Patent Application
20170138511
The present disclosure relates to an expandable high-strength steel material and an expanded high-strength steel pipe having superior expandability and collapse resistance, and methods for manufacturing the expandable high-strength steel material and the expanded high-strength steel pipe.
In general, when steel pipes are installed below the surface of the earth in an oilfield (underground), a hole is initially drilled into the earth to a predetermined depth, and sections of steel pipe called “casing” are installed therein to prevent the collapse of the hole. Thereafter, the hole is further drilled from the lower end of the casing to create a deeper well, and a new casing is installed through the previously installed casing. This work is repeated so as to finally connect oil well pipes (tubing) to an oil layer. If a very deep well is drilled, various kinds of casings having different diameters are used. Since the diameter of oil well pipes through which oil or gas flows is fixed, it is necessary to increase a drilling area in the diameter direction of the oil well tubes by using various kinds of casings. Therefore, steel pipes used as casings are required to have superior expandability.
Such a steel pipe is expanded by stress acting in an outward direction of the steel pipe. However, if inward stress is generated in the steel pipe by external force applied thereto, that is, if compressive stress is generated in the steel pipe, the resistance of the steel pipe to the compressive stress decreases sharply. This is known as the Bauschinger effect: if a plastically deformed material is subjected to stress acting in a direction opposite to the direction of the plastic deformation, the material is deformed, even in the case that the amount of stress is lower than the original compressive yield strength of the material. Therefore, expandable steel pipes are required to have a high degree of compressive yield strength (i.e., a high degree of collapse resistance) as well as a high degree of expandability.
In the related art, low-strength carbon steel having a ferrite-pearlite structure and a high degree of elongation is used to manufacture expandable steel pipes. A typical technique is disclosed in Patent Document 1. However, the application of the carbon steel disclosed in Patent Document 1 as an expandable steel material is limited, because the disclosed carbon steel has a low degree of expandability on the level of less than about 20%. In addition, it is difficult to obtain a desired degree of strength after the carbon steel is expanded, and the collapse resistance of the carbon steel is low due to the Bauschinger effect.
(Patent Document 1) Japanese Patent No. 4833835
Aspects of the present disclosure may include an expandable high-strength steel material and an expanded high-strength steel pipe having excellent expandability and collapse resistance, and methods for manufacturing the expandable high-strength steel material and the expanded high-strength steel pipe.
According to an aspect of the present disclosure, an expandable high-strength steel material having superior expandability and collapse resistance may include, by weight, manganese (Mn): 12% to 18%, carbon (C): 0.3% to 0.6%, and a balance of iron (Fe) and inevitable impurities, wherein the carbon (C) and the manganese (Mn) may satisfy the following condition: 23≦35.5C+Mn≦38, and the expandable high-strength steel material has an austenite single phase microstructure.
According to another aspect of the present disclosure, an expanded high-strength steel pipe having superior expandability and collapse resistance may include, by weight, manganese (Mn): 12% to 18%, carbon (C): 0.3% to 0.6%, and a balance of iron (Fe) and inevitable impurities, wherein the carbon (C) and the manganese (Mn) may satisfy the following condition: 23≦35.5C+Mn≦38, and the expanded high-strength steel pipe may have a microstructure including 5 area % to 50 area % martensite and 50 area % to 95 area % austenite.
According to another aspect of the present disclosure, a method for manufacturing an expandable high-strength steel material having superior expandability and collapse resistance may include: reheating a steel slab and hot-rolling the steel slab at a finish rolling temperature of 850° C. to 1050° C. to obtain a hot-rolled steel material, the steel slab including, by weight, manganese (Mn): 12% to 18%, carbon (C): 0.3% to 0.6%, and a balance of iron (Fe) and inevitable impurities, the carbon (C) and the manganese (Mn) satisfying the following condition: 23≦35.5C+Mn≦38; and cooling the hot-rolled steel material to a temperature of 600° C. or lower at a rate of 5° C./s or higher.
According to another aspect of the present disclosure, a method for manufacturing an expanded high-strength steel pipe having superior expandability and collapse resistance may include: forming a hot-rolled steel material into a steel pipe; and expanding the steel pipe, wherein the hot-rolled steel material may include, by weight, manganese (Mn): 12% to 18%, carbon (C): 0.3% to 0.6%, and a balance of iron (Fe) and inevitable impurities, the carbon (C) and the manganese (Mn) may satisfy the following condition: 23≦35.5C+Mn≦38, and the hot-rolled steel material has an austenite single phase microstructure.
