JP4127143B2 - Constant velocity joint outer ring having excellent fatigue characteristics and method of manufacturing the same - Google Patents

Description

【００５８】
【表２】

【００５９】
【表３】

【００６０】
表２および表３から明らかなように、本発明で規定した成分組成範囲を満足し、かつ本発明の高周波焼入れ条件を満たす条件でマウス部内周面に焼入れを施した等速ジョイント外輪はいずれも、マウス部内周面の表面硬化層の旧オーステナイト粒径が全厚にわたって12μm 以下を満たしており、その結果優れた転動疲労特性を得ることができた。
なお、表３中のＮo.1 とＮo.３９とを比較すると、マウス部内周面だけでなくステム部外周面についても、本発明の高周波焼き入れ条件を満たす条件で焼き入れを施し、表面硬化層の旧オーステナイト粒径が全厚にわたって12μｍ以下を満たすようにすることで、等速ジョイント外輪のねじり疲労強度をも向上できることがわかる。
【００６１】
また、表３中のNo.1と２あるいはNo.4と５を比較すると、焼入れ回数を１回から２回に増やすことで、表面硬化層の粒径が微細化し、疲労特性がさらに向上することが分かる。
【００６２】
さらに、No.8, No.37, No.38を比較すると、焼入れ回数を１回から２回に増やした場合において、２回目の焼入れ深さの方が浅い場合（No.37)には、１回しか施さなかった場合よりも疲労特性はむしろ劣化するのに対し、２回目の焼入れ深さを深くした場合（No.38)には、１回しか施さなかった場合に比べてねじり疲労強度は大幅に向上した。No.38 では、硬化層厚方向で、表面から硬化層厚の 4/5位置で最も旧オーステナイト粒径が大きく、3.5 μm であったが、表層近傍（表面から硬化層厚の 1/5位置）では旧オーステナイト粒径は 2.6μm であり、表層の粒径が微細化していることが、疲労特性の向上に寄与したものと考えられる。
【００６３】
これに対し、No.11 は、加工後の冷却速度が小さいため、ベイナイトとマルテンサイトの合計組織分率が10％未満となっており、その結果、表面硬化層粒径が粗大となり、疲労特性が悪い。
No.24 は、表面硬化層粒径は微細であるものの、Ｃ含有量が本発明の範囲より高いため、粒界強度の低下を招き、そのため疲労特性が劣っている。
No,25, 26, 27 は、それぞれＣ, Si, Moの含有量が本発明の適正範囲よりも低いため、表面硬化層粒径が粗大となり、疲労特性が劣っている。
No.28 はＢ含有量が低く、またNo.29 はMn含有量が、No.30 はＳおよびＰ含有量が、No.31 はCr含有量が、それぞれ本発明の適正範囲を超えているため、いずれも粒界強度の低下を招き、疲労特性が劣っている。
No.32 は、Ti含有量が本発明の適正範囲を超えているため、疲労特性が劣っており、逆にNo.35 はTi含有量が低いため、表面硬化層粒径が粗大となり、疲労特性が劣っている。
No.33 は、高周波焼入れ時の加熱温度が高すぎるため表面硬化層の粒径が粗大となり、一方No.34 は、高周波焼入れ時の加熱温度が低すぎるため表面硬化層が形成されず、いずれも疲労特性に劣っている。
No.36 は、Si量が本発明の下限に満たない0.28mass％の場合であるが、この例のように、Si量が本発明の下限をわずかでも下回る場合には、表面硬化層全厚にわたって12μm 以下の粒径を得ることができず、その結果、疲労特性に劣っている。
【００６４】
【発明の効果】
かくして、本発明によれば、優れた疲労特性を有する等速ジョイント外輪を安定して得ることができ、その結果、自動車用部材の軽量化の要求に対し偉功を奏する。
【図面の簡単な説明】
【図１】 等速ジョイントの部分断面図である。
【図２】 等速ジョイント外輪のにおける表面硬化層を示す断面図である。
【符号の説明】
１ ドライブシャフト
２ ハブ
３ 等速ジョイント
４ 外輪
４ａ マウス部
４ｂ ステム部
５ 内輪
６ ボール
７ 表面硬化層[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an outer ring of a constant velocity joint that has a hardened layer by induction hardening and is used for a drive axle of a power transmission device of an automobile or an industrial machine, and has excellent fatigue characteristics, and a method for manufacturing the same.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in a power transmission device for an automobile, the driving axle on the wheel side is usually via a constant velocity joint 3 to transmit power from the drive shaft 1 to the hub 2 of the wheel as shown in FIG. is there.
The constant velocity joint 3 is a combination of an outer ring 4 and an inner ring 5. That is, the inner ring 5 is slidably fixed to the inner side of the mouse part 4a via a ball 6 fitted in a ball raceway groove formed on the inner surface of the mouse part 4a of the outer ring 4, and the drive shaft 1 is attached to the inner ring 5. On the other hand, the stem 4b of the outer ring 4 is splined to the hub 2, for example, to transmit power from the drive shaft 1 to the hub 2 of the wheel.
[0003]
The outer ring of the constant velocity joint is subjected to hot forging, further cold forging, rolling, etc. on a hot rolled steel bar and processed into a predetermined shape, followed by induction quenching and tempering. It is common to form a hardened surface layer by induction hardening on the outer peripheral surface and the inner peripheral surface of the mouse part, respectively, to ensure the torsional fatigue strength and rolling fatigue strength which are important characteristics for this kind of application ( Patent Document 1).
