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JPH1137163A - Inner ring for rolling bearing and heat treatment method thereof - Google Patents

Inner ring for rolling bearing and heat treatment method thereof

Info

Publication number
JPH1137163A
JPH1137163A JP9191241A JP19124197A JPH1137163A JP H1137163 A JPH1137163 A JP H1137163A JP 9191241 A JP9191241 A JP 9191241A JP 19124197 A JP19124197 A JP 19124197A JP H1137163 A JPH1137163 A JP H1137163A
Authority
JP
Japan
Prior art keywords
raceway surface
inner ring
rolling bearing
raceway
inner diameter
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
JP9191241A
Other languages
Japanese (ja)
Inventor
Hiromasa Tanaka
広政 田中
Katsunori Ito
勝教 伊藤
Seiji Mori
政治 森
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
NTN Corp
Original Assignee
NTN Corp
NTN Toyo Bearing Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by NTN Corp, NTN Toyo Bearing Co Ltd filed Critical NTN Corp
Priority to JP9191241A priority Critical patent/JPH1137163A/en
Publication of JPH1137163A publication Critical patent/JPH1137163A/en
Pending legal-status Critical Current

Links

Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F16ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
    • F16CSHAFTS; FLEXIBLE SHAFTS; ELEMENTS OR CRANKSHAFT MECHANISMS; ROTARY BODIES OTHER THAN GEARING ELEMENTS; BEARINGS
    • F16C33/00Parts of bearings; Special methods for making bearings or parts thereof
    • F16C33/30Parts of ball or roller bearings
    • F16C33/58Raceways; Race rings
    • F16C33/64Special methods of manufacture

Landscapes

  • Engineering & Computer Science (AREA)
  • General Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Mechanical Engineering (AREA)
  • Rolling Contact Bearings (AREA)
  • Heat Treatment Of Articles (AREA)

Abstract

PROBLEM TO BE SOLVED: To prevent the generation of a crack even in case of being used in a high temperature device or a high speed rotating device and facilitate manufacture by induction-hardening the raceway surface positioned on the outer peripheral surface side so as to be put in a compressive stress state. SOLUTION: The raceway surface positioned on the outer peripheral surface side of an inner ring is induction-hardened so as to be put in a compressive stress state. Because of being induction-hardened, texture near the raceway surface is transformed into martensite and is going to expand. A core part of the inner ring, on the other hand, is not transformed into martensite so as to suppress the expansion of the raceway surface. As a result, the raceway surface is put in a compressive stress state, and a crack of the inner ring can be prevented. It is desirable that the Rockwell C hardness difference between the raceway surface and the inner ring core part is 8 or more. With this constitution, the raceway surface and inner diameter surface of the inner ring formed of bearing steel, alloy steel or carbon steel have necessary strength, and the core part has low hardness so as to be able to obtain high crack fatigue strength equal to cemented steel.

Description

【発明の詳細な説明】DETAILED DESCRIPTION OF THE INVENTION

【0001】[0001]

【発明の属する技術分野】この発明は、転がり軸受の内
輪およびその熱処理方法に関し、特に、高い嵌め合い応
力下で使用される自動調心ころ軸受の内輪およびその熱
処理方法に関するものである。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an inner ring of a rolling bearing and a heat treatment method thereof, and more particularly to an inner ring of a self-aligning roller bearing used under high fitting stress and a heat treatment method thereof.

【0002】[0002]

【従来の技術】転がり軸受のうち、2列の軌道を持つ内
輪と、球面状の軌道を持つ外輪との間に球面ころを組込
んだ自動調心ころ軸受は、ラジアル荷重と両方向のスラ
スト荷重を負荷することができ、しかもラジアル負荷能
力が大きく、重荷重や衝撃荷重の作用する用途に適して
いるため、抄紙機械などの大型機械に使用される。
2. Description of the Related Art A self-aligning roller bearing in which a spherical roller is incorporated between an inner ring having two rows of races and an outer ring having a spherical race is a type of rolling bearing which has a radial load and a thrust load in both directions. It can be used for large machines such as paper machines because it has a large radial load capacity and is suitable for applications in which heavy loads and impact loads act.

【0003】この自動調心ころ軸受のうち、内輪の内径
がテーパ穴となったものは、テーパ軸へ押込んでセット
され、押込み量によって残留隙間と締めしろを調整して
使用される。押込みにより軸受の内輪は膨張し引張応力
を受ける。抄紙機械ドライヤなどに代表される大型高温
装置では、中空軸の中を高温の蒸気や油が通るため、運
転時には内輪との温度差によって軸が膨張して、引張応
力、すなわち内輪と軸との間の嵌め合い応力がさらに増
大する傾向にある。
[0003] Of these self-aligning roller bearings, those in which the inner diameter of the inner ring is a tapered hole are set by being pushed into a tapered shaft, and are used after adjusting the residual gap and interference by the pushing amount. The inner ring of the bearing expands due to the indentation and receives tensile stress. In large high-temperature equipment such as paper machine dryers, high-temperature steam and oil pass through the hollow shaft, so that during operation, the shaft expands due to the temperature difference with the inner ring, resulting in tensile stress, that is, the difference between the inner ring and the shaft. The fitting stress between them tends to further increase.

