JP2002105592A - Hot rolled steel sheet for working having excellent low cycle fatigue strength and its production method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hot rolled steel sheet for working having excellent low cycle fatigue strength and to provide a production method by which the steel sheet can inexpensively and stably be produced. SOLUTION: This hot rolled steel sheet for working having excellent low cycle fatigue strength is composed of steel having a composition containing 0.01 to 0.2% C, 0.01 to 2% Si, 0.05 to 3% Mn, <=0.1% P and <=0.01% S, containing Al and N by <=0.2% Al and 0.001 to 0.1% N also so as to satisfy 0.52Al/N<=10, further containing one or more kinds selected from Cr, Mo and V by <=2.5% Cr, <=1% Mo and <=0.1% V also so as to satisfy (Cr+3.5Mo+39 V)>=0.1, and the balance Fe with inevitable impurities, and whose microstructure is composed of a composite one containing ferrite as a phase with the maximum volume fraction and a second phase, mainly composed of martensite, and the area ratio of a cell structure in the dislocated structure dislocated by ferrite observed after a fatigue test is <=50%.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hot-rolled steel sheet for processing which is excellent in low cycle fatigue strength and a method for producing the same, and in particular, durability of a vehicle undercarriage part such as a road wheel is required. The present invention relates to a hot-rolled steel sheet for processing excellent in low cycle fatigue strength suitable as a material of a member and a method for producing the same.

[0002]

2. Description of the Related Art In recent years, the application of light metals such as Al alloys and high-strength steel sheets to automobile members has been promoted for the purpose of weight reduction in order to improve fuel efficiency of automobiles. However, although light metals such as Al alloys have the advantage of high specific strength, their application is limited to special applications because they are significantly more expensive than steel. Therefore, in order to promote the weight reduction of automobiles in a wider range, it is strongly required to use inexpensive high-strength steel sheets.

[0003] In response to such demands for high strength, steel sheets having both strength and deep drawability in the field of cold-rolled steel sheets used for white bodies and panels that occupy about 1/4 of the body weight. And bake-hardening steel plates have been developed, which has contributed to weight reduction of vehicle bodies. However, at present, the object of weight reduction is shifting to structural members and undercarriage members occupying about 20% of the vehicle body weight, and there is an urgent need to develop high-strength hot-rolled steel sheets used for these members.

However, since high strength generally deteriorates material properties such as formability (workability), how to achieve high strength without deteriorating material properties is the key to the development of high strength steel sheets. Become. In particular, hole expandability, fatigue durability, corrosion resistance, and the like are important as characteristics required for a steel sheet for structural members and suspension members, and it is important how to balance these characteristics with high strength and high dimensions. For example, fatigue durability is particularly important as a characteristic required for a steel plate for a road wheel disc. This is because the fatigue durability is controlled by the strictest standards in the member properties of the wheel.

At present, steel sheets of 440 to 590 MPa class are used as the hot-rolled steel sheets for road wheel discs, but the required strength level of these steel sheets for members is from 590 MPa class to 780 MPa class, and further higher strength is required. It is heading. On the other hand, thinning, which is the purpose of strengthening, causes an increase in the strain level applied to the wheel, and some parts have been exposed to an amplitude at a strain level exceeding the yield point.

Hitherto, in applying a high-strength steel plate to a part around a foot such as a road wheel, in order to improve the fatigue durability, the fatigue limit under a repeated load below the yield point has been regarded as important. However, as described above, recently, improvement in low cycle fatigue characteristics (fatigue characteristics up to about 105 times) at a strain level exceeding the yield point has been desired. However, at present, almost no technology for improving low cycle fatigue characteristics is found.

[0007]

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a hot-rolled steel sheet for processing excellent in low cycle fatigue strength and a method of manufacturing the steel sheet at low cost and in a stable manner. .

[0008]

Means for Solving the Problems The present inventors considered the production process of a hot-rolled steel sheet produced on an industrial scale by a continuous hot-rolling equipment which is currently usually used, and considered the production process of the hot-rolled steel sheet. Intensive research was conducted to achieve an improvement in low cycle fatigue strength. As a result, the microstructure was composed of a composite structure in which the phase with the largest volume fraction was ferrite and the second phase was mainly martensite, and the area ratio of the cell structure to the dislocation structure in the ferrite observed after the fatigue test. Is 50%
The present inventors have newly found that the following is very effective in improving the low cycle fatigue strength, and have made the present invention.

That is, the gist of the present invention is as follows. (1) In mass%, C: 0.01 to 0.2%, Si:
0.01-2%, Mn: 0.05-3%, P ≦ 0.1
%, S ≦ 0.01%, Al ≦ 0.2%, N:
0.001 to 0.1%, 0.52 Al / N is contained so as to satisfy Al / N ≦ 10, and one or two or more of Cr, Mo, and V are Cr ≦ 2.5%, Mo ≦ 1%, V
≦ 0.1% and (Cr + 3.5Mo + 39V) ≧
0.1 is a steel containing Fe and unavoidable impurities, the balance of which is microstructure, the phase having the largest volume fraction is ferrite, and the second phase is mainly martensite. Of the dislocation structure in the ferrite observed after the fatigue test,
% Or less, characterized by excellent low cycle fatigue strength.

