Steel pipe having high formability and method for production thereof

Abstract
The invention provides a steel pipe being superior in workability, particularly in bending workability, in which an r-value in the axial direction of the pipe in a portion where melting or transformation of a steel material has occurred during seam welding is as high as comparable to that in a portion where melting or transformation of the steel material has not occurred, and a method of producing the steel pipe. In the high-workability steel pipe, an r-value in the longitudinal direction is not less than 1.2, more preferably not less than 1.6, over an entire area in the circumferential direction, including a seamed portion. The steel pipe is produced by a method comprising the step of performing diameter-reducing rolling on a steel pipe in a temperature range of from 600° C. to Ac3 with a reduction in diameter of not less than 30%, preferably after heating the steel pipe to temperatures of not lower than Ac1, the steel pipe being produced by seam-welding strip steel, or a method further comprising the step of performing heat treatment of holding the rolled steel pipe in a temperature range of from 600° C. to 900° C. for a time of 1 second or longer during cooling subsequent to the diameter-reducing rolling or by reheating the rolled steel pipe after the cooling.
Description


TECHNICAL FIELD

[0001] The present invention relates to a steel pipe having superior workability and a method of producing the steel pipe.



BACKGROUND ART

[0002] For the purpose of reducing the weight and cost, the application of seam (electric resistance) welded steel pipes to automobile parts has been considered. Conventional seam welded steel pipes, however, have not been sufficient in workability. Bending is employed to manufacture, e.g., undercarriage or suspension parts of automobiles. When the conventional seam welded steel pipes are subjected to the bending, a problem has been experienced in that a pipe wall is greatly thinned on the outer side of a bent portion, and in the worst case a pipe is ruptured. Even in the case of not causing a rupture, a large rate of thinning of the pipe wall requires the use of a material having a greater thickness to satisfy the design stress, and therefore a sufficient reduction in weight cannot be achieved.


[0003] As disclosed in Japanese Unexamined Patent Application Publication No. 55-56624, for example, it is known that improving an r-value (Lankford value) of a pipe in the axial direction is effective to overcome the problems described above. As a method for increasing the r-value of a steel pipe, however, it is only known to increase the r-value of strip steel as a base material of a steel pipe as disclosed in, for example, Japanese Unexamined Patent Application Publication No. 6-41689. When producing seam welded steel pipes, there has been a problem that the r-value is reduced in a portion where melting or transformation of a steel material has occurred during seam welding. Another problem has arisen in that the seam welding cannot be applied to steel plates not having a high r-value, such as hot-rolled steel plates, high tensile strength steel plates, and low, medium and high carbon steel plates.


[0004] Accordingly, it is an object of the present invention to provide a steel pipe being superior in workability, particularly in bending workability, in which an r-value of the pipe in the axial direction in a portion where melting or transformation of a steel material has occurred during seam welding is as high as comparable to that in a portion where melting or transformation of the steel material has not occurred, and a method of producing the steel pipe.



DISCLOSURE OF INVENTION

[0005] With the view of overcoming the problems mentioned above, the inventors have conducted studies based on a consideration that working and heat treatment of seam welded steel pipes are required to improve the r-value in a welded portion near the seam. Then, the inventors have studied a method of performing working and heat treatment of a steel pipe evenly at any positions in the circumferential direction, the steel pipe being produced by seam-welding cold-rolled steel having a high r-value. In the process of the studies, the inventors have found that the r-value of the seam welded steel pipe in the longitudinal direction (in the axial direction of the pipe) is noticeably improved to 1.2 or above, in particular to 1.6 or above, at any positions in the circumferential direction, including a seamed portion, by a method of performing diameter-reducing rolling on the seam welded steel pipe in a temperature range of from 600° C. to Ac3 with a reduction in diameter of not less than 30% (referred to as a “method according to the present invention” hereinafter).


[0006] As a result of applying the method according to the present invention to seam welded steel pipes produced using various kinds of steel plates as base-material strip steel, the inventors have also found that a high r-value can be obtained regardless of the r-value of the original strip steel. Further, it has been found that with the method according to the present invention, the restriction of ingredients which has hitherto been employed to obtain a high r-value in steel sheets, i.e., a reduction of the C and N contents and addition of stabilizing elements such as Ti and Nb, are not required. As a result, seam welded steel pipes having a high r-value can also be produced using, as base-material strip steel, hot-rolled steel, high tensile strength steel such as dual phase steel, and low, medium and high carbon steel, which have a difficulty in achieving a high r-value in the stage of strip steel.


