WO2020145325A1 - 鋼材 - Google Patents
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- WO2020145325A1 WO2020145325A1 PCT/JP2020/000367 JP2020000367W WO2020145325A1 WO 2020145325 A1 WO2020145325 A1 WO 2020145325A1 JP 2020000367 W JP2020000367 W JP 2020000367W WO 2020145325 A1 WO2020145325 A1 WO 2020145325A1
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- C21D8/00—Modifying the physical properties by deformation combined with, or followed by, heat treatment
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- C21D8/00—Modifying the physical properties by deformation combined with, or followed by, heat treatment
- C21D8/06—Modifying the physical properties by deformation combined with, or followed by, heat treatment during manufacturing of rods or wires
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- C21D2211/00—Microstructure comprising significant phases
- C21D2211/003—Cementite
Definitions
- the present invention relates to a steel material, and more specifically to a steel material that is a raw material for carburized steel parts.
- a steel material that is a raw material of a machine structural part (carburized steel part) to be carburized generally contains Mn, Cr, Mo, Ni, and the like.
- the steel material used as the material of the carburized steel part is manufactured by casting, forging, rolling, or the like.
- a carburized steel part is manufactured by the following method, for example.
- the above steel materials are forged.
- a cutting process is performed on the steel material after forging to manufacture an intermediate member.
- Carburizing is performed on the intermediate member.
- a carburized steel part including the carburized layer which is the hardened layer of the surface layer and the core which is the base material which is not affected by the carburizing treatment is manufactured.
- Forging methods can be roughly classified into hot forging, warm forging, and cold forging. Warm forging is carried out in a lower temperature range than hot forging. Therefore, the warm forging produces less scale than the hot forging, and the dimensional accuracy is improved as compared with the hot forging. On the other hand, in cold forging, no scale is generated and the dimensional accuracy is equivalent to that of cutting.
- Patent Document 1 is a stage of carburizing steel before carburizing treatment, in which the deformation resistance during cold forging is smaller than that of the conventional steel, and the critical working rate is large, and further, after carburizing treatment, the hardening is equivalent to that of the conventional steel.
- the steel for carburization described in Patent Document 1 has a chemical composition of mass% C: 0.07% to 0.13%, Si: 0.0001% to 0.50%, Mn: 0.0001% to.
- each unavoidable impurity in mass% of each element in the chemical composition is the following formula 1 as a hardness index, the following formula 2 as a hardenability index, and the following formula as a TiC precipitation amount index. It is characterized by satisfying 3 at the same time.
- carburized steel parts are used for the mechanical structural parts used in automobiles.
- carburized steel parts are also used in variable diameter pulleys of continuously variable transmissions (CVTs).
- CVTs continuously variable transmissions
- Large-sized carburized steel parts represented by variable-diameter pulleys are manufactured by hot forging and cutting as described above. Therefore, even for large carburized steel parts, a technology for replacing cutting work with forging is being studied.
- a large steel material is to be formed by cold forging, an excessive load is applied to the cold forging machine. Therefore, when forming large carburized steel parts by cold forging, multiple members are formed by cold forging, and then these multiple members are joined by welding such as friction joining or laser joining, and then joined.
- Technology for manufacturing large-sized carburized steel parts by carburizing steel members has been studied.
- the purpose of the present disclosure is to provide a steel material that can obtain excellent fatigue strength after carburizing even when welding is performed.
- the steel material according to the present disclosure is In mass %, C: 0.09 to 0.16%, Si: 0.01 to 0.50%, Mn: 0.40-0.60%, P: 0.030% or less, S: 0.025% or less, Cr: 0.90 to 2.00%, Mo: 0.10-0.40%, Al: 0.005 to 0.030%, Ti: 0.010 to less than 0.050%, Nb: 0.010 to 0.030%, N: 0.0080% or less, O: 0.0030% or less, B: 0.0003 to 0.0030%, Ca: 0.0005 to 0.0050% is contained,
- the balance consists of Fe and impurities, and satisfies the formulas (1) to (3), In a cross section parallel to the axial direction of the steel material, 70% of Mn sulfide has a Mn content of 10.0% or more, a S content of 10.0% or more, and an O content of less than 10.0% in mass %.
- the oxide O content is 10.0% or more by mass% is 25.0 cells / mm 2 or less.
- 0.140 ⁇ C+0.194 ⁇ Si+0.065 ⁇ Mn+0.012 ⁇ Cr+0.033 ⁇ Mo+0.067 ⁇ Ni+0.097 ⁇ Cu+0.078 ⁇ Al ⁇ 0.235 Formula (1) 13.0 ⁇ (0.70 ⁇ Si+1) ⁇ (5.1 ⁇ Mn+1) ⁇ (2.2 ⁇ Cr+1) ⁇ (3.0 ⁇ Mo+1) ⁇ (0.36 ⁇ Ni+1) ⁇ 45.0 Formula (2 ) 0.004 ⁇ Ti-N ⁇ (48/14) ⁇ 0.030 Formula (3)
- the content (mass %) of the corresponding element is substituted for each element symbol in the formulas (1) to (3). When the corresponding element is not contained, "0" is substituted for the element symbol.
- the steel material according to the present disclosure can obtain excellent fatigue strength in carburized steel parts after carburizing even when welding is performed.
- FIG. 1 is a cross-sectional view perpendicular to the longitudinal direction of the steel material of this embodiment.
- FIG. 2 is a schematic diagram for explaining a sampling position for observing the microstructure of the steel material according to this embodiment.
- FIG. 3 is a schematic diagram for explaining the sampling positions of samples when measuring Mn sulfides and oxides in the present embodiment.
- the steel material according to the present embodiment which is a material for carburized steel parts, will be described below.
- the inventors of the present invention conducted a study to obtain excellent properties (improvement in effective hardened layer depth and core hardness) of a carburized steel part after carburizing in a steel material which is a material of the carburized steel part. As a result, the present inventors have obtained the following findings (a) to (f).
- alloying elements such as Mn, Cr, Mo, Ni that improve the hardenability of steel. It is effective to contain the amount so as to satisfy the above-mentioned formula (2) of the hardenability index. 13.0 ⁇ (0.70 ⁇ Si+1) ⁇ (5.1 ⁇ Mn+1) ⁇ (2.2 ⁇ Cr+1) ⁇ (3.0 ⁇ Mo+1) ⁇ (0.36 ⁇ Ni+1) ⁇ 45.0 (2)
- (F) B effectively enhances the hardenability of the core of carburized steel parts.
- the effect of improving the hardenability by containing B is low. This is because at the time of carburizing treatment, nitrogen invades from the surface of the steel part, combines with solid solution B and precipitates as BN, and the amount of solid solution B is reduced. Therefore, in order to secure the hardenability in the carburized layer which is the surface layer of the carburized steel part, it is effective to satisfy the formula (2) of the hardenability index described in (c) above.
- the present inventors further examined the fatigue strength (joint fatigue strength) of a carburized steel part manufactured by carburizing after welding in the steel material of the present embodiment.
- the fatigue strength of the carburized steel part manufactured by carburizing after welding It was found that the joint fatigue strength
- Mn sulfide having a Mn content of 10.0% or more, an S content of 10.0% or more, and an O content of less than 10.0% is 70.0 pieces/mm 2 or less in mass %.
- the amount of oxide having an O content of 10.0% or more in mass% is set to 25.0 pieces/mm 2 or less.
- Mn sulfide and oxide are present in the steel material.
- Mn sulfides and oxides are defined as follows.
- Mn sulfide When the mass% of inclusions is 100%, the Mn content is 10.0% or more, the S content is 10.0% or more, and the O content is less than 10.0% in mass %.
- Certain inclusions Oxide Inclusions having an oxygen content of 10.0% or more in mass% when the mass% of inclusions is 100%. In the present specification, mass% of inclusions Then, the inclusions containing 10.0% or more of S, 10.0% or more of Mn, and 10.0% or more of O are included in the “oxide” rather than the “Mn sulfide”. ..
- a carburized steel part When a carburized steel part is manufactured by carrying out carburizing treatment after performing welding such as friction welding and laser welding on steel materials, there is a HAZ area in the carburized steel part.
- the intensity of the HAZ region may be lower than the intensity of other regions. Therefore, in the present embodiment, inclusions are reduced as much as possible in order to secure the strength of the HAZ region.
- the number of Mn sulfides and oxides occupying most of the inclusions in the steel is reduced. In this case, the strength of the HAZ region can be secured, and as a result, the fatigue strength of the carburized steel part can be increased.
- the steel material of the present embodiment completed based on the above knowledge has the following configuration.
- the oxide O content is 10.0% or more by mass% is 25.0 cells / mm 2 or less, Steel material.
- 0.140 ⁇ C+0.194 ⁇ Si+0.065 ⁇ Mn+0.012 ⁇ Cr+0.033 ⁇ Mo+0.067 ⁇ Ni+0.097 ⁇ Cu+0.078 ⁇ Al ⁇ 0.235 (1) 13.0 ⁇ (0.70 ⁇ Si+1) ⁇ (5.1 ⁇ Mn+1) ⁇ (2.2 ⁇ Cr+1) ⁇ (3.0 ⁇ Mo+1) ⁇ (0.36 ⁇ Ni+1) ⁇ 45.0 (2) 0.004 ⁇ Ti-N ⁇ (48/14) ⁇ 0.030 (3)
- the content (mass %) of the corresponding element is substituted for each element symbol in the formulas (1) to (3). When the corresponding element is not contained, "0" is substituted for the element symbol.
- the steel material of the present embodiment is a material for carburized steel parts.
- the steel material of the present embodiment is cold forged and then carburized to be a carburized steel part.
- the chemical composition of the steel material of this embodiment contains the following elements.
- Carbon (C) enhances the hardenability of the steel material and enhances the hardness of the core portion in the carburized steel component including the carburized layer and the core portion.
- C content is less than 0.09%, the hardness of the core portion of the carburized steel component is reduced even if the content of other elements is within the range of this embodiment.
- the C content exceeds 0.16%, the hardness of the steel material before cold forging remarkably increases even if the content of other elements is within the range of the present embodiment, and the critical working ratio is descend. Therefore, the C content is 0.09 to 0.16%.
- the C content of the steel material used as the material of the conventional carburized steel part is about 0.20%.
- the C content of the steel material of the present embodiment is lower than that of the conventional steel material.
- the preferable lower limit of the C content is 0.10%, more preferably 0.11%.
- the preferable upper limit of the C content is 0.15%, more preferably 0.14%.
- Si 0.01 to 0.50%
- Silicon (Si) enhances the temper softening resistance of the carburized steel part and enhances the surface fatigue strength of the carburized steel part. If the Si content is less than 0.01%, the above effect cannot be obtained even if the content of other elements is within the range of this embodiment. On the other hand, if the Si content exceeds 0.50%, the hardness of the steel material before cold forging increases and the critical working rate decreases even if the content of other elements is within the range of this embodiment. .. Therefore, the Si content is 0.01 to 0.50%. When importance is attached to the surface fatigue strength of the carburized steel part, the preferable lower limit of the Si content is 0.02%. In the case of emphasizing the improvement of the limit working rate of the carburized steel part, the preferable upper limit of the Si content is 0.48%, more preferably 0.46%.
- Mn 0.40-0.60%
- Manganese (Mn) enhances the hardenability of steel and enhances the strength of the core of carburized steel parts. If the Mn content is less than 0.40%, even if the content of other elements is within the range of this embodiment, this effect cannot be sufficiently obtained. On the other hand, if the Mn content exceeds 0.60%, the hardness of the steel material before forging increases and the critical working rate decreases even if the content of other elements is within the range of this embodiment. Therefore, the Mn content is 0.40 to 0.60%.
- the preferable lower limit of the Mn content is 0.42%, more preferably 0.44%.
- the preferable upper limit of the Mn content is 0.58%, more preferably 0.56%.
- Phosphorus (P) is an unavoidable impurity. That is, the P content is more than 0%. P segregates at the austenite grain boundaries and embrittles the old austenite grain boundaries, causing grain boundary cracking. Therefore, the P content is 0.030% or less.
- the preferable upper limit of the P content is 0.026%, more preferably 0.024%. It is preferable that the P content is as low as possible. However, if the P content is reduced to the utmost, the productivity will decrease and the manufacturing cost will increase. Therefore, in normal operation, the preferable lower limit of the P content is 0.001%.
- S 0.025% or less Sulfur (S) is unavoidably contained. That is, the S content is more than 0%. S combines with Mn to form MnS and improves the machinability of the steel material. If the S content exceeds 0%, this effect can be obtained to some extent. On the other hand, when the S content exceeds 0.025%, coarse MnS is generated and cracks are likely to occur during forging even if the content of other elements is within the range of the present embodiment, and the limit of the steel material is The processing rate decreases. Therefore, the S content is 0.025% or less.
- the preferable upper limit of the S content is 0.022%, more preferably 0.020%. In order to improve the machinability more effectively, the preferable lower limit of the S content is 0.001%, more preferably 0.002%, and further preferably 0.003%.
- Chromium (Cr) enhances the hardenability of steel and enhances the strength of the core of carburized steel parts. If the Cr content is less than 0.90%, this effect cannot be sufficiently obtained even if the content of other elements is within the range of this embodiment. On the other hand, if the Cr content exceeds 2.00%, the hardness of the steel material before forging increases and the critical working rate decreases even if the content of other elements is within the range of this embodiment. Therefore, the Cr content is 0.90 to 2.00%.
- the preferable lower limit of the Cr content is 0.95%, more preferably 1.00%, and further preferably 1.10%.