[0004]
On the other hand, due to environmental problems in recent years, there is a strong demand for weight reduction of automobile members. From this viewpoint, further improvement of the fatigue strength of automobile members is required.
In order to improve the fatigue strength, for example, it is conceivable to increase the quenching depth by induction hardening. However, even if the quenching depth is increased, the fatigue strength is saturated at a certain depth.
Further, improvement of the grain boundary strength is also effective for improving the torsional fatigue strength. From this viewpoint, a technique for refining the prior austenite grain size by dispersing TiC has been proposed (see, for example, Patent Document 2). ).
[0005]
In the technique described in Patent Document 2 described above, since fine TiC is dispersed in a large amount at the time of induction quenching heating, the prior austenite grain size is refined, so that TiC is solutionized before quenching. It is necessary to adopt a process of heating to 1100 ° C or higher in the hot rolling process. Therefore, there is a problem that it is necessary to increase the heating temperature during hot rolling, resulting in poor productivity.
Moreover, even with the technique disclosed in Patent Document 2 described above, there is still a problem in that it cannot sufficiently meet the recent demand for rolling fatigue strength.
[0006]
Further, in Patent Document 3, the ratio (CD / R) between the hardened layer depth CD and the radius R of the induction-hardened shaft component is limited to 0.3 to 0.7, and from this CD / R and the surface after induction hardening. The value A defined by the austenite grain size γf up to 1 mm, the average Vickers hardness Hf up to (CD / R) = 0.1 as induction-quenched, and the average Vickers hardness Hc at the center of the shaft after induction hardening is expressed as C There has been proposed a shaft object part for a machine structure in which torsional fatigue strength is improved by controlling it within a predetermined range according to the amount.
However, in this part, no consideration is given to the rolling fatigue strength, and no consideration is given to the prior austenite grain size over the entire thickness of the hardened hardened layer. I cannot respond enough.
[0007]
[Patent Document 1]
JP-A-8-74874 (Claims)
[Patent Document 2]
JP 2000-154819 A (Claims, paragraph [0008])
[Patent Document 3]
JP-A-8-53714 (Claims)
[0008]
[Problems to be solved by the invention]
The present invention has been developed in view of the above-described present situation, and an object thereof is to propose a constant velocity joint outer ring having a further improved fatigue strength together with its advantageous manufacturing method.
[0009]
[Means for Solving the Problems]
Now, the inventors diligently studied in order to effectively improve the fatigue strength.
As a result, excellent fatigue strength can be obtained by optimizing the chemical composition, structure, quenching conditions, and prior austenite grain size over the entire thickness of the hardened surface layer after quenching, as described below. The knowledge that it will be.
[0010]
(1) When the constant velocity joint outer ring adjusted to an appropriate chemical composition is quenched and the prior austenite grain size over the entire thickness of the hardened surface layer after quenching is 12 μm or less, the fatigue strength is remarkably improved. Specifically, regarding the chemical composition, the addition of Si and Mo in an appropriate range increases the number of austenite nucleation sites during induction hardening and suppresses the growth of austenite grains. The particle size of the hardened surface layer is effectively refined, and as a result, the rolling fatigue strength and the torsional fatigue strength are remarkably improved. In particular, by adding Si in an amount of 0.30 mass% or more, a surface hardened layer having a particle size of 12 μm or less can be obtained over the entire thickness of the surface hardened layer after induction hardening.
[0011]
(2) If the base metal structure of the constant velocity joint outer ring, that is, the structure before quenching is made into a structure containing a bainite structure and / or martensite structure in a specific fraction, the bainite structure or martensite structure is ferrite-pearlite. Since the carbide is a finely dispersed structure as compared with the structure, the area of the ferrite / carbide interface that is the nucleation site of austenite increases during quenching heating, and the generated austenite becomes finer. As a result, the particle size of the surface hardened layer becomes fine, thereby improving the grain boundary strength and increasing the rolling fatigue strength and the torsional fatigue strength.
[0012]
(3) As described above, by properly controlling the induction hardening conditions (heating temperature, time, number of times of quenching) for the constant velocity joint outer ring whose chemical composition and structure are adjusted, the hardened layer particle size is remarkably refined. , Grain boundary strength is improved. Specifically, by setting the heating temperature to 800 to 1000 ° C. and the heating time to 5 seconds or less, fine particles having a particle size of 12 μm or less can be stably obtained over the entire thickness of the surface hardened layer. Furthermore, by repeating the quenching process under the above conditions twice or more, a finer surface hardened layer particle size can be obtained as compared with one quenching.
(4) And by applying the knowledge of (1) to (3) above to the part where rolling fatigue occurs in the constant velocity joint outer ring, that is, the inner peripheral surface of the mouse part, the mouse part of the constant velocity joint outer ring Durability can be improved.
(5) Furthermore, by applying the knowledge of (1) to (3) above to the stem portion of the constant velocity joint outer ring, the torsional fatigue characteristics of the constant velocity joint outer ring are improved and the durability is further improved.
The present invention is based on the above findings.
[0013]
That is, the gist configuration of the present invention is as follows.
