JP2022154870A - rolling bearing device - Google Patents

Abstract

To provide a structure of a rolling bearing device which can make compatible both the securement of the sealing performance of an abutment part between a pair of inner rings, and the securement of the workability of the attachment work and removal work of a seal member.SOLUTION: Inside diameters of both side parts in an axial direction of an outside-diameter side seal part 35 in a free state of a seal member 20 are regulated to dimensions so that fitment between internal peripheral sides of both-side parts in the axial direction of the outside-diameter side seal part 35 and external peripheral faces of small flange parts 25a, 25b is brought into a relationship of clearance fitment or intermediate fitment in advance. By attaching the seal member 20 to a seal holding groove 33 formed on the outside of an abutment part 32 in a radial direction, and elastically gripping an inside-diameter side seal part 36 by a pair of in-groove faces 33b of the seal holding groove 33 from both sides in the axial direction, the internal peripheral faces of both the side parts of the outside-diameter side seal part 35 in the axial direction are made to abut on the external peripheral faces of the small flange parts 25a, 25b with an interference, and a clearance 41a in the radial direction is formed between the internal peripheral face of the inside-diameter side seal part 36 and groove bottom face 33a of the seal holding groove 33.SELECTED DRAWING: Figure 3

Description

The present invention relates to rolling bearing devices.

Rolling bearing devices called hub unit bearings are used to rotatably support automobile wheels. 5 and 6 show an example of a rolling bearing device used to rotatably support and rotationally drive wheels (driving wheels) of heavy vehicles such as trucks and buses. 1 shows a structure described in Japanese Patent Application Laid-Open Publication No. 2004-200012.

Rolling bearing device 100 rotatably supports hub wheel 102 around axle tube 101 . A drive shaft 103 is inserted through the inside of the axle tube 101 . A flange 104 is provided at the end of the drive shaft 103, and the hub wheel 102 is fixed to the flange 104. As shown in FIG. A driving wheel 105 and a braking rotor 106 are fixed to the hub wheel 102 . With such a configuration, the drive wheels 105 and the braking rotor 106 are rotatably supported with respect to the axle tube 101, and the torque from the drive shaft 103 can be transmitted to the drive wheels 105 and the braking rotor 106. there is

As shown in FIG. 6, the rolling bearing device 100 is a double-row tapered roller bearing comprising an outer ring 107 that rotates in use, a pair of inner rings 108a and 108b that do not rotate in use, and a plurality of rolling elements 109a. , 109 b , a sealing member 110 and a connecting ring 111 .
Regarding the rolling bearing device 100, the axially outer side is the left side in FIG. is the right side of FIG.

The outer ring 107 has double-row outer ring raceways 112a and 112b on its inner peripheral surface. The outer ring 107 is internally fitted to the hub ring 102 with an interference fit.

Each of the pair of inner rings 108a, 108b has a single-row inner ring raceway 113a, 113b on its outer peripheral surface. The pair of inner rings 108a and 108b are fitted onto the axle tube 101 with their opposing small-diameter end surfaces facing each other.

The rolling elements 109a and 109b are tapered rollers, and a plurality of rolling elements are arranged for each row between the outer ring raceways 112a and 112b and the inner ring raceways 113a and 113b so as to be free to roll.

The seal member 110 is arranged radially outside of a butted portion 114 between the pair of inner rings 108a and 108b. Specifically, the seal member 110 is arranged inside a seal holding groove 115 provided radially outside the butted portion 114 of the pair of inner rings 108a and 108b. Foreign matter such as differential oil, contamination (oxidized wear powder generated from the differential gear), muddy water, etc. existing inside the axle tube 101 enters the internal space of the rolling bearing device 100 through the abutting portion 114 of the seal member 110 . to prevent

In the rolling bearing device 100 for rotatably supporting the hub wheel 102 around the axle tube 101, a pair of inner rings 108a and 108b are provided so that the rolling bearing device 100 can be attached to and detached from the axle tube 101. is fitted onto the axle tube 101 with a clearance fit. Further, since the inner space of axle tube 101 communicates with the inner space of a differential case (not shown), differential oil or Contamination can enter. Moreover, muddy water may flow into the gap between the inner peripheral surfaces of the inner rings 108 a and 108 b and the outer peripheral surface of the axle tube 101 from the outside. Therefore, the seal member 110 is arranged radially outward of the butted portion 114 to prevent foreign matter such as differential oil, contamination, and muddy water from entering the internal space of the rolling bearing device 100 .