[0007] The views of the inventors regarding the reason why a steel pipe having a high r-value can be obtained from even a steel plate not having a high r-value are as follows.


[0008] By performing the diameter-reducing rolling on a seam welded steel pipe in a temperature range of from 600° C. to Ac3 with a reduction in diameter of not less than 30%, an ideal aggregation structure due to the rolling, in which the <110> axis is parallel to the longitudinal direction and the <111 > to <110> axes are parallel to the radial direction, is formed and then further developed through restoration and recrystallization. That aggregation structure provides a high r-value. The aggregation structure due to the rolling produces very great driving forces because crystals are rotated by working strains. Unlike an aggregation structure that is created through recrystallization in the case of obtaining a high r-value in steel sheets, the aggregation structure due to the rolling is less affected by the second phase and solid solution C. Consequently, even for the type of strip steel which has a difficulty in obtaining a high r-value in the stage of producing steel plates, a high r-value can be obtained in the stage of producing steel pipes.


[0009] Also, the reason why a high r-value is not obtained by performing the diameter-reducing rolling at low temperatures is that ideal crystal rotation is not caused because of high work hardness, or that restoration and recrystallization are not developed at a sufficient level because of low temperatures. Furthermore, the reason why a high r-value is not obtained by a method of performing the diameter-reducing rolling on a steel pipe at low temperatures and then annealing the rolled steel pipe for recrystallization is that the desired aggregation structure is not developed through the cold rolling and the recrystallization because of the effect of the second phase and solid solution C.


[0010] In the field of producing steel sheets, there is known a method of producing a steel sheet having a high r-value by rolling steel into a sheet in the hot ferrite range. This method of producing a steel sheet having a high r-value is featured in that steel containing C and N in reduced amounts and added with stabilizing elements such as Ti and Nb is rolled at low temperatures and then recrystallized. That sheet rolling at low temperatures differs from the diameter-reducing rolling at high temperatures intended by the method according to the present invention. In fact, if the known sheet rolling in the hot ferrite range is carried out at 600° C. or above, the r-value is not improved, but rather noticeably lowered on the contrary. This is because, in the sheet rolling in which draft is applied in the thickness direction of a sheet, strain occurs in a direction different from that in the diameter-reducing rolling of a steel pipe in which draft is applied in the circumferential direction, and hence the aggregation structure effective in increasing the r-value is not developed.


[0011] As a result of further continuing the studies, the inventors have found that, in the method according to the present invention, the thickness deviation can be noticeably reduced and the occurrence of wrinkles near the seam can be suppressed by heating a seam welded steel pipe to temperatures of not lower than Ac1 before the diameter-reducing rolling for austenitic transformation of a part or the whole of a steel structure, because the difference in mechanical properties between the hardened structure of the seam and the remaining portion is reduced. The present invention has been accomplished based on the findings set forth above. The features of the present invention are as follows.


[0012] (1) A high-workability steel pipe wherein an r-value in the longitudinal direction is not less than 1.2, more preferably not less than 1.6, over an entire area in the circumferential direction, including a seamed portion.


[0013] (2) A method of producing a high-workability steel pipe, the method comprising the step of performing diameter-reducing rolling on a steel pipe in a temperature range of from 600° C. to Ac3 with a reduction in diameter of not less than 30%, the steel pipe being produced by seam-welding strip steel.


[0014] (3) A method of producing a high-workability steel pipe, the method comprising the steps of heating a steel pipe to temperatures of not lower than Ac1, the steel pipe being produced by seam-welding strip steel, and then immediately or after cooling and reheating the steel pipe, performing diameter-reducing rolling in a temperature range of from 600° C. to Ac3 with a reduction in diameter of not less than 30%.


[0015] (4) In the method of producing a high-workability steel pipe defined in the above (2) or (3), after the diameter-reducing rolling of the steel pipe, heat treatment of holding the rolled steel pipe in a temperature range of from 600° C. to 900° C. for a time of 1 second or longer is performed during cooling subsequent to the diameter-reducing rolling or by reheating the rolled steel pipe after the cooling.







BRIEF DESCRIPTION OF THE DRAWINGS

[0016]
FIG. 1 is a graph showing the relationship between an r-value in the longitudinal direction of a steel pipe having been subjected to diameter-reducing rolling and a reduction in diameter.


