JP2011058527A - Outer ring with sensor and conical bearing with sensor - Google Patents

Outer ring with sensor and conical bearing with sensor Download PDF

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Publication number
JP2011058527A
JP2011058527A JP2009206765A JP2009206765A JP2011058527A JP 2011058527 A JP2011058527 A JP 2011058527A JP 2009206765 A JP2009206765 A JP 2009206765A JP 2009206765 A JP2009206765 A JP 2009206765A JP 2011058527 A JP2011058527 A JP 2011058527A
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outer ring
sensor
conical
conical cylinder
tapered roller
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JP5333082B2 (en
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Kazuo Hamada
和生 濱田
Hiroshi Ueno
弘 上野
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JTEKT Corp
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JTEKT Corp
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Priority to JP2009206765A priority Critical patent/JP5333082B2/en
Priority to US12/843,258 priority patent/US8827564B2/en
Priority to AT10171239T priority patent/ATE549526T1/en
Priority to EP10171239A priority patent/EP2280180B1/en
Priority to CN2010102429047A priority patent/CN101988546B/en
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Abstract

<P>PROBLEM TO BE SOLVED: To provide an outer ring with a sensor which is achieved in the reduction of weight, reduces an operation cost, a material cost and a manufacturing cost, and occupies a small installation space, and also to provide a conical bearing with a sensor. <P>SOLUTION: The conical bearing with the sensor is equipped with: the outer ring 2 formed by press working an integrated sheet metal; and a distortion gauge 7. At the outer ring 2, formed are: a conical cylinder 31 having a conical orbit plane 38, a radial extension part 32 which extends almost in the radial direction from the end at the small diameter side of the conical cylinder 31; a cylinder 33 whose one end is connected to the outside end in the radial direction of the radial extension part 32; a center backup part 34 which extends to the center in the axial direction of the external peripheral face of the conical cylinder 31 from the other end of the cylinder 33; and a large diameter side bent part 35 which is bent to the outside in the radial direction from the end of the conical cylinder 31. The distortion gauge 7 is fixed to the external peripheral face of the conical cylinder 31. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

本発明は、センサと、外輪とを備えるセンサ付き外輪に関する。また、本発明は、センサと、円錐ころとを備えるセンサ付き円錐ころ軸受に関する。   The present invention relates to an outer ring with a sensor including a sensor and an outer ring. Moreover, this invention relates to a tapered roller bearing with a sensor provided with a sensor and a tapered roller.

従来、円錐ころ軸受としては、特開平11−48805号公報(特許文献1)に記載されているものがある。この円錐ころ軸受は、ディファレンシャルギヤ装置のピニオン軸をディファレンシャル装置のハウジングに対して回転自在に支持している。   Conventionally, as a tapered roller bearing, there is one described in Japanese Patent Application Laid-Open No. 11-48805 (Patent Document 1). This tapered roller bearing supports the pinion shaft of the differential gear device rotatably with respect to the housing of the differential device.

上記円錐ころ軸受は、外輪、内輪および複数の円錐ころを備える。上記外輪の外周面は、上記ハウジングの内周面に内嵌されて固定されている一方、上記内輪の内周面は、上記ピニオン軸の外周面に外嵌されて固定されている。上記複数の円錐ころは、外輪の円錐軌道面と、内輪の円錐軌道面との間に、保持器によって保持された状態で、互いに周方向に間隔をおいて配置されている。上記円錐ころ軸受の外輪は、中実である。   The tapered roller bearing includes an outer ring, an inner ring, and a plurality of tapered rollers. The outer circumferential surface of the outer ring is fitted and fixed to the inner circumferential surface of the housing, while the inner circumferential surface of the inner ring is fitted and fixed to the outer circumferential surface of the pinion shaft. The plurality of tapered rollers are spaced apart from each other in the circumferential direction while being held by a cage between the conical raceway surface of the outer ring and the conical raceway surface of the inner ring. The outer ring of the tapered roller bearing is solid.

しかしながら、上記従来の円錐ころ軸受は、外輪が、中実であるため、軽量化することができず、車両に使用した場合、運転コストが高くなり、材料コストが高くなるという問題がある。   However, since the conventional tapered roller bearing has a solid outer ring, it cannot be reduced in weight, and when used in a vehicle, there is a problem that the operating cost increases and the material cost increases.

また、上記円錐ころ軸受の外輪は、中実であるため、旋削量が大きく、旋削時間が長くなって、製造コストが高くなるという問題がある。   Further, since the outer ring of the tapered roller bearing is solid, there is a problem that the amount of turning is large, the turning time is long, and the manufacturing cost is high.

また、上記円錐ころ軸受は、予圧等を測定するための歪みセンサを設置しにくく、かつ、歪みセンサを設置すると、配置スペースが大きくなりがちであるという問題がある。   Further, the tapered roller bearing has a problem that it is difficult to install a strain sensor for measuring a preload and the like, and when the strain sensor is installed, there is a problem that an arrangement space tends to be increased.

特開平11−48805号公報(第1図)Japanese Patent Laid-Open No. 11-48805 (FIG. 1)

そこで、本発明の課題は、軽量化を達成できて、運転コスト、材料コストおよび製造コストを低減でき、かつ、配置スペースが小さいセンサ付き外輪およびセンサ付き円錐ころ軸受を提供することにある。   Therefore, an object of the present invention is to provide an outer ring with a sensor and a tapered roller bearing with a sensor that can achieve weight reduction, reduce operating costs, material costs, and manufacturing costs, and have a small arrangement space.

上記課題を解決するため、この発明のセンサ付き外輪は、
一体の金属板からなる外輪と、
歪みセンサと
を備え、
上記金属板は、
内周に円錐軌道面を有する円錐筒部と、
上記円錐筒部の小径側の端部から上記円錐筒部の略径方向に延在する径方向延在部と、
上記径方向延在部の上記径方向の外方の端部に一端が連結されると共に、上記円錐筒部の略軸方向に延在する円筒部と、
上記円筒部の他端から上記円錐筒部の外周面の軸方向の中央部まで延在して上記中央部をバックアップする中央バックアップ部と、
上記円錐筒部の大径側の端部から径方向の外方側に屈曲すると共に、径方向の外方の端面の外径が、上記円筒部の外周面の外径と略同一である大径側屈曲部と
を有し、
上記歪みセンサは、上記円錐筒部の外周面に固定されていることを特徴としている。
In order to solve the above problems, the sensor-equipped outer ring of the present invention is
An outer ring made of an integral metal plate,
A strain sensor,
The metal plate is
A conical cylinder portion having a conical track surface on the inner periphery;
A radially extending portion extending in a substantially radial direction of the conical tube portion from an end portion on the small diameter side of the conical tube portion;
One end is connected to the radially outer end of the radially extending portion, and a cylindrical portion extending substantially in the axial direction of the conical tubular portion;
A central backup portion that extends from the other end of the cylindrical portion to the axial central portion of the outer peripheral surface of the conical cylindrical portion, and backs up the central portion;
The large diameter of the conical tube portion is bent from the large diameter end to the radially outward side, and the outer diameter of the radially outer end surface is substantially the same as the outer diameter of the outer peripheral surface of the cylindrical portion. A radial side bend,
The strain sensor is fixed to the outer peripheral surface of the conical cylinder portion.

尚、上記一体の金属板には、例えば、金属製の平板が、含まれるのは勿論のこと、継ぎ目の無い円筒状の金属板や、電縫管等の継ぎ目の有る円筒状の金属板が含まれる。また、上記一体の金属板には、瓦状の金属板等の湾曲した金属製の板材が、含まれる。   The integrated metal plate includes, for example, a metal flat plate, a seamless cylindrical metal plate, and a cylindrical metal plate with a seam such as an electric sewing tube. included. The integrated metal plate includes a curved metal plate material such as a tile-like metal plate.

また、上記中央部とは、円錐筒部の軸方向の両端以外の部分を示す。尚、中央バックアップ部がバックアップする円錐筒部の部分は、上記円錐軌道面の撓みの防止の観点から、視覚を判断基準として、上記円錐筒部の軸方向の略中心付近であることが好ましい。   Moreover, the said center part shows parts other than the both ends of the axial direction of a conical cylinder part. In addition, it is preferable that the part of the conical cylinder part backed up by the central backup part is in the vicinity of the approximate center in the axial direction of the conical cylinder part from the viewpoint of preventing the conical raceway surface from being bent, based on vision.

また、上記歪みセンサには、変位を測定する全てのセンサが含まれるものとする。変位を測定することによって、間接的に歪みを測定できるからである。   The strain sensor includes all sensors that measure displacement. This is because the strain can be measured indirectly by measuring the displacement.

