WEAR RESISTANT STEEL MATERIAL EXCELLENT IN TOUGHNESS AND INTERNAL QUALITY, AND METHOD FOR MANUFACTURING SAME

Abstract

The present invention relates to a wear resistant steel material which can be suitably used for industrial machinery, structural materials, steel materials for slurry pipes, sour steel materials, mining, transportation and storage fields, etc. in the oil gas industry which require properties such as ductility and wear resistance. More particularly, the present invention relates to a wear resistant steel material excellent in toughness and internal quality, and a method for manufacturing the same.

Description

TECHNICAL FIELD

The present disclosure relates to a wear resistant steel material suitable for use in industrial machinery, structural materials, steel materials for slurry pipes, steel materials in sour service, for use in the mining, transportation and storage fields, or the like, and in the oil gas industry, requiring properties such as ductility and wear resistance. More particularly, the present disclosure relates to a wear resistant steel material excellent in terms of toughness and internal quality, and a method for manufacturing the same.

BACKGROUND ART

In recent years, due to the growth of the mining industry as well as the oil and gas exploration industries, wear of a thick steel material (that is, a thick steel plate) used in mining, transportation, refining, and storage processes, has become a problem.

In detail, as the development of oil sands as a source of fossil fuel to replace petroleum has been regularized, wear of a steel material, caused by a slurry including oil, gravel, and sand, is a main cause of an increase in production costs. Therefore, there is significant demand for the development and application of a steel material excellent in terms of wear resistance.

In the mining industry, according to the related art, Hadfield steel, having excellent wear resistance, has mainly been used. In order to increase the wear resistance of a steel material, it has been attempted to increase an austenitic structure and wear resistance by providing a high content of carbon and a large amount of manganese. However, in the case of Hadfield steel, carbon, added in a large amount, allows carbides to be generated along an austenitic grain boundary in the form of a network at high temperature. Thus, there is a disadvantage, in that material properties of a steel material, in detail, ductility, may be rapidly lowered.

In order to suppress the precipitation of carbides in the form of a network, a method for producing high manganese steel by solution treatment at high temperature or by quenching at room temperature after hot working has been proposed. However, in the case in which a change in manufacturing conditions is problematic, such as in the case in which a thickness of a steel material is high or welding is necessarily involved, it is difficult to suppress the precipitation of the carbides in the form of a network. Therefore, there may be a problem in that material properties of a steel material may be rapidly deteriorated.

Moreover, in the case of an ingot or slab of high manganese steel, segregation of an alloying element such as manganese, carbon, and the like inevitably occurs during solidification.

The occurrence of the segregation is further exacerbated in post-processing such as hot rolling, or the like. As a result, partial precipitation of carbides occurs in the form of a network along a segregation zone, deepened in a final product. Thus, non-uniformity of a microstructure is promoted, and material properties are deteriorated.

As described above, to improve wear resistance of a steel material, it is necessary to increase the content of carbon. To solve the problem in which material properties are deteriorated by carbide precipitation caused by the carbon, relatively increasing the content of manganese may be a common method. However, relatively increasing the content of manganese may result in an increase in an amount of alloys and manufacturing costs.

Therefore, in comparison with the increasing of the content of manganese, it is necessary to develop a technique, capable of suppressing the formation of carbides.

DISCLOSURE

Technical Problem

An aspect of the present disclosure may provide a wear resistant steel material excellent in terms of toughness and internal quality, necessarily containing C and Mn to secure wear resistance, while effectively suppressing deterioration of central properties of a slab and a rolled material caused by the C and Mn.

Technical Solution

According to an aspect of the present disclosure, a wear resistant steel material having excellent toughness and internal quality, includes: carbon (C): 0.6 wt % to 1.3 wt %, manganese (Mn): 14 wt % to 22 wt %, a balance of iron (Fe) and other unavoidable impurities, and has a microstructure including carbides in an area fraction of 5% or less (including 0%) and residual austenite.

According to another aspect of the present disclosure, a method for manufacturing a wear resistant steel material having excellent toughness and internal quality, includes: reheating a steel slab including carbon (C): 0.6 wt % to 1.3 wt %, manganese (Mn): 14 wt % to 22 wt %, a balance of iron (Fe) and other unavoidable impurities; manufacturing a hot-rolled steel plate by finish hot rolling the steel slab, having been reheated, at 850° C. to 1050° C.; and cooling the hot-rolled steel plate at a cooling rate of 5° C./s or more to 600° C. or less, wherein the reheating is performed at a temperature (T, ° C.), represented by Relationship 2, or less.