[0017]
FIG. 2 is a graph showing the relationship between an r-value in the longitudinal direction of a steel pipe having been subjected to diameter-reducing rolling and an outgoing-side temperature in the rolling process.


[0018]
FIG. 3 is a graph showing the relationship between a seam thickness deviation in a steel pipe having been subjected to diameter-reducing rolling and a heating temperature before the diameter-reducing rolling.







BEST MODE FOR CARRYING OUT THE INVENTION

[0019] In a high-workability steel pipe according to the present invention, an r-value in the longitudinal direction is not less than 1.2. The reason is that the bending workability of the steel pipe is noticeably improved when the r-value is not less than 1.2. More preferably, the high-workability steel pipe has an r-value of not less than 1.6 because the bending workability is further improved when the r-value is not less than 1.6.


[0020] The high-workability steel pipe according to the present invention can be produced by performing diameter-reducing rolling on a steel pipe in a temperature range of from 600° C. to Ac3 with a reduction in diameter of not less than 30%, the steel pipe being produced by seam-welding strip steel and having a seam. The r-value is affected by the reduction in diameter and the temperature during the diameter-reducing rolling.


[0021]
FIG. 1 is a graph showing the relationship between the r-value in the longitudinal direction and the reduction in diameter resulted at circumferential positions 0°, 90°, 180° and 270° of each steel pipe which was produced by performing the diameter-reducing rolling on a seam welded steel pipe under a condition of the outgoing-side temperature being set to 730° C. while changing the reduction in diameter the seam welded steel pipe being produced by an ordinary method from strip steel having the same composition as steel A in Table 1 given below. The seam position is assumed to be at 0° (this is similarly applied to the following description). From FIG. 1, it is understood that, regardless of the circumferential positions, the r-value of not less than 1.3 is obtained at the reduction in diameter of not less than 30%, and the r-value of not less than 1.6 is obtained at the reduction in diameter of not less than 50%.


[0022]
FIG. 2 is a graph showing the relationship between the r-value in the longitudinal direction and the outgoing-side temperature resulted at circumferential positions 0°, 90°, 180° and 270° of each steel pipe which was produced by performing the diameter-reducing rolling on a seam welded steel pipe under a condition of the reduction in diameter set to 30% while changing the outgoing-side temperature, the seam welded steel pipe being produced by an ordinary method from strip steel having the same composition as steel A in Table 1 given below. From FIG. 2, it is understood that the r-value of not less than 1.2 is obtained at the outgoing-side temperature of not lower than 600° C.


[0023] Based on the experiment results mentioned above, a lower limit of the temperature for the diameter-reducing rolling was set to 600° C. and a lower limit of the reduction in diameter was set to 30%. Also, an upper limit of the temperature for the diameter-reducing rolling was set to the same as an upper limit of the temperature range in which the steel structure contains ferrite, i.e., the temperature Ac3. The r-value is not improved even by the diameter-reducing rolling if it is performed on steel whose structure contains no ferrite. The temperature Ac3 depends on the chemical composition of steel, and can be determined based on experiments. A range of temperature Ac3 is approximately not higher than 900° C. In the present invention, so long as the steel structure contains ferrite, the second phase (phase other than ferrite) is not limited to particular one. For example, austenite may be the second phase. More preferably, the diameter-reducing rolling is performed at temperatures where ferrite forms the main phase (phase having a volume ratio of 50% or more).


[0024] The gist of the present invention resides in that a steel pipe is subjected to the diameter-reducing rolling in a temperature range where the steel structure has the ferrite phase. From the standpoint of improving the r-value, there is no particular restriction upon the history prior to the diameter-reducing rolling. For example, the heating temperature prior to the diameter-reducing rolling may be any of the temperature at which the steel structure has the single austenitic phase, the temperature at which the steel structure has the two austenitic and ferrite phases, and the temperature at which the steel structure has the single ferrite phase. Further, prior to the diameter-reducing rolling, the steel pipe may be rolled at such temperatures as forming austenite as the single phase or the main phase.