1. A constant velocity joint outer ring having a hardened surface layer on the inner peripheral surface of the mouse part to which the constant velocity joint inner ring is mounted,
C: 0.35-0.7 mass%
Si: 0.30 to 1.1 mass%,
Mn: 0.2-2.0 mass%
Al: 0.005 to 0.25 mass%,
Ti: 0.005 to 0.1 mass%,
Mo: 0.05-0.6 mass%,
B: 0.0003 to 0.006 mass%,
S: 0.06 mass% or less,
P: 0.02 mass% or less and
Cr: 0.2 mass% or less, the balance is Fe and inevitable impurities, the base material structure has a bainite structure and / or martensite structure, and the total of these bainite structure and martensite structure A constant velocity joint outer ring excellent in fatigue characteristics, characterized by having a structure fraction of 10% or more and a prior austenite grain size of a hardened surface layer by induction hardening being 12 μm or less over the entire thickness of the hardened surface layer.
[0014]
2. 3. The constant velocity joint outer ring having excellent fatigue characteristics, wherein the hardened surface layer is further provided on an outer peripheral surface of a stem portion serving as a power transmission portion.
[0015]
3. 3. The constant velocity joint outer ring having excellent fatigue characteristics, wherein the thickness of the surface hardened layer is 2 mm or more in 1 or 2 above.
[0016]
4). In any one of 1 to 3 above, the constant velocity joint outer ring further includes:
Cu: 1.0 mass% or less,
Ni: 3.5 mass% or less,
Co: 1.0 mass% or less,
A constant velocity joint outer ring excellent in fatigue characteristics, characterized by having a composition containing one or more selected from Nb: 0.1 mass% or less and V: 0.5 mass% or less.
[0017]
5. C: 0.35-0.7 mass%
Si: 0.30 to 1.1 mass%,
Mn: 0.2-2.0 mass%
Al: 0.005 to 0.25 mass%,
Ti: 0.005 to 0.1 mass%,
Mo: 0.05-0.6 mass%,
B: 0.0003 to 0.006 mass%,
S: 0.06 mass% or less,
P: 0.02 mass% or less and
Cr: The steel material containing 0.2 mass% or less, with the balance being Fe and inevitable impurities, and forming the mouse part and stem part of the constant velocity joint outer ring by hot working, then 0.2 ° C / s or more It has excellent fatigue characteristics, characterized by forming a hardened surface layer on the inner peripheral surface of the mouse part by performing induction hardening under the condition of heating temperature: 800-1000 ° C after cooling at a speed, A method for manufacturing a constant velocity joint outer ring.
[0018]
6). 5. The method for producing a constant velocity joint outer ring having excellent fatigue characteristics, wherein the induction hardening is further performed on the outer peripheral surface of the stem portion to form a hardened surface layer.
[0019]
7). In the above 5 or 6, the steel material is further
Cu: 1.0 mass% or less,
Ni: 3.5 mass% or less,
Co: 1.0 mass% or less,
A method for producing a constant velocity joint outer ring having excellent fatigue characteristics, characterized in that the composition contains one or more selected from Nb: 0.1 mass% or less and V: 0.5 mass% or less.
[0020]
8). 5. The constant velocity joint outer ring having excellent fatigue characteristics, wherein the induction hardening is repeated a plurality of times after the cutting, and the heating temperature at the final induction hardening is set to 800 to 1000 ° C. Manufacturing method.
[0021]
9. 8. The method for producing a constant velocity joint outer ring having excellent fatigue characteristics, wherein the heating temperature during induction hardening is set to 800 to 1000 ° C. for all of the plurality of induction hardenings.
[0022]
10. 10. The method for producing a constant velocity joint outer ring having excellent fatigue characteristics, wherein the heating time in the heating temperature range is 5 seconds or less per induction hardening.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
The present invention will be specifically described below.
That is, as shown in FIG. 2, the constant velocity joint outer ring of the present invention has a hardened surface layer 7 on at least the inner peripheral surface of the mouse portion 4a and further on the outer peripheral surface of the stem portion 4b. The prior austenite grain size in No. 7 is 12 μm or less over the entire thickness of the surface hardened layer.
[0024]
Such a constant velocity joint outer ring will first be described for the reason that its component composition is limited to the above range.
C: 0.35-0.7 mass%
C is an element having the greatest influence on hardenability, and increases the hardness and depth of the hardened hardened layer and contributes effectively to the improvement of rolling strength and torsional fatigue strength. However, in order to ensure the required rolling strength and torsional fatigue strength when the content is less than 0.35 mass%, the quench hardening depth must be dramatically increased, and the occurrence of quenching cracks is remarkable at that time. In addition, since it becomes difficult to form a bainite structure, 0.35 mass% or more is added. On the other hand, if the content exceeds 0.7 mass%, the grain boundary strength is lowered, and accordingly, rolling fatigue strength and torsional fatigue strength are lowered, and machinability, cold forgeability and fire cracking resistance are also lowered. For this reason, C was limited to the range of 0.35 to 0.7 mass%. Preferably it is the range of 0.4-0.6 mass%.
[0025]
Si: 0.30 to 1.1 mass%
Si has the effect of increasing the number of nucleation sites of austenite during quenching heating, suppressing the grain growth of austenite, and reducing the grain size of the quenched hardened layer. Moreover, carbide | carbonized_material production | generation is suppressed and the fall of the grain boundary strength by carbide | carbonized_material is suppressed. Furthermore, it is an element useful for the formation of a bainite structure, and these improve rolling fatigue strength and torsional fatigue strength.
Thus, Si is a very important element in the present invention, and it is essential to contain 0.30 mass% or more. This is because if the Si amount is less than 0.30 mass%, fine particles having a particle diameter of 12 μm or less cannot be obtained over the entire thickness of the cured layer, regardless of how the manufacturing conditions and quenching conditions are adjusted. However, if the Si content exceeds 1.1 mass%, the hardness increases due to the solid solution hardening of ferrite, leading to a decrease in machinability and cold forgeability. Therefore, Si was limited to the range of 0.30 to 1.1 mass%. Preferably it is the range of 0.40-1.0 mass%.