(2) The steel further comprises, by mass%, C
u: The hot-rolled steel sheet for processing having excellent low cycle fatigue strength according to the above (1), characterized by containing 0.2 to 2%. (3) The steel further contains B: 0.000% by mass.
The hot-rolled steel sheet for processing having excellent low cycle fatigue strength according to the above (1) or (2), comprising 2 to 0.002%. (4) The steel further contains, by mass%, Ni: 0.1 to
The hot-rolled steel sheet for processing according to any one of (1) to (3), which is excellent in low cycle fatigue strength, containing 1%.

(5) The steel further comprises, by mass%, C
a: 0.0005 to 0.002%, REM: 0.000
The hot-rolled steel sheet for processing having excellent low cycle fatigue strength according to any one of the above (1) to (4), comprising one or two kinds of 5 to 0.02%. (6) The steel further contains Nb: 0.00% by mass.
1-0.1% and N-0.15Nb ≧ 0.0005%,
Ti: 0.001-0.1% and N-0.29Ti ≧
(1) characterized by containing one or more of 0.0005% and Zr: 0.001 to 0.2%.
A hot-rolled steel sheet for processing having excellent low cycle fatigue strength according to any one of (5) to (5).

(7) When hot rolling a steel slab having the components described in any one of (1) to (6) above, Ar
₃ after completion of the hot finish rolling at a transformation temperature or more Ar ₃ transformation temperature + 100 ° C. or less, Ar ₁ transformation point temperature or more Ar ₃
It stays in the temperature range below the transformation point for 1 to 20 seconds, then cools at a cooling rate of 20 ° C./s or more and winds it at a winding temperature of 350 ° C. or less. Is composed of a composite structure having ferrite as the ferrite phase and martensite as the second phase. The area ratio of the cell structure in the dislocation structure of the ferrite observed after the fatigue test is 50%.
A method for producing a hot-rolled steel sheet for processing having excellent low cycle fatigue strength, characterized by obtaining the following steel sheet. (8) In the hot rolling, after the rough rolling is completed, high-pressure descaling is performed, and the hot finish rolling is completed at an Ar ₃ transformation point temperature or higher and an Ar ₃ transformation point temperature + 100 ° C. or lower. The present invention relates to a method for producing a hot-rolled steel sheet for processing having excellent low cycle fatigue strength.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The results of basic research that led to the present invention will be described below. First, the effect of the addition amount of Al, N, Cr, Mo, and V on the dislocation structure after the fatigue test was investigated. The test material for that was prepared as follows.
That is, 0.06% C-0.9% Si-1.2% Mn
-0.01% P-0.001% S as a basic component of Al,
Hot finish rolling was performed on the ingot by adjusting the composition by changing the amounts of N, Cr, Mo, and V so that the plate thickness became 3.5 mm at any temperature equal to or higher than the Ar ₃ transformation point temperature. After the termination, the temperature is kept for 1 to 15 seconds in any temperature range from the Ar ₁ transformation point temperature to the Ar ₃ transformation point temperature, and then 20 ° C. /
After cooling at a cooling rate of at least s, the film was wound at room temperature.

From the steel sheet thus obtained, a fatigue test piece having the shape shown in FIG.
Samples were taken from the 4W position so that the rolling direction was on the long side, and subjected to a fatigue test. However, the surface of the fatigue test piece was a ground surface with a three-sided finish. The fatigue test was performed using an electrohydraulic servo-type fatigue tester, and the test method was in accordance with ASTM E606-92. As shown in FIG. 2, the test conditions were as follows: a complete swing-pull compression load with a triangular wave in the axial direction, and a total strain amplitude of 0.2
0.6% and a strain rate of 4.0 × 10 ⁻³ / sec. The test was performed while recording changes in strain response and stress response. After the fatigue test, the condition of total strain amplitude is 2
As shown in FIG. 3, with respect to a test piece which was tested in the range of ≦ 2100 × ε _a / YP ≦ 4, a processing strain was not introduced into a transmission electron microscope sample (thin film) from a portion having a thickness of 1/4 near the fractured portion. And the dislocation structure was observed with a transmission electron microscope. However, observation with a transmission electron microscope was performed by changing the crystal grains at a magnification of 2000 to 10000 times.
Observation was made for zero or more visual fields. Where YP: yield stress or 0.
2% yield strength (MPa), ε _a : total strain amplitude (%).