Embodiments of the present disclosure provide an expandable high-strength steel material, an expanded high-strength steel pipe, and methods for manufacturing the expandable high-strength steel material and the expanded high-strength steel pipe. The expandable high-strength steel material and the expanded high-strength steel pipe have a high degree of uniform elongation and a high degree of expandability, and a high degree of compressive yield strength, owing to martensite formed when the steel pipe is processed to have a circular shape after the steel pipe is formed.
The inventors have conducted research into methods of solving problems of existing expandable steel materials and have obtained the following knowledge. High-manganese steel, which is an austenite-based steel material, has a high degree of uniform elongation, and thus the expandability of the high-manganese steel is high. However, the stability of austenite in a negative segregation zone of the high-manganese steel is low due to an alloying composition difference between the negative segregation and a positive segregation zone. Therefore, if austenite formed in a negative segregation zone is deformed by expansion and is thus transformed into martensite, many dislocations are formed, and the Bauschinger effect is weakened by such dislocations. Based on this knowledge, the inventors invented the present invention.
Exemplary embodiments of the present disclosure will now be described.
Manganese (Mn): 12 wt % to 18 wt %
Manganese (Mn), which is a representative element stabilizing austenite, improves uniform elongation and expandability. In addition, manganese (Mn) segregates in a steel material during a casting process. In an exemplary embodiment of the present disclosure, during expansion, this segregation behavior of manganese (Mn) is used for stabilizing austenite in a positive segregation zone in which manganese (Mn) actively segregates and for transforming austenite into martensite in a negative segregation zone having a relatively low manganese (Mn) content compared to the positive segregation zone. Finally, a steel material having improved collapse resistance owing to a layered structure in which austenite and martensite repeat in the thickness direction of the steel material is provided. However, if the content of manganese (Mn) in the steel material is less than 12 wt %, the stability of austenite is low, and thus martensite may be formed. That is, it may be difficult to maintain an austenite single-phase structure, and thus the expandability of the steel material may be lowered. On the other hand, if the content of manganese (Mn) is greater than 18 wt %, the stability of austenite in a negative segregation zone may be excessively high, and thus transformation from austenite into martensite may not occur in the negative segregation zone even in the case that the negative segregation zone is deformed by expansion. Therefore, it may be preferable that the content of manganese (Mn) be within the range of 12 wt % to 18 wt %. Preferably, the lower limit of the content of manganese (Mn) may be 13 wt %, more preferably, 14 wt %. In addition, preferably, the upper limit of the content of manganese (Mn) may be 17 wt %, more preferably, 16 wt %.
Carbon (C): 0.3 wt % to 0.6 wt %
Carbon (C) is an element stabilizing austenite and improving the degree of uniform elongation, strength, and work hardening of a steel material. Carbon (C) also has a tendency to segregate in a region in which manganese (Mn) segregates, thereby facilitating the formation a layered structure in which austenite and martensite repeat and improving the collapse resistance of a steel material. However, if the content of carbon (C) in a steel material is less than 0.3 wt %, the effects of improving the strength and work hardening of the steel material are low, and the stability of austenite in the steel material may be low to cause austenite-to-martensite transformation. That is, an austenite single phase structure may not be maintained in the steel material, and thus the expandability of the steel material may be lowered. On the other hand, if the content of carbon (C) in the steel material is greater than 0.6 wt %, large amounts of carbides may precipitate, and thus a high degree of expandability may not be obtained. In addition, the stability of austenite formed in a negative segregation zone of the steel material may be excessively high, and thus even in the case that the austenite in the negative segregation zone is deformed by expansion, the austenite may not be transformed into martensite. Therefore, it may be preferable that the content of carbon (C) be within the range of 0.3 wt % to 0.6 wt %. Preferably, the lower limit of the content of carbon (C) may be 0.35 wt %, more preferably, 0.4 wt %. In addition, preferably, the upper limit of the content of carbon (C) may be 0.55 wt %, more preferably, 0.5 wt %.
In an exemplary embodiment of the present disclosure, a steel material may include manganese (Mn) and carbon (C) within the above-mentioned ranges and may satisfy the following composition formula: 23≦35.5C+Mn≦38. If 35.5C+Mn is less than 23, the stability of austenite may be low, and thus it may be difficult to obtain an austenite single phase structure and a desired degree of expandability. On the other hand, if 35.5C+Mn is greater than 38, the stability of austenite may be excessive, and thus even after the steel material is expanded, austenite may not be transformed into martensite in a negative segregation zone, thereby lowering the collapse resistance of the steel material.