T(° C.)=1446−(174.459×C)−(3.9507×Mn)  [Relationship 2]

Here, in Relationship 2, C and Mn refer to the weight content of the element.

Advantageous Effects

According to an exemplary embodiment in the present disclosure, a wear resistant steel material in which an internal quality of a steel material, in addition to toughness and wear resistance, is excellent, without the addition of alloying elements other than C and Mn, may be provided.

Moreover, the wear resistant steel material, according to an exemplary embodiment in the present disclosure, may be advantageously applied to a field requiring wear resistance. In detail, a range of applications may be expanded, such as, a field in which toughness and internal quality are required.

DESCRIPTION OF DRAWINGS

FIG. 1 is a microstructure image of Comparative Steel 4 according to an exemplary embodiment of the present disclosure, and a left image illustrates a result in which a defective portion is confirmed using a scanning electron microscope (SEM) in a UT defect test while a right image illustrates a result of EPMA measurement.

BEST MODE FOR INVENTION

The present inventors have intensively researched a method for manufacturing a steel material having excellent internal qualities (material properties, and the like), in addition to wear resistance of a steel material. As a result, while an austenitic steel material, which has a face-centered cubic (fcc) structure, and which is high manganese steel with high contents of carbon and manganese, is used, manufacturing conditions, for controlling a steel central embrittlement problem caused by containing a large amount of carbon and manganese, are optimized. In this case, it is confirmed that a steel material with a required level of wear resistance can be provided, and the present disclosure has been accomplished.

In general, an austenitic steel material has been used for various purposes due to the properties of steel itself such as work hardenability, non-magnetic properties, and the like. In detail, as carbon steel mainly composed of ferrite or martensite, which has been mainly used, has limitations on the required material properties, an application of the austenitic steel material is increasing as a substitute for overcoming shortcomings of the carbon steel mainly composed of ferrite or martensite.

In detail, in the present disclosure, without including additional components other than C and Mn, excellent wear resistance and internal qualities of an austenitic steel material are secured. Moreover, by optimizing manufacturing conditions, not only carbide formation is significantly reduced, but also a degree of segregation of steel material thickness centerline manganese is significantly reduced.

Hereinafter, the present disclosure will be described in detail.

According to one aspect of the present disclosure, in a wear resistant steel material having excellent toughness and internal quality, an alloy composition preferably includes carbon (C): 0.6 wt % to 1.3 wt % and manganese (Mn): 14 wt % to 22 wt %.

Hereinafter, the reason why the alloy composition of the wear resistant steel material provided in the present disclosure is limited as described above will be described in detail. Here, the content of each component means weight % unless otherwise specified.

Carbon (C): 0.6% to 1.3%

Carbon (C), an austenite stabilizing element, serves not only to improve a uniform elongation but also to enhance the strength and increase the strain hardening rate. If the content of carbon is less than 0.6%, it is difficult to form stable austenite at room temperature and it is difficult to secure sufficient strength and strain hardening rate. On the other hand, if the content carbon exceeds 1.3%, a large amount of carbides is precipitated, so the uniform elongation is reduced. Thus, it may be difficult to secure an excellent elongation, and it is not preferable because there are problems of a reduction in wear resistance and early fracture initiation.

Thus, in the present disclosure, the content of C is preferably limited to 0.6 to 1.3%.

Manganese (Mn): 14% to 22%

Manganese (Mn) is an important element for stabilizing austenite and has an effect of improving the uniform elongation. In the present disclosure, to obtain austenite as a main structure, Mn is preferably contained in an amount of 14% or more.

However, if the content of Mn is less than 14%, austenite stability is lowered, and a martensitic structure may be formed. Thus, if an austenitic structure is not sufficiently secured, it may be difficult to secure a sufficient uniform elongation. However, if the content of Mn exceeds 22%, manufacturing costs may be increased. Moreover, it is not preferable because there may be problems of a decrease in corrosion resistance due to the addition of manganese, difficulty in a manufacturing process, and the like.

Thus, in the present disclosure, the content of Mn is preferably limited to 14% to 22%, more preferably, more than 15%.