本発明によれば、外輪が金属の塊より格段に軽い一体の金属板からなるから、従来の中実の外輪と比較して、質量が格段に小さくなる。したがって、本発明の外輪を、車両に使用した場合、中実の外輪と比較して、運転コストが低くなり、材料コストが低くなる。また、本発明によれば、外輪が一体の金属板からなるから、旋削等を不要あるいは旋削量を少なくできて、製造コストが小さくなる。   According to the present invention, since the outer ring is made of an integrated metal plate that is much lighter than the metal lump, the mass is significantly smaller than that of a conventional solid outer ring. Therefore, when the outer ring of the present invention is used in a vehicle, the operating cost is lower and the material cost is lower than that of a solid outer ring. Further, according to the present invention, since the outer ring is made of an integral metal plate, turning or the like is unnecessary or the amount of turning can be reduced, and the manufacturing cost is reduced.

また、本発明によれば、外輪が一体の金属板からなって、ワンピースで外輪としての機能を果たしているから、外輪を複数の部品で形成する場合と異なり、各部品の調整が一切必要なくて、容易に組み付けでき、また、容易に取り扱うことができる。   In addition, according to the present invention, the outer ring is made of an integral metal plate and functions as an outer ring in one piece. Therefore, unlike the case where the outer ring is formed of a plurality of parts, there is no need to adjust each part at all. Can be easily assembled and handled easily.

また、本発明によれば、円錐軌道面を有しているのが、軸方向に連続して存在する円錐筒部であって、円錐軌道面が軸方向に連続して存在しているから、円錐ころの転動面の軸方向の略全域を、円錐筒部で支えることができる。したがって、円錐ころが、円錐軌道面上を安定かつ円滑に転動することができる。   In addition, according to the present invention, the conical orbital surface has a conical cylindrical portion continuously present in the axial direction, and the conical orbital surface continuously exists in the axial direction. The substantially entire area in the axial direction of the rolling surface of the tapered roller can be supported by the conical cylinder portion. Therefore, the tapered roller can roll stably and smoothly on the conical raceway surface.

また、本発明によれば、円錐筒部の小径側の端部から円錐筒部の略径方向に延在する径方向延在部が存在するから、この径方向延在部を、ハウジング等の外輪取付部材の軸方向の端面に当接させることができる。したがって、上記軸方向の端面から抗力を受けることができるから、アキシアル荷重を負荷することができる。   In addition, according to the present invention, since there is a radially extending portion that extends in the substantially radial direction of the conical cylinder portion from the end portion on the small diameter side of the conical cylinder portion, the radially extending portion is used as a housing or the like. The outer ring mounting member can be brought into contact with the axial end surface. Accordingly, since a drag force can be received from the axial end face, an axial load can be applied.

また、本発明によれば、径方向延在部の径方向の外方の端部に連結されて、円錐筒部の略軸方向に延在する円筒部を有するから、この円筒部を上記外輪取付部材の内周面に内嵌して固定することができる。また、同様に、円錐筒部の大径側の端部から径方向の外方側に屈曲して、径方向の外方の端面の外径が、円筒部の外周面の外径と略同一である大径側屈曲部を有するから、この大径側屈曲部をハウジング等の外輪取付部材の内周面に内嵌して固定することができる。したがって、円筒部と大径側屈曲部との軸方向に離間して位置する2箇所を、上記外輪取付部材の内周面に固定することができるから、外輪を安定かつ確実に上記外輪取付部材に固定することができる。   Further, according to the present invention, the cylindrical portion is connected to the radially outer end portion of the radially extending portion and extends substantially in the axial direction of the conical cylindrical portion. It can be fixed by being fitted into the inner peripheral surface of the mounting member. Similarly, the outer diameter of the outer end surface of the cylindrical portion is substantially the same as the outer diameter of the outer peripheral surface of the cylindrical portion, with the outer diameter of the outer end surface of the cylindrical portion being bent outward from the larger diameter end of the conical cylinder portion. Therefore, the large-diameter side bent portion can be fitted and fixed to the inner peripheral surface of an outer ring mounting member such as a housing. Therefore, two locations that are spaced apart in the axial direction between the cylindrical portion and the large-diameter-side bent portion can be fixed to the inner peripheral surface of the outer ring mounting member, so that the outer ring can be stably and reliably fixed to the outer ring mounting member. Can be fixed to.

また、本発明によれば、円筒部の他端から円錐筒部の外周面の軸方向の中央部まで延在して上記中央部をバックアップする中央バックアップ部を有するから、この中央バックアップ部によって、円錐筒部の円錐軌道面の変形を防止できる。   Further, according to the present invention, since the central backup portion extends from the other end of the cylindrical portion to the axial central portion of the outer peripheral surface of the conical cylindrical portion and backs up the central portion, the central backup portion Deformation of the conical track surface of the conical cylinder portion can be prevented.

また、本発明によれば、上記中央バックアップ部によって、外輪の径方向の強度を大きくでき、また、上記径方向延在部および上記大径側屈曲部によっても、径方向の剛性を大きくできる。したがって、上記中央バックアップ部と、径方向延在部と、大径側屈曲部との互いに軸方向に離間して存在する3箇所で、径方向の剛性を大きくできて、外輪の径方向の強度が、問題がないものになる。   Further, according to the present invention, the central backup portion can increase the radial strength of the outer ring, and the radial extension portion and the large-diameter side bent portion can also increase the radial rigidity. Therefore, the rigidity in the radial direction can be increased and the radial strength of the outer ring can be increased at the three locations where the central backup portion, the radially extending portion, and the large-diameter side bent portion are separated from each other in the axial direction. However, there will be no problem.

また、本発明によれば、歪みセンサが、円錐筒部の外周面に固定されているから、このセンサ付き外輪を有するセンサ付き円錐ころ軸受の組み付け時の予圧や、運転時の予圧を、上記歪みセンサの測定値に基づいて正確に測定できる。したがって、組み付け時に、精密に所望の予圧を設定でき、また、運転時に、上記歪センサの測定値に基づいて、予圧を適宜、適切に調整できる。   Further, according to the present invention, since the strain sensor is fixed to the outer peripheral surface of the conical cylinder portion, the preload at the time of assembly of the tapered roller bearing with a sensor having the outer ring with the sensor and the preload at the time of operation are Accurate measurement can be performed based on the measurement value of the strain sensor. Therefore, a desired preload can be accurately set at the time of assembly, and the preload can be appropriately and appropriately adjusted based on the measured value of the strain sensor during operation.

また、本発明によれば、上記歪みセンサが、上記円錐筒部の外周面に固定され、上記歪みセンサが、円錐筒部と、径方向延在部と、円筒部と、中央バックアップ部とで囲まれる室内に配置されるか、または、歪みセンサを、円錐筒部と、中央バックアップ部と、大径側屈曲部とで画定される凹部内に配置できる。したがって、歪みセンサが、外輪を外輪取付部材に取り付けた状態で、密封室となる室内に取り付けられることになるから、外輪への歪みセンサの搭載の前後で、センサ付き外輪の配置スペースが変化することがない。したがって、この発明のセンサ付き外輪を用いると、配置スペースが小さいセンサ付き円錐ころ軸受を実現することができる。   According to the present invention, the strain sensor is fixed to the outer peripheral surface of the conical cylinder part, and the strain sensor includes a conical cylinder part, a radially extending part, a cylindrical part, and a central backup part. The strain sensor can be placed in the enclosed room or in a recess defined by a conical cylinder portion, a central backup portion, and a large-diameter side bend. Therefore, since the strain sensor is mounted in a chamber that is a sealed chamber with the outer ring attached to the outer ring mounting member, the arrangement space of the outer ring with the sensor changes before and after the strain sensor is mounted on the outer ring. There is nothing. Therefore, if the outer ring with a sensor of this invention is used, a tapered roller bearing with a sensor with a small arrangement space can be realized.

また、一実施形態では、
上記歪みセンサは、上記中央バックアップ部と、上記大径側屈曲部との間に位置している。
In one embodiment,
The strain sensor is located between the central backup portion and the large-diameter side bent portion.

上記実施形態によれば、歪みセンサが、円錐筒部と、中央バックアップ部と、大径側屈曲部とで画定される凹部内に配置されることになるから、時間に対する歪みセンサの固定の自由度を大きくすることができて、歪みセンサの取り付け容易性を大きくすることができる。上記歪みセンサを、円錐筒部と、径方向延在部と、円筒部と、中央バックアップ部とで囲まれる室内に配置する構成では、上記歪みセンサが、上記外輪の上記室の完成前に、金属板に固定されなければならない一方、上記歪みセンサを外輪の上記凹部内に配置する構成では、歪みセンサの外輪への設置の時間的な制限が存在することがないからである。   According to the above embodiment, since the strain sensor is disposed in the recess defined by the conical cylinder portion, the central backup portion, and the large-diameter side bent portion, the strain sensor can be freely fixed with respect to time. The degree can be increased, and the ease of mounting the strain sensor can be increased. In the configuration in which the strain sensor is disposed in a room surrounded by the conical cylinder part, the radially extending part, the cylindrical part, and the central backup part, the strain sensor is formed before the chamber of the outer ring is completed. This is because, in the configuration in which the strain sensor is disposed in the concave portion of the outer ring, there is no time limit for installation of the strain sensor on the outer ring, while the strain sensor must be fixed to the metal plate.