[0026]
Mn: 0.2 to 2.0 mass%
Mn is an essential component for improving the hardenability and ensuring the hardening depth during quenching, so it is actively added, but if the content is less than 0.2 mass%, the effect of addition is poor, so 0.2% More than mass%. Preferably it is 0.3 mass% or more. On the other hand, if the amount of Mn exceeds 2.0 mass%, the retained austenite after quenching increases, and the surface hardness decreases. As a result, the rolling fatigue strength and the torsional fatigue strength decrease, so Mn is set to 2.0 mass% or less. . It should be noted that if the content of Mn is large, the base material is hardened, which may be disadvantageous in machinability. Therefore, it is preferable to set the content to 1.2 mass% or less. More preferably, it is 1.0 mass% or less.
[0027]
Al: 0.005 to 0.25 mass%
Al is an element effective for deoxidation. Moreover, it is an element useful also in refine | miniaturizing the particle size of a hardening hardening layer by suppressing the austenite grain growth at the time of quenching heating. However, if the content is less than 0.005 mass%, the effect of addition is poor. On the other hand, even if the content exceeds 0.25 mass%, the effect is saturated, and rather, a disadvantage that causes an increase in the component cost occurs. Limited to a range of ~ 0.25 mass%. Preferably it is the range of 0.05-0.06 mass%.
[0028]
Ti: 0.005 to 0.1 mass%
Ti combines with N mixed as an unavoidable impurity to prevent B from becoming BN and the effect of improving the hardenability of B to disappear, and has the effect of sufficiently exerting the effect of improving the hardenability of B. . In order to obtain this effect, the content of at least 0.005 mass% is required. However, if it exceeds 0.1 mass%, a large amount of TiN is formed, which becomes the starting point of fatigue fracture and rolling fatigue. Since the strength and torsional fatigue strength are significantly reduced, Ti is limited to the range of 0.005 to 0.1 mass%. Preferably it is the range of 0.01-0.07 mass%. Furthermore, it is preferable to satisfy Ti (mass%) / N (mass%) ≧ 3.42 from the viewpoint of securing N securely and improving the hardenability by B to obtain a bainite and martensite structure.
[0029]
Mo: 0.05-0.6 mass%
Mo promotes the formation of a bainite structure, thereby reducing the austenite grain size during quenching and heating, and reducing the grain size of the surface hardened layer. Moreover, it has the effect | action which refines | miniaturizes the particle size of a surface hardening layer by suppressing the grain growth of austenite at the time of quenching heating. Furthermore, since it is an element useful for improving hardenability, it is used for adjusting hardenability. In addition, Mo is an element that suppresses the formation of carbides and effectively prevents a decrease in grain boundary strength due to carbides.
Thus, Mo is a very important element in the present invention, and if the content is less than 0.05 mass%, the particle size over the entire thickness of the surface hardened layer is adjusted no matter how the manufacturing conditions and quenching conditions are adjusted. However, it cannot be made fine particles of 12 μm or less. However, if the content exceeds 0.6 mass%, the hardness of the rolled material is remarkably increased, and the workability is reduced. Therefore, Mo is limited to the range of 0.05 to 0.6 mass%. Preferably it is the range of 0.1-0.6 mass%.
[0030]
B: 0.0003 to 0.006 mass%
B has an effect of promoting the formation of a bainite structure or a martensite structure. B also has the effect of improving hardenability by adding a small amount and improving rolling fatigue strength and torsional fatigue strength by increasing the quenching depth during quenching. Further, B preferentially segregates at the grain boundaries, reduces the concentration of P segregating at the grain boundaries, improves the grain boundary strength, and thus has the effect of improving rolling fatigue strength and torsional fatigue strength.
For this reason, in the present invention, B is positively added, but if the content is less than 0.0003 mass%, the effect of addition is poor. On the other hand, if the content exceeds 0.006 mass%, the effect is saturated, rather the component In order to raise the cost, B is limited to the range of 0.0003 to 0.006 mass%. Preferably it is the range of 0.0005-0.004 mass%.
[0031]
S: 0.06 mass% or less S is a useful element that improves the machinability by forming MnS in steel, but if it exceeds 0.06 mass%, it segregates at the grain boundary and lowers the grain boundary strength. , S was limited to 0.06 mass% or less. Preferably it is 0.04 mass% or less.
[0032]
P: 0.020 mass% or less P segregates at the grain boundaries of austenite and lowers the grain boundary strength, thereby lowering the rolling fatigue strength and the torsional fatigue strength. In addition, there is a harmful effect that promotes burning cracks. Therefore, it is desirable to reduce the P content as much as possible, but it is allowed up to 0.020 mass%.
[0033]
Cr: 0.2 mass% or less
Cr stabilizes carbides and promotes the formation of residual carbides, lowers the grain boundary strength, and degrades rolling fatigue strength and torsional fatigue strength. Therefore, it is desirable to reduce the Cr content as much as possible, but up to 0.2 mass% is acceptable. Preferably it is 0.05 mass% or less.
[0034]
The basic components have been described above. However, in the present invention, other elements described below can be appropriately contained.
Cu: 1.0 mass% or less
Cu is effective for improving the hardenability, and also dissolves in ferrite, and this solid solution strengthening improves rolling fatigue strength and torsional fatigue strength. Further, by suppressing the formation of carbides, the decrease in grain boundary strength due to the carbides is suppressed, and the rolling fatigue strength and the torsional fatigue strength are improved. However, if the content exceeds 1.0 mass%, cracking occurs during hot working, so 1.0 mass% or less is added. In addition, Preferably it is 0.5 mass% or less.