- the preferable upper limit of the Cr content is 1.95%, more preferably 1.92%.
- Mo 0.10-0.40% Molybdenum (Mo) enhances the hardenability of steel and enhances the strength of the core of carburized steel parts. If the Mo content is less than 0.10%, this effect cannot be sufficiently obtained even if the content of other elements is within the range of the present embodiment. On the other hand, when the Mo content exceeds 0.40%, the hardness of the steel material before forging increases and the critical working rate decreases even if the content of other elements is within the range of this embodiment. Therefore, the Mo content is 0.10 to 0.40%.
- the preferable lower limit of the Mo content is 0.11%, more preferably 0.12%, and further preferably 0.13%.
- the preferable upper limit of the Mo content is 0.38%, more preferably 0.36%, and further preferably 0.34%.
- Al 0.005 to 0.030%
- Aluminum (Al) deoxidizes steel in the steelmaking process. Al also forms AlN when solid solution N is present in the steel. However, in the steel material according to the present embodiment, N in the steel is fixed as TiN by adding Ti. Therefore, solid solution N hardly exists in the steel material. As a result, Al does not form AlN and exists as a solid solution Al in the steel material. Al existing in a solid solution state improves the machinability of the steel material. If the Al content is less than 0.005%, the above effects cannot be sufficiently obtained even if the content of other elements is within the range of the present embodiment.
- the Al content is 0.005 to 0.030%.
- the preferable lower limit of Al is 0.010%, more preferably 0.011%, and further preferably 0.012%.
- the preferable upper limit of Al is 0.025%, more preferably 0.022%, and further preferably 0.020%.
- Titanium (Ti) fixes N in the steel material as TiN and suppresses the formation of BN. As a result, Ti secures the amount of solid solution B and improves the hardenability of the steel material. Ti further forms TiC to suppress coarsening of crystal grains during the carburizing process. If the Ti content is less than 0.010%, the above effects cannot be sufficiently obtained even if the content of other elements is within the range of this embodiment. On the other hand, if the Ti content is 0.050% or more, the TiC precipitation amount becomes excessively large even if the content of other elements is within the range of the present embodiment. In this case, the critical working rate of the steel material before cold forging decreases.
- the Ti content is 0.010 to less than 0.050%.
- the preferable lower limit of the Ti content is 0.012%, more preferably 0.014%, further preferably 0.016%, further preferably 0.018%.
- the preferable upper limit of the Ti content is 0.048%, more preferably 0.046%, further preferably 0.044%, further preferably 0.042%, further preferably 0.040%. %.
- Nb 0.010 to 0.030%
- Nb niobium
- Nb carbonitride suppresses coarsening of crystal grains due to the pinning effect. If the Nb content is less than 0.010%, the above effects cannot be sufficiently obtained even if the content of other elements is within the range of the present embodiment. On the other hand, if the Nb content exceeds 0.030%, the effect is saturated. Therefore, the Nb content is 0.010 to 0.030%.
- the preferable lower limit of the Nb content is 0.011%, more preferably 0.012%, further preferably 0.013%, further preferably 0.014%.
- the preferable upper limit of the Nb content is 0.029%, more preferably 0.028%, further preferably 0.027%, further preferably 0.026%, further preferably 0.025. %.
- N 0.0080% or less Nitrogen (N) is an unavoidable impurity. That is, the N content in the steel material is more than 0%. N combines with B to form BN and reduces the amount of solid solution B. In this case, the hardenability of the steel material deteriorates. If the N content exceeds 0.0080%, it becomes impossible to fix N in the steel as TiN even if it contains 0.010 to less than 0.050% Ti, and the solid content that contributes to hardenability It becomes difficult to secure the molten B. Further, coarse TiN is formed. Coarse TiN becomes a starting point of cracking during forging, and lowers the critical working rate of the steel material before forging. Therefore, the N content is 0.0080% or less.
- the preferable upper limit of the N content is 0.0078%, more preferably 0.0076%, further preferably 0.0074%, further preferably 0.0072%.
- the N content is preferably as low as possible. However, if the N content is reduced to the utmost, the productivity will decrease and the manufacturing cost will increase. Therefore, in normal operation, the lower limit of the N content is preferably 0.0001%, more preferably 0.0010%, and further preferably 0.0020%.
- Oxygen (O) is an unavoidable impurity. That is, the O content in the steel material is more than 0%. O forms an oxide and reduces the bondability when welding a steel material before carburizing. In this case, the fatigue strength of the carburized steel part is reduced. Therefore, the O content is 0.0030% or less.
- the preferable upper limit of the O content is 0.0029%, more preferably 0.0028%, further preferably 0.0026%, further preferably 0.0024%, further preferably 0.0022. %. The lower the O content, the better. However, if the O content is reduced to the utmost, the productivity will decrease and the manufacturing cost will increase. Therefore, in normal operation, the lower limit of the O content is preferably 0.0001%, more preferably 0.0005%, and further preferably 0.0010%.
- B 0.0003 to 0.0030% Boron (B) enhances the hardenability of steel and enhances the strength of carburized steel parts. If the B content is less than 0.0003%, the above effects cannot be sufficiently obtained even if the content of other elements is within the range of the present embodiment. On the other hand, if the B content exceeds 0.0030%, the above effect is saturated. Therefore, the B content is 0.0003 to 0.0030%.
- the preferable lower limit of the B content is 0.0004%, more preferably 0.0005%, further preferably 0.0006%, further preferably 0.0007%.
- the preferable upper limit of the B content is 0.0028%, more preferably 0.0026%, and further preferably 0.0024%.
- Ca 0.0005 to 0.0050%
- Calcium (Ca) is contained in the oxide to make the oxide spherical. Spheroidized oxides are unlikely to form clusters. Ca also suppresses the stretching of Mn sulfide. If the Ca content is less than 0.0005%, the above effects cannot be sufficiently obtained even if the content of other elements is within the range of this embodiment. On the other hand, if the Ca content exceeds 0.0050%, coarse sulfides and coarse oxides are formed, and the fatigue strength of carburized steel parts is reduced. Therefore, the Ca content is 0.0005 to 0.0050%.
- the preferable lower limit of the Ca content is 0.0006%, more preferably 0.0007%, further preferably 0.0008%, further preferably 0.0009%, further preferably 0.0010. %, and.
- the preferable upper limit of the Ca content is 0.0048%, more preferably 0.0046%, further preferably 0.0040%, further preferably 0.0035%.
- Remainder Fe and impurities
- the balance of the chemical composition of the steel material according to the present embodiment is Fe and impurities.
- the impurities when industrially manufacturing the steel material, ore as a raw material, scrap, or those that are mixed from the manufacturing environment, etc., components that are not intentionally included in the steel material means.
- the chemical composition of the steel material of the present embodiment may contain one kind or two or more kinds selected from the group consisting of Cu, Ni, and V, instead of part of Fe. All of these elements enhance the strength of carburized steel parts.
- Cu 0.50% or less Copper (Cu) is an optional element and may not be contained. That is, the Cu content may be 0%. When Cu is contained, that is, when the Cu content exceeds 0%, Cu enhances the hardenability of the steel material and enhances the strength of the carburized steel part. Further, Cu is an element that does not form an oxide or a nitride in a gas carburizing gas atmosphere. Therefore, when Cu is contained, it becomes difficult to form an oxide layer or a nitride layer on the surface of the carburized layer, or an abnormal carburized layer due to them. If Cu is contained even a little, the above effect can be obtained to some extent.
- the Cu content is 0.50% or less. That is, the Cu content is 0 to 0.50%.
- the preferable lower limit of the Cu content is more than 0%, more preferably 0.01%, further preferably 0.02%, further preferably 0.05%.
- the preferable upper limit of the Cu content is 0.45%, more preferably 0.40%, further preferably 0.35%.
- Nickel (Ni) is an optional element and may not be contained. That is, the Ni content may be 0%.
- Ni When Ni is contained, that is, when the Ni content exceeds 0%, Ni enhances the hardenability of the steel material and enhances the strength of the carburized steel part. If Ni is contained even a little, the above effect can be obtained to some extent.
- the Ni content exceeds 0.30%, the hardness of the steel material before forging increases and the critical working rate decreases even if the content of other elements is within the range of this embodiment. Therefore, the Ni content is 0.30% or less. That is, the Ni content is 0 to 0.30%.
- the preferable lower limit of the Ni content is 0.01%, more preferably 0.02%, and further preferably 0.05%.
- the preferable upper limit of the Ni content is 0.29%, more preferably 0.28%, and further preferably 0.25%.
- V 0.10% or less Vanadium (V) is an optional element and may not be contained. That is, the V content may be 0%. When V is contained, that is, when the V content is more than 0%, V forms a carbide and enhances the strength of the core portion of the carburized steel component. If V is contained even a little, the above effect can be obtained to some extent. However, if the V content exceeds 0.10%, the cold forgeability of the steel material deteriorates and the marginal workability decreases even if the content of other elements is within the range of this embodiment. Therefore, the V content is 0.10% or less. That is, the V content is 0 to 0.10%.
- the preferable lower limit of the V content is 0.01%, more preferably 0.02%, further preferably 0.03%.
- the preferable upper limit of the V content is 0.09%, and more preferably 0.08%.
- F1 C+0.194 ⁇ Si+0.065 ⁇ Mn+0.012 ⁇ Cr+0.033 ⁇ Mo+0.067 ⁇ Ni+0.097 ⁇ Cu+0.078 ⁇ Al.
- F1 is an index of hardness of a carburized steel part manufactured from a steel material.
- the C content is as low as 0.16% or less. Therefore, in the structure of the steel material before forging, the ferrite fraction is significantly increased as compared with the conventional steel material having a C content of about 0.20%. In this case, the hardness of the steel material is greatly affected not only by the C content (perlite fraction) but also by the hardness of ferrite. F1 indicates the contribution of each alloying element to the solid solution strengthening of ferrite.
- F1 is 0.235 or more, the hardness of the steel material before cold forging is too high. In this case, the limit working rate of the steel material decreases.
- F1 is 0.140 or less, the core hardness as a carburized steel component is insufficient. Therefore, F1 is more than 0.140 and less than 0.235.
- F1 is preferably as low as possible within a range that satisfies the hardenability index (F2) described later.
- the preferable upper limit of F1 is less than 0.230, more preferably 0.225, further preferably 0.220, further preferably 0.215, and further preferably 0.210.
- the F1 value is a value obtained by rounding the calculated value to the fourth decimal place.
- B is effective in enhancing the hardenability of steel materials and enhancing the hardness of the core of carburized steel parts.
- gas carburizing metalmorphic furnace gas system
- the effect of improving the hardenability due to B content is low. This is because N in the atmosphere gas in the furnace invades the surface layer of the carburized steel part during the carburizing process, so that the solid solution B is precipitated as BN, and the amount of the solid solution B contributing to the improvement of the hardenability is insufficient. ..
- B can increase the hardness of the core of the carburized steel component, it hardly contributes to the improvement of the hardness of the carburized layer of the carburized steel component. Therefore, in order to secure the hardenability in the carburized layer which is the surface layer of the carburized steel part, it is necessary to utilize a hardenability improving element other than B.
- F2 is composed of elements other than B that contribute to quenching improvement.
- the carburizing layer depth Vickers hardness is HV550 or more
- C content is about 0.20%. It is impossible to obtain a sufficient depth.
- F2 is 45.0 or more, the hardness of the steel material before cold forging increases and the critical working rate decreases. Therefore, F2 is more than 13.0 and less than 45.0.
- F2 is preferably as large as possible within the range that satisfies the hardness index F1.
- the preferable lower limit of F2 is 13.2, more preferably 13.5, further preferably 14.0, further preferably 14.5, further preferably 15.0.
- the F2 value is a value obtained by rounding off the second decimal place of the calculated value.
- Equation (3) TiC precipitation amount index
- F3 Ti ⁇ N ⁇ (48/14).
- F3 is an index related to the amount of TiC precipitation. When Ti is contained stoichiometrically in excess with respect to N, all of N is fixed as TiN. That is, F3 means an excessive Ti amount other than the Ti amount consumed for forming TiN.
- “14” in F3 is the atomic weight of N, and “48” is the atomic weight of Ti.
- TiC has a pinning effect of preventing coarsening of crystal grains during carburization. If the content of each element in the chemical composition of the steel material satisfies the numerical range of the above-described embodiment and F3 is 0.004 or less, the TiC precipitation amount is insufficient. In this case, it is not possible to suppress the crystal grain coarsening during the carburizing treatment. As a result, the toughness of the carburized steel parts is reduced and the amount of deformation of the steel material after the carburizing treatment is increased.
- F3 is more than 0.004 and less than 0.030.
- the preferable lower limit of F3 is 0.006, and more preferably 0.008.
- the preferable upper limit of F3 is 0.028, and more preferably 0.025.
- the F3 value is a value obtained by rounding the calculated value to the fourth decimal place.
- a steel material having a chemical composition that simultaneously satisfies a hardness index F1, a hardenability index F2, and a TiC precipitation amount index F3 has a critical working rate during cold forging that is lower than that of conventional steel by performing spheroidizing heat treatment. growing. Then, after the carburizing treatment of this steel material, a carburized steel part having the same hardened layer and core hardness as the conventional steel can be obtained.
- Mn sulfides and oxides in the steel satisfy the following conditions in a cross section parallel to the axial direction of the steel material (that is, the longitudinal direction of the steel material).
- Mn sulfide having a Mn content of 10.0% or more, an S content of 10.0% or more, and an O content of less than 10.0% in mass% is 70.0 pieces/mm 2 or less. is there.