また、本発明のセンサ付き円錐ころ軸受は、
本発明のセンサ付き外輪と、
外周に円錐軌道面を有する内側軌道部材と、
上記外輪の上記円錐筒部の上記円錐軌道面と、上記内側軌道部材の上記円錐軌道面との間に配置された円錐ころと
を備えることを特徴としている。
The tapered roller bearing with sensor of the present invention is
An outer ring with a sensor of the present invention;
An inner race member having a conical raceway surface on the outer periphery;
And a tapered roller disposed between the conical raceway surface of the conical cylinder portion of the outer ring and the conical raceway surface of the inner raceway member.

本発明によれば、本発明のセンサ付き外輪を備えるから、軽量化を達成できて、運転コスト、材料コストおよび製造コストを低減でき、かつ、配置スペースを小さくすることができる。   According to the present invention, since the outer ring with a sensor according to the present invention is provided, the weight can be reduced, the operating cost, the material cost and the manufacturing cost can be reduced, and the arrangement space can be reduced.

また、一実施形態では、
上記中央バックアップ部は、上記円錐軌道面の略法線方向に延在している。
In one embodiment,
The central backup portion extends in a substantially normal direction of the conical track surface.

尚、上記略法線方向における略は、人の視覚において判断するものとする。   Note that the abbreviations in the substantially normal direction are determined by human vision.

上記実施形態によれば、中央バックアップ部が、円錐軌道面の略法線方向に延在しているから、円錐軌道面の変形防止効果を、強化することができる。   According to the embodiment, since the central backup portion extends in the substantially normal direction of the conical track surface, the effect of preventing the deformation of the conical track surface can be enhanced.

また、一実施形態では、
上記一体の金属板は、プレス成形されている。
In one embodiment,
The integral metal plate is press-molded.

上記実施形態によれば、一体の金属板が、プレス成形されているから、外輪の製造コストを低減でき、量産性を向上させることができる。   According to the embodiment, since the integral metal plate is press-molded, the manufacturing cost of the outer ring can be reduced and the mass productivity can be improved.

また、一実施形態では、
上記大径側屈曲部が、上記中央バックアップ部と略平行に延在している。
In one embodiment,
The large diameter side bent portion extends substantially parallel to the central backup portion.

上記実施形態によれば、大径側屈曲部が、中央バックアップ部と略平行に延在しているから、径方向の強度を更に大きくすることができる。   According to the embodiment, since the large-diameter side bent portion extends substantially parallel to the central backup portion, the radial strength can be further increased.

本発明のセンサ付き外輪によれば、従来のセンサ付き外輪と比較して質量が格段に小さくなる。   According to the outer ring with a sensor of the present invention, the mass is remarkably reduced as compared with a conventional outer ring with a sensor.

また、本発明のセンサ付き外輪によれば、径方向延在部を、ハウジング等の外輪取付部材の軸方向の端面に当接させることができるから、その端面から抗力を受けることができて、アキシアル荷重を負荷することができる。   Further, according to the outer ring with a sensor of the present invention, the radially extending portion can be brought into contact with the end surface in the axial direction of the outer ring mounting member such as a housing, and therefore, it can receive a drag from the end surface, An axial load can be applied.

また、本発明のセンサ付き外輪によれば、円筒部を外輪取付部材の内周面に内嵌して固定することができる。また、同様に、大径側屈曲部を外輪取付部材の内周面に内嵌して固定することができる。したがって、軸方向に離間して位置する円筒部と大径側屈曲部との2箇所を、外輪取付部材の内周面に固定することができるから、外輪を安定かつ確実に外輪取付部材に固定することができる。   Moreover, according to the outer ring with a sensor of this invention, a cylindrical part can be internally fitted and fixed to the internal peripheral surface of an outer ring attachment member. Similarly, the large-diameter-side bent portion can be fitted and fixed to the inner peripheral surface of the outer ring mounting member. Accordingly, two locations of the cylindrical portion and the large-diameter side bent portion that are spaced apart in the axial direction can be fixed to the inner peripheral surface of the outer ring mounting member, so that the outer ring is stably and reliably fixed to the outer ring mounting member. can do.

また、本発明のセンサ付き外輪によれば、中央バックアップ部を有するから、この中央バックアップ部によって、円錐筒部の円錐軌道面の変形を防止できる。   Moreover, according to the outer ring | wheel with a sensor of this invention, since it has a center backup part, the deformation | transformation of the conical track surface of a cone cylinder part can be prevented with this center backup part.

また、本発明のセンサ付き外輪によれば、中央バックアップ部と、径方向延在部と、大径側屈曲部との互いに軸方向に離間して存在する3箇所で、径方向の剛性を大きくできて、外輪の径方向の強度が、問題がないものになる。   In addition, according to the outer ring with a sensor of the present invention, the radial rigidity is increased at three locations that are separated from each other in the axial direction by the central backup portion, the radially extending portion, and the large-diameter side bent portion. The strength of the outer ring in the radial direction is not problematic.

また、本発明のセンサ付き外輪によれば、このセンサ付き外輪を有するセンサ付き円錐ころ軸受の組み付け時の予圧や、運転時の予圧を、上記歪みセンサの測定値に基づいて正確に測定できる。したがって、組み付け時に、精密に所望の予圧を設定でき、また、運転時に、上記歪センサの測定値に基づいて、予圧を適宜、適切に調整できる。   Further, according to the outer ring with sensor of the present invention, the preload at the time of assembly of the tapered roller bearing with sensor having the outer ring with sensor and the preload at the time of operation can be accurately measured based on the measurement value of the strain sensor. Therefore, a desired preload can be accurately set at the time of assembly, and the preload can be appropriately and appropriately adjusted based on the measured value of the strain sensor during operation.

また、本発明のセンサ付き外輪によれば、歪みセンサが、外輪を外輪取付部材に取り付けた状態で、密封室となる室内に取り付けられることになるから、外輪への歪みセンサの搭載の前後で、センサ付き外輪の配置スペースが変化することがない。したがって、この発明のセンサ付き外輪を用いることにより、配置スペースが小さいセンサ付き円錐ころ軸受を実現することができる。   In addition, according to the outer ring with a sensor of the present invention, the strain sensor is attached in a chamber that becomes a sealed chamber in a state where the outer ring is attached to the outer ring attachment member, so that before and after the strain sensor is mounted on the outer ring. The arrangement space of the outer ring with sensor does not change. Therefore, a tapered roller bearing with a sensor having a small arrangement space can be realized by using the outer ring with a sensor of the present invention.

本発明の第1実施形態のセンサ付き円錐ころ軸受の軸方向の断面図である。It is sectional drawing of the axial direction of the tapered roller bearing with a sensor of 1st Embodiment of this invention. 上記センサ付き円錐ころ軸受の歪みゲージを示す模式図である。It is a schematic diagram which shows the strain gauge of the said tapered roller bearing with a sensor. 上記歪みゲージの一部を示す平面図である。It is a top view which shows a part of said strain gauge. 本発明の第2実施形態のセンサ付き円錐ころ軸受装置の軸方向の断面図である。It is sectional drawing of the axial direction of the tapered roller bearing apparatus with a sensor of 2nd Embodiment of this invention.

以下、本発明を図示の形態により詳細に説明する。   Hereinafter, the present invention will be described in detail with reference to the drawings.

図1は、本発明の第1実施形態のセンサ付き円錐ころ軸受の軸方向の模式断面図である。   FIG. 1 is a schematic cross-sectional view in the axial direction of a tapered roller bearing with a sensor according to a first embodiment of the present invention.