FIGS. 4 and 5 show examples of observation. In each case, the total strain amplitude ε _a = 0.3%. FIG. 4 shows an example of the scope of the present invention, and FIG. 5 shows an example of the scope of the present invention. 4 outside the scope of the invention shows a typical cell structure, whereas FIG. 5 outside the scope of the invention does not show a cell structure. Here, the cell structure means a cell wall (wall, vei) having a high dislocation density specific to the fatigue phenomenon.
n, debris). In addition, a cell is defined as having a completely closed structure surrounded by cell walls on all sides. On the other hand, the area ratio of the cell structure is 1
In each visual field observed in the sample, the value of the area ratio obtained by visual observation or image processing is added for each observation visual field,
This is a so-called average value obtained by dividing the number by the number of observation fields.

The present inventors have examined these experimental results in detail, and as a result, as shown in FIG. 6, there is a very strong correlation between the dislocation structure in ferrite observed after the fatigue test and the low cycle fatigue strength. It has been newly found that when the area ratio of the cell structure in the dislocation structure of ferrite is 50% or less, the low cycle fatigue strength is improved. Further, the dislocation structure in ferrite, the value of 0.52 Al / N, and Cr + 3.
As shown in FIG. 7, a strong correlation was also observed in relation to the value of 5Mo + 39V, and the area ratio of the cell structure was 50% or less in the region of 0.52Al / N ≦ 10 and (Cr + 3.5Mo + 39V) ≧ 0.1. Was newly found to be. Although this mechanism is not always clear, it is presumed as follows. Usually, repeated strain concentrates on the ferrite, which is a soft phase, so that softening occurs repeatedly and low cycle fatigue strength is reduced. Therefore, in order to improve the low cycle fatigue strength, it is necessary to suppress the repetitive softening of ferrite which is a soft phase.

N, C and C in a solid solution state as in the present invention
When r, Mo, and V are contained in a specific range, N and C, which are intrusion-type solid solution elements, and Cr, Mo, and V form pairs or clusters in ferrite, and suppress cross slip of dislocations under repeated loads. By doing so, repeated softening due to rearrangement of dislocations (formation of a cell structure) is suppressed. Further, N and C, which are intrusion-type solid solution elements, escape from pairs or clusters of Cr, Mo, and V due to the action of atomic vacancies generated by the application of the cyclic load, and fix dislocations to cause repeated hardening. Cycle fatigue strength is improved. It has also been newly found that by restricting hot rolling conditions and the like, it is possible to control the state of N and C, which are intrusion-type solid solution elements in ferrite, and to produce a steel sheet having excellent low cycle fatigue strength.

In the present invention, the low cycle fatigue strength is defined as a value obtained by dividing a cyclic yield stress by a tensile strength. Here, the repeated yield stress can be obtained as follows. Changes in strain response and stress response during the fatigue test at a constant total strain amplitude are schematically represented as a hysteresis loop as shown in FIG. The material softens or hardens due to repeated strain, and this change is obtained as a change in Δσ. The value of Δσ of the material is almost saturated and stable at a repetition number of の of the fracture life (Nf). Therefore, Δ at this repetition rate
σ / 2 is defined as the stress amplitude σa at the strain amplitude. FIG. 9 schematically shows σ _a for each strain amplitude. Here, an intersection point obtained by extrapolating a straight line obtained by linearly approximating the σ _a to the strain to the stress-strain curve is defined as a yield point repeatedly. In addition, this intersection may be an intersection with an elastic straight line obtained when the material is assumed to be a linear elastic body (Hooke's body).

Next, the microstructure of the steel sheet according to the present invention will be described in detail. The microstructure of the steel sheet was a composite structure in which the phase having the largest volume fraction was ferrite and the second phase was mainly martensite in order to achieve both fatigue characteristics and workability. However, the second phase allows inclusion of unavoidable pearlite, bainite, and retained austenite. In order to secure good fatigue characteristics, the volume fraction of pearlite is desirably 5% or less. Here, the volume fractions of the ferrite and the second phase are １ ／ of the steel sheet width.
A sample cut from the W or 3 / 4W position is polished and etched into a cross section in the rolling direction, and 200 to 5
It is defined as the area fraction of the microstructure at 1 / 4t of the plate thickness observed at a magnification of 00 times.

Next, the reasons for limiting the chemical components of the present invention will be described. C is an element necessary for obtaining a desired microstructure. However, if the content exceeds 0.2%, workability and weldability deteriorate, so the content is set to 0.2% or less. On the other hand, if it is less than 0.01%, the strength is reduced.
1% or more. Further, C existing in a solid solution state forms pairs and clusters with Cr, Mo, and V like N, so that it is effective in improving low cycle fatigue strength. In the present invention, N is sufficiently added and the range of the solute C amount is not particularly limited. However, a sufficient amount of solid solution C for obtaining the effect is secured in the above range of the total C content lower limit or more, and the range is 0.0005% or more and 0.004% or more.
% Is preferable.

