when the lower limit of the first holding temperature ([(Ac1 + Ac3) / 2-30] ° C.) is reached. It means to shift to a soaking process. Further, during the soaking, the temperature may fluctuate up and down as long as it is within the range of the first soaking temperature. A more preferable upper limit of the holding time is 180 seconds.

<Cooling at an average rate of 1.0 ° C./second or more from the first holding temperature>
By cooling at an average rate of 1.0 ° C./second or more from the first holding temperature, the progress of recrystallization of ferrite is prevented. When the average speed is less than 1.0 ° C./second, recrystallization of ferrite proceeds, and the low-inclined grain boundary density in the ferrite decreases and YS, TS, and bendability decrease.

<Second holding temperature [(Ac1 + Ac3) / 2-90] ° C. or higher and [(Ac1 + Ac3) / 2-50] ° C. or lower, second holding time of 120 seconds to 600 seconds, soaking>
By performing the second soaking step at a lower temperature than the first soaking step, high concentration of Mn in the austenite produced in the first soaking step is promoted, and the stability of the retained austenite is improved.
When the second holding temperature is less than [(Ac1 + Ac3) / 2-90] ° C. or [(Ac1 + Ac3) / 2-50] ° C., or the second holding time is less than 120 seconds, the Mn concentration in the retained austenite decreases. , EL, TS × EL decrease. The upper limit of the second holding time is desirably 600 seconds from the viewpoint of productivity.

<Third cooling step>
In this step, the steel plate after the second soaking step is cooled. The cooling conditions in the third cooling step, which is the final cooling, are not particularly limited, but may be rapidly cooled to room temperature by gas jet or water cooling, may be gradually cooled by air cooling, and may be maintained in the middle. .

<Other processes>
The manufacturing method of the high-strength cold-rolled steel sheet according to the present invention may further include other steps other than the above steps after the third cooling step. Examples of other processes include a plating process, an alloying process, and a skin pass rolling process. In the plating treatment step, the steel plate cooled to a predetermined temperature in the third cooling step may be immersed in a plating bath, or may be reheated after being subcooled in the third cooling step and immersed in the plating bath to obtain a plated steel plate. In the alloying step, for example, the steel plate after the plating treatment step may be heated to be alloyed to form a plating alloy. The conditions for the skin pass rolling are not particularly limited, and can be performed at a rolling reduction in the normal process range.

  EXAMPLES Hereinafter, the present invention will be described more specifically with reference to examples. However, the present invention is not limited by the following examples, but may be appropriately modified within a range that can meet the above-described purpose. Of course, it is possible to implement them, and they are all included in the technical scope of the present invention.

  In order to confirm the applicability of the present invention, a laboratory test was conducted as follows. First, steel materials having the component compositions shown in Table 1 below were melted. Ac1 and Ac3 were experimentally determined by performing a temperature increase test under the condition of a temperature increase rate of 3.0 ° C./second using a cold-rolled sheet described later, and measuring the shrinkage associated with austenite generation. The molten steel is processed into a slab with a thickness of 50 mm by hot forging, soaked at 1200 ° C. for 30 minutes, roughly rolled to 12 mm, soaked again at 1200 ° C. for 30 minutes, and then hot rolled. Finished to a plate thickness of 2.3 mm, cooled to 500 ° C. by water cooling, charged in an atmospheric furnace heated to 500 ° C., held for 30 minutes, cooled in the furnace, and simulated coil cooling by winding. Thereafter, softening annealing is performed in an atmospheric furnace under the conditions shown in Tables 2 and 3 below, after air cooling, the scale is removed by pickling, and cold rolling is performed at the rolling reduction shown in Tables 2 and 3 Thus, a cold-rolled sheet having a thickness of 1.4 mm was produced. However, production No. For No. 6, the hot-rolled finish thickness was 4.0 mm, and a cold-rolled sheet of 1.4 mm was produced by cold rolling (rolling rate 65%). Production No. For No. 7, the thickness of the front and back surfaces of the hot-rolled sheet finished to 2.3 mm was reduced to 1.75 mm, and a cold-rolled sheet of 1.4 mm was produced by cold rolling (rolling ratio 20%). The two-step soaking process was simulated with an atmosphere-controlled heat treatment simulator. Production No. About 1 and 4 to 34, after the 2nd soaking process, it cooled to 200 degreeC with the gas jet, and then air-cooled. Production No. About 2 and 3, after a 2nd soaking process, it cooled with a gas jet to 450 degreeC, was immersed in a molten zinc bath, and manufacture No.3 after that. 2 is air-cooled. In No. 3, the alloy was further heated to 520 ° C. and held for 10 seconds, followed by air cooling.