- Mn sulfides and oxides are defined as follows.
- Mn sulfide When the mass% of inclusions is 100%, the Mn content is 10.0% or more, the S content is 10.0% or more, and the O content is less than 10.0% in mass %.
- Certain inclusions Oxide Inclusions having an O content of 10.0% or more in mass% when the mass% of inclusions is 100%.
- the intermediate member before carburizing is integrally manufactured by joining a plurality of steel members by welding such as friction welding or laser welding
- the intermediate member is carburized.
- the HAZ region may have a lower joint fatigue strength than other regions.
- inclusions in the steel material are reduced as much as possible. If the Mn sulfide and oxide satisfy the above (I) and (II), the joining fatigue strength in the HAZ region can be secured. As a result, the joint fatigue strength of the carburized steel parts integrated by joining can be increased.
- Mn Sulfide and Oxide Measuring Method The number of Mn sulfides and the number of oxides in steel can be measured by the following method.
- a sample is taken from the steel material. Specifically, as shown in FIG. 3, samples are taken from the center axis C1 of the steel material 1 in the radial direction at the R/2 position (R is the radius of the steel bar).
- the size of the observation surface of the sample is L1 ⁇ L2, L1 is 10 mm, and L2 is 5 mm. Further, the sample thickness L3, which is the direction perpendicular to the observation surface, is set to 5 mm.
- the normal line N of the observation surface is perpendicular to the central axis C1 (that is, the observation surface is parallel to the axial direction of the steel material), and the R/2 position is substantially the center position of the observation surface.
- the observation surface of the collected sample is mirror-polished, and 20 fields of view (evaluation area per field of view 100 ⁇ m ⁇ 100 ⁇ m) are randomly observed with a scanning electron microscope (SEM) at a magnification of 1000 times.
- SEM scanning electron microscope
- EDX Energy-dispersive X-ray spectroscopy
- elemental analysis is performed using EDX at at least two measurement points for each inclusion.
- the arithmetic mean value of the element contents obtained at each measurement point is defined as the content (mass %) of each element in the inclusion.
- the arithmetic mean value of Mn content is defined as the content (mass %) of each element in the inclusion.
- Mn sulfurization of inclusions having a Mn content of 10.0% or more, an S content of 10.0% or more, and an O content of less than 10.0% in mass% is performed.
- Ti and Ca may be detected as elements other than Mn and S.
- Mn sulfide if all of the above conditions are satisfied, it is defined as Mn sulfide.
- the inclusion having an O content of 10.0% or more is defined as an oxide.
- oxides Al, Si, Mg, Ca, Ti, etc. may be detected. Also in this case, if the above conditions are satisfied, it is identified as an oxide.
- inclusions containing 10.0% or more of S, 10.0% or more of Mn, and 10.0% or more of O in mass% are identified as oxides.
- the inclusions to be identified above should have an equivalent circle diameter of 0.5 ⁇ m or more.
- the equivalent circle diameter means the diameter of a circle when the area of each inclusion is converted into a circle having the same area.
- the accuracy of elemental analysis increases if the equivalent diameter of the circle is more than twice the diameter of the EDX beam.
- the beam diameter of the EDX used to identify the inclusion is 0.2 ⁇ m.
- inclusions having an equivalent circle diameter of less than 0.5 ⁇ m cannot improve the accuracy of elemental analysis by EDX.
- Inclusions having an equivalent circle diameter of less than 0.5 ⁇ m have a very small effect on fatigue strength. Therefore, in the present embodiment, Mn sulfides and oxides having a circle equivalent diameter of 0.5 ⁇ m or more are set as measurement targets.
- the upper limit of the equivalent circle diameter of Mn sulfide and oxide is not particularly limited, but is 100 ⁇ m, for example.
- the number of Mn sulfides per unit area (number/mm 2 ) is determined based on the total number of Mn sulfides specified in each field of view and the total area of 20 fields of view. Further, the number of oxides per unit area (number/mm 2 ) is calculated based on the total number of oxides specified in each visual field and the total area of 20 visual fields.
- the content of each element in the chemical composition is within the above range, the hardness index F1 satisfies the formula (1), the hardenability index F2 satisfies the formula (2), The TiC precipitation amount index F3 satisfies the formula (3).
- Mn sulfide having a Mn content of 10.0% or more, a S content of 10.0% or more and an O content of less than 10.0% in mass% is 70.0 pieces/mm 2 or less and 25.0 pieces/mm 2 or less of oxides having an O content of 10.0% or more in mass %. Therefore, even if welding is performed before the carburizing treatment, the carburized steel parts after the carburizing treatment have excellent fatigue strength.
- the microstructure of the steel material of this embodiment is not particularly limited.
- the steel material of the present embodiment may be an as-rolled material (that is, an As-rolled material) or may be spheroidized.
- the radius in the cross section perpendicular to the axial direction (longitudinal direction) of the steel material of this embodiment is defined as R (mm).
- the microstructure in the cross section perpendicular to the axial direction of the steel material is any of the following (A) and (B).
- A) In the microstructure the area ratio of bainite in the surface layer region at least from the surface to the depth of 0.1R is 95.0% or more.
- the microstructure of (A) is a microstructure in the case where the steel material of the present embodiment is an as-rolled material.
- the microstructure of the above (B) is a microstructure when the steel material of the present embodiment is spheroidized.
- FIG. 1 is a cross-sectional view perpendicular to the longitudinal direction (axial direction) of the steel material of this embodiment.
- the radius of the steel material 1 is defined as R (mm).
- the region from the surface of the steel material 1 to the depth R of 0.1R is defined as the “surface layer region”. That is, the depth D (mm) means 10% of the radius R.
- the surface layer region has a bainite structure in the cross section perpendicular to the axial direction of the steel material, as described in (A).
- “having a bainite structure” means that the bainite area ratio is 95.0% or more.
- the bainite area ratio of at least the surface layer region D is 95.0% or more in the cross section perpendicular to the axial direction of the steel material 1 of this embodiment.
- “at least the surface layer region has a bainite structure” means that the bainite region may be formed not only in the surface layer region but also in a region deeper than the surface layer region. Specifically, in FIG.
- the depth of the bainite structure from the surface may be at least 0.1R, and the depth of the bainite structure may be deeper than 0.1R.
- the depth of the bainite structure may be 0.2R, 0.3R, or 1.0R. That is, the entire cross section of the steel material 1 perpendicular to the axial direction may have a bainite structure.
- the microstructure of the steel material of the present embodiment may be (B) instead of (A).
- at least the surface layer region has a spheroidized cementite structure in the cross section perpendicular to the axial direction of the steel material of the present embodiment.
- the "spherical cementite structure” means that the microstructure is composed of ferrite and cementite, and the spheroidization rate of the cementite in the microstructure is 90.0% or more.
- the spheroidized cementite structure may be formed not only in the surface layer region but also in a region deeper than the surface layer region.
- the depth of the spheroidized cementite structure from the surface is at least 0.1R, and the depth of the spheroidized cementite structure may be deeper than 0.1R.
- the depth of the spheroidized cementite structure may be 0.2R, 0.3R, or 1.0R. That is, all the cross sections of the steel material 1 perpendicular to the axial direction may be spheroidized cementite.
- the microstructure of the steel material according to the present embodiment is (A), that is, when the steel material is as-rolled material, the steel material is subjected to spheroidizing heat treatment before cold forging. As a result, the microstructure of the steel material becomes (B).
- the cold forgeability (critical workability) can be improved as compared with the microstructure composed of ferrite and pearlite.
- Observation of the microstructure in a cross section of the steel material perpendicular to the longitudinal direction is performed by the following method.
- d radial depth from the surface
- four positions at d 0.05R (90 in FIG. 2). ° Pitch).
- the surface of each sample taken is the observation surface. After the observation surface of each sample is mirror-polished, it is immersed in a Nital etchant for about 10 seconds to reveal the structure by etching.
- each phase of bainite, ferrite, pearlite, cementite, etc. can be distinguished as follows.
- a phase having a lamella structure can be identified as pearlite in SEM observation.
- the phase with no substructure in the grains can be identified as ferrite.
- the phase where the lath-like structure develops from the old ⁇ grain boundary can be identified as bainite.
- a granular phase with high brightness can be identified as cementite.
- the brightness of the layered cementite in pearlite is approximately the same as the brightness of the granular cementite described above.
- the obtained bainite area ratio is 95.0% or more, at least the surface area of 0.1R is certified as a bainite structure (that is, the microstructure is (A)).
- the above area ratio calculation does not include precipitates, inclusions, and retained austenite other than cementite such as BN, TiC, TiN, and AlN.
- the microstructure of the steel may be (B), and the spheroidized cementite ratio (%) is calculated by the following method.
- the aspect ratio (major axis/minor axis) of each cementite to be measured is determined.
- the aspect ratio can be obtained by known image processing.
- Cementite having an aspect ratio of 3.0 or less is defined as “spherical cementite”.
- the ratio (%) of the total number of spheroidized cementite in 24 fields of view to the total number of cementite in 24 fields of view is defined as a spheroidized cementite ratio (%).
- the obtained spheroidized cementite ratio is 90.0% or more, at least the surface layer region of 0.1R is determined to have a spheroidized cementite structure.
- the carburized steel part of the present embodiment includes a carburized layer formed on the surface layer and a core portion inside the carburized layer.
- the carburized layer has an effective hardened layer depth of 0.4 to less than 2.0 mm.
- the effective hardened layer depth means the depth from the surface where the Vickers hardness is HV550 or more.
- the Vickers hardness at a position of a depth of 50 ⁇ m from the surface is preferably 650 to 1000 HV.
- the microstructure at a depth of 0.4 mm from the surface contains 90 to 100% martensite in area %, and the Vickers hardness is 600 to 900 HV.
- the Vickers hardness of the carburized layer at a depth of 50 ⁇ m from the surface is 650 to 1000 HV, wear resistance and fatigue strength are further enhanced. More preferably, the Vickers hardness at a depth of 50 ⁇ m from the surface is 700 to 1000 HV.
- the microstructure of the carburized layer at a depth of 0.4 mm from the surface contains 90 to 100% martensite, and the Vickers hardness of the carburized layer at a depth of 0.4 mm from the surface is 600 to 900 HV. When it is, surface fatigue strength and fatigue strength are further increased. More preferably, the Vickers hardness at a depth of 0.4 mm from the surface is 620 to 900 HV.
- the Vickers hardness is 250 to 500 HV in the core portion at a depth of 2.0 mm from the surface.
- the chemical composition at the position of 2.0 mm in depth from the surface is the above-mentioned chemical composition. More preferably, the Vickers hardness at a position 2.0 mm deep from the surface is 270 to 450 HV. It is preferable that the microstructure at a depth of 2.0 mm from the surface contains at least one of martensite and bainite because the above effect can be further obtained.
- the microstructure at a depth of 0.4 mm from the surface of the carburized steel part is obtained by the following method. From the surface of the carburized steel part, a sample having a depth of 0.4 mm on the surface is taken. The surface of the sample is etched with a Picral solution. Of the surface after etching, arbitrary 3 visual fields are observed by SEM using secondary electron images. The area of each visual field is 400 ⁇ m 2 (magnification: 5000 times). In SEM observation, martensite and bainite (including tempered martensite and tempered bainite), ferrite, pearlite, and cementite can be identified as follows. Specifically, a phase having a lamellar structure can be specified as pearlite.
- the phase with no substructure in the grains can be identified as ferrite.
- the phase containing lath structure can be specified as martensite and bainite.
- tempered martensite and tempered bainite include lath-like structures, and further include carbides in the laths.
- a granular phase with high brightness can be identified as cementite.
- the brightness of the layered cementite in pearlite is similar to that of the granular cementite described above.
- martensite and bainite each include a lath-like structure, and in the present specification, martensite and bainite are not distinguished in the microstructure of the carburized steel part.
- the ratio of the obtained total area of martensite to the total area of the three visual fields is defined as the area ratio (%) of martensite at a depth of 0.5 ⁇ m.
- the above area ratio calculation does not include precipitates such as BN, TiC, TiN, and AlN other than cementite, inclusions, retained austenite, and the like.
- the Vickers hardness of carburized steel parts is measured by the following method.
- the section perpendicular to any surface of the carburized steel part shall be the measurement surface.
- the test force is 0.49N.
- the Vickers hardness HV at 10 locations at a depth of 50 ⁇ m is measured, and the average value is taken as the Vickers hardness HV at the depth of 50 ⁇ m.
- the Vickers hardness HV at 10 positions of 0.4 mm depth is measured, and the average value is taken as the Vickers hardness HV at the 0.4 mm depth position. If the Vickers hardness at the 0.4 mm depth position is 550 HV or more, it is determined that the carburized layer depth is at least 0.4 mm or more.
- the Vickers hardness at a depth of 2.0 mm from the surface is determined by a Vickers hardness test according to JIS Z 2244 (2009) using a micro Vickers hardness meter. The load during the test is 0.49N.
- the Vickers hardness HV at 10 locations at 2.0 mm depth is measured, and the average value is taken as the Vickers hardness HV at 2.0 mm depth.
- the Vickers hardness measurement surface is not particularly limited, but may be a cut surface orthogonal to the axial direction (longitudinal direction) of the carburized steel component.
- An example of the steel material manufacturing method of the present embodiment will be described.
- An example of the method for manufacturing a steel material includes a steel making step, a casting step, a hot working step, and a cooling step. Hereinafter, each step will be described.
- the steel making process includes a refining process and a casting process.