[0021] Si is necessary for obtaining a desired microstructure and is effective as a solid solution strengthening element for increasing the strength. In order to obtain a desired strength, the content needs to be 0.01% or more. However, if the content exceeds 2%, the workability deteriorates. Therefore, the content of Si is set to 0.01% or more and 2% or less. Mn is effective for increasing strength as a solid solution strengthening element. To obtain the desired strength, 0.05% or more is required. Further, if added over 3%, slab cracks occur, so the content is made 3% or less.

P is an impurity and is preferably as low as possible.
If the content exceeds 0.1%, the workability and the weldability are adversely affected and the fatigue characteristics are also reduced. S is an impurity and is preferably as low as possible. If it is too large, A-based inclusions that deteriorate local ductility and hole-expanding properties should be produced. Therefore, the content of S should be reduced as much as possible. .

Al may be used as a deoxidizing agent.
However, since Al combines with N to form AlN, C
Since the effective amount of N that forms a pair or a cluster with r, Mo, and V is reduced, it is desirable that the addition thereof be kept to a minimum necessary within a range that is reasonable in production technology. That is, A
If the amount of l exceeds 0.2%, a large amount of N must be added in order to secure an effective amount of N for forming pairs and clusters with Cr, Mo, and V, and the production cost and processing by precipitation of AlN are required. It is disadvantageous in terms of property deterioration. Therefore, the upper limit of the addition amount of Al is set to 0.2% or less. Further, Al may form non-metallic inclusions such as Al ₂ O ₃ and may cause flaws and decrease in local ductility. Therefore, the amount of Al added is preferably 0.05% or less. Further, in order to easily contain N in steel within a range that does not deteriorate the production cost and the operation efficiency, the content is further desirably 0.02% or less. Although the lower limit of Al is not particularly defined,
If the content is less than 0.001%, the production cost and the operation efficiency are deteriorated. Therefore, the content is desirably 0.001% or more.

N is one of the important elements in the present invention. In the present invention, N and C, which are intrusion-type solid solution elements in the solid solution state, and Cr, Mo, and V form pairs and clusters in ferrite, thereby suppressing dislocation cross slip under repeated loading. Rearrangement of dislocations (formation of cell structure)
, And N and C, which are intrusion-type solid solution elements, escape from Cr, Mo, V pairs and clusters to fix dislocations by the action of atomic vacancies generated by the application of cyclic load. The hardening improves low cycle fatigue strength. Therefore, addition of 0.001% or more is essential. On the other hand, in order to add a large amount of N to molten steel, special equipment and operation such as pressurization are required, so the upper limit is 0.1%. On the other hand, if N is too large, yield point elongation occurs and workability deteriorates, so that the N content is more preferably 0.01% or less.

Further, since N is an element that easily forms AlN by combining with Al, 0.52 Al / N ≦ 10 in order to secure solid solution N which contributes to improvement of low cycle fatigue strength.
Limited. When the value of 0.52 Al / N exceeds 10,
Since AlN is easily precipitated during the cooling process after hot rolling or during winding, this is set as the upper limit. If this value is 10 or less, excessive precipitation of AlN can be avoided by controlling the cooling rate after hot rolling and the winding temperature within the range of the present invention. Further, when the value of 0.52 Al / N is 5 or less, deterioration of workability due to precipitation of fine AlN is improved, so that 0.52 Al / N ≦ 5 is more preferable.

On the other hand, the amount of solute N may be adjusted within the above-mentioned total N content range.
0.004% is desirable. If the solute N is less than 0.0005%, excellent low cycle fatigue strength cannot be obtained,
If it exceeds 0.004%, yield point elongation occurs and workability deteriorates. Further, from the viewpoint of suppressing generation of waist break flaw, the amount of solute N is
0.0012 to 0.003% is desirable.

Here, the solute N includes not only N present alone in Fe but also N forming a pair or a cluster with substitutional solute elements such as Cr, Mo, V, Mn, Si and P. . The amount of solute N is determined by a heating extraction method in a hydrogen stream. In this method, the sample is heated to a temperature range of about 200 to 500 ° C., and the dissolved N and hydrogen are reacted to form ammonia,
This is subjected to mass spectrometry, and the analysis value is converted to obtain the amount of solute N. The amount of solid solution N is calculated from the total amount of N to Al.
It can also be determined from a value obtained by subtracting the amount of N present as a compound such as N, NbN, VN, TiN, or BN (quantified from the chemical analysis of the extraction residue). Furthermore, the internal friction method and FIM (Field Ion Microscopy)
May be determined by:

Cr, Mo and V are important elements in the present invention. The upper limits of the added amounts of Cr, Mo, and V are determined from the viewpoint of securing workability and cost, and are 2.5 and 2.5, respectively.
1, 0.1%. Particularly, if V is added in an excessive amount, nitrides are formed depending on hot rolling conditions, and it may be difficult to secure solid solution N effective for improving low cycle fatigue strength. It is desirable that on the other hand,
In order to obtain excellent low cycle fatigue strength, (Cr + 3.
5Mo + 39V) ≧ 0.1. Further, in order to avoid deterioration of workability due to the occurrence of elongation at the yield point, (Cr + 3.5Mo + 39V) ≧ 0.4 is a more desirable range. In order to avoid deterioration in workability due to the occurrence of yield point elongation, it is more effective to add two or more types of Cr, Mo, and V in combination than to add Cr, Mo, and V alone.