  In Table 1, the shaded portion indicates that it is outside the scope of the present invention. “-” Indicates that the corresponding component composition is not included.

  In Tables 2 and 3, “GJ” indicates a gas jet. The shaded portion indicates that it is outside the scope of the present invention.

  About each steel plate after the said air cooling, the area ratio of each metal structure, the average crystal grain size of retained austenite, the average Mn concentration in retained austenite, and the low-angle grain boundary density in ferrite were measured by the following methods.

[Area ratio of retained austenite and its average crystal grain size, and average Mn concentration in retained austenite]
After polishing the plate thickness section perpendicular to the rolling direction of the steel plate and corroding it with the Picral solution to reveal the metal structure, the region of the plate thickness / 4 is roughly measured by FE-SEM made by JEOL Ltd. Images with a magnification of 10,000 times were taken for 10 fields of 10 μm × 12 μm area. In particular, an area that is corroded and observed with black contrast is assumed to be retained austenite, and image analysis software (Medidia CYBERNETICS, Inc .: ImagePro Plus ver. 7.0) is used to change the area ratio and the equivalent circle diameter from the area of each grain. The converted average crystal grain size was calculated for each field of view, and the average value for 10 fields of view was defined as the area ratio of retained austenite and the average crystal grain size. In addition, at the time of photographing 10 fields, the Mn concentration (mass%) of one retained austenite grain is measured by energy dispersive X-ray spectroscopy (EDS) using FE-SEM in each field, and each perimeter 10 measurement points are averaged. The average Mn concentration (mass%) in the retained austenite was calculated.

[Each area ratio of ferrite, martensite and remaining structure]
After the plate thickness cross section perpendicular to the rolling direction of the steel plate is polished and corroded with 3% nital liquid to reveal the metal structure, the region of plate thickness / 4 is roughly 10 μm × 12 μm by FE-SEM. An image with a magnification of 10000 was taken for 10 fields of view, and when the remaining structure such as bainite or pearlite was included, the total area ratio of the remaining structure was determined in the same manner as the area ratio of retained austenite. On the other hand, since it is difficult to distinguish between ferrite and as-quenched martensite with the annealed structure of the steel sheet, there is no change in the structure fraction and only the cementite precipitation occurs in the as-quenched martensite. Tempering (for example, holding at 300 ° C. for 30 minutes), corroding the steel plate with 3% nital liquid and observing the structure in the same manner, and ferrite (black region) and martensite (region where carbides are precipitated) The ratio was calculated. 100− (area ratio of retained austenite + total area ratio of remaining structure) was multiplied by the ratio of ferrite to obtain the area ratio (%) of ferrite in the metal structure. 100- (area ratio of retained austenite + total area ratio of the remaining structure) was multiplied by the ratio of martensite to obtain the martensite area ratio (%) in the metal structure.

[Low-angle grain boundary density in ferrite]
About a visual field of approximately 20 μm × 20 μm area by polishing EBS (EDAX Co., Ltd .: OIM Data Collection) using FE-SEM for the area of thickness / 4 by polishing the thickness cross section perpendicular to the rolling direction of the steel sheet. Measured at a step interval of 0.05 μm, calculated with the analysis software (EDAX: OIM Analysis 7), limited to the ferrite region, calculated the total length of the low-inclination grain boundaries, and divided by the area of the ferrite region The medium small-angle grain boundary density (μm / μm ² ) was calculated. In addition, the low-angle grain boundary was defined as a region where the crystal orientation rotation between adjacent measurement points was 1 ° or more and less than 15 °. Further, in the EBSD measurement principle, martensite may be included in the ferrite region. However, since the martensite area ratio in the present invention is sufficiently smaller than the ferrite area ratio, the low-angle grain boundary density in the ferrite is low. Even if it does not distinguish at the time of calculation of this, it becomes a parameter | index which shows the recovery organization of a ferrite.

  Moreover, about each steel plate after the said air cooling, yield strength YS, tensile strength TS, total elongation EL, and bendability R / t were measured with the shear cut surface. In addition, the tension test extracted the JIS5 test piece of JISZ2201 from the direction perpendicular | vertical to a rolling direction, implemented according to JISZ2241, and measured YS, TS, and EL. In addition, the bending test was performed by taking a test piece with a shear cutting machine (clearance: 0.15 mm) so that the bending ridge line is perpendicular to the rolling direction, and leaving the shear cut surface without machining. A 90 ° V bending test was performed so that the shear surface side (upper blade side of the shear cutting machine) was on the outer side of the bent portion (tensile side), and the presence of cracks was examined with a stereomicroscope on the outer side of the bent portion. The minimum bending radius at which cracks do not occur was defined as the critical bending radius (R), and R was divided by the plate thickness t to obtain R / t.

