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

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

  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.

  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.

  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.

  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.

  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.

  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.

Japanese Patent Laid-Open No. 11-48805 (FIG. 1)

  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.

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.

  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.

  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.

  The strain sensor includes all sensors that measure displacement. This is because the strain can be measured indirectly by measuring the displacement.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

In one embodiment,
The strain sensor is located between the central backup portion and the large-diameter side bent portion.

  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.

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.

  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.

In one embodiment,
The central backup portion extends in a substantially normal direction of the conical track surface.

  Note that the abbreviations in the substantially normal direction are determined by human vision.

  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.

In one embodiment,
The integral metal plate is press-molded.

  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.

In one embodiment,
The large diameter side bent portion extends substantially parallel to the central backup portion.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

It is sectional drawing of the axial direction of the tapered roller bearing with a sensor of 1st Embodiment of this invention. It is a schematic diagram which shows the strain gauge of the said tapered roller bearing with a sensor. It is a top view which shows a part of said strain gauge. It is sectional drawing of the axial direction of the tapered roller bearing apparatus with a sensor of 2nd Embodiment of this invention.

  Hereinafter, the present invention will be described in detail with reference to the drawings.

  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.

  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

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  The outer ring 2 is manufactured, for example, as follows.

  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. .

  As another method, the outer ring 2 can be formed as follows.

  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.

  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.

  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.

  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.

  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.

  FIG. 3 is a plan view showing a part of the strain gauge 7.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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. .

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

  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.

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)

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. 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. 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.

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