- refining process In the refining process, first, refining (primary refining) in a converter is performed on the hot metal produced by a known method. Secondary refining is performed on the molten steel tapped from the converter. In the secondary refining, alloying elements are added to molten steel to produce molten steel satisfying the above chemical composition.
- deoxidation treatment is performed by adding Al to molten steel discharged from the converter.
- slag treatment is carried out.
- secondary refining is carried out.
- the secondary refining is, for example, complex refining. For example, first, a refining process using LF (Ladle Furnace) or VAD (Vacuum Arc Degassing) is performed. Further, RH (Ruhrstahl-Hausen) vacuum degassing treatment is performed. After that, final adjustment of other alloy components except Si and Ca is performed.
- the molten steel After performing secondary refining and adjusting the composition of the molten steel other than Si and Ca, the molten steel undergoes the following treatments (heating and holding step and final composition adjusting step).
- Vg gas flow rate (Nm 3 /min)
- M l molten steel mass in ladle (ton)
- T l molten steel temperature (K)
- h 0 gas injection depth (m)
- P 0 molten steel Surface pressure (Pa)
- ⁇ stirring power value (W/ton)
- ⁇ uniform mixing time (s).
- the holding time ts is less than twice the uniform mixing time ⁇
- the oxides present in the molten steel in the ladle cannot be sufficiently aggregated and combined. Therefore, the floating removal of the oxide cannot be performed, and the number of oxides increases.
- Mg or the like mixed from the slag combines with S in molten steel to form MgS or the like, and MgS is dispersed in the molten steel. The dispersed MgS becomes MnS precipitation sites. As a result, the number of Mn sulfides increases.
- the holding time ts is at least twice the uniform mixing time ⁇ , the number of oxides in the steel can be suppressed. Further, since MgS once formed becomes MgO by reoxidation, the precipitation sites of MnS are reduced, and as a result, the number of Mn sulfides in the steel can be suppressed. As a result, after the final component adjusting step of the next step, the Mn sulfide content is 70.0/mm 2 or less and the oxide content is 25.0/mm 2 or less.
- Si and Ca are added to the molten steel after the heating and holding step to produce a molten steel satisfying the above chemical composition and the formulas (1) to (3).
- Si and Ca may be added to molten steel as individual raw materials.
- a Si-Ca alloy may be used as a raw material and added to molten steel.
- the oxide is modified from Al 2 O 3 to a composite inclusion containing SiO 2 and CaO, and Mn sulfide is also Ca. Is modified to a sulfide containing. Therefore, assuming that the holding time ts is at least twice the uniform mixing time ⁇ , the Mn sulfide content is 70.0/mm 2 or less and the oxide content is 25.0/mm 2 or less. become.
- Si and Ca are added to the molten steel after the addition of Al.
- the order of addition of Si and Ca is not particularly limited. Si and Ca may be added at the same time. Either Si or Ca may be added first.
- a raw material (a slab or an ingot) is manufactured using the molten steel manufactured by the refining process. Specifically, a slab is manufactured by continuous casting using molten steel. Alternatively, an ingot may be made by molten steel using the ingot making method. The hot working step of the next step is carried out using this cast piece or ingot.
- the slab or ingot is referred to as "material”.
- the material (bloom or ingot) prepared in the casting step is subjected to hot working to manufacture a steel material.
- the shape of the steel material is not particularly limited, but is, for example, a steel bar or a wire rod. In the following description, a case where the steel material is steel bar will be described as an example. However, even if the steel material has a shape other than the steel bar, it can be manufactured by the same hot working process.
- the hot working includes a rough rolling process and a finish rolling process.
- the material is hot worked to produce a billet.
- the rough rolling process uses, for example, a slab mill.
- a slab mill is used to slab the material to produce a billet.
- a continuous rolling mill is installed downstream of the slab, the billet after slabbing is further hot-rolled using a continuous rolling mill to produce a smaller billet. May be.
- a horizontal stand having a pair of horizontal rolls and a vertical stand having a pair of vertical rolls are alternately arranged in a line.
- the heating temperature in the rough rolling step is not particularly limited, but is, for example, 1100 to 1300°C.
- the billet is heated using a heating furnace or soaking furnace.
- the billet after heating is subjected to hot rolling using a continuous rolling mill to manufacture a steel material (bar steel).
- the heating temperature at the finish rolling temperature is not particularly limited, but is, for example, 1000 to 1250°C.
- the area ratio of bainite in the surface layer region at least from the surface to the depth of 0.1R is 95.0% or more in the microstructure in the cross section perpendicular to the axial direction. That is, the steel material (as-rolled material) having the microstructure (A) is manufactured by the above manufacturing process.
- the steel material after the cooling step may be further subjected to a spheroidizing heat treatment step to make the steel material of the present embodiment a steel material having a microstructure (B). That is, in this case, spheroidizing heat treatment is performed to manufacture a steel material having a microstructure (B).
- the spheroidizing heat treatment may be a known method.
- the spheroidizing heat treatment is performed, for example, by the following method.
- the steel material after the cooling step is heated to a temperature just below A c1 point (the temperature at which austenite starts to be generated during heating) or immediately above (for example, within A c1 point +50° C.) and held for a predetermined time, and then gradually Cool.
- a treatment in which the steel material after the cooling step is heated to a temperature just above the A c1 point and cooled to a temperature just below the A r1 point (when cooling, austenite completes transformation to ferrite or ferrite, cementite) It may be repeated several times.
- the steel material after the cooling step may be once quenched and then tempered at a temperature range of 600 to 700° C. for 3 to 100 hours.
- the spheroidizing heat treatment method is not particularly limited as long as the well-known annealing or spheroidizing heat treatment method as described above is applied.
- the steel material manufactured by performing the spheroidizing heat treatment in the microstructure in the cross section perpendicular to the axial direction, at least the surface layer region from the surface to the depth of 0.1R is composed of ferrite and cementite, and the spherical shape of the cementite The conversion rate becomes 90.0% or more. That is, the steel material having the microstructure (B) is manufactured by the above manufacturing process.
- the steel material of this embodiment can be manufactured by the above manufacturing process.
- microstructure of the steel material of this embodiment is (A)
- the steel material of this embodiment is an as-rolled material
- cold rolling is performed after performing the above-mentioned spheroidizing heat treatment process with respect to the steel material. Perform a forging process.
- a cold drawing step such as a wire drawing step is performed if necessary.
- Cold forging process cold forging is performed on the steel material manufactured by the above-described manufacturing method to give a shape to manufacture a plurality of intermediate members.
- cold forging conditions such as a working rate and a strain rate are not particularly limited.
- suitable conditions may be appropriately selected.
- the plurality of intermediate members are welded and integrated in the next welding process.
- the welding process is an optional process and may not be performed.
- the above-mentioned plurality of intermediate members are welded and integrated by friction welding or laser welding.
- the welding method is not particularly limited.
- the joint surface of the intermediate member may be formed into a flat surface by machining.
- Mn sulfide is 70.0 pieces/mm 2 or less and oxide is 25.0 pieces/mm 2 or less. Therefore, the steel material of the present embodiment is excellent in bondability, and even when the intermediate member is welded to form a carburized steel part, the carburized steel part is excellent in joint fatigue strength.
- the cutting process is an optional process and need not be performed.
- the intermediate member after the cold forging process and before the carburizing process described later is subjected to the cutting process to give a shape.
- By carrying out the cutting process it is possible to impart a precision shape to the carburized steel part which is difficult only by the cold forging step.
- the carburizing process is performed on the intermediate member (the integrally joined intermediate member when the welding process is performed).
- a known carburizing process is performed.
- the carburizing process includes a carburizing process, a diffusion process, and a quenching process.
- the carburizing conditions in the carburizing process and diffusion process may be adjusted appropriately.
- the carburizing temperature in the carburizing step and the diffusion step is, for example, 830 to 1100°C.
- the carbon potential in the carburizing process and the diffusion process is, for example, 0.5 to 1.2%.
- the holding time in the carburizing step is, for example, 60 minutes or more, and the holding time in the diffusion step is 30 minutes or more.
- the carbon potential in the diffusion step is preferably lower than that in the carburization step.
- the conditions in the carburizing process and the diffusion process are not limited to the above-mentioned conditions.
- the intermediate member after the diffusion step is held at the quenching temperature of the Ar 3 transformation point or higher.
- the holding time at the quenching temperature is not particularly limited, but is, for example, 30 to 60 minutes.
- the quenching temperature is below the carburizing temperature.
- the temperature of the quenching medium is preferably room temperature to 250°C.
- the quenching medium is, for example, water or oil.
- a sub-zero treatment may be performed after quenching if necessary.
- Tempeering process A known tempering process is performed on the intermediate member after the carburizing process.
- the tempering temperature is, for example, 100 to 250°C.
- the holding time at the tempering temperature is, for example, 60 to 150 minutes.
- the carburized steel part after the tempering step may be further subjected to grinding or shot peening.
- the grinding process it is possible to impart a precise shape to the carburized steel part.
- compressive residual stress is introduced into the surface layer portion of the carburized steel component. Compressive residual stress suppresses the initiation and propagation of fatigue cracks. Therefore, the fatigue strength of carburized steel parts is increased.
- the carburized steel part is a gear, the fatigue strength of the root and the tooth surface of the carburized steel part can be improved.
- the shot peening process may be performed by a known method.
- the shot peening treatment is preferably performed, for example, by using shot grains having a diameter of 0.7 mm or less and an arc height of 0.4 mm or more.
- the steel material of the present embodiment can be applied as a material for a carburized steel part that is integrated by welding a plurality of intermediate members. Further, the steel material of the present embodiment can naturally be applied as a material for carburized steel parts without welding.
- Examples The effects of one aspect of the steel material of the present disclosure will be described more specifically with reference to Examples.
- the conditions in the examples are one condition example adopted to confirm the feasibility and effects of the steel material of the present disclosure.
- the steel material of the present disclosure is not limited to this one condition example.
- the steel material of the present disclosure may adopt various conditions as long as the object of the present disclosure is achieved without departing from the gist of the present disclosure.
- the molten steel after refining was cast by continuous casting to obtain a slab.
- the blank portion in Table 1 means that the content of the corresponding element was below the detection limit. In other words, the blank portion means that it was below the detection limit at the lowest digit of the corresponding element content. For example, in the case of the Cu content in Table 1, the smallest digit is the second decimal place. Therefore, the Cu content of test number 1 means that it was not detected in the number of digits up to the second decimal place (the significant figure was 0% in the content up to the second decimal place).
- Stepelmaking condition (2) in Table 2 shows the order of addition of Al, Si, and Ca.
- “1” means that Si and Ca were added after deoxidizing by adding Al.
- “2” means that Al and Ca were added after Si was added.
- the steel making process was implemented aiming at the chemical composition of steel number B1. For test numbers 23 and 25, the steelmaking process was performed with the chemical composition of steel number C1 as the target.
- a rough rolling process was performed to obtain a billet having a cross section perpendicular to the longitudinal direction of 162 mm ⁇ 162 mm.
- a finish rolling process was carried out using this billet.
- hot rolling is performed by a continuous rolling mill using a billet heated to 1000 to 1250° C., and a steel bar having a circular cross section orthogonal to the longitudinal direction and a cut surface diameter of 30 mm is obtained.
- a cooling process was performed on the steel bar immediately after the finish rolling process.
- the average cooling rate (°C/sec) at 800 to 500°C in the cooling step was as shown in Table 2. For each test number, a plurality of steel bars after the cooling process (hereinafter referred to as "as-rolled material”) were prepared.
- SA step Spherodising Annealing
- SA material The steel material (as-rolled material, SA material) of each test number was manufactured by the above manufacturing method.
- the obtained bainite area ratio is 95.0% or more, it was determined that at least the surface layer region at a depth of 0.1 R from the surface has a bainite structure (in Table 2, "Y-rolled material microstructure", “Y )). On the other hand, when the obtained bainite area ratio was less than 95.0%, it was determined that the surface layer region at a depth of 0.1R from the surface was not a bainite structure (in Table 2, "Microstructure of as-rolled material” N").
- spheroidized cementite ratio (%) was determined by the following method. First, the major axis ( ⁇ m) and the minor axis ( ⁇ m) of each cementite were determined in each visual field (24 visual fields). Of the straight lines connecting any two points on the interface between cementite and the matrix (ferrite), the maximum length of the straight line was defined as the major axis ( ⁇ m) of the cementite. Of the straight lines connecting any two points on the interface between the cementite and the matrix, the length of the straight line perpendicular to the major axis was defined as the minor axis ( ⁇ m) of the cementite. Cementite having the obtained major axis of 0.1 ⁇ m or more was used as a measurement target (counting target).
- the aspect ratio (major axis/minor axis) of each cementite to be measured was determined.
- Cementite having an aspect ratio of 3.0 or less was defined as “spherical cementite”.
- the ratio (%) of the total number of spheroidized cementite in 24 fields of view to the total number of cementite in 24 fields of view was defined as a spheroidized cementite ratio (%).
- Y in “SA material microstructure” in Table 2).
- a compression test piece was produced from a steel material having a test number of 30 mm in diameter so that the longitudinal direction of the steel material was the compression direction.
- the compression test piece had a diameter of 29.5 mm and a length of 44 mm.
- the central axis of the compression test piece was almost coincident with the central axis of the steel material.
- a notch was formed in the circumferential direction of the central position in the longitudinal direction of the compression test piece.
- the notch angle was 30° C.
- the notch depth was 0.8 mm
- the radius of curvature of the notch tip was 0.15 mm.
- the compression test pieces were collected from the as-rolled material and the SA material.