[0035]
Ni: 3.5 mass% or less
Since Ni is an element that improves hardenability, Ni is used when adjusting hardenability. Moreover, it is an element which suppresses the production | generation of a carbide | carbonized_material and suppresses the fall of the grain boundary strength by a carbide | carbonized_material, and improves torsional fatigue strength. However, Ni is an extremely expensive element, and if added over 3.5 mass%, the cost of the constant velocity joint outer ring will increase. In addition, since the effect of improving hardenability and the effect of suppressing the decrease in grain boundary strength are small when added at less than 0.05 mass%, it is desirable to add 0.05 mass% or more. Preferably it is 0.1-1.0 mass%.
[0036]
Co: 1.0 mass% or less
Co is an element that suppresses the formation of carbides, suppresses a decrease in grain boundary strength due to carbides, and improves rolling fatigue strength and torsional fatigue strength. However, Co is an extremely expensive element, and if added in excess of 1.0 mass%, the cost of the constant velocity joint outer ring will increase, so it should be added at 1.0 mass% or less. In addition, since addition of less than 0.01 mass% has a small effect of suppressing the decrease in grain boundary strength, it is desirable to add 0.01 mass% or more. Preferably it is 0.02-0.5 mass%.
[0037]
Nb: 0.1 mass% or less
Nb not only has an effect of improving hardenability, but also combines with C and N in steel and acts as a precipitation strengthening element. It is also an element that improves tempering and softening resistance. These effects improve rolling fatigue strength and torsional fatigue strength. However, since the effect is saturated even if it contains exceeding 0.1 mass%, 0.1 mass% is made an upper limit. In addition, if less than 0.005% is added, the effect of improving precipitation strengthening and tempering softening resistance is small, so it is desirable to add 0.005 mass% or more. Preferably it is 0.01-0.05 mass%.
[0038]
V: 0.5 mass% or less V combines with C and N in steel and acts as a precipitation strengthening element. It is also an element that improves tempering softening resistance, and these effects improve rolling fatigue strength and torsional fatigue strength. However, since the effect is saturated even if it contains exceeding 0.5 mass%, it shall be 0.5 mass% or less. In addition, since the improvement effect of fatigue strength is small when added less than 0.01 mass%, it is desirable to add 0.01 mass% or more. Preferably it is 0.03-0.3 mass%.
[0039]
The preferred component composition range has been described above. However, in the present invention, it is not sufficient to limit the component composition to the above range, and adjustment of the matrix structure is also important.
That is, in the present invention, the base material structure of the constant velocity joint outer ring, that is, the structure before quenching (corresponding to the structure other than the surface hardened layer after induction hardening) has a bainite structure and / or a martensite structure, and The total structure fraction of the bainite structure and martensite structure must be 10% or more in terms of volume fraction (vol%). The reason for this is that the bainite structure or martensite structure is a structure in which carbides are finely dispersed compared to the ferrite-pearlite structure, so the area of the ferrite / carbide interface, which is an austenite nucleation site, is increased during quenching heating. This is because the generated austenite is made finer, and thus contributes effectively to making the grain size of the hardened surface hardened layer finer. And by grain refinement | miniaturization of the surface hardened layer, grain boundary strength rises and rolling fatigue strength and torsional fatigue strength improve. Here, the total structure fraction of the bainite structure and the martensite structure is more preferably 20 vol% or more.
[0040]
The remaining structure other than the bainite structure or martensite structure may be ferrite, pearlite, or the like, and is not particularly defined.
Further, regarding the refinement of the grain size of the hardened surface layer after quenching, the martensite structure has the same effect as the bainite structure, but from an industrial point of view, the bainite structure is better than the martensite structure. Since the amount of the alloy element added is smaller and it can be produced at a low cooling rate, it is advantageous in production.
[0041]
Further, in the constant velocity joint outer ring of the present invention, the prior austenite particle size needs to be 12 μm or less over the entire thickness of the hardened surface layer of the inner peripheral surface of the mouse portion after induction hardening. This is because if the prior austenite grain size over the entire thickness of the surface hardened layer exceeds 12 μm, sufficient grain boundary strength cannot be obtained, and satisfactory improvement in torsional fatigue strength cannot be expected. The thickness is preferably 10 μm or less, more preferably 5 μm or less.
[0042]
Here, the measurement of the prior austenite particle size over the entire thickness of the hardened surface layer is performed as follows.
In the constant velocity joint outer ring of the present invention after induction hardening, the outermost surface layer of the inner peripheral surface of the mouse part subjected to induction hardening has a martensite structure of 100% in area ratio. And as it goes from the surface to the inside, the area of 100% martensite structure continues at a certain depth, but the area ratio of the martensite structure decreases rapidly from a certain depth.
In the present invention, the depth region from the surface of the inner peripheral surface of the mouse portion of the constant velocity joint outer ring to the region where the martensite structure area ratio is reduced to 98% is defined as the surface hardened layer.
Then, for this surface hardened layer, the average prior austenite particle size at each of the 1/5 position, 1/2 position and 4/5 position of the hardened layer thickness from the surface was measured, and any average prior austenite particle diameter was 12 μm. In the following cases, it is assumed that the prior austenite grain size over the entire thickness of the surface hardened layer is 12 μm or less.