If the steel material of the embodiment of the present disclosure has the above-mentioned alloying composition and satisfies the composition formula, the expandability and collapse resistance of the steel material may be superior even in the case that the steel material does not include additional alloying elements. However, due to the reasons described below, the steel material may further include one or more of chromium (Cr): 5 wt % or less and copper (Cu): 2 wt % or less.
Chromium (Cr): 5 wt % or Less
Chromium (Cr) is an element increasing the strength of the steel material. However, if the content of chromium (Cr) in the steel material is greater than 5 wt %, large amounts of carbides may precipitate, and thus the degree of elongation of the steel material may be lowered.
Copper (Cu): 2 wt % or Less
Copper (Cu) is an element improving the degree of elongation of the steel material and the corrosion resistance of the steel material as well. However, if the content of copper (Cu) in the steel material is greater than 2 wt %, the stability of austenite in the steel material may be too high, and thus the austenite may not be transformed into martensite.
In addition, the steel material of the embodiment of the present disclosure may further include a small amount of aluminum (Al). However, since aluminum (Al) stabilizes austenite and hinders austenite from transforming into martensite in the negative segregation zone of the steel material, the negative segregation zone may have an austenite single phase structure even after the steel material is expanded. Therefore, the steel material of the embodiment of the present disclosure may not include aluminum (Al).
The steel material of the embodiment of the present disclosure may have an austenite single phase structure for a high degree of uniform elongation and a high degree of work hardening. However, carbides may inevitably precipitate in the microstructure of the steel material during manufacturing processes, and it may be preferable that the fraction of carbide precipitates in the steel material be controlled to be within an amount of 1 area % or less. If the fraction of carbide precipitates is greater than 1 area %, the degree of elongation of the steel material may be lowered, and the steel material may not have a high degree of expandability.
In the steel material of the embodiment of the present disclosure, austenite existing in the negative segregation zone is transformed into martensite during an expansion process, thereby creating many dislocations in the internal structure of the steel material and forming a layer structure in which the martensite and austenite of a positive segregation zone are repeatedly formed in the thickness direction of the steel material. Thus, the steel material may be less affected by the Bauschinger effect.
In the steel material, it may be preferable that the faction of martensite range from 5 area % to 50 area %, and the fraction of austenite range from 50 area % to 95 area %. If the fraction of martensite is greater than 50 area % or the fraction of austenite is less than 50 area %, cracks may be formed in the martensite due to an excessive fraction of the martensite, and the degree of elongation of the steel material may be lowered due to an insufficient fraction of the austenite. On the other hand, if the fraction of martensite is less than 5 area % or the fraction of austenite is greater than 95 area %, the Bauschinger effect may not be suppressed, and thus the compressive yield strength of the steel material may be lowered.
As described above, according to the embodiment of the present disclosure, the steel material may have the above-described alloying composition and a microstructure including martensite in an amount of 5 area % to 50 area % and austenite in an amount of 50 area % to 95 area %. When an expansion test in which both ends of a sample are fixed is performed on the steel material, the degree of expansion of the steel material may be 30% or greater, and since the steel material has a layer structure in which austenite and martensite are alternately formed, the steel material may have a high compressive yield strength of 500 MPa or greater and thus a high degree of collapse resistance after the steel material is expanded.
Hereinafter, a method for manufacturing a steel material and a steel pipe will be described in detail, according to exemplary embodiments of the present disclosure.
First, a steel slab having the above-described alloying composition is subjected to a reheating process and a hot rolling process to form a hot-rolled steel material. In the above, it may be preferable that the hot rolling process be performed at a finish rolling temperature of 850° C. to 1050° C. If the finish hot rolling temperature is lower than 850° C., carbides may precipitate to result in a decrease in the degree of uniform elongation of the steel slab, and the grains of the microstructure of the steel slab may be changed into pancake grains to result in non-uniform elongation caused by the anisotropy of the microstructure. On the other hand, if the finish hot rolling temperature is higher than 1050° C., grains of the steel slab may become coarse, and the strength of the steel slab may be lowered. Therefore, it may be preferable that the finish hot rolling temperature be within the range of 850° C. to 1050° C. In addition, the reheating process is performed within a temperature range common in the related art. That is, in the embodiments of the present disclosure, the temperature of the reheating process is not particularly limited.