The sealing member 110 is composed of a metal core 116 and an elastic portion 117 made of an elastic material.

The cored bar 116 is made of a metal plate, has an annular shape as a whole, and has a substantially L-shaped cross section. The core bar 116 has a cylindrical portion 116a and an outward flange portion 116b bent radially outward from an axially inner end portion of the cylindrical portion 116a. The cylindrical portion 116 a is embedded inside the elastic portion 117 . A radially outer end portion of the outward flange portion 116 b is exposed from the outer peripheral surface of the elastic portion 117 .

The elastic portion 117 has a thin cylindrical shape and is fixed to the surface of the cylindrical portion 116a. The elastic portion 117 has a pair of lip portions 117a protruding radially inward at two axially spaced positions on the inner peripheral surface. Each of the pair of lip portions 117 a is in contact with the bottom surface of the seal holding groove 115 .

The connecting ring 111 is circular as a whole and has a U-shaped cross section. The connecting ring 111 has a cylindrical connecting portion 118 and a pair of outward flange-shaped locking portions 119 . The connecting ring 111 is provided with a pair of locking portions 119 on the inner peripheral surfaces of the pair of inner rings 108a and 108b, respectively, while the connecting portion 118 covers the butting portion 114 from the inside in the radial direction. It is locked in the locking concave grooves 120a and 120b. Thereby, the connecting ring 111 axially connects the pair of inner rings 108a and 108b. When the rolling bearing device 100 is assembled to the axle tube 101, the friction acting on the inner rings 108a and 108b causes the pair of inner rings 108a and 108b to separate from each other, or the inner ring 108a and the axle tube 101, which are arranged axially outwardly, separate from each other. This prevents the inner ring 108a from slipping out of the axle tube 101 in the axial direction due to collision with the inner ring 108a.

Japanese Patent Laying-Open No. 2010-25216 discloses a structure in which the rolling bearing device 100 rotatably supports the driving wheel 105 with respect to the axle tube 101. The structure of a driven wheel support device that rotatably supports a driven wheel with respect to a spindle is also conventionally known.

JP 2010-25216 A

The rolling bearing device 100 having the conventional structure described in Japanese Patent Application Laid-Open No. 2010-25216 has room for further improvement in the following aspects.

In the conventional rolling bearing device 100, only the pair of lip portions 117a of the inner peripheral surface of the elastic portion 117 constituting the seal member 110 are in contact with the groove bottom surface of the seal holding groove 115. The portion outside the lip portion 117 a is radially separated from the groove bottom surface of the seal holding groove 115 . As a result, a part of the elastic portion 117 is prevented from being pinched by the abutment portion 114 and a gap is prevented from occurring in the abutment portion 114 .

On the other hand, the rolling bearing device 100 may require measurement of the axial clearance after assembly. In this case, it is necessary to remove the seal member 110 and the connecting ring 111 after being attached. The reason for this is that the seal member 110 for ensuring the sealing performance of the butted portion 114 may interfere with the measurement of the axial clearance (preload) of the rolling bearing device 100 . In order to explain why the sealing member 110 interferes with the measurement of the axial clearance, first, the method of measuring the axial clearance will be explained.

It is known to measure the axial clearance of a double-row rolling bearing by a method as shown in FIG. First, as shown in FIG. 7A, a pair of inner rings 108x and 108y are abutted against each other on the small-diameter side, and rolling elements 109x and 109y are arranged around the pair of inner rings 108x and 108y. , one inner ring 108x (or 108y) faces downward and the other inner ring 108y (or 108x) faces upward. Then, the axial height from the reference plane 121 to the large-diameter side end face of the inner ring 108y (or 108x) arranged on the upper side is measured by a displacement meter 122 such as a dial gauge, and the measured value is used as a reference value ( dial to 0).