- the one collected from the as-rolled material is referred to as “as-rolled test piece”
- SA-test piece the one collected from the SA material
- a critical compression test was performed on the above-mentioned compression test pieces (as-rolled test pieces, SA test pieces) by the following method.
- a 500 ton hydraulic press was used for the limit compression test.
- Each test piece was cold-pressed using a restraining die at a speed of 10 mm/min. The compression was stopped when a minute crack of 0.5 mm or more occurred near the notch, and the compression ratio (%) at that time was calculated. This measurement was performed 10 times in total, the compression rate (%) at which the cumulative damage probability was 50% was obtained, and the compression rate was defined as the limit compression rate (%).
- Table 2 shows the limit compression ratio (%) of each test number.
- the as-rolled material cold drawing such as wire drawing may be performed before the spheroidizing heat treatment step, as described above.
- the as-rolled material needs to have workability such that breakage due to internal cracks (chevron cracks) does not occur during cold drawing. Therefore, the as-rolled test piece was judged to have an excellent limit working rate when the limit compression rate was 50% or more.
- the limit compression ratio of the as-rolled test piece of less than 50% the subsequent evaluation test of the carburized steel parts was not performed.
- the limit compression rate of the conventional steel material used as the material of the carburized steel parts is about 65%, so if the value exceeds 75%, which is clearly higher than this value, the limit processing rate is It was judged to be excellent.
- the evaluation test of the carburized steel part was not implemented with respect to the test number whose critical compression ratio is less than 75%.
- the observation surface of the collected sample was mirror-polished, and 20 fields of view (evaluated area per field of view 100 ⁇ m ⁇ 100 ⁇ m) were randomly observed at a magnification of 1000 times using a scanning electron microscope (SEM) (as-rolled material. 20 fields of view, 20 fields of SA material).
- SEM scanning electron microscope
- Identified inclusions in each field of view were energy dispersive X-ray spectroscopy (EDX) was used to identify Mn sulfides and oxides for each identified inclusion. Specifically, using EDX, elemental analysis was performed at at least two measurement points for each inclusion. Then, in each inclusion, the arithmetic mean value of the element contents obtained at each measurement point was defined as the content (mass %) of each element in the inclusion.
- EDX Energy dispersive X-ray spectroscopy
- the arithmetic mean value of the Mn content, the arithmetic mean value of the S content, and the arithmetic mean value of the O content obtained at the two measurement points It was defined as Mn content (mass %), S content (mass %), and O content (mass %) in the inclusions. If the Mn content is 10.0% or more, the S content is 10.0% or more, and the O content is less than 10.0% in the elemental analysis result of the identified inclusions, the inclusions The product was identified as Mn sulfide. Further, in the elemental analysis result of the specified inclusion, when the O content was 10.0% or more, the inclusion was identified as an oxide.
- the inclusion to be specified was an inclusion having a circle equivalent diameter of 0.5 ⁇ m or more. The beam diameter of the EDX used to identify the inclusions was 0.2 ⁇ m.
- Mn sulfides and oxides having an equivalent circle diameter of 0.5 ⁇ m or more were measured.
- the number of Mn sulfides per unit area (number/mm 2 ) was determined based on the total number of Mn sulfides specified in each field of view and the total area of 20 fields of view. Further, the number of oxides per unit area (number/mm 2 ) was determined based on the total number of oxides specified in each visual field and the total area of 20 visual fields.
- Table 2 shows the number of Mn sulfides in the as-rolled material (pieces/mm 2 ) and the number of oxides in the as-rolled material (pieces/mm 2 ).
- the number of Mn sulfides in the SA material was the same as the number of Mn sulfides in the as-rolled material
- the number of oxides in the SA material was the same as the number of oxides in the as-rolled material.
- the as-rolled material of each test number was subjected to spheroidizing annealing. Specifically, the as-rolled material was heated to 740°C. Then, the as-rolled material was gradually cooled at a cooling rate of 8° C./hr until the temperature of the material reached 650° C. The steel material was air-cooled to a temperature of 650° C. to room temperature to produce a spheroidized and as-rolled material.
- Test specimens were taken from the as-rolled as-spheroidized material.
- the test piece was a round bar with a diameter of 29.5 mm and a length of 44 mm.
- the length direction of the test piece was the same as the longitudinal direction of the as-rolled material.
- ⁇ Cold forging was simulated on this test piece, and cold upsetting was performed at a compression rate of 50%. Upsetting compression was performed at room temperature and a restraining die was used. The strain rate during upsetting compression was 1/sec.
- Gas carburizing was performed on the test piece after the upsetting compression by the shift converter gas system. In this gas carburizing, the carbon potential was set to 0.8%, the holding was carried out at 950° C. for 5 hours, and then the holding was carried out at 850° C. for 0.5 hours. After gas carburization, oil quenching to 130° C. was performed as a finishing heat treatment step. After quenching, tempering was performed at 150° C. for 90 minutes. Through the above steps, a test piece simulating a carburized steel part was produced from the as-rolled material.
- test pieces simulating carburized steel parts were prepared in the same manner as the as-rolled material described above. Specifically, a test piece was collected from the SA material of each test number. The test piece was a round bar with a diameter of 29.5 mm and a length of 44 mm. The length direction of the test piece was the same as the longitudinal direction of the SA material. This test piece was subjected to cold forging, and cold upsetting was performed at a compression rate of 50%. Upsetting compression was performed at room temperature and a restraining die was used. The strain rate during upsetting compression was 1/sec. Gas carburizing was performed on the test piece after the upsetting compression by the shift converter gas system.
- the carbon potential was set to 0.8%, the holding was carried out at 950° C. for 5 hours, and then the holding was carried out at 850° C. for 0.5 hours.
- oil quenching to 130° C. was performed as a finishing heat treatment step.
- tempering was performed at 150° C. for 90 minutes.
- the total area of martensite in the three visual fields of the 0.4 mm depth position sample was obtained.
- the ratio of the obtained total area of martensite to the total area of three visual fields was defined as the area ratio (%) of martensite at a depth of 0.5 ⁇ m.
- the Vickers hardness and chemical composition of the core of the above-mentioned test piece simulating a carburized steel part were measured by the following methods.
- the Vickers hardness at a depth of 2.0 mm from the surface of the cut surface perpendicular to the longitudinal direction of the carburized steel part was determined by a Vickers hardness test according to JIS Z 2244 (2009) using a micro Vickers hardness meter. It was The test force was 0.49N.
- the measurement was performed 10 times at the 2.0 mm depth position, and the average value was taken as the Vickers hardness (HV) at the 2.0 mm depth position from the surface.
- the obtained Vickers hardness is shown in Table 3.
- the core hardness was sufficient and it was determined to be acceptable.
- the Vickers hardness at the 0.4 mm depth position is 600 HV or more and the Vickers hardness at the 2.0 mm position is less than 600 HV, the carburized layer is effective in the range of 0.4 to less than 2.0 mm. It was judged to have a cured layer. That is, in this case, the 2.0 mm depth position from the surface was recognized as the core.
- the grain size of each old-austenite crystal grain was determined by the equivalent circle diameter ( ⁇ m) with respect to the specified austenite crystal grain. If any of the old austenite crystal grains has a circle equivalent diameter exceeding the circle equivalent diameter (88.4 ⁇ m) corresponding to the JIS-specified grain size number 4 (“Coarse grain generation”) Yes”. The judgment results are shown in Table 3.
- the as-rolled material and SA material of each test number were machined to produce a round bar having a diameter of 20 mm and a length of 150 mm. Using this round bar (as-rolled material, SA material), a basic fatigue test piece and a joining fatigue test piece were produced. Before producing the following basic fatigue test pieces and joining fatigue test pieces, the as-rolled material was subjected to spheroidizing annealing under the same conditions as described above, and then machined to a diameter of 20 mm and a length of 150 mm. A round bar was made.
- the basic fatigue test piece was prepared by the following method.
- An Ono-type rotary bending fatigue test piece having a diameter of 20 mm and a length of 150 mm was formed from a central portion of a cross section of a round bar having an evaluation portion diameter of 8 mm and a parallel portion length of 15 mm. This test piece was used as a basic fatigue test piece.
- the longitudinal direction of the basic fatigue test piece was the same as the longitudinal direction of the round bar.
- Bonding fatigue test pieces were prepared by the following method. 20 mm diameter and 150 mm long round bars of the same test piece number were abutted against each other to prepare a joined round bar under the following friction welding conditions.
- Friction welding conditions Friction pressure: 100 MPa, Friction time: 5 seconds, Upset pressure (pressure applied from both ends of the round bar to the joint): 200 MPa, Upset time (pressurization time to the joint): 5 seconds, Rotation speed: 2000 rpm, Side allowance: 5 to 12 mm.
- An Ono-type rotating bending fatigue test piece with a diameter of 8 mm for the evaluation part and a length of 15.0 mm for the parallel part was created from the center of the cross section of the joined round bar and used as the pressure contact fatigue test piece.
- the central portion in the longitudinal direction of the parallel portion was used as the joint surface.
- the longitudinal direction of the joint fatigue test piece was the same as the longitudinal direction of the round bar.
- Carburized steel parts (test pieces using as-rolled material after spheroidizing heat treatment, test pieces using SA material) were subjected to the following carburizing and quenching treatments on the basic fatigue test piece and the joining fatigue test piece. did.
- gas carburizing was carried out by the gas conversion converter system. Specifically, the carbon potential was set to 0.8% and the temperature was maintained at 950° C. for 5 hours. Then, the same carbon potential was maintained at 850° C. for 0.5 hour. Then, it was immersed in oil at 130° C. to carry out oil quenching. After the oil quenching, tempering was performed by holding at 150° C. for 90 minutes.
- An Ono-type rotary bending fatigue test was performed on the manufactured basic fatigue test piece and joining fatigue test piece. Specifically, each of the above Ono-type rotary bending fatigue test pieces (basic fatigue test piece, joining fatigue test piece) was used at room temperature and in the air atmosphere, and the Ono-type rotation was performed in accordance with JIS Z 2274 (1978). A bending fatigue test was carried out. The rotation speed was 3000 rpm, the stress ratio R was ⁇ 1, and the maximum stress that did not break after the stress load cycle was 1 ⁇ 10 7 cycles was defined as fatigue strength (MPa).
- Table 3 shows the fatigue strength ratios obtained. When the fatigue strength ratio was 85% or more, it was judged that excellent fatigue strength was obtained even after joining.
- Test results The test results are shown in Tables 2 and 3. With reference to Tables 2 and 3, the chemical compositions of Test Nos. 1 to 11 and 28 were suitable and satisfied the formulas (1) to (3). Furthermore, the steelmaking conditions were also appropriate. Moreover, the cooling rate in the cooling step was also appropriate. Therefore, the number of MnS in the as-rolled material and the SA material was 70.0 pieces/mm 2 or less, and the number of oxides was 25.0 pieces/mm 2 or less. Further, in the as-rolled material, the bainite area ratio at least in the surface layer region from the surface to the depth of 0.1R is 95.0% or more (“Y” in the “microstructure of as-rolled material” column in Table 2).
- SA material the microstructure of the surface layer region at least from the surface to the depth of 0.1R is composed of ferrite and cementite, and the spheroidization rate of cementite in the surface layer region is 90.0% or more (“SA material in Table 2 "Y") in the "Microstructure of" column.
- SA material in Table 2 "Y" the spheroidization rate of cementite in the surface layer region is 90.0% or more
- the Vickers hardness at a depth of 50 ⁇ m is 650 to 1000 HV and at a depth of 0.4 mm.
- the martensite area ratio was 90.0% or more
- the Vickers hardness at the 0.4 mm depth position was 600 to 900 HV or more.
- the Vickers hardness at a depth of 2.0 mm from the surface was 250 to 500 HV
- the effective hardened layer depth of the carburized layer was 0.4 to less than 2.0 mm.
- the former austenite grain boundaries were not coarsened in the core.
- the fatigue strength ratios based on the joint fatigue test piece and the basic fatigue test piece were both high at 85% or more, and excellent fatigue strength was exhibited both when joined and after welding.
- test number 12 the C content was too high. Therefore, the limit compression ratio of the as-rolled material was less than 50%. Furthermore, the critical compressibility of the SA material was less than 75%, and a sufficient critical compressibility could not be obtained.
- test number 13 the C content was too low. Therefore, sufficient hardness was not obtained in the core of the test piece simulating the carburized steel part.
- test number 14 the oxygen content was too high. Therefore, the number of oxides was too large.
- the as-rolled material and the SA material had a low fatigue strength ratio of less than 85% based on the joint fatigue test piece and the basic fatigue test piece, and the fatigue strength after welding was low.
- test number 17 F1 was less than the lower limit of formula (1). Therefore, the core hardness of the as-rolled carburized part and the SA part of the carburized steel part were too low.
- F2 was less than the lower limit of formula (2). Therefore, in the carburized parts of the as-rolled material and the carburized steel parts of the SA material, the hardness at the 0.4 mm depth position was too low.
- the holding time ts at the temperature of 1500 to 1600° C. for the molten steel in the ladle after the secondary refining was less than 2.0 times the uniform mixing time ⁇ . Therefore, in the as-rolled material and the SA material, the number of MnS exceeded 70.0/mm 2 and the number of oxides exceeded 25.0/mm 2 . As a result, the fatigue strength ratio was as low as less than 85% in the joint fatigue test pieces simulating the as-rolled carburized parts and SA-material carburized steel parts.