The remainder of the present disclosure is iron (Fe). However, in a steel manufacturing process according to the related art, impurities, not intended, may be inevitably incorporated from a raw material or a surrounding environment, so such impurities cannot be excluded. All of these impurities are not specifically described in this specification, as they are commonly known to those skilled in the art of steelmaking.

The wear resistant steel material of the present disclosure satisfying an alloy composition described above preferably has an austenitic single phase, as a microstructure. However, it may contain a portion of carbides, inevitably formed in a manufacturing process, and the carbides may be preferably included in an area fraction of 5% or less (including 0%).

The carbides are formed to be concentrated in a grain boundary having higher energy as compared to an interior of a grain. If the carbides are included in an area fraction of more than 5%, ductility is reduced. Thus, there is a problem in that it may be difficult to secure desired levels of toughness, wear resistance, and the like, in the preset disclosure.

The wear resistant steel material, according to the present disclosure, satisfying the alloy composition and microstructure, described above, may secure excellent wear resistance and toughness without the addition of additional alloying elements, other than C and Mn.

In detail, a wear resistant steel material according to the present disclosure has excellent central properties, as compared to an austenitic steel material according to the related art. For example, a degree of segregation of manganese (Mn) in a central portion of a steel material, represented by Relationship 1, is 1.16 or less.

Degree of segregation of Mn=(Mn element in a central portion of steel material)/(Mn element in molten steel)  [Relationship 1]

Here, in Relationship 1, a central portion of a steel material refers to a region of the steel material, located above and below a ½t position in a thickness direction, by 50 μm or less. Here, t refers to a thickness (mm).

If a degree of segregation of manganese (Mn) in a central portion of a wear resistant steel material exceeds 1.16, there may be is problems in that not only the impact toughness is deteriorated but also the UT defect is caused.

Thus, to obtain a wear resistant steel material, having excellent toughness and internal quality required in the present disclosure, a degree of segregation of manganese (Mn) in a central portion is preferably 1.16 or less, and more preferably 1.10 or less.

As described above, a wear resistant steel material according to the present disclosure has technical effects of not only securing toughness but also significantly reducing deterioration of a central portion, even when the content of Mn is high, for example, 14% or more, further more than 15%, without the addition of an additional alloying element, except for C and Mn.

Hereinafter, a method for manufacturing a wear resistant steel material having excellent toughness and internal quality according to another aspect of the present disclosure will be described in detail.

The wear resistant steel material according to the present disclosure could be manufactured by preparing a steel slab satisfying an alloy composition proposed by the present disclosure, and then reheating—hot rolling—cooling the steel slab. Hereinafter, conditions of respective processes will be described in detail

[Reheating of Steel Slab]

In the present disclosure, when a steel slab is reheated, reheating is preferably performed at a temperature (T, ° C.), represented by Relationship 2, or less. In this case, a temperature is preferable to satisfy a temperature range of 1100° C. to 1300° C.

T(° C.)=1446−(174.459×C)−(3.9507×Mn)  [Relationship 2]

Here, in Relationship 2, C and Mn refer to the weight contents of the element.

If the reheating is performed at a temperature exceeding the temperature (T) obtained by Relationship 2, partial melting occurs in segregation in a slab, so a center brittle phenomenon may occur. In detail, after a subsequent hot rolling, as a degree of segregation of manganese in a central portion exceeds 1.16, not only is impact toughness deteriorated, but a UT defect may also be caused. Thus, the reheating, performed at a temperature, exceeding the temperature (T), is not preferable.

[Hot Rolling]

The steel slab, having been reheated, is hot finish rolled to manufacture a hot-rolled steel plate. In the present disclosure, hot finish rolling is preferably performed in a temperature range of 850° C. to 1050° C.

If a temperature during the hot finish rolling is less than 850° C., a large amount of carbides may be precipitated, so a reduction in a uniform elongation may be caused. Moreover, a microstructure may be pancaked, so the difference of elongation along axis caused by structural anisotropy may occur. On the other hand, if a hot finish temperature exceeds 1050° C., there may be a problem in that a crystal grain may easily become coarsening due to the active growth of the crystal grain, so strength is lowered.

The hot-rolled steel plate, obtained as described above, is a thick plate with a relatively high thickness, and preferably has a thickness of 10 mm to 80 mm.