[0025]
FIG. 3 is a graph showing the relationship between a heating temperature and a thickness deviation resulted for each steel pipe which was produced by performing the diameter-reducing rolling on a seam welded steel pipe under conditions of the reduction in diameter set to 30% and the rolling temperature set to 700° C. while changing the heating temperature, the seam welded steel pipe being produced by an ordinary method from strip steel having the same composition as steel A in Table 1 given below. From FIG. 3, it is understood that the heating prior to the diameter-reducing rolling is preferably set to be not lower than the temperature Ac1 from the standpoint of suppressing the thickness deviation and wrinkles occurred near the seam. The temperature Ac1 depends on the chemical composition of the steel pipe, etc., and can be determined based on experiments. A range of temperature Ac1 is approximately not lower than 800° C. However, if the heating temperature is too high, the crystal grain size would be excessively increased, thus resulting in a problem of, for example, increasing surface roughness during the working. For that reason, the heating temperature is preferably set to be not higher than 900° C.


[0026] There is no particular restriction upon the cooling after the heating of the steel pipe. Subsequent to the heating, the diameter-reducing rolling may be performed, for example, after cooling the steel pipe down to temperatures at which ferrite forms the main phase, or by reheating the steel pipe after cooling it down to the room temperature.


[0027] Further, preferably, after the diameter-reducing rolling of the steel pipe, heat treatment of holding the rolled steel pipe in a temperature range of from 600° C. to 900° C. for a time of 1 second or longer is performed in the present invention.


[0028] In the present invention, since the diameter-reducing rolling is performed at temperatures of not lower than 600° C., the work hardness is low and a sufficient level of workability is obtained with additional treatment. Even so, by performing heat treatment for holding the rolled steel pipe at a certain temperature for a certain time in succession to the diameter-reducing rolling, the elongation and the r-value are further improved. This effect is developed by holding the rolled steel pipe at temperatures of not lower than 600° C. for a time of 1 second or longer. However, if the holding temperature exceeds 900° C., the steel structure would be transformed into the single austenitic phase and the r-value would be reduced because of the randomized aggregation structure. For that reason, the heat treatment is preferably performed on conditions of the holding temperature in the range of from 600° C. to 900° C. and the holding time of 1 second or longer. Additionally, the heat treatment may be performed during cooling subsequent to the diameter-reducing rolling or by reheating the rolled steel pipe after the cooling.



EXAMPLE

[0029] Seam welded steel pipes were produced by an ordinary method from various kinds of hot-rolled steel plates having chemical compositions shown in Table 1, and the diameter-reducing rolling was performed on each steel pipe under conditions shown in Table 2. Heating of the steel pipe prior to the diameter-reducing rolling was not held at all or held for a time of 1 to 600 seconds after reaching the temperature shown in Table 2. Tensile specimens of JIS No. 12-A were sampled from circumferential positions 0°, 90°, 180° and 270° of each steel pipe obtained. After bonding a strain gauge with a gauge length of 2 mm to each specimen, a tensile test was carried out on the specimen by applying a nominal strain of 6 to 7%. Then, a ratio of a true strain εw in the width direction to a true strain εL in the longitudinal direction was measured. From a gradient ρ of that ratio, the r-value was calculated based on the following formulae:


ρ=εLw


r-value=ρ/(−1−ρ)


[0030] Further, a thickness deviation η was calculated by measuring a pipe wall thickness ts of a seamed portion and an average pipe wall thickness tb of the remaining portion. That is:


thickness deviation η%=(ts−tb)/tb×100%


[0031] Moreover, the presence or absence of wrinkles was determined by observing an image of an area near the seam in a cross-section perpendicular to the axis of the steel pipe, the image being enlarged at a magnification of 50 times.


[0032] Those results are listed in Table 3 along with the tensile strength (TS) and the elongation (E1).


[0033] The r-value is 1.2 or above at any positions in the circumferential direction in Examples of the present invention, whereas the r-value is below 1.2 in Comparative Examples. Also, in the specimens heated to temperatures of not lower than Ac1, the thickness deviation is smaller and wrinkles are not caused.