Next, as shown in FIG. 7B, the rolling elements 109x of one side row and the inner ring 108x are assembled to the raceway surface of one side row of the outer ring 107x, and the inner ring 108x is directed upward toward the reference plane. 121. Then, the displacement meter 122 measures the axial height (Hout) from the reference surface 121 to the large-diameter end surface of the inner ring 108x. Similarly, although not shown, the rolling elements 109y of the other side row and the inner ring 108y are attached to the raceway surface of the other side row of the upside down outer ring 107x. Place on surface 121 . Then, the displacement gauge 122 measures the axial height (Hin) from the reference surface 121 to the large-diameter end surface of the inner ring 108y. Finally, the two axial dimensions (Hin, Hout) are totaled, and the total value [-(Hin+Hout)] is taken as the axial clearance.

In the method of measuring the axial clearance as described above, as shown in FIG. The axial height to the large-diameter side end surface of the inner ring 108y (or 108x) is used as a reference value. Therefore, if a part of the elastic portion 117 is caught between the abutting portions 114 while the seal member 110 is attached to the rolling bearing device 100, there is a possibility that the axial clearance cannot be accurately measured.

For the reasons described above, if it is necessary to measure the axial clearance after assembly of the rolling bearing device 100, the seal member 110 and the connecting ring 111 must be removed. Therefore, the seal member 110 is required to be removed efficiently. In addition, since the seal member 110 needs to be reattached after the axial clearance is measured, the seal member 110 is also required to be able to be attached efficiently.

For this reason, in the rolling bearing device 100 having the conventional structure, it is difficult to sufficiently increase the interference of the pair of lip portions 117a from the viewpoint of ensuring the workability of attaching and detaching the seal member 110 . Therefore, in the rolling bearing device 100 having the conventional structure, it is difficult to ensure both the sealing performance of the butted portion 114 and the workability of attaching and removing the seal member 110 .

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and is intended to ensure compatibility between the sealability of the butted portions of a pair of inner rings and the workability of attaching and removing seal members. It is an object of the present invention to provide a rolling bearing device that can be manufactured.

A rolling bearing device according to one aspect of the present invention includes an outer ring, a pair of inner rings, a plurality of rolling elements, a sealing member, and a connecting ring.
The outer ring has a double-row outer ring raceway.
Each of the pair of inner rings has a single-row inner ring raceway and a small flange portion adjacent to a small diameter side portion of the inner ring raceway.
The rolling elements are arranged between the outer ring raceway and the inner ring raceway.
The seal member seals the abutted portions of the pair of inner rings.
The connecting ring connects the pair of inner rings.
The pair of inner rings has seal retaining grooves on the radially outer side of the abutting portions, the seal retaining grooves including a pair of axially opposed groove inner surfaces and a radially outward facing groove bottom surface.

In the rolling bearing device according to the aspect of the present invention, the seal member is made of an elastic material having a substantially T-shaped cross section, and has an annular shape as a whole, and is disposed on the outer diameter side of the seal holding groove. It has a seal portion and an inner diameter side seal portion arranged inside the seal holding groove.
The inner diameters of both axial side portions of the outer diameter side seal portion in the free state of the seal member are equal to the inner peripheral surfaces of the axial both side portions of the outer diameter side seal portion and the pair of inner rings. The fitting with the outer peripheral surface of the provided small flange portion is regulated to a dimension that results in a clearance fit or an intermediate fit.
The sealing member elastically sandwiches the inner diameter side seal portion from both sides in the axial direction by the pair of groove inner surfaces, so that the inner peripheral surfaces of the outer diameter side seal portion on both sides in the axial direction are: At least a portion near the inner diameter side seal portion in the axial direction is brought into contact with the outer peripheral surface of the small flange portion provided on each of the pair of inner rings with an interference, and the inner diameter side seal portion A radial gap is provided between the inner peripheral surface and the bottom surface of the groove.

In the rolling bearing device according to the aspect of the present invention, the seal member is made of an elastic material having a substantially T-shaped cross section, and has an annular shape as a whole, and is disposed on the outer diameter side of the seal holding groove. It has a seal portion and an inner diameter side seal portion arranged inside the seal holding groove.
The inner peripheral surfaces on both sides in the axial direction of the outer diameter side seal portion are tapered surfaces in which the inner diameter decreases toward the inner diameter side seal portion in the axial direction.
The inner diameters of both axial side portions of the outer diameter side seal portion in the free state of the seal member are the inner peripheral surfaces of the axial both side portions of the outer diameter side seal portion and the inner rings of the pair of inner rings. The fitting with the outer peripheral surface of the small flange provided in the is an interference fit relationship in a portion close to the inner diameter side seal portion in the axial direction, and a gap is formed in a portion far from the inner diameter side seal portion in the axial direction. It is regulated to the dimension that becomes the relationship of fitting.
The sealing member elastically sandwiches the inner diameter side seal portion from both sides in the axial direction by the pair of groove inner surfaces, so that the inner peripheral surfaces of the outer diameter side seal portion on both sides in the axial direction are: At least a portion near the inner diameter side seal portion in the axial direction is brought into contact with the outer peripheral surface of the small flange portion provided on each of the pair of inner rings with an interference, and the inner diameter side seal portion A radial gap is provided between the inner peripheral surface and the bottom surface of the groove.