このセンサ付き円錐ころ軸受は、内輪軌道部材としての内輪1と、センサ付き外輪40と、複数の円錐ころ3とを備え、センサ付き外輪40は、外輪2と、歪みセンサとしての歪みゲージ7とを有する。   This tapered roller bearing with sensor includes an inner ring 1 as an inner ring raceway member, an outer ring 40 with sensor, and a plurality of tapered rollers 3, and the outer ring with sensor 40 includes an outer ring 2 and a strain gauge 7 as a strain sensor. Have

上記内輪1は、軸部材5の外周面に外嵌されて固定されている。上記内輪1は、円錐軌道面21、大鍔部22および小鍔部23を有している。上記大鍔部22は、円錐軌道面21の大径側に位置する一方、小鍔部23は、円錐軌道面21の小径側に位置している。上記軸部材5は、径方向に広がる段部26を有している。上記内輪1の円錐軌道面21の大径側の端面25は、上記段部26に当接している。   The inner ring 1 is fixed by being fitted onto the outer peripheral surface of the shaft member 5. The inner ring 1 has a conical raceway surface 21, a large collar part 22, and a small collar part 23. The large collar portion 22 is located on the large diameter side of the conical raceway surface 21, while the small collar portion 23 is located on the small diameter side of the conical raceway surface 21. The shaft member 5 has a step portion 26 that expands in the radial direction. An end surface 25 on the large diameter side of the conical raceway surface 21 of the inner ring 1 is in contact with the step portion 26.

上記外輪2は、一体ものの板金をプレス成形してなっている。ここで、板金の材料としては、SUJ2等の塑性加工できる軸受鋼、塑性加工できる軸受鋼に浸炭窒化処理等の硬化処理を施した鋼材、普通鋼SPCC等の塑性加工できる金属、S55Cなどの炭素鋼、SCM415などのクロムモリブデン鋼、N22CB,N35CB(日新製綱規格)のようなプレス性を考慮した材料等がある。   The outer ring 2 is formed by press-molding an integral sheet metal. Here, the material of the sheet metal includes bearing steel that can be plastically processed such as SUJ2, steel material that has been subjected to hardening treatment such as carbonitriding treatment on bearing steel that can be plastically processed, metal that can be plastically processed such as ordinary steel SPCC, carbon such as S55C, etc. Steel, chromium molybdenum steel such as SCM415, and materials such as N22CB and N35CB (Nisshin Steel Standard) in consideration of pressability.

上記外輪2は、円錐筒部31と、径方向延在部32と、円筒部33と、中央バックアップ部34と、大径側屈曲部35とを有する。   The outer ring 2 includes a conical cylinder portion 31, a radially extending portion 32, a cylindrical portion 33, a central backup portion 34, and a large-diameter side bent portion 35.

上記円錐筒部31は、内周に円錐軌道面38を有している。上記径方向延在部32は、円錐筒部31の小径側の端部から円錐筒部31の略径方向に延在している。上記円筒部33は、径方向延在部32の径方向の外方の端部に一端が連結されている。上記円筒部33は、円錐筒部31の略軸方向に延在している。上記円筒部33は、円筒外周面41を有している。   The conical cylinder portion 31 has a conical track surface 38 on the inner periphery. The radially extending portion 32 extends from the end on the small diameter side of the conical cylinder portion 31 in the substantially radial direction of the conical cylinder portion 31. One end of the cylindrical portion 33 is connected to the radially outer end of the radially extending portion 32. The cylindrical portion 33 extends in a substantially axial direction of the conical cylindrical portion 31. The cylindrical portion 33 has a cylindrical outer peripheral surface 41.

上記中央バックアップ部34は、円筒部33の他端から円錐筒部31の外周面の軸方向の中央付近(この中央付近は、人の視覚において判断)まで延在して、円錐筒部の中央付近の外周面に接触している。上記中央バックアップ部34は、このようにして、円錐筒部31の中央付近の外周面をバックアップしている。上記中央バックアップ部34は、軸方向の断面において、外輪2の円錐軌道面38の略法線方向(ここにおける略は、人の視覚において判断)に延在している。上記中央バックアップ部34、円錐筒部31、径方向延在部32および円筒部33は、密封室49を画定している。   The central backup portion 34 extends from the other end of the cylindrical portion 33 to the vicinity of the axial center of the outer peripheral surface of the conical cylindrical portion 31 (this central vicinity is determined by human vision) It is in contact with a nearby outer peripheral surface. The central backup part 34 backs up the outer peripheral surface near the center of the conical cylinder part 31 in this way. The central backup portion 34 extends in a substantially normal direction of the conical raceway surface 38 of the outer ring 2 (the abbreviation here is determined by human vision) in the axial cross section. The central backup portion 34, the conical cylinder portion 31, the radially extending portion 32, and the cylindrical portion 33 define a sealed chamber 49.

上記大径側屈曲部35は、円錐筒部31の大径側の端部につながっている。上記大径側屈曲部35は、円錐筒部31の大径側の端部から径方向の外方側に屈曲して、中央バックアップ部34に略平行に延在している。上記大径側屈曲部35の径方向の外方の端面は、円筒外周面42になっている。上記大径側屈曲部35の円筒外周面42の外径は、円筒部33の円筒外周面41の外径と略同一になっている。   The large-diameter side bent portion 35 is connected to the large-diameter end of the conical cylinder portion 31. The large-diameter side bent portion 35 is bent radially outward from the large-diameter end of the conical cylinder portion 31 and extends substantially parallel to the central backup portion 34. A radially outer end surface of the large-diameter side bent portion 35 is a cylindrical outer peripheral surface 42. The outer diameter of the cylindrical outer peripheral surface 42 of the large-diameter side bent portion 35 is substantially the same as the outer diameter of the cylindrical outer peripheral surface 41 of the cylindrical portion 33.

上記外輪2は、ハウジング9の内周面に内嵌されて固定されている。詳しくは、上記円筒部33の円筒外周面41と、大径側屈曲部35の円筒外周面42とは、ハウジング9の内周面に内嵌されて固定されている。   The outer ring 2 is fitted and fixed to the inner peripheral surface of the housing 9. Specifically, the cylindrical outer peripheral surface 41 of the cylindrical portion 33 and the cylindrical outer peripheral surface 42 of the large-diameter side bent portion 35 are fitted and fixed to the inner peripheral surface of the housing 9.

上記径方向延在部32の軸方向の大径側屈曲部35とは反対側の端面46は、ハウジング9の径方向に延在する段部47に当接している。上記内輪1の円錐軌道面21の軸方向の外方の端面25を、軸部材5の段部26に当接すると共に、上記径方向延在部32の上記端面46を、ハウジング9の段部47に当接している。このようにして、ハウジング9と、軸部材5で、円錐ころ軸受を軸方向に挟み付けて、円錐ころ軸受に、所定の軸方向の予圧を生成するようにしている。また、図1に示すように、上記複数の円錐ころ3は、内輪1の円錐軌道面21と、外輪2の円錐筒部31の円錐軌道面38との間に、保持器50によって保持された状態で、周方向に互いに間隔をおいて配置されている。   An end face 46 opposite to the large-diameter side bent portion 35 in the axial direction of the radially extending portion 32 is in contact with a stepped portion 47 extending in the radial direction of the housing 9. The axially outer end surface 25 of the conical raceway surface 21 of the inner ring 1 is brought into contact with the step portion 26 of the shaft member 5, and the end surface 46 of the radially extending portion 32 is connected to the step portion 47 of the housing 9. Abut. In this way, the tapered roller bearing is sandwiched between the housing 9 and the shaft member 5 in the axial direction, and a preload in a predetermined axial direction is generated in the tapered roller bearing. Further, as shown in FIG. 1, the plurality of tapered rollers 3 are held by a cage 50 between the conical raceway surface 21 of the inner ring 1 and the conical raceway surface 38 of the conical cylinder portion 31 of the outer ring 2. In the state, they are arranged at intervals in the circumferential direction.

上記外輪2は、例えば、次のようにして製造するようになっている。   The outer ring 2 is manufactured, for example, as follows.

先ず、金属製の平板に、プレス打ち抜き加工により貫通穴を空ける。次に、貫通穴を有する平板をプレス加工により、塑性変形して、円錐筒部を形成する。続いて、プレス加工により、上記円錐筒部の小径側を、塑性変形して、径方向延在部を形成する。続いて、プレス加工により、径方向延在部の径方向の外方側を塑性変形して、軸方向に延在する円筒部を形成する。続いて、プレス加工して、円筒部の径方向延在部側とは反対側を塑性変形して、円筒部の径方向延在部側とは反対側から円錐筒部の軸方向の中央付近まで延在する中央バックアップ部を形成する。続いて、プレス加工によって、円錐筒部の大径側を屈曲させて、大径側屈曲部を形成する。最後に、大径側屈曲部の径方向の端面を、研磨等して、円筒外周面にする。このようにして、外輪を形成する。尚、平板の金属材料によっては、外輪の形状の生成後、浸炭、浸炭窒化、ずぶ焼入れ、高周波焼入れ、焼戻し、および、これらの組み合わせ等の熱処理や、ショットピーニング等の硬化処理を行うことが好ましい。   First, a through hole is formed in a metal flat plate by press punching. Next, the flat plate having the through hole is plastically deformed by pressing to form a conical cylinder portion. Subsequently, the small diameter side of the conical cylinder portion is plastically deformed by press working to form a radially extending portion. Subsequently, the outer side in the radial direction of the radially extending portion is plastically deformed by pressing to form a cylindrical portion extending in the axial direction. Subsequently, pressing is performed to plastically deform the side opposite to the radially extending portion side of the cylindrical portion, and from the side opposite to the radially extending portion side of the cylindrical portion, near the center in the axial direction of the conical cylinder portion Forming a central backup section extending to Subsequently, the large diameter side bent portion is formed by bending the large diameter side of the conical cylinder portion by pressing. Finally, the end surface in the radial direction of the large-diameter side bent portion is polished to form a cylindrical outer peripheral surface. In this way, an outer ring is formed. Depending on the metal material of the flat plate, it is preferable to perform a heat treatment such as carburizing, carbonitriding, sub-quenching, induction hardening, tempering, and a combination thereof, or a hardening treatment such as shot peening after the generation of the outer ring shape. .

