JP2007321831A - Wheel bearing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To press a cap into the end of an outward member without deforming a bottom portion of the cap on which a magnetic sensor is mounted. <P>SOLUTION: The cap 10 has an annular portion 10b provided between a cylindrical portion 10a and the bottom portion 10d so as to be bent inward from the cylindrical portion 10a, and a stepped cylindrical portion 10c extending from the inner end of the annular portion 10b to the axial direction and ranging to the bottom portion 10d. When the cap 10 is pressed into the end of the outward member 1, the annular portion 10b can be thrust with a press-in tool. Thus, the cap 10 can be pressed into the end of the outward member 1 without deforming the bottom portion 10d on which a sensor unit 13 of the magnetic sensor 13a is mounted. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a wheel bearing device equipped with a rotation sensor.

  A wheel bearing device for supporting a wheel of an automobile has an outer member having a double row raceway surface on the inner diameter side, and a double row raceway surface facing each raceway surface on the outer member on the outer diameter side. The inner member and rolling elements arranged in a double row between the outer member and the inner member raceway surface, a fixing member for fixing the outer member to the vehicle body side, and the inner member for the wheel side There is a rotating member that can be attached to.

  In recent years, ABS (Antilock Brake System) or the like is often incorporated in order to improve the running stability of a car, and a rotation sensor for detecting the rotation of the wheel for the control is mounted on the wheel bearing device. ing. The rotation sensor for detecting the rotation of the wheel includes a magnetic encoder having a magnetized portion magnetized by a plurality of magnetic poles in the circumferential direction, and a magnetic sensor for detecting a change in magnetic flux accompanying the rotation of the magnetic encoder. The magnetic encoder is mounted on the rotating member side of the outer member and the inner member, and the magnetic sensor is mounted on the fixed member side so as to face this. A magnetic sensor is usually mounted on the fixed member side as a sensor unit that incorporates a processing circuit for its output.

  In the wheel bearing device in which the outer member described above is a fixed member and the inner member is a rotating member, a cylindrical portion of a cap having a bottom portion is fitted to an end portion on the inboard side of the outer member. Some have a magnetic sensor for detecting a change in magnetic flux accompanying rotation of a magnetic encoder at the bottom (see, for example, Patent Document 1). Patent Document 1 describes an example in which the magnetic sensor is mounted so as to face the magnetized portion of the magnetic encoder in the axial direction, and an example in which the magnetic sensor is mounted so as to face in the radial direction. .

JP 2005-351408 A

  Like the wheel bearing device described in Patent Document 1, a magnetic sensor attached to the bottom of the cap fitted to the end of the outer member on the inboard side is shown in FIG. When the cylindrical portion 10a is pressed into the end of the outer member 1, it is necessary to press the bottom portion 10d on which the magnetic sensor 13a incorporated in the sensor unit 13 is mounted by the press-fitting jig 20 or the like. 10 may be deformed, and the mounting position of the magnetic sensor 13a, which needs to be opposed to the magnetized portion 12a of the magnetic encoder 12 with a slight gap, may be shifted, thereby impairing the detection accuracy of the rotation sensor. .

  Therefore, an object of the present invention is to enable the cap to be press-fitted into the end of the outer member without deforming the bottom of the cap to which the magnetic sensor is attached.

  In order to solve the above-described problems, the present invention has an outer member that has a double-row raceway surface on the inner diameter side and is fixed to the vehicle body side, and a double-row facing each raceway surface of the outer member. The inner member includes an inner member having a raceway surface on the outer diameter side and attached to the wheel side, and rolling elements arranged in a double row between the outer member and the raceway surface of the inner member. A cylindrical portion of a cap having a magnetic encoder having a magnetized portion magnetized by a plurality of magnetic poles in a circumferential direction at an end portion on the inboard side of the outer member, and having a bottom portion at an end portion on the inboard side of the outer member In a wheel bearing device in which a magnetic sensor for detecting a change in magnetic flux accompanying rotation of the magnetic encoder is mounted on the bottom of the cap so as to face the magnetized portion of the magnetic encoder, Between the cylindrical part and the bottom part, an annular part bent inward from the cylindrical part, and this Employing the configuration provided a stepped cylindrical portion continuous to the bottom portion extends axially from the inner end of the annular portion.

  That is, by providing an annular portion bent inward from the cylindrical portion and a stepped cylindrical portion extending in the axial direction from the inner end of the annular portion and continuing to the bottom portion between the cylindrical portion and the bottom portion of the cap. When the cap is pressed into the end of the outer member, the annular portion can be pressed with a press-fitting jig or the like, and the cap is inserted into the end of the outer member without deforming the bottom where the magnetic sensor is mounted. I was able to press fit into the part.