In the rolling bearing device according to the aspect of the present invention, the radial thickness of the outer diameter side seal portion can be made larger than the radial thickness of the inner diameter side seal portion.

In the rolling bearing device according to one aspect of the present invention, the outer ring is a rotating ring that rotates together with the wheel during use, the pair of inner rings are stationary rings that do not rotate during use, and each of the plurality of rolling elements is: It can be a tapered roller.

According to the present invention, it is possible to realize a rolling bearing device that can ensure both the sealing performance of the abutted portion between a pair of inner rings and the workability of mounting and removing seal members.

FIG. 1 is a cross-sectional view showing a driving wheel support device incorporating a rolling bearing device according to a first embodiment. FIG. 2 is a partial cross-sectional view showing the rolling bearing device according to the first embodiment. FIG. 3(A) is an enlarged view of a portion corresponding to part A in FIG. 2, showing a state before the butted portions of the pair of inner rings are in close contact, and FIG. 3(B) is an enlarged view of FIG. It is a partial enlarged view of the A section. FIG. 4 is a diagram corresponding to FIG. 3A, showing a second example of the embodiment. FIG. 5 is a cross-sectional view showing a drive wheel support device incorporating a conventional rolling bearing device. FIG. 6 is a partial cross-sectional view showing a conventional rolling bearing device. 7(A) and 7(B) are cross-sectional views for explaining a conventionally known axial clearance measuring method in the order of steps.

[First example of embodiment]
A first example of the embodiment will be described with reference to FIGS. 1 to 3. FIG. In this example, the rolling bearing device of the present invention is applied to a driving wheel support device for a heavy heavy vehicle such as a truck or a bus.

[Overall Configuration of Driving Wheel Support Device]
The drive wheel support device 1 includes a rolling bearing device 2, an axle tube 3, a hub wheel 4, and a drive shaft 5, as shown in FIG. The driving wheel support device 1 rotatably supports a driving wheel 6 such as a rear wheel of a truck and a braking rotor 7, and transmits driving torque to the driving wheel 6 and the braking rotor 7. It has a floating configuration.

Regarding the driving wheel support device 1, the axially outer side is the left side in FIG. It is the right side of FIG. 1, which is the center side.

The rolling bearing device 2 rotatably supports the wheel hub 4 around the outer end in the axial direction of the axle tube 3 . The rolling bearing device 2 is arranged between the outer peripheral surface of the axle tube 3 and the inner peripheral surface of the hub wheel 4 .

The axle tube 3 is also called an axle housing, has a cylindrical shape, and has an axially inner end connected to a differential case (not shown). Therefore, the axle tube 3 does not rotate during use. The internal space of the axle tube 3 communicates with the internal space of the differential case. The axle tube 3 has a cylindrical surface portion 8 on the axially outer portion of the outer peripheral surface. Further, the axle tube 3 has a stepped surface 9 facing axially outward at a portion of the outer peripheral surface adjacent to the axially inner side of the cylindrical surface portion 8, and a portion adjacent to the axially outwardly of the cylindrical surface portion 8, It has a male screw portion 10 having a diameter smaller than that of the cylindrical surface portion 8 . A nut 11 for applying preload to the rolling bearing device 2 is screwed onto the male threaded portion 10 .

The drive shaft 5 , also called an axle shaft, is solid and passes through the inside of the axle tube 3 . The drive shaft 5 is arranged coaxially with the axle tube 3 . An axially inner end of the drive shaft 5 is connected to a differential gear (not shown). Therefore, the drive shaft 5 rotates during use. The drive shaft 5 has an outward flange-like flange 12 at its axially outer end projecting from the axle tube 3 . A hub wheel 4 is fixed to the flange 12 with a plurality of bolts 13 .