また、他の方法として、外輪2は、次のようにして、形成することもできる。   As another method, the outer ring 2 can be formed as follows.

先ず、金属製の円板状の平板に、プレス打ち抜き加工により貫通穴を空けて、径方向延在部を形成する。続いて、プレス加工により、径方向延在部の径方向の内方側を塑性変形して、径方向延在部の径方向の内方側に、径方向延在部から離れるにしたがって、内径が大きくなる円錐筒部を形成する。その後、プレス加工により、径方向延在部の径方向の外方側を塑性変形して、径方向延在部の径方向の外方側に、軸方向に延在する円筒部を形成する。その後、プレス加工して、円筒部の径方向延在部側とは反対側を塑性変形して、円筒部の径方向延在部側とは反対側に、この反対側から円錐筒部の軸方向の中央付近まで延在する中央バックアップ部を形成する。続いて、プレス加工によって、円錐筒部の大径側を屈曲させて、大径側屈曲部を形成する。最後に、大径側屈曲部の径方向の端面を、研磨等して、円筒外周面にする。このようにして、外輪を形成する。   First, a through hole is formed in a metal disk-shaped flat plate by press punching to form a radially extending portion. Subsequently, the inner side in the radial direction of the radially extending portion is plastically deformed by pressing, and the inner diameter increases as the distance from the radially extending portion increases toward the radially inner side of the radially extending portion. A conical cylinder portion is formed in which becomes larger. Thereafter, the outer side in the radial direction of the radially extending portion is plastically deformed by pressing to form a cylindrical portion extending in the axial direction on the outer side in the radial direction of the radially extending portion. After that, pressing is performed to plastically deform the side opposite to the radially extending portion side of the cylindrical portion, and from the opposite side to the side opposite to the radially extending portion side of the cylindrical portion, the axis of the conical cylindrical portion is A central backup portion extending to near the center of the direction is formed. Subsequently, the large diameter side bent portion is formed by bending the large diameter side of the conical cylinder portion by pressing. Finally, the end surface in the radial direction of the large-diameter side bent portion is polished to form a cylindrical outer peripheral surface. In this way, an outer ring is formed.

上記歪みゲージ7は、外輪2の円錐筒部31の外周面88に固定されている。上記歪みゲージ7は、中央バックアップ部34の大径側屈曲部35に位置している。上記歪みゲージ7は、外輪2をハウジング9に固定した状態で、ハウジング9に間隔をおいて位置している。上記歪みゲージ7は、外輪2をハウジング9に固定した状態で、ハウジング9、中央バックアップ部34、円錐筒部31および大径側屈曲部35で画定される密封室90内に配置されている。言い換えれば、上記歪みゲージ7は、中央バックアップ部34、円錐筒部31および大径側屈曲部35で画定される外輪2の凹部91内に配置されている。   The strain gauge 7 is fixed to the outer peripheral surface 88 of the conical cylinder portion 31 of the outer ring 2. The strain gauge 7 is located at the large-diameter side bent portion 35 of the central backup portion 34. The strain gauge 7 is located at a distance from the housing 9 with the outer ring 2 fixed to the housing 9. The strain gauge 7 is disposed in a sealed chamber 90 defined by the housing 9, the central backup portion 34, the conical cylinder portion 31, and the large-diameter side bent portion 35 with the outer ring 2 fixed to the housing 9. In other words, the strain gauge 7 is disposed in the concave portion 91 of the outer ring 2 defined by the central backup portion 34, the conical cylinder portion 31, and the large-diameter side bent portion 35.

図2は、歪みゲージ7の一部の周辺の模式拡大図である。尚、図2において、矢印Aは、歪みゲージ7の長手方向を示している。   FIG. 2 is a schematic enlarged view of a part of the periphery of the strain gauge 7. In FIG. 2, an arrow A indicates the longitudinal direction of the strain gauge 7.

上記歪みゲージ7は、樹脂部81と、金属線部82とを有する。上記樹脂部81は、ポリイミド等の樹脂材からなり、直方体状の形状を有している。また、上記金属線部82は、銅線等の金属線からなり、その金属線は、樹脂部81上を蛇行するように形成されている。上記金属線部82の蛇行の進行方向は、歪みゲージ7の長手方向に一致している。   The strain gauge 7 has a resin part 81 and a metal wire part 82. The resin part 81 is made of a resin material such as polyimide and has a rectangular parallelepiped shape. The metal wire portion 82 is made of a metal wire such as a copper wire, and the metal wire is formed to meander on the resin portion 81. The direction of meandering of the metal wire portion 82 coincides with the longitudinal direction of the strain gauge 7.

上記歪みゲージ7は、歪みゲージ7の長手方向Aが、外輪2の円錐筒部31の外周面88(図1参照)の周方向と垂直な方向に一致するように、上記外周面88に固定されている。   The strain gauge 7 is fixed to the outer peripheral surface 88 such that the longitudinal direction A of the strain gauge 7 coincides with a direction perpendicular to the peripheral direction of the outer peripheral surface 88 (see FIG. 1) of the conical cylinder portion 31 of the outer ring 2. Has been.

図3は、上記歪みゲージ7の一部を示す平面図である。   FIG. 3 is a plan view showing a part of the strain gauge 7.

図3において、斜線のハッチングで示す部分は、樹脂部81であり、斜線のハッチングで示す部分の間に存在するハッチングがない蛇行している部分は、金属線部82である。   In FIG. 3, the portion indicated by hatching is the resin portion 81, and the meandering portion having no hatching existing between the portions indicated by hatching is the metal line portion 82.

図2および図3に示す歪みゲージ7は、被測定物である円錐筒部31が変形する度合と同一の度合で変形するようになっている。また、歪みゲージ7の金属線部82は、伸びにより断面積が減るとともに長さが長くなり、その結果抵抗値が増えるようになっている。上記金属線部の抵抗値を測定することで、円錐筒部31の歪みを測定して、センサ付き円錐ころ軸受の予圧を測定するようになっている。また、詳述しないが、上記歪みゲージ7からの信号を、ハウジング9に形成された貫通穴(図示せず)に挿通された絶縁体で覆われた配線を介して取り出すようにしている。   The strain gauge 7 shown in FIG. 2 and FIG. 3 is configured to be deformed at the same degree as the conical cylinder part 31 that is the object to be measured is deformed. In addition, the metal wire portion 82 of the strain gauge 7 is reduced in cross-sectional area due to elongation and lengthened, and as a result, the resistance value increases. By measuring the resistance value of the metal wire part, the distortion of the conical cylinder part 31 is measured, and the preload of the tapered roller bearing with sensor is measured. Although not described in detail, the signal from the strain gauge 7 is taken out through a wiring covered with an insulator inserted into a through hole (not shown) formed in the housing 9.

上記構成において、第1実施形態のセンサ付き円錐ころ軸受は、組立時や運転時に、歪みゲージ7からの信号に基づいて測定した予圧が、所望の予圧と異なる場合には、ねじ(図示しない)の締め込み量を適宜調整することによって、ハウジング9の段部47と、軸部材5の段部26との距離を適宜調整して、予圧を所望の予圧に設定するようになっている。   In the above configuration, the tapered roller bearing with sensor according to the first embodiment has a screw (not shown) when the preload measured based on the signal from the strain gauge 7 during assembly or operation is different from the desired preload. By appropriately adjusting the tightening amount, the distance between the stepped portion 47 of the housing 9 and the stepped portion 26 of the shaft member 5 is appropriately adjusted to set the preload to a desired preload.