Since Cu has the effect of improving fatigue characteristics in a solid solution state, it is added as necessary. However, if the content is less than 0.2%, the effect is small, and even if the content exceeds 2%, the effect is saturated. Therefore, the content of Cu is set in the range of 0.2 to 2%. B is added as necessary since it is effective to increase the fatigue limit by being combined with Cu. However, if it is less than 0.0002%, it is insufficient to obtain the effect, and if it exceeds 0.002%, slab cracking occurs. Therefore, the addition of B is set to 0.0002% or more and 0.002% or less. B is 0.0004
%, BN is formed, and there is a possibility that the effective amount of dissolved N that forms pairs or clusters with Cr, Mo, and V is reduced. Therefore, the addition of B is more preferably in the range of 0.0002% to 0.0004%.

Ni is added as necessary to prevent hot brittleness due to the inclusion of Cu. However, if the content is less than 0.1%, the effect is small, and if the content exceeds 1%, the effect is saturated. Therefore, the content is set to 0.1 to 1%. Ca and REM
Is an element that becomes a starting point of destruction or changes the form of nonmetallic inclusions that degrade workability and renders them harmless. However, if less than 0.0005% is added, there is no effect.
If a exceeds 0.002%, and if REM exceeds 0.02%, the effect is saturated.
It is desirable to add 0.002% and REM: 0.0005 to 0.02%.

Since Nb is effective for improving workability and increasing strength by making the structure finer and more uniform, Nb is added as necessary. However, if the amount of addition is less than 0.001%, no effect is exhibited, and even if added over 0.1%, the effect is saturated. Further, when the value of N-0.15Nb is more than 0.0005%, it becomes difficult to secure solid solution N effective for improving low cycle fatigue strength. Therefore, the added amount of Nb is set to 0.001 to 0.1% and N-0.15Nb ≧ 0.0005%. On the other hand, N
If b is added in excess of 0.012%, NbN is likely to be formed, and it may be difficult to secure solid solution N effective for improving low cycle fatigue strength. Therefore, 0.001 to 0.012% is more desirable.

Since Ti also has the same effect as Nb, it is added as necessary. However, if the amount of addition is less than 0.001%, no effect is exhibited, and even if added over 0.1%, the effect is saturated. The value of N-0.29Ti is 0.000
It becomes difficult to secure the solute N effective for improving the low cycle fatigue strength of more than 5%. Therefore, the addition amount of Ti is 0.001.
% To 0.1% and N−0.29Ti ≧ 0.0005%. On the other hand, if more than 0.012% of Ti is added, it may precipitate or crystallize as TiN, and it may be difficult to secure solid solution N effective for improving low cycle fatigue strength. .012% is more desirable.

Further, in order to impart strength, Zr may be added as a precipitation strengthening or solid solution strengthening element. However, if it is less than 0.001%, the effect cannot be obtained. The effect is saturated even if it is added in excess of 0.2%. Therefore, Zr is added in the range of 0.001% to 0.2%. However, since Zr forms ZrN and may reduce the amount of solute N effective for improving the low cycle fatigue strength, it is preferably set to 0.01% or less. Steel containing these as main components may contain Sn, Co, Zn, W, and Mg in a total amount of 1% or less. However, since Sn may cause flaws during hot rolling, 0.05% or less is desirable.

Next, the reasons for limiting the production method of the present invention will be described in detail below. In the present invention, a slab obtained by casting molten steel whose components have been adjusted so as to have a target component content may be directly sent to a hot rolling mill as a high-temperature slab, or a heating furnace after cooling to room temperature. And then hot-rolled. The reheating temperature is not particularly limited. However, if the temperature is 1400 ° C. or more, the scale-off amount becomes large and the yield decreases.
Desirably less than ° C. Further, since the heating at a temperature lower than 1000 ° C. significantly impairs the operation efficiency on a schedule, the reheating temperature is desirably 1000 ° C. or higher. Further, when it is necessary to dissolve AlN to secure solid solution N, 115
It is desirable that the temperature be 0 ° C. or higher.

The hot rolling process after completion of the rough rolling, performs the finish rolling, is necessary to the final pass temperature (FT) is completed in a temperature range of Ar ₃ transformation point temperature or more Ar ₃ transformation temperature + 100 ° C. or less is there. This is because during hot rolling the rolling temperature is Ar
₃ transformation point off temperature and strain ductility workability would be decreased to deteriorate remains, the finishing temperature is Ar ₃ transformation temperature + 100 ° C. than for austenite grain size after finish rolling becomes large This is because the promotion of ferrite transformation in the two-phase region performed in the subsequent cooling step becomes insufficient, and a desired microstructure cannot be obtained. Therefore finishing temperature is Ar ₃ transformation point temperature or more Ar ₃ transformation temperature + 100 ° C.
The following is assumed.