Industrial Applicability

[0034] According to the present invention, a high-workability steel pipe can be provided which has a high r-value over an entire area in the circumferential direction, including a seamed portion, and also has a good shape. Limits in bending and expanding work of the steel pipe are noticeably improved, whereby omission of steps due to the integral forming and a reduction in weight can be achieved. Further, seam welded steel pipes having a high r-value can also be produced using, as base materials, hot-rolled steel, high tensile strength steel such as dual phase steel, and low, medium and high carbon steel, which have a difficulty in achieving a high r-value with a conventional method of producing a steel pipe by simply seam-welding a steel plate. As a result, the present invention is able to remarkably enlarge the applicable range of bending of steel pipes and hence greatly contributes to development of the industry.
1TABLE 1Chemical Composition (&)Ac1Ac3SteelCSiMnPSAlNCrTiNbBNiCu(° C.)(° C.)A0.060.10.30.010.0050.020.003730840B0.10.20.80.010.0050.020.003730820C0.250.30.80.010.0050.020.003750800D0.250.30.50.010.0050.020.0030.002750800E0.40.31.60.010.0050.020.003 0.03730780F0.081.01.40.010.0050.020.003 0.90.01750840G0.151.41.50.010.0050.020.003 0.3770820H0.080.51.20.010.0050.020.0030.04770820I0.080.041.50.010.0050.020.0030.04750800J0.081.51.80.010.0050.020.0030.1 780830K0.090.051.80.010.0050.020.0030.150.05750800L0.010.21.50.010.0050.020.00311.00.250.4730800


[0035]

2













TABLE 2











Incoming-side
Outgoing-side
Total
Effective







Temperature
Temperature
Reduction
Reduction




Heating
in Diameter-
in Diameter-
in
in




Temperature
Reducing
Reducing
Diameter
Diameter*
Heat


No.
Steel
(° C.)
Rolling (° C.)
Rolling (° C.)
(%)
(%)
Treatment
Remarks























1
A
800
780
730
50
50

Example


2
A
900
880
830
50
5

Comparative










Example


3
A
630
610
560
50
10

Comparative










Example


4
B
800
780
730
50
50

Example


S
B
800
780
730
50
50

Example


6
C
800
780
730
50
50
730° C. ×
Example









5 min.


7
D
900**
720
680
50
50

Example


8
D
850
720
680
50
50

Example


9
D
800
780
730
50
50

Example


10
D
800
720
680
50
50

Example


11
D
750
720
680
50
50

Example


12
D
735
720
680
50
50

Example


13
D
720
720
680
50
50

Example


14
E
800
780
730
50
50

Example


15
F
800
780
730
0
0

Comparative










Example


16
F
800
780
730
15
15

Comparative










Example


17
F
800
780
730
30
30

Example


18
F
800
780
730
40
40

Example


19
F
800
780
730
50
50

Example


20
F
800
780
730
60
60

Example


21
F
800
780
730
70
70

Example


22
F
900
890
850
30
2

Comparative










Example


23
F
850
840
780
30
30

Example


24
F
750
730
680
30
30

Example


25
F
700
680
600
30
30

Example


26
F
630
610
560
50
10

Comparative










Example


27
G
900
780
730
50
50

Example


28
G
850
780
730
50
50

Example


29
G
800
780
730
30
30

Example


30
G
800
780
730
40
40

Example


31
G
800
780
730
50
50

Example


32
H
800
780
730
50
50

Example


33
I
800
780
730
50
50

Example


34
J
800
780
730
50
50

Example


35
K
800
780
730
50
50

Example


36
L
760
740
700
60
60

Example






*effective reduction in diameter: reduction in diameter in temperature range of 600° C. to Ac3




**rolling after cooling and reheating (for other types of steel, rolling immediately after heating)








[0036]