【0004】[0004]

【発明が解決しようとする課題】大きな嵌め合い応力下
で使用される内輪は、内輪軌道面が引張応力を加えられ
た状態で、転動体から繰返し応力を受けるので、軌道面
表面近傍の応力集中源(非金属介在物、微小剥離、錆な
ど)が存在すると、そこを起点として疲労き裂が軸方向
に進展し、内輪が軸方向に割れる可能性が考えられる。
この現象は、抄紙機械の軸受などの高温装置のみなら
ず、高速回転される自動調心ころ軸受でも内輪の軌道面
が大きな引張応力を受けるために損傷の発生する可能性
が高くなることも予想される。
An inner ring used under a large fitting stress receives repeated stress from rolling elements in a state where the inner ring raceway surface is subjected to a tensile stress. If there is a source (non-metallic inclusions, micro exfoliation, rust, etc.), fatigue cracks may propagate in the axial direction starting there, and the inner ring may crack in the axial direction.
This phenomenon is expected not only in high temperature equipment such as paper machine bearings, but also in spherical roller bearings rotating at high speed, the possibility of damage is increased because the raceway surface of the inner ring receives large tensile stress. Is done.

【0005】もし内輪軌道面にこのような応力集中源が
あっても上記した損傷が生じる可能性を限りなく小さく
することが機械の信頼性を向上させる意味からも必要と
される。
[0005] Even if there is such a source of stress concentration on the inner raceway surface, it is necessary to minimize the possibility of the above-mentioned damage from the viewpoint of improving the reliability of the machine.

【0006】この対策の1つに、高温装置において、軸
を冷却することが考えられるが、装置構成が複雑となる
ため、一般的な手法とは言い難い。また、遠心力の増大
による引張応力の発生は、遠心力を軽減する、すなわ
ち、回転数を小さくしない限りさけられないのでこれも
現実的ではない。
As one of the countermeasures, it is conceivable to cool the shaft in a high-temperature device, but it is difficult to say that this is a general method because the structure of the device becomes complicated. Also, the generation of a tensile stress due to an increase in the centrifugal force is not realistic because it cannot be avoided unless the centrifugal force is reduced, that is, the rotational speed is reduced.

【0007】一方、内輪の材質として、浸炭鋼を用いる
ことで内輪割れの対策となるが、浸炭焼入処理は通常の
ずぶ焼入処理と比較すると処理時間が長くなり、軸受製
造コストが高くなるという問題がある。
On the other hand, carburized steel can be used as a material for the inner ring to prevent cracking of the inner ring. However, the carburizing and quenching treatment requires a longer processing time than the normal soaking quenching treatment, and the bearing manufacturing cost increases. There is a problem.

【0008】また、高炭素クロム軸受鋼を油焼入する際
の冷却速度をコントロールして割れに強い軸受を製造す
る技術も知られているが、冷却速度のコントロールが難
しく、さらに、素材の焼入特性を調整するのが難しいと
いう問題がある。
There is also known a technique for manufacturing a bearing that is resistant to cracking by controlling the cooling rate during oil quenching of high carbon chromium bearing steel. However, it is difficult to control the cooling rate, and furthermore, the quenching of the material is difficult. There is a problem that it is difficult to adjust the input characteristics.

【0009】そこで、この発明は上述のような問題点を
解決するためになされたものであり、高温装置や高速回
転装置で使用しても割れが生じにくく、かつ、製造が容
易な転がり軸受の内輪とその熱処理方法を提供すること
を目的とするものである。
Therefore, the present invention has been made to solve the above-mentioned problems, and a rolling bearing which is hardly cracked even when used in a high-temperature device or a high-speed rotating device and which is easy to manufacture. An object of the present invention is to provide an inner ring and a heat treatment method therefor.

【0010】[0010]

【課題を解決するための手段】発明者らは、内輪割れの
原因について詳細に検討した結果、以下のことを発見し
た。
Means for Solving the Problems As a result of detailed examination of the cause of the inner ring crack, the inventors have found the following.