The hub wheel 4 has an annular shape. The hub wheel 4 has a cylindrical fitting surface 14 on its inner peripheral surface, and a rotary flange 15 on an axially intermediate portion of its outer peripheral surface. A driving wheel 6 is fixed to the rotating flange 15 by a connecting member 16 such as a hub bolt or a stud. A braking rotor 7 is fixed to the inner side of the hub wheel 4 in the axial direction by bolts 13 .

The driving wheel support device 1 rotatably supports the driving wheels 6 and the braking rotating body 7 with respect to the axle tube 3, and transmits torque from the driving shaft 5 to the driving wheels 6 and the braking rotating body. 7 can be transmitted. Further, in the fully floating drive wheel support device 1 , the load of the vehicle is supported not by the drive shaft 5 but by the axle tube 3 . The drive shaft 5 only bears the transmission of torque.

A specific structure of the rolling bearing device 2 of this example will be described below with reference to FIGS. 2 and 3. FIG.
Regarding the rolling bearing device 2, the axially outer side is the left side in FIGS. It is the right side of FIG.2 and FIG.3 which becomes the width direction center side.

<Rolling bearing device>
The rolling bearing device 2 is a back-to-back type double-row tapered roller bearing, and is of a rotating outer ring type. The rolling bearing device 2 includes an outer ring 17 that rotates in use, a pair of stationary inner rings 18a and 18b that do not rotate in use, a plurality of rolling elements 19a and 19b, and a seal member 20. and a connecting ring 21 .

《Outer ring》
The outer ring 17 is made of bearing steel, for example, and has an annular shape. The outer ring 17 has a cylindrical surface on its outer peripheral surface, and has outer ring raceways 22a and 22b in a conical concave double-row shape on its inner peripheral surface. The outer ring 17 is internally fitted and fixed to the fitting surface 14 provided on the inner peripheral surface of the hub wheel 4 by an interference fit when the rolling bearing device 2 is assembled to the vehicle. Therefore, the outer ring 17 is a rotating ring that rotates together with the hub wheel 4 and the drive wheel 6 during use.

《Inner ring》
Each of the pair of inner rings 18a, 18b is made of, for example, bearing steel and has an annular shape. Each of the pair of inner rings 18a, 18b has a conical convex single-row inner ring raceway 23a, 23b in the axially intermediate portion of the outer peripheral surface. Each of the pair of inner rings 18a, 18b has large flanges 24a, 24b and small flanges 25a, 25b on both axial sides of the inner ring raceways 23a, 23b. Specifically, each of the pair of inner rings 18a, 18b has large flanges 24a, 24b protruding radially outward at portions adjacent to the large diameter side portions of the inner ring raceways 23a, 23b. Small flange portions 25a and 25b protruding radially outward are provided at portions adjacent to the small diameter side portions of the inner ring raceways 23a and 23b. For this reason, each of the pair of inner rings 18a, 18b has an outer diameter at the large-diameter end provided with the large flanges 24a, 24b larger than the outer diameter at the small-diameter end provided with the small flanges 25a, 25b. is also getting bigger. The outer peripheral surfaces of the large flange portions 24a, 24b and the small flange portions 25a, 25b are cylindrical surfaces whose outer diameter does not change along the axial direction.

Each of the pair of inner rings 18a, 18b has locking recessed grooves 26a, 26b on the inner peripheral surface of the small-diameter end. The locking recessed grooves 26a, 26b are opened only on the inner peripheral surfaces of the inner rings 18a, 18b, respectively, and are provided over the entire circumferences of the inner rings 18a, 18b. The inner peripheral surfaces of the inner rings 18a and 18b have cylindrical small-diameter surface portions 27a and 27b at portions axially deviating from the locking grooves 26a and 26b toward the large-diameter end surfaces. Cylindrical large-diameter surface portions 28a and 28b having an inner diameter larger than that of the small-diameter surface portions 27a and 27b are provided at portions off the locking grooves 26a and 26b toward the small-diameter side end surfaces.

The pair of inner rings 18a and 18b are arranged coaxially with the outer ring 17 radially inward of the outer ring 17 with their small diameter side end surfaces facing each other. The pair of inner ring raceways 23a and 23b are arranged in double rows at positions facing the double row outer ring raceways 22a and 22b in the radial direction.