- the average cooling rate from 800 to 500 in the slow cooling step after hot rolling was too fast. Therefore, the microstructure of the as-rolled steel became a martensite-based microstructure. As a result, the limit compression ratio of the as-rolled material was less than 50%.
- the microstructure of the SA material at least the microstructure in the surface layer region from the surface to the depth of 0.1R is made of ferrite and cementite, and the spheroidization rate of the cementite in the surface layer region is 90.0% or more. Therefore, the critical compression rate of the SA material was 75% or more.
- the Vickers hardness of the carburized layer of the carburized steel part made of SA material was appropriate, and the martensite fraction at the 0.4 mm depth position was 90.0% or more. Further, the core hardness and chemical composition were appropriate, and the former austenite grain size was not coarsened. Furthermore, in the joint fatigue test piece, the fatigue strength ratio was as high as 85% or more, and even when joined, excellent fatigue strength was exhibited.
Abstract
Description
質量%で、
C:0.09~0.16%、
Si:0.01~0.50%、
Mn:0.40~0.60%、
P:0.030%以下、
S:0.025%以下、
Cr:0.90~2.00%、
Mo:0.10~0.40%、
Al:0.005~0.030%、
Ti:0.010~0.050%未満、
Nb:0.010~0.030%、
N:0.0080%以下、
O:0.0030%以下、
B:0.0003~0.0030%、
Ca:0.0005~0.0050%、を含有し、
残部がFe及び不純物からなり、式(1)~式(3)を満たし、
前記鋼材の軸方向に平行な断面において、質量%でMn含有量が10.0%以上、S含有量が10.0%以上、O含有量が10.0%未満であるMn硫化物が70.0個/mm2以下であり、質量%でO含有量が10.0%以上である酸化物が25.0個/mm2以下である。
0.140<C+0.194×Si+0.065×Mn+0.012×Cr+0.033×Mo+0.067×Ni+0.097×Cu+0.078×Al<0.235 式(1)
13.0<(0.70×Si+1)×(5.1×Mn+1)×(2.2×Cr+1)×(3.0×Mo+1)×(0.36×Ni+1)<45.0 式(2)
0.004<Ti-N×(48/14)<0.030 式(3)
ここで、式(1)~式(3)の各元素記号には、対応する元素の含有量(質量%)が代入される。対応する元素が含有されていない場合、その元素記号には「0」が代入される。
13.0<(0.70×Si+1)×(5.1×Mn+1)×(2.2×Cr+1)×(3.0×Mo+1)×(0.36×Ni+1)<45.0 (2)
0.140<C+0.194×Si+0.065×Mn+0.012×Cr+0.033×Mo+0.067×Ni+0.097×Cu+0.078×Al<0.235 (1)
0.004<Ti-N×(48/14)<0.030 (3)
(I)質量%で、Mn含有量が10.0%以上、S含有量が10.0%以上、O含有量が10.0%未満であるMn硫化物を70.0個/mm2以下にする。
(II)質量%で、O含有量が10.0%以上である酸化物を25.0個/mm2以下にする。
以下、この点について詳述する。
Mn硫化物:介在物の質量%を100%とした場合に、質量%でMn含有量が10.0%以上、S含有量が10.0%以上、O含有量が10.0%未満である介在物
酸化物:介在物の質量%を100%とした場合に、質量%で、酸素含有量が10.0%以上である介在物
なお、本明細書において、介在物のうち、質量%で、10.0%以上のSと、10.0%以上のMnと、10.0%以上のOとを含有する介在物は、「Mn硫化物」ではなく、「酸化物」に含まれる。
鋼材であって、
質量%で、
C:0.09~0.16%、
Si:0.01~0.50%、
Mn:0.40~0.60%、
P:0.030%以下、
S:0.025%以下、
Cr:0.90~2.00%、
Mo:0.10~0.40%、
Al:0.005~0.030%、
Ti:0.010~0.050%未満、
Nb:0.010~0.030%、
N:0.0080%以下、
O:0.0030%以下、
B:0.0003~0.0030%、
Ca:0.0005~0.0050%、を含有し、
残部がFe及び不純物からなり、式(1)~式(3)を満たし、
前記鋼材の軸方向に平行な断面において、質量%でMn含有量が10.0%以上、S含有量が10.0%以上、O含有量が10.0%未満であるMn硫化物が70.0個/mm2以下であり、質量%でO含有量が10.0%以上である酸化物が25.0個/mm2以下である、
鋼材。
0.140<C+0.194×Si+0.065×Mn+0.012×Cr+0.033×Mo+0.067×Ni+0.097×Cu+0.078×Al<0.235 (1)
13.0<(0.70×Si+1)×(5.1×Mn+1)×(2.2×Cr+1)×(3.0×Mo+1)×(0.36×Ni+1)<45.0 (2)
0.004<Ti-N×(48/14)<0.030 (3)
ここで、式(1)~式(3)の各元素記号には、対応する元素の含有量(質量%)が代入される。対応する元素が含有されていない場合、その元素記号には「0」が代入される。
[1]に記載の鋼材であって、
前記鋼材の軸方向に垂直な断面での半径をR(mm)と定義したとき、前記鋼材の軸方向に垂直な断面におけるミクロ組織において、少なくとも表面から0.1R深さまでの表層領域でのベイナイトの面積率が95.0%以上である、
鋼材。
[1]に記載の鋼材であって、
前記鋼材の軸方向に垂直な断面での半径をR(mm)と定義したとき、前記鋼材の軸方向に垂直な断面におけるミクロ組織において、少なくとも表面から0.1R深さまでの表層領域は、フェライトと、セメンタイトとからなり、前記表層領域での前記セメンタイトの球状化率が90.0%以上である、
鋼材。
[1]~[3]のいずれか1項に記載の鋼材であって、
前記Feの一部に代えて、質量%で、
Cu:0.50%以下、
Ni:0.30%以下、及び、
V:0.10%以下、
からなる群から選択される1元素以上を含有する、
鋼材。
本実施形態の鋼材は、浸炭鋼部品の素材である。本実施形態の鋼材は冷間鍛造された後、浸炭処理されて、浸炭鋼部品となる。本実施形態の鋼材の化学組成は、次の元素を含有する。
炭素(C)は、鋼材の焼入れ性を高め、浸炭層と芯部とを備える浸炭鋼部品における芯部の硬さを高める。C含有量が0.09%未満であれば、他の元素含有量が本実施形態の範囲内であっても、浸炭鋼部品の芯部の硬さが低下する。一方、C含有量が0.16%を超えれば、他の元素含有量が本実施形態の範囲内であっても、冷間鍛造前の鋼材の硬さが顕著に増加し、限界加工率が低下する。したがって、C含有量は0.09~0.16%である。なお、従来の浸炭鋼部品の素材となる鋼材のC含有量は0.20%程度である。そのため、本実施形態の鋼材のC含有量は、従来の鋼材よりも低い。C含有量の好ましい下限は0.10%であり、さらに好ましくは0.11%である。C含有量の好ましい上限は0.15%であり、さらに好ましくは0.14%である。
シリコン(Si)は、浸炭鋼部品の焼戻し軟化抵抗を高め、浸炭鋼部品の面疲労強度を高める。Si含有量が0.01%未満であれば、他の元素含有量が本実施形態の範囲内であっても、上記効果が得られない。一方、Si含有量が0.50%を超えれば、他の元素含有量が本実施形態の範囲内であっても、冷間鍛造前の鋼材の硬さが上昇し、限界加工率が低下する。したがって、Si含有量は0.01~0.50%である。浸炭鋼部品の面疲労強度を重視する場合、Si含有量の好ましい下限は0.02%である。浸炭鋼部品の限界加工率の向上を重視する場合、Si含有量の好ましい上限は0.48%であり、さらに好ましくは0.46%である。
マンガン(Mn)は、鋼材の焼入れ性を高め、浸炭鋼部品の芯部の強度を高める。Mn含有量が0.40%未満であれば、他の元素含有量が本実施形態の範囲内であっても、この効果が十分に得られない。一方、Mn含有量が0.60%を超えれば、他の元素含有量が本実施形態の範囲内であっても、鍛造前の鋼材の硬さが上昇して、限界加工率が低下する。したがって、Mn含有量は0.40~0.60%である。Mn含有量の好ましい下限は0.42%であり、さらに好ましくは0.44%である。Mn含有量の好ましい上限は0.58%であり、さらに好ましくは0.56%である。
燐(P)は、不可避に含有される不純物である。つまり、P含有量は0%超である。Pは、オーステナイト粒界に偏析して旧オーステナイト粒界を脆化し、粒界割れを引き起こす。したがって、P含有量は0.030%以下である。P含有量の好ましい上限は0.026%であり、さらに好ましくは0.024%である。P含有量はなるべく低い方が好ましい。しかしながら、P含有量を極限まで低減すれば、生産性が低下し、製造コストが高くなる。したがって、通常の操業において、P含有量の好ましい下限は0.001%である。
硫黄(S)は不可避に含有される。つまり、S含有量は0%超である。SはMnと結合してMnSを形成し、鋼材の被削性を高める。S含有量が0%超であれば、この効果がある程度得られる。一方、S含有量が0.025%を超えれば、他の元素含有量が本実施形態の範囲内であっても、粗大なMnSが生成して、鍛造時に割れが生じやすくなり、鋼材の限界加工率が低下する。したがって、S含有量は0.025%以下である。S含有量の好ましい上限は0.022%であり、さらに好ましくは0.020%である。被削性をより有効に高める場合、S含有量の好ましい下限は0.001%であり、さらに好ましくは0.002%であり、さらに好ましくは0.003%である。
クロム(Cr)は、鋼材の焼入れ性を高め、浸炭鋼部品の芯部の強度を高める。Cr含有量が0.90%未満であれば、他の元素含有量が本実施形態の範囲内であっても、この効果が十分に得られない。一方、Cr含有量が2.00%を超えれば、他の元素含有量が本実施形態の範囲内であっても、鍛造前の鋼材の硬さが上昇して、限界加工率が低下する。したがって、Cr含有量は0.90~2.00%である。Cr含有量の好ましい下限は0.95%であり、さらに好ましくは1.00%であり、さらに好ましくは1.10%である。Cr含有量の好ましい上限は1.95%であり、さらに好ましくは1.92%である。
モリブデン(Mo)は、鋼材の焼入れ性を高め、浸炭鋼部品の芯部の強度を高める。Mo含有量が0.10%未満であれば、他の元素含有量が本実施形態の範囲内であっても、この効果が十分に得られない。一方、Mo含有量が0.40%を超えれば、他の元素含有量が本実施形態の範囲内であっても、鍛造前の鋼材の硬さが上昇して、限界加工率が低下する。したがって、Mo含有量は0.10~0.40%である。Mo含有量の好ましい下限は0.11%であり、さらに好ましくは0.12%であり、さらに好ましくは0.13%である。Mo含有量の好ましい上限は0.38%であり、さらに好ましくは0.36%であり、さらに好ましくは0.34%である。
アルミニウム(Al)は製鋼工程において鋼を脱酸する。Alはさらに、鋼中に固溶Nが存在する場合、AlNを形成する。しかしながら、本実施形態に係る鋼材では、鋼中のNがTiの添加によってTiNとして固定される。そのため、鋼材中に固溶Nがほとんど存在しない。その結果、AlはAlNを形成せず、鋼材中に固溶Alとして存在している。固溶状態で存在するAlは、鋼材の被削性を高める。Al含有量が0.005%未満であれば、他の元素含有量が本実施形態の範囲内であっても、上記効果が十分に得られない。一方、Al含有量が0.030%を超えれば、他の元素含有量が本実施形態の範囲内であっても、鍛造前の鋼材の硬さが上昇し、限界加工率が低下する。したがって、Al含有量は0.005~0.030%である。Alの好ましい下限は0.010%であり、さらに好ましくは0.011%であり、さらに好ましくは0.012%である。Alの好ましい上限は0.025%であり、さらに好ましくは0.022%であり、さらに好ましくは0.020%である。