When high-pressure descaling is performed after the completion of rough rolling, the collision pressure P (MP
It is desirable that a) × flow rate L (liter / cm ² ) ≧ 0.0025 is satisfied. The collision pressure P of the high-pressure water on the steel plate surface is described as follows. ("Iron and steel" 1991
vol. 77 No. 9 P1450) P (MPa) = 5.64 × P ₀ × V / H ² where P ₀ (MPa): liquid pressure V (liter / min): nozzle flow H (cm): steel sheet surface and nozzle Distance between

The flow rate L is described as follows. L (liter / cm ² ) = V / (W × v), where V (liter / min): Nozzle flow amount W (cm): Width of jet liquid per nozzle hitting steel sheet surface v (cm / min): Passing speed The upper limit of the collision pressure P × the flow rate L does not need to be particularly determined in order to obtain the effect of the present invention. However, increasing the flow rate of the nozzle causes inconvenience such as intensified wear of the nozzle.
It is desirable to set it to 0.02 or less.

Further, the maximum height R of the steel sheet after the finish rolling is performed.
y is 15 μm (15 μm Ry, 12.5 mm, ln1
2.5 mm) or less. This is apparent from the fact that the fatigue strength of a hot-rolled or pickled steel sheet is correlated with the maximum height Ry of the steel sheet surface, as described in, for example, Handbook of Fatigue Design for Metallic Materials, edited by The Society of Materials Science, Japan, page 84. is there. Further, the subsequent finish rolling is performed in order to prevent scale from being formed again after descaling.
It is desirable to do this within seconds.

The steps after finishing the rolling are as follows:
It stays for 1 to 20 seconds in the temperature range from the r ₃ transformation point to the Ar ₁ transformation point (two-phase region of ferrite and austenite).
The retention here is performed in order to promote ferrite transformation in the two-phase region, but if less than 1 second, the ferrite transformation in the two-phase region is insufficient, so that sufficient ductility cannot be obtained. A pearlite is formed, and a composite structure in which the phase having the intended maximum volume fraction is ferrite and the second phase is mainly martensite cannot be obtained. Further, the temperature range in which the retention is performed for 1 to 20 seconds is desirably from the Ar ₁ transformation point to 800 ° C. in order to facilitate the ferrite transformation. Further A
700 ° C. or lower is more preferable from the viewpoint of suppressing the precipitation of 1N. Further, the residence time for 1 to 20 seconds is desirably 1 to 10 seconds in order not to significantly reduce the productivity.

In order to satisfy these conditions, it is necessary to quickly reach the temperature range at a cooling rate of 20 ° C./s or more after finish rolling. The upper limit of the cooling rate is not particularly defined, but 300 ° C./s or less is a reasonable cooling rate in view of the capacity of the cooling equipment. Further, if the cooling rate is too high, the cooling end temperature cannot be controlled, and there is a possibility of overshoot and overcooling to the Ar ₁ transformation point or less. Therefore, the cooling rate here is desirably 150 ° C./s or less. .

Next, cooling is performed at a cooling rate of 20 ° C./s or more from the temperature range to the winding temperature (CT).
At a cooling rate of less than s, pearlite or bainite is generated, and sufficient martensite cannot be obtained, and the desired ferrite is the phase having the maximum volume fraction and the microstructure having martensite as the second phase cannot be obtained. . Although the effect of the present invention can be obtained without particularly setting the upper limit of the cooling rate to the winding temperature, it is preferable to set the cooling rate to 300 ° C./s or less because there is a concern about warpage due to thermal strain.

If the winding temperature is higher than 350 ° C., bainite is formed and sufficient martensite cannot be obtained, and a microstructure having the target ferrite as the phase having the maximum volume fraction and martensite as the second phase is obtained. The winding temperature is
Limit to 350 ° C or less. The lower limit of the winding temperature is not particularly limited, but if the coil is in a wet state for a long time, the appearance may be poor due to rust. After the hot rolling process, pickling is performed if necessary, and then the in-line or off-line rolling reduction is 10%.
The following skin pass or cold rolling to a rolling reduction of about 40% may be performed.

[0043]

The present invention will be further described below with reference to examples. The steels A to N having the chemical components shown in Table 1 were melted in a converter and continuously cast, and then heated at a temperature shown in Table 2 (SR
T), and after rough rolling, after rolling at a finish rolling temperature (FT) shown in Table 2 to a sheet thickness of 1.2 to 5.4 mm, winding at a winding temperature (CT) shown in Table 2 respectively. I took it. For some parts, after rough rolling, the collision pressure was 2.7MP.
a, High-pressure descaling was performed under the conditions of a flow rate of 0.001 liter / cm ² . However, the indication of the chemical composition in the table is% by mass.