Preferably, the hot-rolled steel material obtained after the hot rolling process may be cooled to a temperature of 600° C. or lower at a rate of 5° C./s or higher, so as to suppress the precipitation of carbides in grain boundaries and thus to prevent a decrease in the expandability of the hot-rolled steel material. If the cooling rate is less then 5° C./s or the cooling stop temperature is higher than 600° C., carbides may precipitate to lower the degree of elongation of the hot-rolled steel material. Therefore, it may be preferable that the hot-rolled steel material be cooled to a temperature of 600° C. or lower at a rate of 5° C. or higher. Preferably, the cooling rate may be 10° C./s or higher, more preferably, 15° C./s or higher. However, it may be difficult to increase the cooling rate to a value greater than 500° C./s due to limitations on process conditions. Since effects of the embodiments of the present disclosure are obtainable as long as the cooling stop temperature is 600° C. or lower, the lower limit of the cooling stop temperature is not particularly limited. Preferably, the cooling stop temperature may be 500° C. or lower.
Thereafter, the hot-rolled steel material cooled as described above is formed into a steel pipe. The steel pipe formed as described above does not have a circular shape, and thus, it may be difficult to use the steel pipe. Therefore, a process for adjusting the shape of the steel pipe to have a circular shape may be performed. In the process, the steel pipe may be contracted or expanded at a strain of 1% to 10%. This is different from the case in which the steel pipe is expanded for being used as a casing after the steel pipe is manufactured.
Hereinafter, the embodiments of the present disclosure will be described more specifically through examples. However, the examples are for clearly explaining the exemplary embodiments and are not intended to limit the scope of the embodiments.
Steel slabs having alloying compositions shown in Table 1 were processed under conditions shown in Table 2 so as to form hot-rolled steel materials. The hot-rolled steel materials were formed into steel pipes, and the steel pipes were processed with a deformation of 5% so that the steel pipes could have a circular shape. Thereafter, the fractions of microstructures in the steel pipes and the expandability of the steel pipes were measured as shown in Table 3. In addition, the steel pipes were expanded at an expansion ratio of 30%, and then the fractions of microstructures of the steel pipes and the compressive yield strength of the steel pipes were measured as shown in Table 3.
22.49
38.10
20
0.15
840
650
98 (carbides
24
97.5 (carbides
21
92.5 (carbides
16
91 (M
23
482
436
As shown in Tables 1 to 3, Inventive samples 1 to 6 satisfying the alloying compositions and process conditions proposed in the embodiments of the present disclosure had an austenite single phase structure before being expanded and a microstructure formed by 5 area % to 50 area % martensite and 50 area % to 95 area % austenite after being expanded, and thus Inventive samples 1 to 6 have superior expandability and compressive yield strength.
Comparative Samples 1 to 3 satisfied the alloying compositions proposed in the embodiments of the present disclosure but did not satisfy the process conditions proposed in the embodiments of the present disclosure. Thus, carbides precipitated in the Comparative Samples 1 to 3 during a rolling process (Comparative Sample 1) or a cooling process (Comparative Sample 2), or after the cooling process (Comparative Sample 3). Therefore, Comparative Samples 1 to 3 had low degrees of uniform elongation and thus low degrees of expansion. In addition, Comparative Samples 1 to 3 were fractured during expansion, and thus compressive yield strength thereof could not be measured.
Comparative Sample 4 did not satisfy the condition (≧23) of the composition formula proposed in the embodiments of the present disclosure, and thus martensite was prematurely formed in a negative segregation zone before expansion and was excessive after expansion. Therefore, Comparative Sample 4 had a low degree of expansion.
Comparative Sample 5 did not satisfy the condition (≦38) in the composition formula proposed in the embodiments of the present disclosure. Thus, austenite was excessively stabilized, and after expansion, the amount of martensite transformed from austenite was low. Therefore, the Bauschinger effect was large, and thus Comparative Sample 5 had a low degree of compressive yield strength.
Comparative Sample 6 had a very low carbon (C) content, and thus even though transformation into martensite occurred, Comparative Sample 6 had a low degree of compressive yield strength due to the low carbon (C) content.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10-2014-0073369 | Jun 2014 | KR | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/KR2014/011531 | 11/28/2014 | WO | 00 |