チタン(Ti)は、鋼材中のNをTiNとして固定し、BNの形成を抑制する。これにより、Tiは固溶B量を確保して鋼材の焼入れ性を高める。Tiはさらに、TiCを形成して、浸炭処理時における結晶粒の粗大化を抑制する。Ti含有量が0.010%未満であれば、他の元素含有量が本実施形態の範囲内であっても、上記効果が十分に得られない。一方、Ti含有量が0.050%以上であれば、他の元素含有量が本実施形態の範囲内であっても、TiCの析出量が過剰に多くなる。この場合、冷間鍛造前の鋼材の限界加工率が低下する。したがって、Ti含有量は0.010~0.050%未満である。Ti含有量の好ましい下限は0.012%であり、さらに好ましくは0.014%であり、さらに好ましくは0.016%であり、さらに好ましくは0.018%である。Ti含有量の好ましい上限は0.048%であり、さらに好ましくは0.046%であり、さらに好ましくは0.044%であり、さらに好ましくは0.042%であり、さらに好ましくは0.040%である。
Nb(ニオブ)は、鋼材中でN及びCと結合して、Nb炭窒化物を形成する。Nb炭窒化物は、ピンニング効果により、結晶粒の粗大化を抑制する。Nb含有量が0.010%未満であれば、他の元素含有量が本実施形態の範囲内であっても、上記効果が十分に得られない。一方、Nb含有量が0.030%を超えれば、その効果が飽和する。したがって、Nb含有量は0.010~0.030%である。Nb含有量の好ましい下限は0.011%であり、さらに好ましくは0.012%であり、さらに好ましくは0.013%であり、さらに好ましくは0.014%である。Nb含有量の好ましい上限は0.029%であり、さらに好ましくは0.028%であり、さらに好ましくは0.027%であり、さらに好ましくは0.026%であり、さらに好ましくは0.025%である。
窒素(N)は不可避に含有される不純物である。つまり、鋼材中のN含有量は0%超である。NはBと結合してBNを形成し、固溶B量を低減する。この場合、鋼材の焼入れ性が低下する。N含有量が0.0080%を超えれば、0.010~0.050%未満のTiを含有していても、鋼中のNをTiNとして固定することができなくなり、焼入れ性に寄与する固溶Bを確保することが困難となる。さらに、粗大なTiNが形成される。粗大なTiNは鍛造時に割れの起点になり、鍛造前の鋼材の限界加工率を低下する。したがって、N含有量は0.0080%以下である。N含有量の好ましい上限は0.0078%であり、さらに好ましくは0.0076%であり、さらに好ましくは0.0074%であり、さらに好ましくは0.0072%である。N含有量はなるべく低い方が好ましい。しかしながら、N含有量を極限まで低減すれば、生産性が低下し、製造コストが高くなる。したがって、通常の操業において、N含有量の好ましい下限は0.0001%であり、さらに好ましくは0.0010%であり、さらに好ましくは0.0020%である。
酸素(O)は不可避的に含有される不純物である。つまり、鋼材中のO含有量は0%超である。Oは、酸化物を形成し、浸炭処理前の鋼材を溶接する場合に、接合性を低下する。この場合、浸炭鋼部品の疲労強度が低下する。したがって、O含有量は0.0030%以下である。O含有量の好ましい上限は0.0029%であり、さらに好ましくは0.0028%であり、さらに好ましくは0.0026%であり、さらに好ましくは0.0024%であり、さらに好ましくは0.0022%である。O含有量は低い方が好ましい。しかしながら、O含有量を極限まで低減すれば、生産性が低下し、製造コストが高くなる。したがって、通常の操業において、O含有量の好ましい下限は0.0001%であり、さらに好ましくは0.0005%であり、さらに好ましくは0.0010%である。
ホウ素(B)は鋼材の焼入れ性を高め、浸炭鋼部品の強度を高める。B含有量が0.0003%未満であれば、他の元素含有量が本実施形態の範囲内であっても、上記効果が十分に得れない。一方、B含有量が0.0030%を超えれば、上記効果が飽和する。したがって、B含有量は0.0003~0.0030%である。B含有量の好ましい下限は0.0004%であり、さらに好ましくは0.0005%であり、さらに好ましくは0.0006%であり、さらに好ましくは0.0007%である。B含有量の好ましい上限は0.0028%であり、さらに好ましくは0.0026%であり、さらに好ましくは0.0024%である。
カルシウム(Ca)は、酸化物に含有されて酸化物を球状化する。球状化した酸化物はクラスターを形成しにくい。Caはさらに、Mn硫化物の延伸を抑制する。Ca含有量が0.0005%未満であれば、他の元素含有量が本実施形態の範囲内であっても、上記効果が十分に得られない。一方、Ca含有量が0.0050%を超えれば、粗大な硫化物及び粗大な酸化物を形成して、浸炭鋼部品の疲労強度を低下する。したがって、Ca含有量は0.0005~0.0050%である。Ca含有量の好ましい下限は0.0006%であり、さらに好ましくは0.0007%であり、さらに好ましくは0.0008%であり、さらに好ましくは0.0009%であり、さらに好ましくは0.0010%であり、である。Ca含有量の好ましい上限は0.0048%であり、さらに好ましくは0.0046%であり、さらに好ましくは0.0040%であり、さらに好ましくは0.0035%である。
本実施の形態による鋼材の化学組成の残部は、Fe及び不純物からなる。ここで、不純物とは、鋼材を工業的に製造する際に、原料としての鉱石、スクラップ、又は製造環境などから混入されるものであって、意図的に鋼材に含有させたものではない成分を意味する。
本実施形態の鋼材の化学組成は、Feの一部に代えて、Cu、Ni、及び、Vからなる群から選択される1種又は2種以上を含有してもよい。これらの元素はいずれも、浸炭鋼部品の強度を高める。
銅(Cu)は任意元素であり、含有されなくてもよい。つまり、Cu含有量は0%であってもよい。Cuが含有される場合、つまり、Cu含有量が0%超の場合、Cuは鋼材の焼入れ性を高め、浸炭鋼部品の強度を高める。また、Cuは、ガス浸炭のガス雰囲気で、酸化物や窒化物を形成しない元素である。そのため、Cuを含有した場合、浸炭層表面の酸化物層や窒化物層、又は、それらに起因する浸炭異常層が形成されにくくなる。Cuが少しでも含有されれば、上記効果がある程度得られる。しかしながら、Cu含有量が0.50%を超えれば、他の元素含有量が本実施形態の範囲内であっても、1000℃以上の高温域における鋼材の延性が低下する。この場合、連続鋳造、圧延時の歩留まりが低下する。さらに、鍛造前の鋼材の硬さが上昇して、限界加工率が低下する。したがって、Cu含有量は0.50%以下である。つまり、Cu含有量は0~0.50%である。Cu含有量の好ましい下限は0%超であり、さらに好ましくは0.01%であり、さらに好ましくは0.02%であり、さらに好ましくは0.05%である。Cu含有量の好ましい上限は0.45%であり、さらに好ましくは0.40%であり、さらに好ましくは0.35%である。
ニッケル(Ni)は任意元素であり、含有されなくてもよい。つまり、Ni含有量は0%であってもよい。Niが含有される場合、つまり、Ni含有量が0%超の場合、Niは鋼材の焼入れ性を高め、浸炭鋼部品の強度を高める。Niが少しでも含有されれば、上記効果がある程度得られる。しかしながら、Ni含有量が0.30%を超えれば、他の元素含有量が本実施形態の範囲内であっても、鍛造前の鋼材の硬さが上昇して、限界加工率が低下する。したがって、Ni含有量は0.30%以下である。つまり、Ni含有量は0~0.30%である。Ni含有量の好ましい下限は0.01%であり、さらに好ましくは0.02%であり、さらに好ましくは0.05%である。Ni含有量の好ましい上限は0.29%であり、さらに好ましくは0.28%であり、さらに好ましくは0.25%である。
バナジウム(V)は任意元素であり、含有されなくてもよい。つまり、V含有量は0%であってもよい。Vが含有される場合、つまり、V含有量が0%超である場合、Vは炭化物を形成して、浸炭鋼部品の芯部の強度を高める。Vが少しでも含有されれば、上記効果がある程度得られる。しかしながら、V含有量が0.10%を超えれば、他の元素含有量が本実施形態の範囲内であっても、鋼材の冷間鍛造性が低下し、限界加工率が低下する。したがって、V含有量は0.10%以下である。つまり、V含有量は0~0.10%である。V含有量の好ましい下限は0.01%であり、さらに好ましくは0.02%であり、さらに好ましくは0.03%である。V含有量の好ましい上限は0.09%であり、さらに好ましくは0.08%である。
本実施形態の鋼材の化学組成は、さらに、次の式(1)~式(3)を満たす。
0.140<C+0.194×Si+0.065×Mn+0.012×Cr+0.033×Mo+0.067×Ni+0.097×Cu+0.078×Al<0.235 式(1)
13.0<(0.70×Si+1)×(5.1×Mn+1)×(2.2×Cr+1)×(3.0×Mo+1)×(0.36×Ni+1)<45.0 式(2)
0.004<Ti-N×(48/14)<0.030 式(3)
ここで、式(1)~式(3)中の元素記号には、対応する元素の含有量(質量%)が代入される。対応する元素が任意元素であり、含有されていない場合、その元素記号には「0」が代入される。以下、各式について説明する。
F1=C+0.194×Si+0.065×Mn+0.012×Cr+0.033×Mo+0.067×Ni+0.097×Cu+0.078×Alと定義する。F1は、鋼材を素材として製造される浸炭鋼部品の硬さの指標である。
F2=(0.70×Si+1)×(5.1×Mn+1)×(2.2×Cr+1)×(3.0×Mo+1)×(0.36×Ni+1)と定義する。F2は鋼材の焼入れ性に関する指標である。
F3=Ti-N×(48/14)と定義する。F3は、TiC析出量に関する指標である。TiがNに対して化学量論的に過剰に含有された場合、Nは全てTiNとして固定される。つまり、F3は、TiNを形成するために消費されたTi量以外の過剰なTi量を意味する。F3中の「14」はNの原子量であり、「48」はTiの原子量を示す。
本実施形態の鋼材ではさらに、鋼材の軸方向(すなわち、鋼材の長手方向)に平行な断面において、鋼中のMn硫化物及び酸化物が次の条件を満たす。
(I)質量%でMn含有量が10.0%以上、S含有量が10.0%以上、O含有量が10.0%未満であるMn硫化物が70.0個/mm2以下である。
(II)質量%で酸素含有量が10.0%以上である酸化物が25.0個/mm2以下である。
Mn硫化物:介在物の質量%を100%とした場合に、質量%でMn含有量が10.0%以上、S含有量が10.0%以上、O含有量が10.0%未満である介在物
酸化物:介在物の質量%を100%とした場合に、質量%で、O含有量が10.0%以上である介在物
鋼中のMn硫化物の個数、及び、酸化物の個数については、次の方法で測定できる。鋼材から、サンプルを採取する。具体的には、図3に示すとおり、鋼材1の中心軸線C1から径方向にR/2位置(Rは棒鋼の半径)から、サンプルを採取する。サンプルの観察面のサイズはL1×L2であってL1を10mmとし、L2を5mmとする。さらに、観察面と垂直の方向であるサンプル厚さL3を5mmとする。観察面の法線Nは、中心軸線C1に垂直(つまり、観察面は、鋼材の軸方向と平行)とし、R/2位置は、観察面の略中央位置とする。
本実施形態の鋼材のミクロ組織は特に限定されない。本実施形態の鋼材は、圧延まま材(つまり、As-rolled材)であってもよいし、球状化処理されていてもよい。
(A)ミクロ組織において、少なくとも表面から0.1R深さまでの表層領域でのベイナイトの面積率が95.0%以上である。
(B)ミクロ組織において、少なくとも表面から0.1R深さまでの表層領域は、フェライトと、セメンタイトとからなり、表層領域でのセメンタイトの球状化率が90.0%以上である。
上記(A)のミクロ組織は、本実施形態の鋼材が圧延まま材である場合のミクロ組織である。上記(B)のミクロ組織は、本実施形態の鋼材が球状化処理されている場合のミクロ組織である。
ベイナイト面積率(%)=24視野でのベイナイトの総面積/24視野の総面積×100
次に、本実施形態の鋼材を素材として製造される、浸炭鋼部品について説明する。
本実施形態に係る鋼材、及び、浸炭鋼部品の製造方法について説明する。
初めに、本実施形態の鋼材の製造方法の一例について説明する。鋼材の製造方法の一例は、製鋼工程と、鋳造工程と、熱間加工工程と、冷却工程とを含む。以下、各工程について説明する。
製鋼工程は、精錬工程と鋳造工程とを含む。
精錬工程では初めに、周知の方法で製造された溶銑に対して転炉での精錬(一次精錬)を実施する。転炉から出鋼した溶鋼に対して、二次精錬を実施する。二次精錬において、溶鋼に合金元素を添加して、上記化学組成を満たす溶鋼を製造する。
二次精錬(最終成分調整)後の取鍋内の溶鋼に対して、1500~1600℃の温度で下記式によって算定される均一混合時間τ(s)の2倍以上の保持時間tsで加熱する。
τ=800×ε-0.4
ε=((6.18×Vg×Tl)/Ml)ln(1+(h0/(1.46×10-5×P0)))
ここで、Vg:ガス流量(Nm3/min)、Ml:取鍋内溶鋼質量(ton)、Tl:溶鋼温度(K)、h0:ガス吹き込み深さ(m)、P0:溶鋼表面圧力(Pa)、ε:攪拌動力値(W/ton)、τ:均一混合時間(s)である。
加熱保持工程後の溶鋼にSi及びCaを添加して、上述の化学組成及び式(1)~式(3)を満たす溶鋼を製造する。Si及びCaはそれぞれ単独の原料として溶鋼に添加してもよい。Si-Ca合金を原料として、溶鋼に添加してもよい。
上記精錬工程により製造された溶鋼を用いて、素材(鋳片又はインゴット)を製造する。具体的には、溶鋼を用いて連続鋳造法により鋳片を製造する。又は、溶鋼を用いて造塊法によりインゴットしてもよい。この鋳片又はインゴットを用いて、次工程の熱間加工工程を実施する。以下、鋳片又はインゴットを「素材」という。