  A step ring portion bent inward from a bearing outer end of the cylindrical portion to a core metal fitted to the outer diameter surface of the inboard side end portion of the inner member by the cylindrical portion; A step cylindrical portion extending in the axial direction from the inner end of the step annular portion and an annular portion bent inward from the tip of the step cylindrical portion are provided, and the magnetized portion is provided on the bearing outer surface of the annular portion. When the core bar of the magnetic encoder is press-fitted into the outer diameter surface of the end of the inner member, the stepped annular portion not provided with the magnetized portion is pressed with a press-fitting jig or the like. The core bar of the magnetic encoder can be pressed into the outer diameter surface of the end portion of the inner member without damaging the magnetized portion.

  The step cylindrical portion of the cap has an outer diameter smaller than an outer diameter of an end on the inboard side of the inner member, and an inner diameter thereof is an outer diameter of the step cylindrical portion of the core bar of the magnetic encoder. The rotation sensor can be mounted on the wheel bearing device in a compact manner.

  The wheel bearing device according to the present invention includes an annular portion bent inward from the cylindrical portion between the cylindrical portion and the bottom portion of the cap, and a step extending in the axial direction from the inner end of the annular portion and continuing to the bottom portion. By providing a cylindrical part, when the cap is press-fitted into the end of the outer member, the annular part can be pressed with a press-fitting jig or the like, so that the bottom part to which the magnetic sensor is attached is deformed. The cap can be pressed into the end of the outer member, and the mounting position of the magnetic sensor can be set with high accuracy.

  A stepped annular portion that bends inwardly from a bearing outer end of the cylindrical portion to a core metal that is fitted to the outer diameter surface of the inboard side end portion of the inner member by the cylindrical portion, A step cylindrical portion extending in the axial direction from the inner end of the step annular portion and an annular portion bent inward from the tip of the step cylindrical portion are provided, and a magnetized portion is provided on the bearing outer surface of the annular portion. Therefore, when the core bar of the magnetic encoder is press-fitted into the outer diameter surface of the end of the inner member, the stepped annular portion not provided with the magnetized portion is pressed with a press-fitting jig or the like. The core bar of the magnetic encoder can be pressed into the outer diameter surface of the end portion of the inner member without damaging the magnetic part.

  The step cylindrical portion of the cap has an outer diameter that is smaller than the outer diameter of the end on the inboard side of the inner member, and an inner diameter that is smaller than the outer diameter of the step cylindrical portion of the core of the magnetic encoder. By forming it so as to be large, the rotation sensor can be mounted on the wheel bearing device in a compact manner.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. As shown in FIG. 1, the wheel bearing device includes an outer member 1 having double-row raceway surfaces 2 a and 2 b on the inner diameter side, and double-row facing each raceway surface 2 a and 2 b of the outer member 1. An inner member 3 having raceway surfaces 4a and 4b on the outer diameter side, and balls 5 as rolling elements arranged in a double row in a bearing space between the outer member 1 and the inner member 3, The outer member 1 is a fixed member fixed to the vehicle body side by a flange 6, and the inner member 3 is a rotating member whose wheels are attached to the flange 7 by hub bolts 8. The track surface 4b on the inboard side of the inner member 3 is provided on the outer diameter surface of a separate inner ring 3a fixed to the inner member 3 by caulking. The outboard side of the bearing space is sealed with a seal member 9, and the entire inboard side is sealed with a cap 10 that is fitted to the end of the outer member 1.

  On the inboard side of the inner ring 3a of the inner member 3, a cylindrical portion 11a fitted to the outer diameter surface of the end portion, a step annular portion 11b bent inward from the bearing outer end of the cylindrical portion 11a, A core bar 11 of a magnetic encoder 12 comprising a step cylindrical portion 11c extending axially outward from the inner end of the step annular portion 11b and an annular portion 11d bent inward from the tip of the step cylindrical portion 11c is mounted. A magnetized portion 12a made of magnetic rubber magnetized by a plurality of magnetic poles in the circumferential direction is provided on the bearing outer surface of the annular portion 11d.

  The cap 10 fitted to the end portion on the inboard side of the outer member 1 includes a cylindrical portion 10a fitted to the inner diameter surface of the end portion of the outer member 1, and a bearing outer end of the cylindrical portion 10a. An annular portion 10b that is folded and bent inward, a step cylindrical portion 10c that extends axially outward from the inner end of the annular portion 10b, and a bottom portion 10d that continues at the bearing outer end of the step cylindrical portion 10c. The sensor unit 13 of the magnetic sensor 13a facing the magnetized portion 12a of the magnetic encoder 12 in the axial direction is attached to the bottom portion 10d so as to detect a change in magnetic flux accompanying the rotation of the magnetic encoder 12.