【0011】内輪割れが発生するのは軌道面に大きな引
張応力が加えられた状態で内輪が使用されるからであ
り、この引張応力を小さくする、さらに好ましくは圧縮
応力にすれば内輪割れは発生しない。
The reason why the inner ring crack occurs is that the inner ring is used in a state where a large tensile stress is applied to the raceway surface. If the tensile stress is reduced, more preferably, if the compressive stress is reduced, the inner ring crack is generated. do not do.

【0012】軌道面に圧縮応力を付与するためには、軌
道面をマルテンサイト変態させ、内輪の芯部はマルテン
サイト変態させないことが有効である。
In order to apply compressive stress to the raceway surface, it is effective to transform the raceway surface into martensite and not to transform the core of the inner ring into martensite.

【0013】このような検討結果に基づきなされたこの
発明の転がり軸受用の内輪は、外周面側に位置する軌道
面を高周波焼入して軌道面を圧縮応力状態にしたもので
ある。
The inner ring for a rolling bearing according to the present invention, which has been made on the basis of the above study results, is obtained by induction hardening the raceway surface located on the outer peripheral surface side to bring the raceway surface into a compressive stress state.

【0014】以上のように構成された転がり軸受の内輪
においては、軌道面が高周波焼入されているため、軌道
面付近の組織がマルテンサイト変態し、膨張しようとす
る。一方、高周波焼入によれば、内輪の芯部はマルテン
サイト変態しないため、この芯部が軌道面の膨張を抑え
ようとする。その結果、軌道面が圧縮応力状態となり、
内輪の割れを防止することができる。
In the inner race of the rolling bearing constructed as described above, since the raceway surface is induction hardened, the structure near the raceway surface is transformed into martensite and tends to expand. On the other hand, according to induction hardening, the core portion of the inner ring does not undergo martensitic transformation, and this core portion attempts to suppress the expansion of the raceway surface. As a result, the raceway surface becomes in a compressive stress state,
Cracking of the inner ring can be prevented.

【0015】また、軌道面のHRC(Cスケールのロッ
クウェル硬度)と内輪芯部のHRCとの差が8以上であ
ることが好ましい。ここで、「内輪芯部」とは、内輪の
内部のうち、軌道面と内径面とからほぼ等しい距離にあ
る部分をいう。
Preferably, the difference between the HRC of the raceway surface (Rockwell hardness of C scale) and the HRC of the inner race core is 8 or more. Here, the “inner ring core portion” refers to a portion of the inside of the inner ring which is located at substantially the same distance from the raceway surface and the inner diameter surface.

【0016】また、軌道面のHRCと内径面のHRCと
の差が5以上であることが好ましい。
Preferably, the difference between the HRC of the raceway surface and the HRC of the inner diameter surface is 5 or more.

【0017】さらに、内径面のHRCと内輪芯部のHR
Cとの差が8以上であることが好ましい。
Further, the HRC of the inner diameter surface and the HR of the inner race core portion are set.
The difference from C is preferably 8 or more.

【0018】またさらに、高周波焼入された軌道面のH
RCが58以上であることが好ましい。
Further, the H of the induction hardened raceway surface
Preferably, RC is 58 or more.

【0019】また、内径面のHRCが48〜55である
ことが好ましい。この発明に従った転がり軸受の内輪の
熱処理方法は、転がり軸受の内輪の外周面側に位置する
軌道面が圧縮応力状態になるように軌道面を高周波焼入
するものである。
It is preferable that the inner diameter surface has an HRC of 48 to 55. The heat treatment method for the inner race of a rolling bearing according to the present invention is to induction harden the raceway surface so that the raceway surface located on the outer peripheral surface side of the inner race of the rolling bearing is in a compressive stress state.

【0020】この方法に従えば、軌道面に圧縮応力を付
与するため、割れが生じにくい内輪を提供することがで
きる。
According to this method, a compressive stress is applied to the raceway surface, so that it is possible to provide an inner ring that is less likely to crack.

【0021】この発明の別の局面に従った転がり軸受の
内輪の熱処理方法は、転がり軸受の内輪の内径面と外周
面側に位置する軌道面とを高周波で加熱し、内径面を冷
却する速度よりも速い冷却速度で軌道面を冷却するもの
である。
According to another aspect of the present invention, there is provided a method for heat-treating an inner race of a rolling bearing, wherein the inner race and the raceway located on the outer periphery of the inner race of the rolling bearing are heated at a high frequency to cool the inner race. This is to cool the raceway surface at a faster cooling rate.