熱間加工工程では、鋳造工程にて準備された素材(ブルーム又はインゴット)に対して、熱間加工を実施して、鋼材を製造する。鋼材の形状は特に限定されないが、たとえば、棒鋼又は線材である。以下の説明では、一例として、鋼材が棒鋼である場合について説明する。しかしながら、鋼材が棒鋼以外の他の形状であっても同様の熱間加工工程で製造可能である。
冷却工程では、熱間加工工程完了直後の鋼材を冷却する。具体的には、鋼材の表面温度が800℃~500℃となる温度範囲を、1.0℃/秒超~30.0℃/秒の冷却速度で冷却する。
上記冷却工程後の鋼材に対して、さらに、球状化熱処理工程を実施して、本実施形態の鋼材を、ミクロ組織が(B)の鋼材としてもよい。つまり、この場合、球状化熱処理を実施してミクロ組織が(B)の鋼材を製造する。
次に、本実施形態の鋼材を素材とする浸炭鋼部品の製造方法の一例について説明する。本製造方法は、上述の鋼材に対して冷間鍛造を実施して、複数の中間部材を製造する冷間鍛造工程と、必要に応じて、製造された複数の中間部材を溶接して一体品とする溶接工程と、必要に応じて、中間部材に対して切削加工を実施する切削加工工程と、中間部材に対して浸炭処理を実施する浸炭処理工程と、浸炭処理工程後の中間鋼材に対して焼戻しを実施する焼戻し工程とを含む。なお、本明細書において、浸炭処理は、浸炭窒化処理も含む。
冷間鍛造工程では、上述の製造方法で製造された鋼材に対して冷間鍛造を実施して形状を付与し、複数の中間部材を製造する。この冷間鍛造工程での、加工率、ひずみ速度などの冷間鍛造条件は、特に限定されない。冷間鍛造条件は、適宜、好適な条件を選択すればよい。複数の中間部材は次工程の溶接工程で溶接され、一体化される。
溶接工程は任意の工程であり、実施しなくてもよい。実施する場合、溶接工程では、摩擦接合、又は、レーザー接合により、上述の複数の中間部材を溶接して、一体化する。溶接方法は特に限定されない。溶接後、中間部材の接合面を機械加工により平坦に形成してもよい。本実施形態の鋼材では、Mn硫化物が70.0個/mm2以下であり、かつ、酸化物が25.0個/mm2以下である。そのため、本実施形態の鋼材は接合性に優れ、中間部材を溶接して浸炭鋼部品とした場合であっても、浸炭鋼部品の接合疲労強度に優れる。
切削加工工程は任意の工程であり、実施しなくてもよい。実施する場合、切削加工工程では、冷間鍛造工程後であって後述の浸炭処理工程前の中間部材に対して、切削加工を実施して形状を付与する。切削加工を実施することにより、冷間鍛造工程だけでは困難な、精密形状を浸炭鋼部品に付与することができる。
浸炭処理工程では、中間部材(溶接工程を実施した場合は、一体に接合された中間部材)に対して、浸炭処理を実施する。浸炭処理工程では、周知の浸炭処理を実施する。浸炭処理工程は、浸炭工程と、拡散工程と、焼入れ工程とを含む。
浸炭処理工程後の中間部材に対して、周知の焼戻し工程を実施する。焼戻し温度はたとえば、100~250℃である。焼戻し温度での保持時間はたとえば、60~150分である。
必要に応じて、焼戻し工程後の浸炭鋼部品に対してさらに、研削加工を実施したり、ショットピーニング処理を実施してもよい。研削加工を実施することにより、精密形状を浸炭鋼部品に付与することができる。また、ショットピーニング処理を実施することにより、浸炭鋼部品の表層部に圧縮残留応力が導入される。圧縮残留応力は疲労き裂の発生及び進展を抑制する。そのため、浸炭鋼部品の疲労強度を高める。たとえば、浸炭鋼部品が歯車である場合、浸炭鋼部品の歯元及び歯面の疲労強度を向上できる。ショットピーニング処理は、周知の方法で実施すればよい。ショットピーニング処理はたとえば、直径が0.7mm以下のショット粒を用い、アークハイトが0.4mm以上の条件で実施するのが好ましい。
各試験番号の鋼材について、次の試験を実施した。
ミクロ組織観察試験を次の方法で実施した。具体的には、各試験番号の鋼材の長手方向に垂直な断面のうち、表面からの径方向の深さをd(mm)としたとき、d=0.05R位置の4箇所(図2では90°ピッチ)からサンプルを採取した。さらに、d=0.1R位置の4箇所(図2では90°ピッチ)からサンプルを採取した。採取した各サンプルの表面Sを観察面とした。各サンプルの観察面を鏡面に研磨した後、ナイタール腐食液に10秒程度浸漬して、エッチングによる組織現出を行った。エッチングした観察面を、SEMを用いて、二次電子像にて3視野観察した。視野面積は400μm2(倍率5000倍)とした。各視野において、ベイナイトと、その他の相(フェライト、パーライト、セメンタイト等)とは、上述のとおり、区別できた。
ベイナイト面積率(%)=24視野でのベイナイトの総面積/24視野の総面積×100
直径が30mmの各試験番号の鋼材から、鋼材の長手方向が圧縮方向となるように、圧縮試験片を作製した。圧縮試験片の直径は29.5mmであり、長さは44mmであった。圧縮試験片の中心軸は、鋼材の中心軸とほぼ一致した。圧縮試験片の長手方向における中央位置の周方向に切欠きを形成した。切欠き角度は30℃であり、切欠き深さは0.8mmであり、切欠き先端の曲率半径は0.15mmであった。圧縮試験片は、圧延まま材、SA材からそれぞれ採取した。以下、各試験片において、圧延まま材から採取したものを「圧延まま試験片」といい、SA材から採取したものを「SA試験片」という。
上述の各試験番号の圧延まま材及びSA材の各々からサンプルを採取した。具体的には、図3に示すとおり、圧延まま材、SA材の中心軸線C1から径方向にR/2位置から、サンプルを採取した。サンプルの観察面のサイズはL1×L2であってL1を10mmとし、L2を5mmとした。さらに、観察面と垂直の方向であるサンプル厚さL3を5mmとした。観察面の法線Nは、中心軸線C1に垂直とし、R/2位置は、観察面の中央位置に相当した。
各試験番号の圧延まま材に対して、球状化焼鈍を実施した。具体的には、圧延まま材を740℃に加熱した。その後、圧延まま材の温度が650℃になるまで冷却速度8℃/hrで徐冷した。鋼材温度が650℃~常温までは空冷して、球状化焼鈍された圧延まま材を製造した。
上記製造した浸炭鋼部品模擬試験片(圧延まま材、SA材)の、浸炭層及び芯部に対して、次の試験を実施した。
各試験番号の浸炭鋼部品を模擬した上記試験片(圧延まま材、SA材)の長手方向に垂直な切断面において、表面から50μm深さ位置のビッカース硬さと、表面から0.4mm深さ位置のビッカース硬さとを、マイクロビッカース硬度計を用いて、JIS Z 2244(2009)に準拠したビッカース硬さ試験により求めた。試験力は0.49Nとした。50μm深さ位置10箇所のビッカース硬さHVを測定して、その平均値を、50μm深さ位置でのビッカース硬さHVとした。また、0.4mm深さ位置10箇所のビッカース硬さHVを測定して、その平均値を、0.4mm深さ位置でのビッカース硬さHVとした。
浸炭鋼部品を模擬した上記試験片(圧延まま材、SA材)の表面から深さ0.4mm位置でのミクロ組織を、次の方法で求めた。試験片の表面から深さ0.4mm位置を表面に含むサンプルを採取した。サンプルの表面に対して、ピクラール液によるエッチングを実施した。エッチング後の表面のうち、任意の3視野をSEMを用いて二次電子像にて観察した。各視野の面積は400μm2(倍率5000倍)とした。マルテンサイト及びベイナイト(焼戻しマルテンサイト及び焼戻しベイナイトを含む)、フェライト、パーライト、セメンタイトは、コントラストから判別可能であった。0.4mm深さ位置サンプルの3視野におけるマルテンサイトの総面積を求めた。求めたマルテンサイトの総面積の、3視野の総面積に対する割合を、深さ0.5μm位置でのマルテンサイトの面積率(%)と定義した。
浸炭鋼部品を模擬した上記試験片の芯部のビッカース硬さ及び化学組成を次の方法で測定した。浸炭鋼部品の長手方向に垂直な切断面において、表面から2.0mm深さ位置のビッカース硬さを、マイクロビッカース硬度計を用いて、JIS Z 2244(2009)に準拠したビッカース硬さ試験により求めた。試験力は0.49Nとした。2.0mm深さ位置にて10回の測定を行い、その平均値を表面から2.0mm深さ位置でのビッカース硬さ(HV)とした。得られたビッカース硬さを表3に示す。0.2mm深さ位置でのビッカース硬さが、250~500HVである場合、芯部硬さが十分であり合格と判定した。なお、0.4mm深さ位置でのビッカース硬さが600HV以上であり、かつ、2.0mm位置でのビッカース硬さが600HV未満である場合、浸炭層が0.4~2.0mm未満の有効硬化層を有すると判断した。つまり、この場合、表面から2.0mm深さ位置は芯部と認定した。
上記浸炭鋼部品を模擬した上記試験片(圧延まま材及びSA材)の芯部について、表面から深さ2mmの位置での、旧オーステナイト結晶粒の観察を行った。具体的には、浸炭鋼部品の長手方向に垂直な切断面を観察面とした。観察面を鏡面研磨した後、ピクリン酸飽和水溶液にてエッチングを行った。エッチングされた観察面の、表面から2mm深さ位置を含む視野(300μm×300μm)を光学顕微鏡(400倍)で観察して、旧オーステナイト結晶粒を特定した。特定された旧オーステナイト結晶粒に対して、JIS G 0551(2013)に準拠して、各旧―ステナイト結晶粒の結晶粒径を円相当径(μm)で求めた。旧オーステナイト結晶粒のうち、円相当径が上記JIS規定の結晶粒度番号の4番に相当する円相当径(88.4μm)を超える結晶粒が一つでも存在している場合に「粗大粒発生あり」と判定した。判定結果を表3に示す。
各試験番号の圧延まま材及びSA材を機械加工して、直径20mm、長さ150mmの丸棒を作製した。この丸棒(圧延まま材、SA材)を用いて、基本疲労試験片、及び、接合疲労試験片を作製した。なお、下記基本疲労試験片、及び、接合疲労試験片を作製する前において、圧延まま材に対して上述と同じ条件の球状化焼鈍を実施し、その後、機械加工により直径20mm、長さ150mmの丸棒を作製した。
摩擦圧力:100MPa、
摩擦時間:5秒、
アップセット圧力(接合部への丸棒両端部からの加圧力):200MPa、
アップセット時間(接合部への加圧時間):5秒、
回転数:2000rpm、
寄り代:5~12mm。
疲労強度比(%)=接合疲労試験片の疲労強度/基本疲労試験片の疲労強度×100
試験結果を表2及び表3に示す。表2及び表3を参照して、試験番号1~11及び28の化学組成は適切であり、式(1)~式(3)を満たした。さらに、製鋼条件も適切であった。また、冷却工程での冷却速度も適切であった。そのため、圧延まま材及びSA材でのMnS個数は70.0個/mm2以下であり、かつ、酸化物個数は25.0個/mm2以下であった。さらに、圧延まま材において、少なくとも表面から0.1R深さまでの表層領域でのベイナイト面積率は95.0%以上(表2中の「圧延まま材のミクロ組織」欄で「Y」)であり、SA材において、少なくとも表面から0.1R深さまでの表層領域のミクロ組織がフェライト及びセメンタイトとからなり、表層領域でのセメンタイトの球状化率が90.0%以上(表2中の「SA材のミクロ組織」欄で「Y」)であった。その結果、圧延まま材での限界圧縮率は50%以上であり、SA材での限界圧縮率は75%以上であり、優れた限界圧縮率を示した。
Claims (4)
- 鋼材であって、
質量%で、
C:0.09~0.16%、
Si:0.01~0.50%、
Mn:0.40~0.60%、
P:0.030%以下、
S:0.025%以下、
Cr:0.90~2.00%、
Mo:0.10~0.40%、
Al:0.005~0.030%、
Ti:0.010~0.050%未満、
Nb:0.010~0.030%、
N:0.0080%以下、
O:0.0030%以下、
B:0.0003~0.0030%、
Ca:0.0005~0.0050%、を含有し、
残部がFe及び不純物からなり、式(1)~式(3)を満たし、
前記鋼材の軸方向に平行な断面において、質量%でMn含有量が10.0%以上、S含有量が10.0%以上、O含有量が10.0%未満であるMn硫化物が70.0個/mm2以下であり、質量%でO含有量が10.0%以上である酸化物が25.0個/mm2以下である、
鋼材。
0.140<C+0.194×Si+0.065×Mn+0.012×Cr+0.033×Mo+0.067×Ni+0.097×Cu+0.078×Al<0.235 (1)
13.0<(0.70×Si+1)×(5.1×Mn+1)×(2.2×Cr+1)×(3.0×Mo+1)×(0.36×Ni+1)<45.0 (2)
0.004<Ti-N×(48/14)<0.030 (3)
ここで、式(1)~式(3)の各元素記号には、対応する元素の含有量(質量%)が代入される。対応する元素が含有されていない場合、その元素記号には「0」が代入される。 - 請求項1に記載の鋼材であって、
前記鋼材の軸方向に垂直な断面での半径をR(mm)と定義したとき、前記鋼材の軸方向に垂直な断面におけるミクロ組織において、少なくとも表面から0.1R深さまでの表層領域でのベイナイトの面積率が95.0%以上である、
鋼材。 - 請求項1に記載の鋼材であって、
前記鋼材の軸方向に垂直な断面での半径をR(mm)と定義したとき、前記鋼材の軸方向に垂直な断面におけるミクロ組織において、少なくとも表面から0.1R深さまでの表層領域は、フェライトと、セメンタイトとからなり、前記表層領域での前記セメンタイトの球状化率が90.0%以上である、
鋼材。 - 請求項1~請求項3のいずれか1項に記載の鋼材であって、
前記Feの一部に代えて、質量%で、
Cu:0.50%以下、
Ni:0.30%以下、及び、
V:0.10%以下、
からなる群から選択される1元素以上を含有する、
鋼材。
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