[Cooling]

In the present disclosure, by a process of rapidly cooling the hot-rolled steel plate manufactured as described above, solid solubility of carbon (C) in a matrix structure may be secured to be high. In this case, cooling is preferably performed in a matrix structure at a cooling rate of 5° C./s or more to 600° C. or less.

If the cooling rate is less than 5° C./s or a cooling end temperature exceeds 600° C., there may be a problem in that C is not solidified, but is precipitated as carbides, so an elongation may be lowered.

More preferably, the cooling is performed at a cooling rate of 10° C./s or more, and further more preferably, performed at a cooling rate of 15° C./s or more. However, an upper limit of the cooling rate can be limited to 50° C./s in consideration of the limitation of the cooling facility.

Further, there is no effect on steel properties even if a cooling end temperature is lowered to room temperature. However, a lower limit of the cooling end temperature is limited to 200° C. in consideration of facility efficiency.

[Mode for Invention]

Hereinafter, the present disclosure will be described in more detail with reference to Examples. It should be noted, however, that the embodiments described below are for the purpose of illustrating the present disclosure and are not intended to limit the scope of the present disclosure, since the scope of the present disclosure is determined by the matters described in the claims and matters able to be reasonably deduced therefrom.

Example

A steel slab, satisfying the component system and composition range as illustrated in Table 1, is used through a series of processed illustrated in Table 1 to manufacture hot-rolled steel plate having a thickness of 20 mm.

Then, a microstructure of each of the hot-rolled steel plate having been manufactured, a degree of segregation of Mn in central portion, a UT defect, yield strength, a uniform elongation were measured, and a result thereof is illustrated in Table 2. Moreover, impact toughness (−40° C.) with respect to the hot-rolled steel plate was measured, and a result thereof is illustrated in Table 2.

In this case, a microstructure was observed using an optical microscope, and a degree of segregation of Mn in central portion is illustrated by measuring the content of Mn in a hot-rolled steel plate central portion (a region located above and below a ½t position in a thickness direction, by 50 μm or less) and the content of Mn in molten steel.

Moreover, regarding a UT defect, a ultrasonic test (UT), a non-destructive test to confirm the presence or absence of cracking inside a material using ultrasonic waves, was conducted to determine whether there is a defect (Pass or Fail). In addition, impact toughness at −40° C. was measured using a Charpy impact tester.

	TABLE 1
	Component		Manufacturing Conditions
	Composition		Reheating	Finish Rolling	Cooling	Cooling Stop
	(wt %)	Relationship	Temperature	Temperature	Rate	Temperature
Classification	C	Mn	2	(° C.)	(° C.)	(° C./s)	(° C.)
Inventive	0.65	16.6	1267.0	1231	885	26	380
Steel 1
Inventive	0.80	18.2	1234.5	1201	915	15	210
Steel 2
Inventive	1.09	19.5	1178.8	1164	1023	33	480
Steel 3
Inventive	1.23	14.4	1174.5	1157	995	41	270
Steel 4
Comparative	0.33	15.2	1328.4	1248	1025	21	490
Steel 1
Comparative	1.35	15.8	1148.1	1125	895	18	420
Steel 2
Comparative	0.65	12.2	1284.4	1255	915	28	350
Steel 3
Comparative	1.23	19.1	1156.0	1223	925	18	370
Steel 4
Comparative	0.64	16.4	1269.6	1215	835	21	385
Steel 5
Comparative	0.61	18.3	1267.3	1218	912	4	430
Steel 6
Comparative	0.75	17.6	1245.6	1188	947	22	650
Steel 7

TABLE 2
					Uniform
		Degree of	UT	Yield	Elongation	Impact
		segregation	Defect	Strength	Ratio	Toughness
Classification	Microstructure	of Mn	Test	(MPa)	(%)	(−40° C.)
Inventive	γ + carbide 5%	1.061	Pass	449	52	198
Steel 1	or less
Inventive	γ + carbide 5%	1.079	Pass	408	61	225
Steel 2	or less
Inventive	γ + carbide 5%	1.120	Pass	496	55	210
Steel 3	or less
Inventive	γ + carbide 5%	1.095	Pass	520	48	114
Steel 4	or less
Comparative	γ + carbide 5%	1.066	Pass	266	50	84
Steel 1	or less
Comparative	γ + carbide 8.2%	1.097	Pass	578	20	28
Steel 2
Comparative	γ + M	—	Pass	376	35	17
Steel 3
Comparative	γ + carbide 5%	1.184	Fail	301	52	29
Steel 4	or less
Comparative	γ + carbide 5.7%	1.088	Pass	416	38	48
Steel 5
Comparative	γ + carbide 7.1%	1.039	Pass	428	54	31
Steel 6
Comparative	γ + carbide 6.9%	1.044	Pass	516	45	45
Steel 7

Here, in Table 2, y refers to austenite, and M refers to martensite.