  The measurement results are shown in Table 4 and Table 5 below. In these tables, regarding the mechanical properties of the steel sheet, YS is 900 MPa or more, TS is 1180 MPa or more, TS × EL is 30000 MPa% or more, and R / t is all indicated by ○ as a pass, Other than that, it was shown as x as rejected.

In Table 4 and Table 5, α represents ferrite. Martens indicates martensite. γ _R represents retained austenite. θ indicates cementite. The shaded portion for the metal structure indicates that it is outside the scope of the present invention. The shaded portion for the mechanical properties indicates that sufficient mechanical properties are not obtained.

  As shown in Table 4 and Table 5 above, Production No. Steel plates 1-3, 6, 11, 17, 18, 20, 21, 24, 25, 28-34 all use steel types that satisfy the provisions of the component composition of the present invention, and under recommended production conditions. As a result of manufacturing, it is an invention steel sheet that satisfies the requirements of the organization provision of the present invention, the evaluation is ○, YS, TS, TS × EL, R / t all satisfy the acceptance criteria, and is excellent in formability It was confirmed that a high-strength steel plate was obtained.

  On the other hand, production No. which is a comparative steel plate. The steel sheets of 4, 5, 7 to 10, 12 to 16, 19, 22, 23, 26, and 27 have an evaluation of x, and at least one of YS, TS, TS x EL, and R / t is inferior. .

  For example, manufacturing No. Although the steel plates of 4, 5, 7 to 10, and 12 to 15 satisfy the requirements for the component composition, any of the manufacturing conditions is out of the recommended range, so that the requirements for defining the metal structure of the present invention are satisfied. At least one of them is not satisfied, and at least one of YS, TS, TS × EL, and R / t is inferior.

  For example, manufacturing No. Steel plate No. 4 has a softening annealing temperature that is too high, residual austenite is coarsened, and R / t is inferior.

  In addition, production No. Steel plate No. 5 has a softening annealing holding time that is too long, residual austenite is coarsened, and R / t is inferior.

  In addition, production No. Steel plate No. 7 has a too low rolling reduction, lacks the low-inclined grain boundary density in ferrite, and is inferior in YS, TS, and R / t.

  In addition, production No. Steel plate No. 8 has an average speed to the first holding temperature after cold rolling that is too low, the low-angle grain boundary density in ferrite is insufficient, and YS, TS, and R / t are inferior.

  In addition, production No. Steel plate No. 9 has a first holding temperature that is too low, and the ferrite is excessive, while the retained austenite is insufficient, the low-angle grain boundary density in the ferrite is excessive, and TS and TS × EL are inferior.

  On the other hand, production No. Steel plate No. 10 has a first holding temperature that is too high, while ferrite and residual austenite are insufficient, while martensite is excessive, average Mn concentration in residual austenite is insufficient, and TS × EL and R / t are inferior. ing.

  In addition, production No. No. 12, the first holding time is too long, the low-angle grain boundary density in ferrite is insufficient, and YS, TS, and R / t are inferior.

  In addition, production No. Steel plate No. 13 has an average speed to the second holding temperature that is too low, the low-angle grain boundary density in the ferrite is insufficient, and YS, TS, and R / t are inferior.

  In addition, production No. No. 14 steel sheet has a second holding temperature that is too low, the average Mn concentration in the retained austenite is insufficient, and TS × EL is inferior.

  On the other hand, production No. Steel plate No. 15 has a second holding temperature that is too high, the average Mn concentration in the retained austenite is insufficient, and TS × EL is inferior.

  In addition, production No. In the steel sheets of Nos. 16, 19, 22, 23, 26, and 27, any of the components of the present invention is out of the specified range. Except for the 22 steel plates, at least one of the requirements for defining the structure of the present invention does not satisfy at least one of YS, TS, TS × EL, and R / t.

  For example, manufacturing No. Steel plate No. 16 (steel type B) has too low C content, lack of retained austenite, and TS and TS × EL are inferior.

  On the other hand, production No. Steel plate No. 19 (steel type E) has too high C content, ferrite is insufficient, while martensite is excessive, average Mn concentration in residual austenite is insufficient, and TS × EL and R / t are inferior. ing.