[0044]

[Table 1]

In the tensile test of the hot-rolled sheet obtained in this manner, the test material was first processed into a No. 5 test piece described in JIS Z2201, and the tensile test was performed in accordance with the test method described in JIS Z2241. Table 2 shows the test results. Here, the volume ratio of the ferrite and the second phase is 1/4 W of the steel sheet width.
Alternatively, a sample cut out from the 3 / 4W position is polished and etched into a cross section in the rolling direction, and then 200 to 50 using an optical microscope.
It is defined as the area fraction of the microstructure at 1 / 4t of the plate thickness observed at a magnification of 0x.

[0046]

[Table 2]

Next, a fatigue test piece having the shape shown in FIG. 1 was sampled from the 1/4 W or 3/4 W position of the steel sheet width so that the rolling direction became a longer side, and subjected to a low cycle fatigue test. However, the surface of the fatigue test piece was a ground surface with a three-sided finish.
The fatigue test was performed using an electrohydraulic servo-type fatigue tester, and the test method was in accordance with ASTM E606-92. As shown in FIG. 2, the test conditions were as follows: a complete triangular wave in the axial direction, a complete swinging tensile compression load, a total strain amplitude of 0.3 to 0.6% and a strain rate of 4.0 × 10 ⁻³ / sec. And The test was performed while recording changes in strain response and stress response.

After completion of the fatigue test, the condition of the total strain amplitude is 2
As shown in FIG. 3, with respect to a test piece which was tested in the range of ≦ 2100 × ε _a / YP ≦ 4, a processing strain was not introduced into a transmission electron microscope sample (thin film) from a portion having a thickness of 1/4 near the fractured portion. And the dislocation structure was observed with a transmission electron microscope. Table 2 shows the area ratio of the cell structure as S _cell . However, observation with a transmission electron microscope is 2
The crystal grains were changed at a magnification of 000 to 10000 times and observed in 10 visual fields or more. Where YP: yield stress or 0.2%
Strength (MPa), ε _a : total strain amplitude (%).

The low cycle fatigue strength of the steel sheet was evaluated by dividing the yield stress by the tensile strength. Here, the term “repeated yield stress” refers to an intersection point obtained by extrapolating a stress-strain curve or an elastic straight line to a straight line obtained by linearly approximating the stress amplitude σ _a at a repetition number of 破 断 of the rupture life (Nf) to the strain. . According to the present invention, steel A, B, D, E, G, H, J-
1, 8 steels of N, containing a predetermined amount of steel components, the microstructure of which is a composite structure in which the phase having the largest volume fraction is ferrite and the second phase is mainly martensite, Wherein the area ratio of the cell structure among the dislocation structures in the ferrite observed after the test is 50% or less,
Hot-rolled steel sheets for processing with excellent low cycle fatigue strength have been obtained.

Other steels are outside the scope of the present invention for the following reasons. That is, since the content of C is out of the range of the present invention, the steel C does not have a desired microstructure and does not have sufficient low cycle fatigue strength (CYS / TS). Steel F does not have sufficient elongation (El) because the content of S is out of the range of the present invention. Steel I is P
Is out of the range of the present invention, a sufficient low cycle fatigue strength (CYS / TS) is not obtained. Steel J-2
The finish rolling end temperature (FT) is higher than the range of the present invention, and a sufficient elongation (E
l) is not obtained.

The finish rolling temperature (FT) of the steel J-3 is lower than the range of the present invention, the strain remains and the ductility (El) is maintained.
Also decrease. In steel J-4, the retention temperature (MT) was lower than the range of the present invention, the desired microstructure was not obtained, and sufficient elongation (El) was not obtained. In steel J-5, the retention temperature (MT) was higher than the range of the present invention, and the desired microstructure was not obtained and sufficient elongation (El) was not obtained. Steel J-6 does not have a residence time (Time), a desired microstructure cannot be obtained, and a sufficient elongation (El) has not been obtained. Steel J-7 has a higher winding temperature (CT) than the range of the present invention, and a sufficient elongation (E
l) is not obtained. Further, sufficient low cycle fatigue strength (CYS / TS) has not been obtained.

In steel J-8, the cooling rate (CR) after stagnation was lower than the range of the present invention, and the desired microstructure was not obtained and sufficient elongation (El) was not obtained. Further, sufficient low cycle fatigue strength (CYS / TS) has not been obtained. Steel K does not have sufficient low cycle fatigue strength (CYS / TS) because the value of 0.52 Al / N is out of the range of the present invention. Steel L does not have sufficient low cycle fatigue strength (CYS / TS) because the value of Cr + 3.5Mo + 39V is out of the range of the present invention. In steel M, since the content of C is out of the range of the present invention, a desired microstructure cannot be obtained and a sufficient elongation (El) cannot be obtained.