【0022】この方法に従えば、軌道面が急速に冷却さ
れるため、軌道面はマルテンサイト変態して膨張する。
このとき、内径面はゆっくりと冷却されるため、また、
内輪の内部はあまり加熱されないため、いずれもマルテ
ンサイト変態しない。その結果、内径面と芯部は膨張せ
ず、芯部が軌道面の膨張を抑えることになり、軌道面が
圧縮応力を受け、割れの生じにくい内輪を提供すること
ができる。
According to this method, the raceway surface is rapidly cooled, so that the raceway surface is transformed by martensitic expansion.
At this time, since the inner diameter surface is cooled slowly,
Since the inside of the inner ring is not heated very much, none of them undergoes martensitic transformation. As a result, the inner diameter surface and the core portion do not expand, the core portion suppresses the expansion of the raceway surface, and the raceway surface receives a compressive stress, so that it is possible to provide an inner ring that is less likely to crack.

【0023】また、この発明のさらに別の局面に従った
転がり軸受の内輪の熱処理方法は、転がり軸受の内輪の
内径面と外周面側に位置する軌道面とを高周波で加熱
し、内径面と軌道面とを冷却するものである。
Further, the heat treatment method for the inner race of a rolling bearing according to still another aspect of the present invention is characterized in that the inner race surface of the inner race of the rolling bearing and the raceway surface located on the outer peripheral surface side are heated at a high frequency, and This is to cool the raceway surface.

【0024】この方法に従えば、軌道面が高周波で加熱
され、内輪の芯部はあまり加熱されないため、軌道面で
はマルテンサイト変態が生じ、芯部ではあまり変態しな
い。その結果、膨張しようとする軌道面を芯部が抑える
ことになり、軌道面に圧縮応力が付与され、割れが生じ
にくい内輪を提供することができる。また、内径面も高
周波焼入されるため、内径面の硬度が上がり、内径面の
耐摩耗性が向上する。
According to this method, since the raceway surface is heated at a high frequency and the core of the inner ring is not heated much, martensitic transformation occurs on the raceway surface and does not transform much on the core portion. As a result, the core portion suppresses the raceway surface to be expanded, and a compressive stress is applied to the raceway surface, so that it is possible to provide an inner race that is less likely to crack. Further, since the inner diameter surface is also induction hardened, the hardness of the inner diameter surface is increased, and the wear resistance of the inner diameter surface is improved.

【0025】この発明のさらに別の局面に従った転がり
軸受の内輪の熱処理方法は、転がり軸受の内輪の内径面
を高周波で加熱した後冷却し、その後、外周面側に位置
する軌道面を高周波で加熱した後冷却するものである。
A method for heat treating the inner ring of a rolling bearing according to still another aspect of the present invention is to heat the inner diameter surface of the inner ring of the rolling bearing at a high frequency and then cool the same, and thereafter to reduce the raceway surface located on the outer peripheral surface side to a high frequency. And then cool.

【0026】この方法に従えば、まず内径面が焼入され
るため内径面が硬くなるが、その後外径面を焼入する際
に、この加熱の影響を受けて内径面が焼戻されて最適な
硬さとなる。一方、外径面は高周波で加熱され、その後
冷却されるので、マルテンサイト変態を起こす。芯部は
あまり加熱されないため、マルテンサイト変態を起こさ
ず、膨張しようとする軌道面を抑える働きをする。その
結果、軌道面に圧縮応力が付与され、割れにくい内輪を
提供することができる。
According to this method, first, the inner surface is hardened because the inner surface is quenched. However, when the outer surface is quenched, the inner surface is tempered under the influence of this heating. Optimum hardness. On the other hand, since the outer diameter surface is heated at a high frequency and then cooled, martensitic transformation occurs. Since the core is not heated so much, it does not cause martensitic transformation and acts to suppress the raceway surface which is about to expand. As a result, a compressive stress is applied to the raceway surface, and it is possible to provide an inner ring that is difficult to crack.

【0027】[0027]

【実施例】サンプルの作成 条件1(サンプルNo.1〜4の作成) 表1で示す鋼種からなるJIS呼番NU2215/60
の円筒ころ軸受の内輪全体を高周波で温度860〜88
0℃まで加熱し、軌道面が形成される外周面を水溶性冷
却材5%を含んだ水を用いて急冷した(冷却速度40℃
/s)。一方、内径面は空冷した。次に、内輪を温度1
80℃で1時間焼戻をして表1で示すサンプルNo.1
〜4を得た。
EXAMPLES Sample preparation conditions 1 ( preparation of sample Nos. 1 to 4) JIS standard number NU2215 / 60 consisting of steel types shown in Table 1
Temperature of the entire inner ring of the cylindrical roller bearing of 860-88
After heating to 0 ° C., the outer peripheral surface on which the raceway surface was formed was quenched using water containing 5% of a water-soluble coolant (cooling rate: 40 ° C.).
/ S). On the other hand, the inner diameter surface was air-cooled. Next, set the inner ring to temperature 1
After tempering at 80 ° C. for 1 hour, sample No. 1 shown in Table 1 was obtained. 1
~ 4.