The average prior austenite grain size is measured 400 times (1 field area: 0.25 mm x 0.225 mm) to 1000 times (1 field area: 0.10 mm x 0.09 mm) at each position using an optical microscope. This is done by observing 5 fields of view and measuring the average particle size with an image analyzer.
[0043]
Furthermore, in the present invention, the thickness of the surface hardened layer by induction hardening is preferably 2 mm or more. This is because when the surface hardened layer thickness is too small, rolling stress affects the non-hardened layer and causes damage from the non-hardened layer.
Moreover, in this invention, it is preferable to have the surface hardened layer mentioned above also in the outer peripheral surface of a stem part. The stem part is a part where torsional fatigue occurs because torsional force is applied, but the above-mentioned hardened surface layer is effective not only for rolling fatigue but also for improving torsional fatigue strength. The torsional fatigue strength of the constant velocity joint outer ring is also improved by forming a hardened surface layer on the outer peripheral surface.
Also in this case, the surface hardened layer thickness is preferably 2 mm or more, more preferably 2.5 mm or more, and further preferably 3 mm or more.
In the stem portion of the constant velocity joint outer ring, the torsional fatigue failure is most likely to occur near the boundary between the contact portion with the hub and the non-contact portion. It is preferable to have a thickness.
[0044]
Next, conditions for manufacturing the constant velocity joint outer ring of the present invention will be described.
First, a steel bar obtained by rolling a steel material adjusted to a predetermined component composition is cut into a predetermined length, and then the mouse part and the stem part of the constant velocity joint outer ring are integrally formed by hot forging, as necessary. Next, the ball rail groove on the inner surface of the constant velocity joint outer ring is formed by cold forging, and the forming of the spline shaft on the stem portion of the constant velocity joint outer ring is performed by rolling. Then, induction hardening is performed on the outer surface of the inner peripheral surface of the mouse portion, more preferably, the outer peripheral surface of the stem portion to obtain a product.
[0045]
In the present invention, the base material structure has the above-described bainite structure and / or martensite structure, and the total structure fraction of these bainite structure and martensite structure is 10 vol% or more. The material before quenching needs to be cooled at a rate of 0.2 ° C / s or higher after being processed into a predetermined shape by hot working such as forging. This is because when the cooling rate is less than 0.2 ° C./s, it becomes difficult to obtain a bainite or martensite structure, and the total structure fraction of these structures may not reach 10 vol%. The preferable range of the cooling rate after hot working is 0.3 to 30 ° C./s.
[0046]
In addition, it is preferable to perform hot working in a temperature range of over 900 ° C. to 1150 ° C. If the temperature is 900 ° C. or lower, the necessary bainite structure and / or martensite structure cannot be obtained. On the other hand, if it exceeds 1150 ° C., the heating cost increases, which is economically disadvantageous.
[0047]
Next, in the present invention, induction hardening is performed in order to obtain the above-described hardened surface layer, and the heating temperature range during this induction hardening needs to be 800-1000 ° C. This is because when the heating temperature is less than 800 ° C., the austenite structure is not sufficiently generated, and the surface hardened layer structure described above is insufficiently generated. As a result, sufficient fatigue strength cannot be ensured. When the heating temperature exceeds 1000 ° C., the growth of austenite grains is promoted and becomes coarse, and the grain size of the surface hardened layer becomes coarse, so that the fatigue strength is also lowered. A more preferable heating temperature range is 800 to 950 ° C.
[0048]
When the above-described induction hardening is repeated a plurality of times, at least the final induction hardening may be performed at a heating temperature of 800 to 1000 ° C. Here, when induction hardening is repeated a plurality of times, it is most desirable to set the heating temperature to 800 to 1000 ° C. for all induction hardening. Further, by performing repeated quenching twice or more, a finer surface hardened layer particle size can be obtained as compared with the single quenching.
[0049]
When induction hardening is repeated a plurality of times, it is preferable that at least the final quenching depth by induction hardening be equal to or greater than the previous quenching depth by induction hardening. This is because the crystal grain size of the hardened surface layer is most strongly affected by the last induction hardening, so if the quenching depth by the last induction hardening is smaller than the previous quenching depth by induction hardening, the surface This is because the average grain size over the entire thickness of the hardened layer is rather increased, and the fatigue strength tends to decrease.
[0050]
Further, in the present invention, the induction hardening is preferably performed with the heating time in the above heating temperature range being 5 seconds or less. This is because when the heating time is set to 5 seconds or less, the austenite grain growth can be further suppressed as compared with the case where the heating time exceeds 5 seconds, and a very fine surface hardened layer particle size can be obtained. it can. A more preferable heating time is 3 seconds or less.
[0051]
【Example】
Steel materials having the composition shown in Table 1 were melted by a converter and cast into continuous slabs. The slab size was 300 × 400mm. This slab was rolled into a 150 mm square billet through a breakdown process, and then rolled into a 50 mmφ steel bar. The finishing temperature of rolling was over 900 ° C. as a suitable temperature from the viewpoint of bainite or martensite structure formation. Cooling after rolling was performed under the conditions shown in Table 2.
[0052]
Next, after cutting this steel bar to a predetermined length, the mouse part (outer diameter: 60 mm) and stem part (diameter: 20 mm) of the constant velocity joint outer ring are integrally formed by hot forging, and then at a constant speed by cold forging. In addition to forming the ball rail groove on the inner surface of the joint portion of the joint outer ring, the stem portion of the constant velocity joint outer ring was formed by rolling to form a spline shaft.