The pair of inner rings 18a and 18b are loosely fitted to the cylindrical surface portion 8 provided on the outer peripheral surface of the axle tube 3 when the rolling bearing device 2 is assembled to the vehicle. The pair of inner rings 18 a and 18 b are axially sandwiched between a stepped surface 9 provided on the outer peripheral surface of the axle tube 3 and a nut 11 . Thereby, a predetermined preload is applied to the rolling bearing device 2 . For example, the screwing amount (screwing position) of the nut 11 is set so that the internal clearance in the axial direction of the rolling bearing device 2 is zero or a slightly positive or negative value.

In this example, the pair of inner rings 18a and 18b are made of the same member and arranged in opposite directions with respect to the axial direction. For this reason, the pair of inner rings 18a and 18b have the same shape and dimensions, except that they are oriented in the opposite axial direction. However, when carrying out the present invention, it is also possible to use members having different shapes and sizes for each part as a pair of inner rings.

As shown in FIG. 3A, of the pair of inner rings 18a and 18b, the inner ring 18a arranged on the outer side in the axial direction has a first butting surface 29a on the small diameter side end face, which is the inner end face in the axial direction. , and a first annular groove 30a.

The first butting surface 29a is a flat surface that exists on a virtual plane perpendicular to the central axis of the inner ring 18a, and is provided on the radially inner half of the axially inner end surface of the inner ring 18a.

The first annular recessed groove 30a is positioned radially outward of the first abutment surface 29a and is provided in the radially outer half of the axially inner end surface of the inner ring 18a. Further, the first annular recessed groove 30a is arranged adjacent to the inner side of the small flange portion 25a in the axial direction. The first annular recessed groove 30a is open to each of the outer peripheral surface and the axially inner end surface of the inner ring 18a, and has a rectangular cross-sectional shape. In the illustrated example, of the inner surface of the first annular groove 30a, the radial bottom surface facing radially outward is formed of a cylindrical surface.

The axial bottom surface, which is the axial side surface of the first annular groove 30a, is a flat surface that exists on a virtual plane perpendicular to the central axis of the inner ring 18a. However, when carrying out the present invention, the axial bottom surface of the first annular groove can be inclined with respect to the virtual plane.

Of the pair of inner rings 18a and 18b, the inner ring 18b arranged on the inner side in the axial direction has a second butting surface 29b and a second annular recessed groove 30b on the small-diameter side end face, which is the outer end face in the axial direction. .

The second butting surface 29b is a flat surface that exists on a virtual plane perpendicular to the central axis of the inner ring 18b, and is provided on the radially inner half of the axially outer end surface of the inner ring 18b. The outer and inner diameter dimensions of the second butting surface 29b are the same as the outer and inner diameter dimensions of the first butting surface 29a.

The second annular recessed groove 30b is positioned radially outward of the second abutment surface 29b and is provided in the radially outer half of the axially outer end surface of the inner ring 18b. Further, the second annular groove 30b is arranged adjacent to the axially outer side of the small flange portion 25b. The second annular recessed groove 30b is open to each of the outer peripheral surface and the axially outer end surface of the inner ring 18b, and has a rectangular cross-sectional shape. Of the inner surface of the second annular groove 30b, the radial bottom surface facing radially outward is composed of a cylindrical surface.

The axial bottom surface, which is the axial side surface of the second annular groove 30b, is a flat surface that exists on a virtual plane perpendicular to the central axis of the inner ring 18b. However, when carrying out the present invention, the axial bottom surface of the first annular groove can be inclined with respect to the virtual plane. Further, when carrying out the present invention, the radial depth and axial depth of the first annular groove and the radial depth and axial depth of the second annular groove can be made different from each other. Further, the radial bottom surfaces of the first annular groove and the second annular groove may be formed of tapered surfaces, or may be formed of surfaces having other generatrix shapes.

As shown in FIG. 3B, the rolling bearing device 2 is configured such that a nut 11 is fastened to a male threaded portion 10 provided on the outer peripheral surface of the axle tube 3, and the inner ring 18a is arranged axially outward. The first butting surface 29a and the second butting surface 29b of the inner ring 18b arranged axially inward are axially butted together to form a butting portion 32. As shown in FIG. Further, in the state where the butted portion 32 is formed, the first annular groove 30a and the second annular groove 30b are connected in the axial direction to form a seal holding groove 33 that opens only radially outward. For this reason, the pair of inner rings 18a, 18b has a seal holding groove 33 extending across the inner rings 18a, 18b in the axial direction.