【0028】[0028]

【表1】 [Table 1]

【0029】表1中「軌道面の残留応力」が負のものは
残留圧縮応力であることを示す。表2,3でも同様であ
る。
In Table 1, a negative "residual stress on the raceway surface" indicates a residual compressive stress. The same applies to Tables 2 and 3.

【0030】なお、これらのいずれのサンプルにおいて
も、内径面で硬度が一番小さく、軌道面に近づくに従っ
て硬度が増加した。
In each of these samples, the hardness was smallest on the inner diameter surface, and increased as approaching the raceway surface.

【0031】条件2(サンプルNo.5〜8の作成) 表2で示す鋼種からなるJIS呼番NU2215/60
の円筒ころ軸受の内輪の内径面と軌道面を温度860〜
880℃に加熱し、両面を同時に冷却した(冷却速度4
0℃/s)。内輪を温度180℃で1時間焼戻して表2
に示すサンプル5〜8を得た。
Condition 2 (Preparation of Sample Nos. 5 to 8) JIS No. NU2215 / 60 consisting of steel types shown in Table 2
Temperature of the inner ring surface and raceway surface of the inner ring of cylindrical roller bearings
Heated to 880 ° C. and cooled both sides simultaneously (cooling rate 4
0 ° C / s). After tempering the inner ring at 180 ° C for 1 hour, Table 2
Were obtained.

【0032】[0032]

【表2】 [Table 2]

【0033】なお、サンプル5〜8の内部硬度は、内径
面から芯部へ近づくにつれて小さくなって芯部で最小と
なり、さらに、芯部から軌道面へ近づくにつれて大きく
なった。
The internal hardness of Samples 5 to 8 decreased as the distance from the inner diameter surface to the core decreased, became minimum at the core, and increased as the distance from the core to the track surface increased.

【0034】条件3(サンプルNo.9〜12の作成) 表3で示す鋼種からなるJIS呼番NU2215/60
の円筒ころ軸受の内輪の内径面を高周波で加熱して温度
860〜880℃とし内径面を急冷した(冷却速度40
℃/s)。この内輪を温度180℃で1時間焼戻したと
ころ、内径面の硬度は表2に示す値と同様のものとなっ
た。次に、軌道面を高周波で加熱して温度860〜88
0℃とし急冷した(冷却速度40℃/s)。この内輪を
温度180℃で1時間焼戻して表3で示すサンプルN
o.9〜12を得た。
Condition 3 (Preparation of Sample Nos. 9 to 12) JIS No. NU2215 / 60 consisting of steel types shown in Table 3
The inner diameter surface of the inner ring of the cylindrical roller bearing was heated at a high frequency of 860 to 880 ° C., and the inner diameter surface was rapidly cooled (cooling speed 40
° C / s). When this inner ring was tempered at a temperature of 180 ° C. for 1 hour, the hardness of the inner diameter surface was similar to the value shown in Table 2. Next, the raceway surface is heated at a high frequency to a temperature of 860-88.
The temperature was set to 0 ° C. and quenched (cooling rate: 40 ° C./s). This inner ring was tempered at a temperature of 180 ° C. for 1 hour, and sample N shown in Table 3
o. 9-12 were obtained.

【0035】[0035]

【表3】 [Table 3]

【0036】なお、サンプルNo.9〜12について、
内径面の硬度が表2で示す値よりも小さくなっているの
は、軌道面を加熱する際の熱の影響を受けて内径面の硬
度が低下したためである。また、内輪の硬度は内径面で
一番小さく、軌道面に近づくにつれて増加した。
The sample No. About 9-12
The hardness of the inner diameter surface is smaller than the value shown in Table 2 because the hardness of the inner diameter surface is reduced by the influence of heat when heating the raceway surface. The hardness of the inner ring was smallest on the inner diameter surface, and increased as approaching the raceway surface.

【0037】(サンプルNo.13〜15の作成)比較
例として、JIS呼番NU2215/60の円筒ころ軸
受の内輪を以下の条件で処理してサンプルNo.13〜
15を得た。
(Preparation of Sample Nos. 13 to 15) As a comparative example, the inner ring of a cylindrical roller bearing of JIS No. NU2215 / 60 was processed under the following conditions, and the sample No. 13 was prepared. 13 ~
15 was obtained.

【0038】SUJ2を温度850℃で70分保った
後、温度120℃の油で焼入れをした。次に、このSU
J2を温度180℃で120分保って焼戻してサンプル
No.13を得た。
After maintaining SUJ2 at a temperature of 850 ° C. for 70 minutes, it was quenched with an oil at a temperature of 120 ° C. Next, this SU
J2 was kept at a temperature of 180 ° C. for 120 minutes and tempered to obtain a sample No. 13 was obtained.