  As shown in FIG. 2, the step cylindrical portion 10c of the cap 10 has an outer diameter D smaller than an outer diameter A of the inner ring 3a on the inboard side of the inner member 3, and an inner diameter d of the magnetic encoder. The rotation sensor composed of the magnetic encoder 12 and the sensor unit 13 incorporating the magnetic sensor 13a is formed compactly so as to be larger than the outer diameter B of the step cylindrical portion 11c of the twelve metal core 11. It is mounted on a bearing device for a vehicle.

  FIG. 3 shows a state in which the core 11 of the magnetic encoder 12 is press-fitted into the outer diameter surface of the end of the inner ring 3a. The metal core 11 is pressed into the stepped annular portion 11b of the magnetic encoder 12 where the magnetized portion 12a is not provided by the annular tip of the press-fitting jig 20a, and is press-fitted into the outer diameter surface of the end of the inner ring 3a. . Therefore, the magnetized portion 12a of the magnetic encoder 12 is not damaged.

  FIG. 4 shows a state in which the cap 10 is press-fitted into the inner diameter surface of the end portion on the inboard side of the outer member 1. The cap 10 is pressed into the inner diameter surface of the end portion of the outer member 1 by pressing the annular portion 10b with the annular tip portion of the press-fitting jig 20b. Therefore, the bottom portion 10d to which the sensor unit 13 of the magnetic sensor 13a is mounted is not deformed, and the axial gap between the magnetic sensor 13a and the magnetized portion 12a of the magnetic encoder 12 can be set with high accuracy.

  In the embodiment described above, the magnetic sensor is opposed to the magnetized portion of the magnetic encoder in the axial direction. However, the magnetic sensor may be opposed to the magnetized portion of the magnetic encoder in the radial direction.

A longitudinal sectional view showing an embodiment of a wheel bearing device Sectional drawing which shows the mounting part of the rotation sensor of FIG. Sectional drawing which shows the state which press-fits the metal core of the magnetic encoder of FIG. Sectional drawing which shows the state which press-fits the cap of FIG. Sectional drawing which shows the state which press-fits the conventional cap

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Outer member 2a, 2b Raceway surface 3 Inner member 3a Inner ring 4a, 4b Raceway surface 5 Ball 6, 7 Flange 8 Hub bolt 9 Seal member 10 Cap 10a Cylindrical part 10b Ring part 10c Step cylindrical part 10d Bottom part 11 Core 11a Cylindrical portion 11b Step annular portion 11c Step cylindrical portion 11d Circular portion 12 Magnetic encoder 12a Magnetized portion 13 Sensor unit 13a Magnetic sensor 20, 20a, 20b Press-fitting jig

Claims (3)

  A double-row raceway surface on the inner diameter side, an outer member fixed to the vehicle body side, and a double-row raceway surface facing each raceway surface of the outer member on the outer diameter side, on the wheel side The inner member to be attached and rolling elements arranged in a double row between the outer member and the raceway surface of the inner member, and a plurality of circumferential members at the end on the inboard side of the inner member. A magnetic encoder having a magnetized portion magnetized on the magnetic pole of the outer member is attached, and a cylindrical portion of a cap having a bottom portion is fitted to an end portion on the inboard side of the outer member, and the magnetic portion is attached to the bottom portion of the cap. In a wheel bearing device in which a magnetic sensor for detecting a change in magnetic flux accompanying the rotation of the encoder is mounted to face the magnetized portion of the magnetic encoder, the inner portion extends from the cylindrical portion between the cylindrical portion and the bottom portion of the cap. An annulus that bends in the direction toward the bottom and extends in the axial direction from the inner end of the annulus to the bottom Wheel bearing apparatus characterized by comprising a step cylindrical unit made.   A step ring portion bent inward from a bearing outer end of the cylindrical portion to a core metal fitted to the outer diameter surface of the inboard side end portion of the inner member by the cylindrical portion; A step cylindrical portion extending in the axial direction from the inner end of the step annular portion and an annular portion bent inward from the tip of the step cylindrical portion are provided, and the magnetized portion is provided on the bearing outer surface of the annular portion. The wheel bearing device according to claim 1, wherein the wheel bearing device is provided.   The step cylindrical portion of the cap has an outer diameter smaller than an outer diameter of an end on the inboard side of the inner member, and an inner diameter thereof is an outer diameter of the step cylindrical portion of the core bar of the magnetic encoder. The wheel bearing device according to claim 2, wherein the wheel bearing device is formed to be larger.

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