上記第1実施形態のセンサ付き外輪40によれば、外輪2が金属の塊より格段に軽い一体の金属板からなるから、従来の中実の外輪と比較して、質量が格段に小さくなる。具体的には、上記第1実施形態の外輪2は、その外輪2と略同一の円錐軌道面を有する従来の中実の円錐ころ軸受の外輪の40%程度(40%程度に限らないのは言うまでもない)の質量しかなくて、従来の中実の外輪と比較して質量が急激に小さくなる。したがって、上記第1実施形態の外輪2を、車両に使用した場合、従来の中実の外輪と比較して、運転コストが低くなり、材料コストが低くなる。また、上記第1実施形態の外輪2によれば、外輪2が一体の金属板からなるから、旋削等を不要あるいは旋削量を少なくできて、製造コストが小さくなる。   According to the sensor-equipped outer ring 40 of the first embodiment, since the outer ring 2 is made of an integrated metal plate that is much lighter than a metal lump, the mass is remarkably smaller than that of a conventional solid outer ring. Specifically, the outer ring 2 of the first embodiment is about 40% (not limited to about 40%) of the outer ring of a conventional solid tapered roller bearing having a conical raceway surface substantially the same as the outer ring 2. Needless to say, there is only a small mass, and the mass is drastically reduced as compared with a conventional solid outer ring. Therefore, when the outer ring 2 of the first embodiment is used in a vehicle, the operating cost is lower and the material cost is lower than a conventional solid outer ring. Further, according to the outer ring 2 of the first embodiment, since the outer ring 2 is made of an integral metal plate, turning or the like is unnecessary or the amount of turning can be reduced, and the manufacturing cost is reduced.

また、上記第1実施形態のセンサ付き外輪40によれば、外輪2が一体の板金からなって、ワンピースで外輪としての機能を果たしているから、外輪を複数の部品で形成する場合と異なり、各部品の調整が一切必要なくて、容易に組み付けでき、容易に取り扱うことができる。   Moreover, according to the outer ring 40 with a sensor of the said 1st Embodiment, since the outer ring | wheel 2 consists of integral sheet metal, and has fulfilled the function as an outer ring | wheel with one piece, unlike the case where an outer ring | wheel is formed with several components, There is no need to adjust any parts, and it can be easily assembled and handled easily.

また、上記第1実施形態のセンサ付き外輪40によれば、円錐軌道面38を有しているのが、軸方向に連続して存在する円錐筒部31であって、円錐軌道面38が軸方向に連続して存在しているから、円錐ころ3の転動面の軸方向の略全域を、円錐筒部31で支えることができる。したがって、円錐ころ3が、円錐軌道面38上を安定かつ円滑に転動することができる。   Further, according to the sensor-equipped outer ring 40 of the first embodiment, the conical raceway surface 38 is the conical tube portion 31 continuously present in the axial direction, and the conical raceway surface 38 is the axis. Since it exists continuously in the direction, the substantially entire area in the axial direction of the rolling surface of the tapered roller 3 can be supported by the conical cylinder portion 31. Therefore, the tapered roller 3 can roll stably and smoothly on the conical raceway surface 38.

また、上記第1実施形態のセンサ付き外輪40によれば、円錐筒部31の小径側の端部から円錐筒部31の略径方向に延在する径方向延在部32が存在するから、この径方向延在部32を、ハウジング9の軸方向の段部47に当接させることができる。したがって、上記ハウジング9の段部47から抗力を受けることができるから、アキシアル荷重を負荷することができる。   Moreover, according to the outer ring 40 with a sensor of the said 1st Embodiment, since the radial direction extension part 32 extended in the substantially radial direction of the cone cylinder part 31 from the edge part by the side of the small diameter of the cone cylinder part 31 exists, The radially extending portion 32 can be brought into contact with the axial step portion 47 of the housing 9. Therefore, since a drag force can be received from the step portion 47 of the housing 9, an axial load can be applied.

また、上記第1実施形態のセンサ付き外輪40によれば、径方向延在部32の径方向の外方の端部に連結されて、円錐筒部31の略軸方向に延在する円筒部33を有するから、この円筒部33をハウジング9の内周面に内嵌して固定することができる。また、同様に、円錐筒部31の大径側の端部から径方向の外方側に屈曲して延在する大径側屈曲部35の外周面をハウジング9の内周面に内嵌して固定することができる。したがって、円筒部33と大径側屈曲部35との軸方向に離間して位置する2箇所を、ハウジング9の内周面に固定することができるから、外輪2を安定かつ確実にハウジング9に固定することができる。   Moreover, according to the outer ring 40 with a sensor of the said 1st Embodiment, it connects with the outer end part of the radial direction of the radial direction extension part 32, and the cylindrical part extended in the substantially axial direction of the conical cylinder part 31 Since it has 33, this cylindrical part 33 can be fitted and fixed to the inner peripheral surface of the housing 9. Similarly, the outer peripheral surface of the large-diameter side bent portion 35 that is bent and extended from the end portion on the large-diameter side of the conical cylinder portion 31 to the radially outer side is fitted into the inner peripheral surface of the housing 9. Can be fixed. Accordingly, the two portions of the cylindrical portion 33 and the large-diameter-side bent portion 35 that are spaced apart in the axial direction can be fixed to the inner peripheral surface of the housing 9, so that the outer ring 2 can be stably and reliably attached to the housing 9. Can be fixed.

また、上記第1実施形態のセンサ付き外輪40によれば、円筒部33の他端から円錐筒部31の外周面の軸方向の中央付近まで延在して上記中央付近をバックアップする中央バックアップ部34を有するから、この中央バックアップ部34によって、円錐筒部31の円錐軌道面38の変形を防止できる。   Moreover, according to the outer ring 40 with a sensor of the said 1st Embodiment, the central backup part which extends from the other end of the cylindrical part 33 to the axial vicinity of the outer peripheral surface of the conical cylinder part 31, and backs up the said center vicinity. Therefore, the central backup portion 34 can prevent the conical track surface 38 of the conical cylinder portion 31 from being deformed.

また、上記第1実施形態のセンサ付き外輪40によれば、上記中央バックアップ部34によって、外輪2の径方向の強度を大きくでき、また、径方向延在部32および大径側屈曲部35によっても、径方向の剛性を大きくできる。したがって、上記中央バックアップ部34と、径方向延在部32と、大径側屈曲部35との互いに軸方向に離間して存在する3箇所で、径方向の剛性を大きくできて、外輪2の径方向の強度が、問題がないものになる。   Moreover, according to the sensor-equipped outer ring 40 of the first embodiment, the central backup portion 34 can increase the radial strength of the outer ring 2, and the radial extending portion 32 and the large-diameter side bent portion 35 can increase the radial strength. However, the radial rigidity can be increased. Therefore, the rigidity in the radial direction can be increased at the three locations where the central backup portion 34, the radially extending portion 32, and the large-diameter side bent portion 35 are spaced apart from each other in the axial direction. The strength in the radial direction is not problematic.

また、上記第1実施形態のセンサ付き外輪40によれば、歪みゲージ7が、円錐筒部31の外周面88に固定されているから、このセンサ付き外輪40を有するセンサ付き円錐ころ軸受の組み付け時の予圧や、運転時の予圧を、歪みゲージ7の測定値に基づいて正確に測定できる。したがって、組み付け時に、精密に所望の予圧を設定でき、また、運転時に、上記歪みゲージ7の測定値に基づいて、予圧を適宜、適切に調整できる。   Moreover, according to the outer ring 40 with a sensor of the said 1st Embodiment, since the strain gauge 7 is being fixed to the outer peripheral surface 88 of the conical cylinder part 31, the assembly | attachment of the tapered roller bearing with a sensor which has this outer ring 40 with a sensor is carried out. The preload during operation and the preload during operation can be accurately measured based on the measured value of the strain gauge 7. Therefore, a desired preload can be accurately set at the time of assembly, and the preload can be appropriately and appropriately adjusted based on the measured value of the strain gauge 7 during operation.

また、上記第1実施形態のセンサ付き外輪40によれば、上記歪みゲージ7が、円錐筒部31と、中央バックアップ部34と、大径側屈曲部35とで画定される凹部91内に配置されて、歪みゲージ7が、外輪2をハウジング9に取り付けた状態で、密封室となる室90内に取り付けられているから、外輪2への歪みゲージ7の搭載の前後で、外輪2の配置スペースが変化することがない。したがって、この発明のセンサ付き外輪40を用いると、配置スペースが小さいセンサ付き円錐ころ軸受を実現することができる。   Further, according to the sensor-equipped outer ring 40 of the first embodiment, the strain gauge 7 is disposed in the recess 91 defined by the conical cylinder portion 31, the central backup portion 34, and the large-diameter side bent portion 35. Since the strain gauge 7 is mounted in the chamber 90 which is a sealed chamber with the outer ring 2 attached to the housing 9, the outer ring 2 is disposed before and after the strain gauge 7 is mounted on the outer ring 2. Space does not change. Therefore, if the outer ring 40 with a sensor of this invention is used, a tapered roller bearing with a sensor with a small arrangement space can be realized.