【0039】SUJ3を温度825℃で70分保った
後、温度120℃の油で焼入れをした。次に、このSU
J3を温度180℃で120分保って焼戻してサンプル
No.14を得た。
After keeping SUJ3 at a temperature of 825 ° C. for 70 minutes, it was quenched with oil at a temperature of 120 ° C. Next, this SU
J3 was kept at a temperature of 180 ° C. for 120 minutes and tempered. 14 was obtained.

【0040】SCR420を浸炭性ガス中、温度890
℃で96分、温度920℃で72分、温度950℃で2
40分、温度910℃で72分、および温度860℃で
72分の順に保って浸炭した後、温度120℃の油で焼
入れをした。次に、このSCR420を温度180℃で
120分保って焼戻してサンプルNo.15を得た。
The SCR 420 was placed in a carburizing gas at a temperature of 890.
96 ° C, 72 minutes at 920 ° C, 2 minutes at 950 ° C
Carburizing was carried out for 40 minutes, at a temperature of 910 ° C. for 72 minutes, and at a temperature of 860 ° C. for 72 minutes, followed by quenching with oil at a temperature of 120 ° C. Next, this SCR420 was kept at a temperature of 180 ° C. for 120 minutes and tempered to obtain a sample no. 15 was obtained.

【0041】割れ疲労寿命試験 サンプルNo.1〜15について、内輪の軌道面に長さ
5mm、幅0.2mm、深さ0.25mmの人工傷を放
電加工で付与した。この内輪を軸受に組込んで試験軸受
とし、転動により内輪割れが発生するか否かを調べた。
試験条件を表4に示す。
Crack fatigue life test sample no. Regarding 1 to 15, an artificial wound having a length of 5 mm, a width of 0.2 mm, and a depth of 0.25 mm was applied to the raceway surface of the inner ring by electric discharge machining. This inner ring was assembled into a bearing to form a test bearing, and it was examined whether or not the inner ring was cracked by rolling.
Table 4 shows the test conditions.

【0042】[0042]

【表4】 [Table 4]

【0043】本試験条件での軸受の計算寿命は766時
間であるので、計算寿命以上である1100時間を試験
打切り時間とした。
Since the calculated life of the bearing under the test conditions is 766 hours, 1100 hours which is longer than the calculated life was set as the test cutoff time.

【0044】試験結果を表5に示す。Table 5 shows the test results.

【0045】[0045]

【表5】 [Table 5]

【0046】表5中の「f/n」は、n個について試験
を行なったところ、f個について破損が生じたことを示
す。また、破損が生じたサンプルについては、破損に至
るまでの時間をワイブル分布にして50%寿命を算出
し、50%寿命を表5中「L50」として示した。さら
に、全数について破損が生じなかったものについては、
打切り時間を示した。
"F / n" in Table 5 indicates that when n tests were performed, f damage occurred. Further, for the sample in which the breakage occurred, the 50% life was calculated by setting the time until the breakage to the Weibull distribution, and the 50% life was shown as “L50” in Table 5. In addition, if no damage occurred for all of the items,
The censoring time is indicated.

【0047】表5からわかるように、比較例としてのS
UJ2およびSUJ3の標準熱処理品(サンプルNo.
13および14)は、12個の検査数のうちのすべてに
ついて人工傷から割れが発生した。比較例の浸炭品(サ
ンプルNo.15)、SUJ2、SUJ3およびSCM
440からなる高周波焼入サンプル(サンプルNo.1
〜3、5〜7、9〜11は、すべての検査体において破
損が生じなかった。S53CからなるサンプルNo.
4、8、12は、人工傷を起点にして剥離が発生したも
のがあった。この結果から、嵌め合い応力下で用いられ
る軸受の内輪割れは、軌道面を硬度を高くし、芯部また
は内径部の硬度を低くして軌道面表層部を圧縮応力とす
ることにより防止できることがわかる。なお、サンプル
No.1〜12の製造コストは、浸炭品(サンプルN
o.15)の製造コストより低かった。
As can be seen from Table 5, S as a comparative example
Standard heat-treated products of UJ2 and SUJ3 (Sample No.
In 13 and 14), cracks occurred from artificial wounds in all of the 12 inspection numbers. Carburized products of comparative examples (Sample No. 15), SUJ2, SUJ3 and SCM
Induction hardened sample consisting of No. 440 (sample No. 1)
In Nos. 3, 5, 7 and 9 to 11, no damage occurred in all the test pieces. No. S53C.
Samples Nos. 4, 8, and 12 were peeled off from an artificial wound. From these results, it can be seen that the inner ring crack of the bearing used under the fitting stress can be prevented by increasing the hardness of the raceway surface, lowering the hardness of the core or inner diameter portion, and making the raceway surface surface layer a compressive stress. Recognize. The sample No. The production costs of carburized products (sample N
o. 15) It was lower than the production cost.