[0053]
As shown in FIG. 2, on the inner peripheral surface of the mouse portion 4a and the outer peripheral surface of the stem portion 4b of the constant velocity joint outer ring 4, quenching is performed using an induction hardening apparatus having a frequency of 15 kHz, and the surface hardened layer 7 is formed. After forming, the product was tempered using a heating furnace under the conditions of 180 ° C. × 2 h to obtain a product. Here, the quenching conditions were as shown in Table 3. The constant velocity joint outer ring thus obtained has an inner ring connected to a drive shaft via a ball (steel ball) attached to the mouth portion of the constant velocity joint unit, and the stem portion is fitted to the hub. (See Fig. 1). The specifications of the ball, inner ring and hub are as follows.
Ball: Quenched and tempered steel of high carbon chrome bearing steel SUJ 2 Inner ring: Carburized and tempered steel of chromium SCr Hub: Carbon steel for machine structure [0054]
Next, using this constant velocity joint unit, an endurance test on rolling fatigue strength and torsional fatigue strength was performed in a power transmission system that transmits the rotational motion of the drive shaft to the hub via the inner ring and outer ring of the constant velocity joint.
[0055]
In the rolling fatigue test, power is transmitted under the conditions of torque: 900 N · m, operating angle (angle formed by the outer ring axis and the drive shaft axis): 20 °, and rotation speed: 300 rpm. The time until the part was subjected to rolling fatigue failure was evaluated as the rolling fatigue strength.
Furthermore, in this power transmission system, a durability test on torsional fatigue strength was performed. Here, in the torsional fatigue test, the constant velocity joint unit operating angle is 0 °, and a torsional fatigue tester with a maximum torque of 4900N · m is used to apply a torsional force between the hub and the drive shaft. By changing the maximum torque of the stem part and changing the stress conditions by both swings, the stress that gives a life of 1 × 10 ⁵ times was evaluated as the torsional fatigue strength. In the torsional fatigue test, in order to evaluate the torsional fatigue of the constant velocity joint outer ring, the dimensions of the hub and the drive shaft were adjusted so that the strength of the hub and the drive shaft was sufficiently increased.
In addition, even in the rolling fatigue test, the dimensions and shapes of the constant velocity joint inner ring and the steel ball were set so that the inner peripheral surface of the constant velocity Jonto outer ring was the weakest part during the durability test.
[0056]
Moreover, about the constant velocity joint outer ring | wheel produced on the same conditions, the average prior austenite particle size obtained over the base material structure | tissue, the surface hardening layer thickness after hardening, and the whole thickness of a surface hardening layer was measured using the optical microscope.
Table 2 shows the results of the investigation of the base material structure, and Table 3 also shows the results of the investigation of the surface hardened layer thickness and the average prior austenite grain size.
Here, as described above, the thickness of the hardened surface layer was set to a depth at which the area ratio of the martensite structure was reduced to 98% from the surfaces of the inner peripheral surface of the mouse portion and the outer peripheral surface of the stem portion of the constant velocity joint outer ring. Moreover, about what performed induction hardening several times, the surface hardening layer thickness after each hardening was measured. Furthermore, for the surface hardened layer particle size, the average prior austenite particle size at each of the 1/5 position, 1/2 position and 4/5 position of the hardened layer thickness from the surface was measured and the maximum value was shown. . In addition, about what performed induction hardening several times, the average prior-austenite particle size after final hardening was measured.
[0057]
[Table 1]

[0058]
[Table 2]

[0059]
[Table 3]

[0060]
As is apparent from Tables 2 and 3, all the constant velocity joint outer rings that satisfy the component composition range defined in the present invention and are hardened on the inner peripheral surface of the mouse portion under the conditions satisfying the induction hardening conditions of the present invention The old austenite grain size of the surface hardened layer on the inner peripheral surface of the mouse part satisfied 12 μm or less over the entire thickness, and as a result, excellent rolling fatigue characteristics could be obtained.
In addition, when comparing No. 1 and No. 39 in Table 3, not only the inner peripheral surface of the mouse part but also the outer peripheral surface of the stem part was hardened under the conditions satisfying the induction hardening condition of the present invention, and surface hardening was performed. It can be seen that the torsional fatigue strength of the constant velocity joint outer ring can be improved by making the prior austenite grain size of the layer satisfy 12 μm or less over the entire thickness.
[0061]
In addition, when comparing No. 1 and 2 or No. 4 and 5 in Table 3, increasing the number of times of quenching from 1 to 2 makes the surface hardened layer finer and further improves the fatigue characteristics. I understand that.
[0062]
Furthermore, comparing No.8, No.37, and No.38, when the number of quenching was increased from 1 to 2 and the second quenching depth was shallower (No.37), Fatigue properties deteriorate rather than the case where it was applied only once, whereas the torsional fatigue strength is higher when the second quenching depth is increased (No. 38) than when it is applied only once. Improved significantly. In No. 38, in the thickness direction of the hardened layer, the oldest austenite grain size was 3.5 μm at the 4/5 position from the surface to the hardened layer thickness. ), The prior austenite grain size is 2.6μm, and the finer grain size of the surface layer is thought to have contributed to the improvement of fatigue properties.
[0063]
In contrast, No. 11 has a low cooling rate after processing, so the total structural fraction of bainite and martensite is less than 10%. As a result, the surface hardened layer has a coarse grain size and fatigue characteristics. Is bad.
No. 24 has a fine surface-hardened layer particle size, but its C content is higher than the range of the present invention, which leads to a decrease in grain boundary strength, and therefore fatigue properties are inferior.