The seal holding groove 33 has a rectangular cross-sectional shape and is arranged radially outside the butted portion 32 . The seal holding groove 33 has a groove bottom surface 33a composed of the radial bottom surface of the first annular groove 30a and the radial bottom surface of the second annular groove 30b. The seal holding groove 33 also has a pair of groove inner surfaces 33b, which are composed of the axial bottom surface of the first annular groove 30a and the axial bottom surface of the second annular groove 30b.

《Rolling element》
Each of the plurality of rolling elements 19a, 19b is a tapered roller made of bearing steel or ceramic, for example. Each of the plurality of rolling elements 19a, 19b is arranged between the outer ring raceways 22a, 22b and the inner ring raceways 23a, 23b so as to be rollably held by cages 34a, 34b. In addition, each of the rolling elements 19a in the axially outer row has a portion of the axially outer end surface that contacts and faces the large flange portion 24a, and a portion of the axially inner end surface that closely faces the small flange portion 25a. I am letting Each of the rolling elements 19b in the axially inner row has a portion of the axially inner end surface that contacts and faces the large flange portion 24b, and a portion of the axially outer end surface that closely faces the small flange portion 25b. there is

《Seal member》
The seal member 20 is for sealing the butted portion 32 between the pair of inner rings 18a and 18b, and is arranged radially outside the butted portion 32. As shown in FIG.

As shown in FIG. 3, in the rolling bearing device 2 of this example, the cross-sectional shape of the seal member 20 is substantially T-shaped. Moreover, the sealing member 20 has a symmetrical shape with respect to the axial direction.

The sealing member 20 is made of only an elastic material, and has an annular shape as a whole. The seal member 20 is made of acrylonitrile-butadiene rubber (NBR, high-hardness nitrile) having a hardness of Hs 85 or more and Hs 95 or less (HS 90±5) so as to retain its annular shape to some extent before being mounted in the seal holding groove 33 . Made of material. In this example, the hardness of the sealing member 20 is about Hs90.

The seal member 20 includes an outer diameter side seal portion 35 and an inner diameter side seal portion 36 .

The outer diameter side seal portion 35 constitutes the radially outer half portion of the seal member 20 and has a substantially rectangular cross-sectional shape. As shown in FIG. 3B, the outer diameter side seal portion 35 is arranged outside the seal holding groove 33 with the seal member 20 mounted in the seal holding groove 33 . In other words, the outer diameter side seal portion 35 protrudes radially outward from the seal holding groove 33 . The outer diameter side seal portion 35 has annular fitting cylinder portions 37a and 37b on both sides in the axial direction, which protrude further in the axial direction than the inner diameter side seal portion 36, respectively. In addition, the outer diameter side seal portion 35 has chamfered portions 38 at both ends in the axial direction of the outer peripheral surface.

The inner diameter side seal portion 36 constitutes the radially inner half portion of the seal member 20 and has a substantially rectangular cross-sectional shape. The inner diameter side seal portion 36 extends radially inward from an axial intermediate portion of the inner peripheral surface of the outer diameter side seal portion 35 . As shown in FIG. 3B, the inner diameter side seal portion 36 is arranged inside the seal holding groove 33 with the seal member 20 mounted in the seal holding groove 33 . Specifically, the inner diameter side seal portion 36 is held inside the seal holding groove 33 without looseness. The inner diameter side seal portion 36 has an inner peripheral surface 39 and a pair of axial side surfaces 40 .

In the seal member 20 of this example, a nut 11 is fastened to a male threaded portion 10 provided on the outer peripheral surface of the axle tube 3, and the butted portions 32 of the pair of inner rings 18a and 18b are brought into close contact (first butted surfaces 29a and 29b). Before and after the contact surface 29b is brought into close contact with the second butting surface 29b, the shape and dimensions change. For this reason, a detailed description of the seal member 20 will be made in the free state shown in FIG. The elastic deformation state after the butted portions 32 of the pair of inner rings 18a and 18b are brought into close contact with each other is performed separately. In the rolling bearing device 2 of the present embodiment, it is assumed that the abutting portion 32 is not in close contact with the abutting portion 32 only by attaching the connecting ring 21 to the pair of inner rings 18a and 18b, and an axial clearance exists in the abutting portion 32. Become. In other words, it is possible to attach the connecting ring 21 to the pair of inner rings 18 a and 18 b without elastically deforming the inner diameter side seal portion 36 of the seal member 20 .