また、上記第1実施形態のセンサ付き外輪40によれば、歪みゲージ7が、外輪2の室49内に配置されることがなくて、外輪2の凹部91内に配置されることになるから、時間に対する歪みゲージ7の固定の自由度を大きくすることができて、歪みゲージ7の取り付け容易性を大きくすることができる。というのは、歪みゲージを外輪の室内に配置する構成では、歪みゲージが、外輪の室の完成前に、金属板に固定されなければならない一方、第1実施形態のように、歪みゲージ7を外輪2の凹部91内に配置する構成では、歪みゲージ7の外輪2への設置の時間的な制限が存在することがないからである。   Further, according to the sensor-equipped outer ring 40 of the first embodiment, the strain gauge 7 is not disposed in the chamber 49 of the outer ring 2 but is disposed in the recess 91 of the outer ring 2. The degree of freedom of fixing the strain gauge 7 with respect to time can be increased, and the ease of attachment of the strain gauge 7 can be increased. This is because, in the configuration in which the strain gauge is disposed in the outer ring chamber, the strain gauge must be fixed to the metal plate before the outer ring chamber is completed. This is because the arrangement of the strain gauge 7 in the outer ring 2 is not limited in the configuration in which the outer ring 2 is disposed in the recess 91.

また、上記第1実施形態のセンサ付き外輪40によれば、中央バックアップ部34が、円錐軌道面38の略法線方向に延在しているから、円錐軌道面38の変形防止効果を、強化することができる。更に述べると、第1実施形態では、中央バックアップ部34が、荷重負荷点である円錐筒部31の中央付近に接触しているから、円錐軌道面38の撓みを効率的に防止することができる。   Further, according to the sensor-equipped outer ring 40 of the first embodiment, since the central backup portion 34 extends in the substantially normal direction of the conical raceway surface 38, the effect of preventing deformation of the conical raceway surface 38 is enhanced. can do. More specifically, in the first embodiment, since the central backup portion 34 is in contact with the vicinity of the center of the conical cylinder portion 31 that is the load point, it is possible to efficiently prevent the conical track surface 38 from being bent. .

また、上記第1実施形態のセンサ付き外輪40によれば、外輪2が、一体の金属板をプレス成形してなっているから、製造コストを低減でき、量産性を向上させることができる。   Moreover, according to the sensor-equipped outer ring 40 of the first embodiment, since the outer ring 2 is formed by press-molding an integral metal plate, manufacturing cost can be reduced and mass productivity can be improved.

また、上記第1実施形態のセンサ付き外輪40によれば、上記大径側屈曲部35が、中央バックアップ部34と略平行に延在しているから、径方向の強度を更に大きくすることができる。   Moreover, according to the outer ring 40 with a sensor of the said 1st Embodiment, since the said large diameter side bending part 35 is extended substantially parallel to the center backup part 34, the intensity | strength of radial direction can be enlarged further. it can.

また、上記第1実施形態のセンサ付き円錐ころ軸受によれば、従来と比較して外輪2が軽量であるから、従来と比較して、センサ付き円錐ころ軸受の質量が格段に小さくなる。   Moreover, according to the tapered roller bearing with a sensor of the said 1st Embodiment, since the outer ring | wheel 2 is lightweight compared with the past, compared with the past, the mass of the tapered roller bearing with a sensor becomes remarkably small.

尚、上記第1実施形態のセンサ付き外輪40では、外輪2を、金属製の一体の板をプレス成形して形成したが、この発明では、外輪を、金属製の一体の板を、転造加工、鍛造加工等の他の塑性加工を用いて形成しても良い。   In the outer ring 40 with a sensor according to the first embodiment, the outer ring 2 is formed by press-molding a metal integral plate. However, in the present invention, the outer ring is formed by rolling a metal integral plate. You may form using other plastic processing, such as a process and a forge process.

また、上記第1実施形態のセンサ付き外輪40では、平板状の金属板から外輪2を形成したが、この発明では、継ぎ目のない筒状の金属体を塑性変形して、外輪を形成しても良く、また、電縫管等の継ぎ目のある筒状の金属体を、塑性変形して、外輪を形成しても良い。   Further, in the outer ring with sensor 40 of the first embodiment, the outer ring 2 is formed from a flat metal plate. However, in the present invention, a seamless cylindrical metal body is plastically deformed to form an outer ring. Alternatively, the outer ring may be formed by plastically deforming a tubular metal body having a seam such as an electric sewing tube.

また、上記第1実施形態のセンサ付き外輪40では、中央バックアップ部34が、外輪2の円錐軌道面38の略法線方向に延在していたが、この発明では、中央バックアップ部は、外輪の円錐軌道面の法線方向に延在していなくても良い。   Further, in the outer ring with sensor 40 of the first embodiment, the central backup portion 34 extends in the substantially normal direction of the conical raceway surface 38 of the outer ring 2, but in this invention, the central backup portion is the outer ring. It does not have to extend in the normal direction of the conical track surface.

また、上記第1実施形態のセンサ付き外輪40では、大径側屈曲部35が、中央バックアップ部と略平行に延在していた。しかしながら、この発明では、外輪の大径側屈曲部が、中央バックアップ部と平行に延在していなくても良い。   Moreover, in the outer ring 40 with a sensor of the said 1st Embodiment, the large diameter side bending part 35 extended substantially parallel to the center backup part. However, in the present invention, the large-diameter side bent portion of the outer ring does not have to extend in parallel with the central backup portion.

また、上記第1実施形態のセンサ付き外輪40では、歪みゲージ7が、円錐筒部31の外周面であって、中央バックアップ部34の大径屈曲部35側に位置していたが、この発明では、歪みセンサは、円錐筒部の外周面であって、中央バックアップ部の径方向延在部側に位置しても良い。   Further, in the outer ring with sensor 40 of the first embodiment, the strain gauge 7 is located on the outer peripheral surface of the conical cylinder portion 31 and on the large-diameter bent portion 35 side of the central backup portion 34. Then, the strain sensor may be located on the outer peripheral surface of the conical cylinder portion and on the radially extending portion side of the central backup portion.

また、上記第1実施形態のセンサ付き外輪40では、歪みゲージ7は、金属抵抗線の抵抗を利用するものであったが、この発明では、歪みセンサは、金属抵抗体の抵抗の代わりにシリコン半導体の抵抗を利用するものであっても良い。また、この発明では、歪みセンサは、光や温度や超音波等を用いて変位を測定するセンサであっても良い。この発明の歪みセンサは、円錐筒部の変位を測定できるセンサであれば、如何なるセンサであっても良い。   In the outer ring with a sensor 40 of the first embodiment, the strain gauge 7 uses the resistance of a metal resistance wire. In the present invention, the strain sensor is a silicon instead of the resistance of the metal resistor. A semiconductor resistor may be used. In the present invention, the strain sensor may be a sensor that measures displacement using light, temperature, ultrasonic waves, or the like. The strain sensor of the present invention may be any sensor as long as it can measure the displacement of the conical cylinder portion.

尚、円錐軌道面の表面粗さの程度の表面粗さを有する金属板を原材として使用すると、その金属板をプレス加工して外輪を生成した場合に、製品としての外輪の円錐軌道面の軌道精度が得られることが確認されている。したがって、円錐軌道面の研磨等が、必要がないことが確認されている。したがって、本発明の外輪では、製造工数を格段に低減することができる。   If a metal plate having a surface roughness of the surface roughness of the conical raceway surface is used as a raw material, when the outer ring is produced by pressing the metal plate, the product of the conical raceway surface of the outer ring as a product is used. It has been confirmed that orbital accuracy can be obtained. Therefore, it has been confirmed that polishing of the conical track surface is unnecessary. Therefore, in the outer ring of the present invention, the number of manufacturing steps can be significantly reduced.

図4は、本発明の第2実施形態のセンサ付き円錐ころ軸受装置の軸方向の断面図である。   FIG. 4 is a sectional view in the axial direction of a tapered roller bearing device with a sensor according to a second embodiment of the present invention.

このセンサ付き円錐ころ軸受装置(以下、単に軸受装置という)は、第1実施形態のセンサ付き転がり軸受と同一のセンサ付き転がり軸受100と、予圧調整ピストン機構101とを備える。   This sensor-equipped tapered roller bearing device (hereinafter simply referred to as a bearing device) includes a sensor-equipped rolling bearing 100 that is the same as the sensor-equipped rolling bearing of the first embodiment and a preload adjusting piston mechanism 101.