  In addition, production No. Steel sheet No. 22 (steel type H) has both a high Si content and a total Si + Al content, and is inferior in TS × EL and R / t.

  In addition, production No. The steel plate No. 23 (Steel Type I) has a too low Mn content, insufficient residual austenite, and insufficient average Mn concentration in the residual austenite, and TS and TS × EL are inferior.

  On the other hand, production No. The steel plate of No. 26 (steel type L) has an excessively high Mn content, an excessively small grain boundary density in ferrite, and inferior TS × EL and R / t.

  In addition, production No. Steel No. 27 (steel grade M) has a total content of Si + Al that is too low, the low-angle grain boundary density in ferrite becomes excessive, the average Mn concentration in residual austenite is insufficient, and TS × EL and R / t are Inferior.

As a result, the applicability of the present invention was confirmed.

Claims (4)

C: 0.05 mass% or more and 0.25 mass% or less,
Si: more than 0% by mass and 3.0% by mass or less,
Mn: 5.0% by mass or more and 9.0% by mass or less,
P: more than 0% by mass and 0.100% by mass or less,
S: more than 0% by mass and 0.010% by mass or less,
Al: 0.001 mass% or more and 3.0 mass% or less,
Si + Al: 0.8 mass% or more and 3.0 mass% or less,
N: more than 0% by mass and 0.0100% by mass or less, and the balance: iron and inevitable impurities,
Having a component composition of
Ferrite: 40 area% or more and less than 80 area%,
Martensite: less than 25 area%,
Retained austenite: 20 area% or more, and the remainder: less than 10 area% of the metal structure,
The low-angle grain boundary density in the ferrite is 1.0 μm / μm ² or more and 2.4 μm / μm ² or less,
The residual austenite has an average crystal grain size of 1.5 μm or less, and
A high-strength cold-rolled steel sheet, wherein an average Mn concentration in the retained austenite is more than 9.0% by mass. Cr: 0.01% by mass or more and 0.20% by mass or less,
Mo: 0.01% by mass or more and 0.20% by mass or less,
Cu: 0.01% by mass or more and 0.20% by mass or less,
The composition further comprises one or more selected from the group consisting of Ni: 0.01% by mass to 0.20% by mass and B: 0.00001% by mass to 0.02% by mass. The high-strength cold-rolled steel sheet as described in 1. Ca: 0.0005 mass% or more and 0.01 mass% or less,
2. One or more selected from the group consisting of Mg: 0.0005 mass% to 0.01 mass% and REM: 0.0001 mass% to 0.01 mass% are further contained. Or the high intensity | strength cold-rolled steel plate of Claim 2. C: 0.05 mass% or more and 0.25 mass% or less,
Si: more than 0% by mass and 3.0% by mass or less,
Mn: 5.0% by mass or more and 9.0% by mass or less,
P: more than 0% by mass and 0.100% by mass or less,
S: more than 0% by mass and 0.010% by mass or less,
Al: 0.001 mass% or more and 3.0 mass% or less,
Si + Al: 0.8 mass% or more and 3.0 mass% or less,
N: more than 0% by mass and 0.0100% by mass or less, and the balance: iron and inevitable impurities,
A step of hot rolling a steel material having a component composition of:
A first step of cooling the steel sheet after the hot rolling step to room temperature;
Annealing the steel material after the first cooling step under conditions of a temperature of 400 ° C. or more and less than Ac1, a holding time of 0.5 hours or more and 72 hours or less;
Cold rolling the steel after the annealing step at a rolling reduction of 25% or more and 80% or less;
A step of heating the steel material after the cold rolling step at an average speed of 3.0 ° C./second or more;
The steel sheet after the temperature raising step is soaked under a condition of a first holding temperature [(Ac1 + Ac3) / 2-30] ° C. or higher and [(Ac1 + Ac3) / 2 + 10] ° C. or lower and a first holding time of 0 second or longer and 300 seconds or shorter. The first step;
A second step of cooling the steel material after the first soaking step at an average rate of 1.0 ° C./second or more from the first holding temperature;
The steel sheet after the second cooling step is subjected to a second holding temperature [(Ac1 + Ac3) / 2-90] ° C. to [(Ac1 + Ac3) / 2-50] ° C. and a second holding time of 120 seconds to 600 seconds. A second step of soaking,
A method for producing a high-strength cold-rolled steel sheet, comprising: a third step of cooling the steel plate after the second soaking step.