【0048】また、実施例の熱処理条件3では、軌道面
からの加熱、焼入時の熱影響で内径側の硬度を下げた
が、優れた品質を得るためには、内径面を焼入した後温
度300〜400℃で1時間高温焼戻を行ない、内径面
の硬度を表3で示す値にした後外径面を焼入して表3で
示す硬度にすることも可能である。この方法に従って製
造したサンプルについて表4と同じ条件で割れ疲労強度
を測定したところ、サンプルNo.9〜12と同様の結
果を得た。所定の硬度分布を得るには、この方法の方が
確実である。
In the heat treatment condition 3 of the embodiment, the hardness on the inner diameter side was reduced due to the influence of heating and quenching from the raceway surface, but in order to obtain excellent quality, the inner diameter surface was hardened. It is also possible to perform high-temperature tempering at a post-temperature of 300 to 400 ° C. for 1 hour, to set the hardness of the inner diameter surface to the value shown in Table 3, and then to harden the outer diameter surface to the hardness shown in Table 3. When the crack fatigue strength of the sample manufactured according to this method was measured under the same conditions as in Table 4, the sample No. The same results as in Nos. 9 to 12 were obtained. This method is more reliable for obtaining a predetermined hardness distribution.

【0049】以上、この発明の実施例について説明した
が、ここで示した実施例ではさまざまに変形可能であ
る。まず、転がり軸受を構成する鋼として、他の高炭素
クロム軸受鋼を使用することも可能であり、また、ここ
で示した鋼以外の構造用合金鋼や構造用炭素鋼を使用す
ることもできる。また、加熱条件や焼戻条件は鋼種に応
じて変えることが可能である。今回開示された実施例は
すべての点で例示であって制限的なものではないと考え
られるべきである。本発明の範囲は上記した説明ではな
くて特許請求の範囲によって示され、特許請求の範囲と
均等の意味および範囲内でのすべての変更が含まれるこ
とが意図される。
Although the embodiment of the present invention has been described above, the embodiment shown here can be variously modified. First, as the steel constituting the rolling bearing, it is also possible to use other high-carbon chromium bearing steel, and it is also possible to use structural alloy steel or structural carbon steel other than the steel shown here. . The heating conditions and tempering conditions can be changed according to the type of steel. The embodiments disclosed this time are to be considered in all respects as illustrative and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

【0050】[0050]

【発明の効果】この発明によれば、転がり軸受の内輪の
熱処理に高周波焼入を用いることにより軸受鋼(SUJ
2、SUJ3)、合金鋼(SCM440等)または炭素
鋼(S53C等)からなる軸受内輪の軌道面および内径
面を必要な強度にし、芯部を低い硬度にして軌道面に圧
縮応力を付与することにより、浸炭鋼に匹敵する高い割
れ疲労強度を有する軸受を実現させることができる。ま
た、軌道面を硬化させ、内径面をこれより低い硬度にし
ても浸炭鋼に匹敵する高い割れ疲労強度を有する軸受を
実現することができる。
According to the present invention, by using induction hardening for heat treatment of the inner ring of a rolling bearing, the bearing steel (SUJ
(2, SUJ3), alloy steel (SCM440, etc.) or carbon steel (S53C, etc.) to make the raceway surface and inner diameter surface of the bearing inner ring necessary strength, make the core part low hardness and apply compressive stress to the raceway surface. Thereby, a bearing having high crack fatigue strength comparable to carburized steel can be realized. Further, even if the raceway surface is hardened and the inner diameter surface has a lower hardness, a bearing having high crack fatigue strength comparable to carburized steel can be realized.

Claims (10)