[0053]

As described above in detail, the present invention relates to a hot-rolled steel sheet for processing and excellent in low cycle fatigue strength and a method for producing the same. It can be said that the present invention is an industrially high invention because a significant improvement in low cycle fatigue characteristics, which is one of the important characteristics of members requiring durability, can be expected.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating the shape of a fatigue test piece.

FIG. 2 is a diagram illustrating a method of loading a fatigue test.

FIG. 3 is a diagram illustrating a transmission electron microscope sample collection position.

FIG. 4 is an electron micrograph showing an example of a cell structure among dislocation structures observed after a fatigue test.

FIG. 5 is an electron micrograph showing an example of a dislocation structure observed after a fatigue test, other than a cell structure.

FIG. 6 is a diagram showing the results of a preliminary experiment leading to the present invention in a relationship between the cell structure area ratio after a fatigue test and low cycle fatigue strength (a value obtained by dividing a cyclic yield stress by a tensile strength).

FIG. 7 shows the results of preliminary experiments leading to the present invention,
It is a figure which shows in the relationship of the range of the value of / N, the range of the value of Cr + 3.5Mo + 39V, and the cell structure area ratio after a fatigue test.

FIG. 8 shows a stress amplitude σ _a at 1 / 2Nf in a fatigue test.
FIG.

FIG. 9 is a diagram illustrating a repeated yield stress CYS in a fatigue test.

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor Manabu Takahashi 20-1 Shintomi, Futtsu-shi, Chiba F-term in the Technology Development Division, Nippon Steel Corporation 4K037 EA01 EA02 EA05 EA06 EA09 EA11 EA13 EA15 EA16 EA17 EA18 EA19 EA20 EA23 EA25 EA27 EA28 EA31 EA32 EA35 EA36 EB09 EB11 FA02 FA03 FA05 FB10 FC07 FD03 FD04 FD08 FE01

Claims (8)

[Claims] C .: 0.01 to 0.2%, Si: 0.01 to 2%, Mn: 0.05 to 3%, P ≦ 0.1%, S ≦ 0. Al ≦ 0.2%, N: 0.001-0.1%, 0.52 Al / N ≦ 10
Containing Al and N to satisfy Cr, Mo, V
One or two or more of the following to satisfy Cr ≦ 2.5%, Mo ≦ 1%, V ≦ 0.1%, and (Cr + 3.5Mo + 39V) ≧ 0.1, with the balance being Fe and inevitable A steel consisting of impurities, the microstructure of which is a composite structure in which the phase with the largest volume fraction is ferrite and the second phase is mainly martensite, and the dislocation structure in the ferrite observed after the fatigue test. A hot-rolled steel sheet for processing excellent in low cycle fatigue strength, wherein the area ratio of the cell structure is 50% or less. 2. The steel according to claim 1, further comprising:
The hot-rolled steel sheet for processing having excellent low cycle fatigue strength according to claim 1, characterized by containing 0.2 to 2%. 3. The steel according to claim 1, further comprising:
The hot-rolled steel sheet for processing having excellent low cycle fatigue strength according to claim 1 or 2, which contains 0.0002 to 0.002%. 4. The steel according to claim 1, further comprising:
The hot-rolled steel sheet for processing having excellent low cycle fatigue strength according to any one of claims 1 to 3, characterized by containing 0.1 to 1%. 5. The steel further comprises, in mass%, one or two of Ca: 0.0005 to 0.002% and REM: 0.0005 to 0.02%. The hot-rolled steel sheet for processing according to any one of claims 1 to 4, which is excellent in low cycle fatigue strength. 6. The steel according to claim 1, wherein the steel further comprises Nb:
0.001-0.1% and N-0.15Nb ≧ 0.00
05%, Ti: 0.001-0.1% and N-0.29
The low cycle fatigue according to any one of claims 1 to 5, wherein one or more of Ti ≧ 0.0005% and Zr: 0.001 to 0.2% is contained. Hot rolled steel sheet for processing with excellent strength. 7. Hot-rolling of a slab having the composition according to claim 1 at a temperature between the Ar ₃ transformation point temperature and the Ar ₃ transformation point temperature + 100 ° C. or less. Is completed, and is retained for 1 to 20 seconds in a temperature range from the Ar ₁ transformation point temperature to the Ar ₃ transformation point temperature.
It is cooled at a cooling rate of 0 ° C./s or more, and wound at a winding temperature of 350 ° C. or less, and its microstructure is a composite in which the phase having the largest volume fraction is ferrite and the second phase is mainly martensite. Production of a hot-rolled steel sheet for processing excellent in low cycle fatigue strength, characterized by obtaining a steel sheet having a structure and an area ratio of a cell structure of 50% or less among dislocation structures in ferrite observed after a fatigue test. Method. 8. The low cycle fatigue strength according to claim 7, wherein, during the hot rolling, after the rough rolling is completed, high-pressure descaling is performed, and the hot finish rolling is completed at the Ar ₃ transformation point temperature or higher. Method of manufacturing hot rolled steel sheet for processing with excellent performance.