In Nos. 25, 26, and 27, the contents of C, Si, and Mo are lower than the appropriate ranges of the present invention, respectively, so that the surface hardened layer particle size is coarse and fatigue characteristics are inferior.
No. 28 has a low B content, No. 29 has an Mn content, No. 30 has an S and P content, and No. 31 has a Cr content exceeding the proper range of the present invention. For this reason, both of them cause a decrease in grain boundary strength and inferior fatigue properties.
No.32 is inferior in fatigue characteristics because the Ti content exceeds the appropriate range of the present invention, and conversely No.35 has a low Ti content, resulting in a coarse surface hardened layer grain size and fatigue. The characteristics are inferior.
In No.33, the particle size of the surface hardened layer becomes coarse because the heating temperature during induction hardening is too high, while in No.34, the surface hardening layer is not formed because the heating temperature during induction hardening is too low. Is also inferior in fatigue properties.
No. 36 is the case where the Si amount is 0.28 mass% which is less than the lower limit of the present invention. However, when the Si amount is slightly below the lower limit of the present invention as in this example, the total thickness of the surface hardened layer is The particle size of 12 μm or less cannot be obtained over the entire range, and as a result, the fatigue properties are inferior.
[0064]
【The invention's effect】
Thus, according to the present invention, it is possible to stably obtain a constant velocity joint outer ring having excellent fatigue characteristics, and as a result, it is excellent for the demand for reducing the weight of automobile members.
[Brief description of the drawings]
FIG. 1 is a partial cross-sectional view of a constant velocity joint.
FIG. 2 is a cross-sectional view showing a hardened surface layer of a constant velocity joint outer ring.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Drive shaft 2 Hub 3 Constant velocity joint 4 Outer ring 4a Mouse part 4b Stem part 5 Inner ring 6 Ball 7 Surface hardening layer

Claims (10)

A constant velocity joint outer ring having a hardened surface layer on the inner peripheral surface of the mouse part to which the constant velocity joint inner ring is mounted,
C: 0.35-0.7 mass%
Si: 0.30 to 1.1 mass%,
Mn: 0.2-2.0 mass%
Al: 0.005 to 0.25 mass%,
Ti: 0.005 to 0.1 mass%,
Mo: 0.05-0.6 mass%,
B: 0.0003 to 0.006 mass%,
S: 0.06 mass% or less,
P: 0.02 mass% or less and
Cr: 0.2 mass% or less, the balance is Fe and inevitable impurities, the base material structure has a bainite structure and / or martensite structure, and the total of these bainite structure and martensite structure A constant velocity joint outer ring excellent in fatigue characteristics, characterized by having a structure fraction of 10% or more and a prior austenite grain size of a hardened surface layer by induction hardening being 12 μm or less over the entire thickness of the hardened surface layer. The constant velocity joint outer ring excellent in fatigue characteristics according to claim 1, further comprising the surface hardened layer on an outer peripheral surface of a stem portion serving as a power transmission portion. 3. The constant velocity joint outer ring having excellent fatigue characteristics according to claim 1, wherein the thickness of the surface hardened layer is 2 mm or more. The constant velocity joint outer ring according to any one of claims 1 to 3, further comprising:
Cu: 1.0 mass% or less,
Ni: 3.5 mass% or less,
Co: 1.0 mass% or less,
A constant velocity joint outer ring excellent in fatigue characteristics, characterized by having a composition containing one or more selected from Nb: 0.1 mass% or less and V: 0.5 mass% or less. C: 0.35-0.7 mass%
Si: 0.30 to 1.1 mass%,
Mn: 0.2-2.0 mass%
Al: 0.005 to 0.25 mass%,
Ti: 0.005 to 0.1 mass%,
Mo: 0.05-0.6 mass%,
B: 0.0003 to 0.006 mass%,
S: 0.06 mass% or less,
P: 0.02 mass% or less and
Cr: The steel material containing 0.2 mass% or less, with the balance being Fe and inevitable impurities, and forming the mouse part and stem part of the constant velocity joint outer ring by hot working, then 0.2 ° C / s or more It has excellent fatigue characteristics, characterized by forming a hardened surface layer on the inner peripheral surface of the mouse part by performing induction hardening under the condition of heating temperature: 800-1000 ° C after cooling at a speed, A method for manufacturing a constant velocity joint outer ring. 6. The method of manufacturing a constant velocity joint outer ring having excellent fatigue characteristics according to claim 5, further comprising forming a hardened surface layer by performing induction hardening on an outer peripheral surface of the stem portion. The steel material according to claim 5 or 6, further comprising:
Cu: 1.0 mass% or less,
Ni: 3.5 mass% or less,
Co: 1.0 mass% or less,
A method for producing a constant velocity joint outer ring having excellent fatigue characteristics, characterized in that the composition contains one or more selected from Nb: 0.1 mass% or less and V: 0.5 mass% or less. 8. The constant velocity joint excellent in fatigue characteristics according to claim 5, wherein after the cutting, induction hardening is repeated a plurality of times, and a heating temperature at the final induction hardening is set to 800 to 1000 ° C. Manufacturing method of outer ring. 9. The method for manufacturing a constant velocity joint outer ring having excellent fatigue characteristics according to claim 8, wherein the heating temperature during induction hardening is set to 800 to 1000 ° C. for all of the plurality of induction hardenings. The method for manufacturing a constant velocity joint outer ring having excellent fatigue characteristics according to any one of claims 5 to 9, wherein the heating time in the heating temperature range is 5 seconds or less per induction hardening.

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