As illustrated in Tables 1 and 2, in the case of Inventive Steels 1 to 4 satisfying the alloy composition and manufacturing conditions proposed in the present disclosure, a steel material is austenitic steel, the strength, elongation, and toughness are excellent, and a degree of segregation of Mn is 1.16% or less. Thus, it is confirmed that internal quality of the steel material is excellent.

On the other hand, in the case of Comparative Steel 1, in which the content of C was insufficient, sufficient strength was not secured. In the case of Comparative Steel 2, in which the content of C was excessive, strength was secured, while ductility could not be secured.

Moreover, in the case of Comparative Steel 3 in which the content of Mn is insufficient, an austenitic phase is not stably formed. Moreover, as martensite is formed in addition to austenite, impact toughness was inferior.

In the case of Comparative Steel 4 to 7, a steel alloy composition satisfies the present disclosure, but a manufacturing condition is outside of the present disclosure. Among Comparative Steel 4 to 7, in the case of Comparative Steel 4, as a reheating temperature is higher than Relationship 2, a degree of segregation of Mn exceeds 1.16. Thus, a result of a UT defect test is fail.

Moreover, Comparative Steel 5 to 7 correspond to the cases, in which a finish hot rolling temperature, a cooling rate, and a cooling end temperature are not satisfied with the present disclosure, respectively. In Comparative Steel 5 to 7, as a large amount of carbides is formed, impact toughness was inferior.

FIG. 1 is a microstructure image of Comparative Steel 4, in which a degree of segregation of Mn in a central portion exceeds 1.16. In this case, as a result of EPMA measurement, it is confirmed that Mn segregation occurred. In a UT defect test, a defective portion could be confirmed.

While exemplary embodiments have been shown and described above, it will be apparent to those skilled in the art that modifications and variations could be made without departing from the scope of the present invention as defined by the appended claims.

Claims

1. A wear resistant steel material having excellent toughness and internal quality, comprising:

carbon (C): 0.6 wt % to 1.3 wt %, manganese (Mn): 14 wt % to 22 wt %, a balance of iron (Fe) and other unavoidable impurities, and

having a microstructure including carbides in an area fraction of 5% or less (including 0%) and residual austenite.

2. The wear resistant steel material having excellent toughness and internal quality of claim 1, wherein the steel material includes manganese (Mn) greater than 15 wt %.

3. The wear resistant steel material having excellent toughness and internal quality of claim 1, wherein the steel material has a degree of segregation of manganese (Mn), represented by Relationship 1, of 1.16 or less.

Degree of segregation of Mn=(Mn element in a central portion of a steel material)/(Mn element in molten steel)  [Relationship 1]

where, in Relationship 1, a central portion of a steel material refers to a region of the steel material, located above and below a ½t position in a thickness direction, by 50 μm or less,

where t refers to a thickness (mm).

4. A method for manufacturing a wear resistant steel material having excellent toughness and internal quality, comprising:

reheating a steel slab including carbon (C): 0.6 wt % to 1.3 wt %, manganese (Mn): 14 wt % to 22 wt %, a balance of iron (Fe) and other unavoidable impurities;

manufacturing a hot-rolled steel plate by finish hot rolling the steel slab, having been reheated, at 850° C. to 1050° C.; and

cooling the hot-rolled steel plate at a cooling rate of 5° C./s or more to 600° C. or less,

wherein the reheating is performed at a temperature (T, ° C.), represented by Relationship 2, or less. T(° C.)=1446−(174.459×C)−(3.9507×Mn)  [Relationship 2]

where, in Relationship 2, C and Mn refer to the weight content of the element.

5. The method for manufacturing a wear resistant steel material having excellent toughness and internal quality of claim 4, wherein the steel slab includes manganese (Mn) greater than 15 wt %.

6. The method for manufacturing a wear resistant steel material having excellent toughness and internal quality of claim 4, wherein the hot-rolled steel plate has a thickness of 10 mm to 80 mm.