この軸受装置は、図示しないマイクロコンピュータを有し、このマイクロコンピュータで、歪みゲージ7からの信号に基づいて、センサ付き円錐ころ軸受100の予圧を算出するようになっている。上記マイクロコンピュータは、算出した予圧値が、組み付け時または運転時の所望の予圧と異なる予圧である場合に、予圧調整ピストン機構101の図示しない油供給部に、油を供給あるいは油を排出することを表す信号を出力するようになっている。このようにして、予圧調整ピストン機構101のピストン内の油が充填される室107の容積を調整して、ピストンの押圧部105の軸方向の位置を適宜調整するようになっている。そして、この押圧部105の軸方向の位置の調整に基づいて、押圧部105に軸方向に当接している外輪2の径方向延在部32の軸方向の位置を適宜調整することにより、センサ付き円錐ころ軸受100の予圧を所望な予圧に調整している。   This bearing device has a microcomputer (not shown), and this microcomputer calculates the preload of the tapered roller bearing 100 with a sensor based on a signal from the strain gauge 7. The microcomputer supplies or discharges oil to an oil supply section (not shown) of the preload adjusting piston mechanism 101 when the calculated preload value is different from a desired preload during assembly or operation. Is output. In this way, the volume of the chamber 107 filled with the oil in the piston of the preload adjusting piston mechanism 101 is adjusted, and the axial position of the piston pressing portion 105 is appropriately adjusted. Based on the adjustment of the position of the pressing portion 105 in the axial direction, the position of the radially extending portion 32 of the outer ring 2 that is in contact with the pressing portion 105 in the axial direction is appropriately adjusted to thereby adjust the sensor. The preload of the tapered roller bearing 100 is adjusted to a desired preload.

上記第2実施形態の軸受装置によれば、センサ付き円錐ころ軸受100の荷重負荷能力を常時自動的に優れたものにすることができる。また、センサ付き円錐ころ軸受100に過度の荷重が作用して、センサ付き円錐ころ軸受100が破損することを防止することができる。   According to the bearing device of the second embodiment, the load carrying capacity of the sensor-equipped tapered roller bearing 100 can be made excellent automatically at all times. Moreover, it can prevent that the excessive load acts on the tapered roller bearing 100 with a sensor, and the tapered roller bearing 100 with a sensor breaks.

1 内輪
2 外輪
3 円錐ころ
7 歪みゲージ
21 内輪の円錐軌道面
31 円錐筒部
32 径方向延在部
33 円筒部
34 中央バックアップ部
35 大径側屈曲部
38 外輪の円錐軌道面
40 センサ付き外輪
100 センサ付き円錐ころ軸受
DESCRIPTION OF SYMBOLS 1 Inner ring 2 Outer ring 3 Tapered roller 7 Strain gauge 21 Conical raceway surface of inner ring 31 Conical cylinder part 32 Radially extending part 33 Cylindrical part 34 Central backup part 35 Large-diameter side bending part 38 Conical raceway surface of outer ring 40 Outer ring with sensor 100 Tapered roller bearing with sensor

Claims (3)

一体の金属板からなる外輪と、
歪みセンサと
を備え、
上記金属板は、
内周に円錐軌道面を有する円錐筒部と、
上記円錐筒部の小径側の端部から上記円錐筒部の略径方向に延在する径方向延在部と、
上記径方向延在部の上記径方向の外方の端部に一端が連結されると共に、上記円錐筒部の略軸方向に延在する円筒部と、
上記円筒部の他端から上記円錐筒部の外周面の軸方向の中央部まで延在して上記中央部をバックアップする中央バックアップ部と、
上記円錐筒部の大径側の端部から径方向の外方側に屈曲すると共に、径方向の外方の端面の外径が、上記円筒部の外周面の外径と略同一である大径側屈曲部と
を有し、
上記歪みセンサは、上記円錐筒部の外周面に固定されていることを特徴とするセンサ付き外輪。
An outer ring made of an integral metal plate,
A strain sensor,
The metal plate is
A conical cylinder portion having a conical track surface on the inner periphery;
A radially extending portion extending in a substantially radial direction of the conical tube portion from an end portion on the small diameter side of the conical tube portion;
One end is connected to the radially outer end of the radially extending portion, and a cylindrical portion extending substantially in the axial direction of the conical tubular portion;
A central backup portion that extends from the other end of the cylindrical portion to the axial central portion of the outer peripheral surface of the conical cylindrical portion, and backs up the central portion;
The large diameter of the conical tube portion is bent from the large diameter end to the radially outward side, and the outer diameter of the radially outer end surface is substantially the same as the outer diameter of the outer peripheral surface of the cylindrical portion. A radial side bend,
The outer ring with a sensor, wherein the strain sensor is fixed to an outer peripheral surface of the conical cylinder portion.
請求項1に記載のセンサ付き外輪において、
上記歪みセンサは、上記中央バックアップ部と、上記大径側屈曲部との間に位置していることを特徴とするセンサ付き外輪。
In the outer ring with a sensor according to claim 1,
The outer ring with a sensor, wherein the strain sensor is located between the central backup portion and the large-diameter side bent portion.
請求項1または2に記載のセンサ付き外輪と、
外周に円錐軌道面を有する内側軌道部材と、
上記外輪の上記円錐筒部の上記円錐軌道面と、上記内側軌道部材の上記円錐軌道面との間に配置された円錐ころと
を備えることを特徴とするセンサ付き円錐ころ軸受。
An outer ring with a sensor according to claim 1 or 2,
An inner race member having a conical raceway surface on the outer periphery;
A tapered roller bearing with a sensor, comprising: a tapered roller disposed between the conical raceway surface of the conical cylinder portion of the outer ring and the conical raceway surface of the inner raceway member.
JP2009206765A 2009-07-31 2009-09-08 Sensor outer ring and sensor tapered roller bearing Expired - Fee Related JP5333082B2 (en)

Priority Applications (5)

Application Number Priority Date Filing Date Title
JP2009206765A JP5333082B2 (en) 2009-09-08 2009-09-08 Sensor outer ring and sensor tapered roller bearing
US12/843,258 US8827564B2 (en) 2009-07-31 2010-07-26 Outer ring of tapered roller bearing, tapered roller bearing, and manufacturing method of outer ring of tapered roller bearing
AT10171239T ATE549526T1 (en) 2009-07-31 2010-07-29 OUTER RING OF A TAPERED BEARING, TAPERED BEARING AND MANUFACTURING METHOD FOR THE OUTER RING OF THE TAPERED BEARING
EP10171239A EP2280180B1 (en) 2009-07-31 2010-07-29 Outer ring of tapered roller bearing, tapered roller bearing, and manufacturing method of outer ring of tapered roller bearing
CN2010102429047A CN101988546B (en) 2009-07-31 2010-07-30 Outer ring of tapered roller bearing, tapered roller bearing, and manufacturing method of outer ring of tapered roller bearing

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP2009206765A JP5333082B2 (en) 2009-09-08 2009-09-08 Sensor outer ring and sensor tapered roller bearing

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE102012203789A1 (en) * 2012-03-12 2013-09-12 Schaeffler Technologies AG & Co. KG Rolling bearing such as tapered roller bearing for motor car gearbox, has bearing ring consisting of sheet metal, which is resiliently biased against rolling elements by track portion and is curved in track portion

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1950036U (en) * 1966-09-22 1966-11-17 Skf Kugellagerfabriken Gmbh INCLINED ROLLERS OR ANGLE NEEDLE BEARING.
US3653731A (en) * 1970-08-14 1972-04-04 John C Rau Roller bearing
DE102005019482A1 (en) * 2005-04-27 2006-11-09 Ab Skf Tapered roller bearing in particular for area with low requirements at stability, comprising hollow space formed by inner as well as by outer ring
DE102006004752A1 (en) * 2006-02-02 2007-08-09 Schaeffler Kg Anti-friction bearing e.g. angular roller bearing, has rolling units arranged between outer ring and inner ring in cage, where outer ring and inner ring are arranged axially opposed to each other with their J- and/or L-shaped cross section

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE1950036U (en) * 1966-09-22 1966-11-17 Skf Kugellagerfabriken Gmbh INCLINED ROLLERS OR ANGLE NEEDLE BEARING.
US3653731A (en) * 1970-08-14 1972-04-04 John C Rau Roller bearing
DE102005019482A1 (en) * 2005-04-27 2006-11-09 Ab Skf Tapered roller bearing in particular for area with low requirements at stability, comprising hollow space formed by inner as well as by outer ring
DE102006004752A1 (en) * 2006-02-02 2007-08-09 Schaeffler Kg Anti-friction bearing e.g. angular roller bearing, has rolling units arranged between outer ring and inner ring in cage, where outer ring and inner ring are arranged axially opposed to each other with their J- and/or L-shaped cross section

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE102012203789A1 (en) * 2012-03-12 2013-09-12 Schaeffler Technologies AG & Co. KG Rolling bearing such as tapered roller bearing for motor car gearbox, has bearing ring consisting of sheet metal, which is resiliently biased against rolling elements by track portion and is curved in track portion

Also Published As

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