【特許請求の範囲】[Claims] 【請求項1】 外周面側に位置する軌道面を高周波焼入
して前記軌道面を圧縮応力状態にした、転がり軸受の内
輪。
1. An inner race of a rolling bearing, wherein a raceway surface located on an outer peripheral surface side is induction hardened so that the raceway surface is in a compressive stress state.
【請求項2】 前記軌道面のHRC(Cスケールのロッ
クウェル硬度)と内輪芯部のHRCとの差が8以上であ
る、請求項1に記載の転がり軸受の内輪。
2. The inner race of the rolling bearing according to claim 1, wherein a difference between HRC (Rockwell hardness of C scale) of the raceway surface and HRC of the inner race core is 8 or more.
【請求項3】 前記軌道面のHRCと内径面のHRCと
の差が5以上である、請求項1または2に記載の転がり
軸受の内輪。
3. The inner race of a rolling bearing according to claim 1, wherein a difference between the HRC of the raceway surface and the HRC of the inner diameter surface is 5 or more.
【請求項4】 内径面のHRCと内輪芯部のHRCとの
差が8以上である、請求項1〜3のいずれか1項に記載
の転がり軸受の内輪。
4. The inner race of a rolling bearing according to claim 1, wherein the difference between the HRC of the inner diameter surface and the HRC of the inner race core is 8 or more.
【請求項5】 高周波焼入された前記軌道面のHRCが
58以上である、請求項1〜4のいずれか1項に記載の
転がり軸受の内輪。
5. The inner race of a rolling bearing according to claim 1, wherein the HRC of the raceway surface that has been induction hardened is 58 or more.
【請求項6】 内径面のHRCが48〜55である、請
求項1〜3または5のいずれか1項に記載の転がり軸受
の内輪。
6. The inner race of a rolling bearing according to claim 1, wherein the HRC of the inner diameter surface is 48 to 55.
【請求項7】 外周面側に位置する軌道面が圧縮応力状
態になるように前記軌道面を高周波焼入する、転がり軸
受の内輪の熱処理方法。
7. A heat treatment method for an inner ring of a rolling bearing, wherein the raceway surface is induction hardened so that the raceway surface located on the outer peripheral surface side is in a compressive stress state.
【請求項8】 転がり軸受の内輪の内径面と外周面側に
位置する軌道面を高周波で加熱し、前記内径面を冷却す
る速度よりも速い冷却速度で前記軌道面を冷却する、転
がり軸受の内輪の熱処理方法。
8. A rolling bearing according to claim 1, wherein the raceway surface located on the inner diameter surface and the outer peripheral surface side of the inner race of the rolling bearing is heated at a high frequency, and the raceway surface is cooled at a cooling rate higher than the cooling speed of the inner diameter surface. Inner ring heat treatment method.
【請求項9】 転がり軸受の内輪の内径面と外周面側に
位置する軌道面とを高周波で加熱し、前記内径面と前記
軌道面とを冷却する、転がり軸受の内輪の熱処理方法。
9. A heat treatment method for an inner ring of a rolling bearing, comprising heating an inner diameter surface of an inner ring of a rolling bearing and a raceway surface located on an outer peripheral surface side with high frequency, and cooling the inner diameter surface and the raceway surface.
【請求項10】 転がり軸受の内輪の内径面を高周波で
加熱した後冷却し、その後、外周面側に位置する軌道面
を高周波で加熱した後冷却する、転がり軸受の内輪の熱
処理方法。
10. A method for heat-treating an inner ring of a rolling bearing, wherein the inner surface of the inner ring of the rolling bearing is heated at a high frequency and then cooled, and then the raceway surface located on the outer peripheral surface is heated and cooled at a high frequency.
JP9191241A 1997-07-16 1997-07-16 Inner ring for rolling bearing and heat treatment method thereof Pending JPH1137163A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP9191241A JPH1137163A (en) 1997-07-16 1997-07-16 Inner ring for rolling bearing and heat treatment method thereof

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP9191241A JPH1137163A (en) 1997-07-16 1997-07-16 Inner ring for rolling bearing and heat treatment method thereof

Publications (1)

Publication Number Publication Date
JPH1137163A true JPH1137163A (en) 1999-02-09

Family

ID=16271254

Family Applications (1)

Application Number Title Priority Date Filing Date
JP9191241A Pending JPH1137163A (en) 1997-07-16 1997-07-16 Inner ring for rolling bearing and heat treatment method thereof

Country Status (1)

Country Link
JP (1) JPH1137163A (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP1462669A2 (en) * 2003-03-26 2004-09-29 Ntn Corporation Rolling bearings
JP2009019670A (en) * 2007-07-11 2009-01-29 Nsk Ltd Rolling bearing
US9487843B2 (en) 2011-01-21 2016-11-08 Ntn Corporation Method for producing a bearing ring

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP1462669A2 (en) * 2003-03-26 2004-09-29 Ntn Corporation Rolling bearings
EP1462669A3 (en) * 2003-03-26 2006-01-18 Ntn Corporation Rolling bearings
CN100410556C (en) * 2003-03-26 2008-08-13 Ntn株式会社 Rolling bearing
JP2009019670A (en) * 2007-07-11 2009-01-29 Nsk Ltd Rolling bearing
US9487843B2 (en) 2011-01-21 2016-11-08 Ntn Corporation Method for producing a bearing ring

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