3












TABLE 3
















Wrinkles








Seam
∘ not



0° (Seam)
90°
180°
270°
Thickness
occurred























TS/
EI*
r-
TS/
EI*
r-
TS/
EI*
r-
TS/
EI*
r-
Deviation
x



No
Mpa
/%
value
Mpa
/%
value
Mpa
/%
value
Mpa
/%
value
/%
occurred
Remarks

























1
300
55
2.0
303
54
2.0
307
54
2.1
301
55
2.1
0.3

Example


2
300
45
0.8
309
45
0.9
307
45
0.8
308
45
0.8
0.3

Comparative

















Example


3
450
35
1.0
450
35
1.1
459
36
1.0
451
34
1.1
10.0
X
Comparative

















Example


4
350
50
2.0
356
51
2.0
356
50
2.0
350
51
2.0
0.5

Example


5
350
50
2.4
358
51
2.4
351
49
2.5
356
49
2.4
0.5

Example


6
620
25
1.8
624
24
1.8
625
25
1.8
629
25
1.9
0.3

Example


7
640
27
1.7
646
27
1.7
641
27
1.7
647
26
1.7
0.5

Example


8
631
25
1.7
651
26
1.6
641
25
1.8
641
25
1.8
1.0

Example


9
620
28
1.8
626
29
1.8
621
29
1.9
627
28
1.9
0.5

Example


10
640
24
1.6
659
24
1.7
632
24
1.7
636
24
1.7
2.0

Example


11
644
22
1.6
650
22
1.7
635
22
1.7
632
22
1.8
30

Example


12
653
20
1.6
657
21
1.6
640
21
1.8
623
21
1.8
8.0
x
Example


13
644
19
1.7
650
19
1.7
637
19
1.9
614
19
1.8
15.0
x
Example


14
650
25
1.8
652
25
1.9
651
25
1.8
651
26
1.9
0.5

Example


15
500
25
0.7
508
26
0.8
503
24
0.8
SOl
25
0.8
0.3

Comparative

















Example


16
590
28
1.0
593
28
1.1
599
29
1.1
595
28
1.0
0.3

Comparative

















Example


17
610
28
1.3
610
28
1.3
618
28
1.3
614
29
1.3
0.9

Example


18
610
29
1.4
619
29
1.4
611
30
1.4
611
28
1.4
0.9

Example


19
610
30
1.6
6l7
31
1.7
611
30
1.6
61S
31
1.6
0.9

Example


20
610
32
2.0
616
31
2.0
612
33
2.1
610
31
2.1
0.9

Example


21
610
35
2.5
615
35
2.6
613
36
2.6
618
36
2.6
0.8

Example


22
590
28
0.8
593
27
0.8
599
28
0.8
593
28
0.9
0.2

Comparative

















Example


23
610
29
1.4
612
30
1.4
614
30
1.5
616
29
1.5
0.2

Example


24
610
28
1.3
613
29
1.3
615
28
1.4
612
28
1.4
0.0

Example


25
650
27
1.2
651
26
1.2
650
27
1.2
658
26
1.2
3.0
x
Example


26
630
22
0.9
680
21
1.0
687
22
1.0
685
23
0.9
15.0
x
Comparative

















Example


27
630
30
1.3
638
30
1.3
639
31
1.4
640
31
1.3
0.7

Example


28
630
33
1.4
636
33
1.4
630
33
1.5
638
33
1.5
0.5

Example


29
630
30
1.3
638
30
1.3
639
31
1.4
640
31
1.3
0.3

Example


30
630
33
1.4
636
33
1.4
630
33
1.5
638
33
1.5
0.3

Example


31
630
35
1.8
637
34
1.9
635
35
1.8
633
34
1.9
0.4

Example


32
600
30
1.8
606
30
1.8
609
30
1.9
600
30
1.8
0.5

Example


33
600
30
1.8
604
29
1.8
605
31
1.9
601
29
1.9
0.8

Example


34
820
24
1.6
823
25
1.6
821
25
1.7
825
24
1.7
0.3

Example


35
820
22
1.6
821
22
1.6
823
23
1.7
830
22
1.7
0.8

Example


36
695
28
1.8
595
28
1.8
595
28
1.8
595
28
1.8
0.3

Example






*sheet thickness = 1.6 mm








Claims
  • 1. A high-workability steel pipe wherein an r-value in the longitudinal direction is not less than 1.2 over an entire area in the circumferential direction, including a seamed portion.
  • 2. A method of producing a high-workability steel pipe, said method comprising the step of performing diameter-reducing rolling on a steel pipe in a temperature range of from 600° C. to Ac3 with a reduction in diameter of not less than 30%, said steel pipe being produced by seam-welding strip steel.
  • 3. A method of producing a high-workability steel pipe according to claim 2, wherein said method comprises the steps of heating a steel pipe to temperatures of not lower than Ac1, said steel pipe being produced by seam-welding strip steel, and then immediately or after cooling and reheating said steel pipe, performing diameter-reducing rolling in a temperature range of from 600° C. to Ac3 with a reduction in diameter of not less than 30%.
  • 4. A method of producing a high-workability steel pipe according to claim 2 or 3, wherein after the diameter-reducing rolling of said steel pipe, heat treatment of holding the rolled steel pipe in a temperature range of from 600° C. to 900° C. for a time of 1 second or longer is performed during cooling subsequent to the diameter-reducing rolling or by reheating the rolled steel pipe after said cooling.
PCT Information
Filing Document Filing Date Country Kind
PCT/JP01/05053 6/14/2001 WO