<Free state of sealing member>
Before the abutting portions 32 of the pair of inner rings 18a and 18b are in close contact as shown in FIG. 3A, the seal member 20 undergoes no or only slight elastic deformation. not Therefore, before the butted portions 32 of the pair of inner rings 18a and 18b are brought into close contact, the shape of the seal member 20 is substantially the same as that in the free state.

In the free state of the seal member 20, the axial width W _35X of the outer diameter side seal portion 35 is sufficiently larger than the axial width W _36X of the inner diameter side seal portion 36 (W 35x >W _{36x )} , and the outer diameter The radial thickness T 35x of the side seal portion 35 is sufficiently larger than the radial thickness T _36x of the inner diameter side seal portion ₃₆ (T 35x >T _{36x )} . In the illustrated example, the axial width _W35x of the outer diameter side seal portion 35 is approximately 2.5 times the axial width _W36x of the inner diameter side seal portion 36, and the radial thickness of the outer diameter side seal portion 35 is T 35x is approximately 2.5 times the radial thickness T _36x of the inner diameter side seal portion ₃₆ . Further, the axial width W _35x of the outer diameter side seal portion 35 is larger than the radial thickness T _35x of the outer diameter side seal portion 35 . The axial width W _36x of the inner diameter seal portion 36 is slightly larger than the radial thickness T _36x of the inner diameter seal portion 36 .

In this example, the radial thickness _T35x of the outer seal portion 35 is made larger than the radial thickness _T36x of the inner seal portion 36 to ensure the rigidity of the outer seal portion 35. . Accordingly, as will be described later, when the inner diameter side seal portion 36 is sandwiched between the pair of groove inner surfaces 33b from both sides in the axial direction, the outer diameter side seal portion 35 is pushed up radially outward by the inner diameter side seal portion 36. prevent The axial width W _36x of the outer diameter side seal portion 35 is sufficiently larger than the axial width W ₃₃ of the opening of the seal holding groove 33 (see FIG. 3B).

The inner peripheral surface of each of the pair of fitting tubular portions 37a and 37b provided in the outer diameter side seal portion 35 is formed in a cylindrical shape. That is, the inner diameter of each of the pair of fitting cylinders 37a and 37b is constant along the axial direction. Also, the inner diameters of the pair of fitting cylinder portions 37a and 37b are the same.

In particular, in this example, the inner diameters of the pair of fitting tubular portions 37a and 37b in the free state of the seal member 20 are the inner peripheral surfaces of the pair of fitting tubular portions 37a and 37b and the pair of inner rings. The fitting with the outer peripheral surfaces of the small flanges 25a and 25b provided on the respective parts 18a and 18b is regulated to a size that results in a clearance fit or an intermediate fit.

Specifically, when the fitting is set to a clearance fit, the size of the pair of small flanges 25a and 25b is larger than the minimum allowable dimension of the respective inner peripheral surfaces of the pair of fitting cylinders 37a and 37b. The inner diameter of each of the pair of fitting cylinders 37a and 37b is regulated in relation to the outer diameter of each of the pair of small flanges 25a and 25b so that the maximum allowable dimension of each outer peripheral surface is small. . In this example, rattling of the sealing member 20 can be prevented when the axially outer fitting tubular portion 37a (or the axially inner fitting tubular portion 37b) is fitted onto the small flange portion 25a (25b). The size of the gap between the inner peripheral surface of the fitting cylinder portion 37a (37b) and the outer peripheral surface of the small flange portion 25a (25b) is set small. Specifically, the size of the maximum gap between the inner peripheral surface of the fitting cylinder portion 37a (37b) and the outer peripheral surface of the small flange portion 25a (25b) is about 0 mm to 0.7 mm (diameter value). there is

On the other hand, when the fitting is set to intermediate fitting, the outer circumference of the pair of small flanges 25a and 25b is larger than the minimum allowable dimension of the inner peripheral surface of each of the pair of fitting cylinders 37a and 37b. The maximum allowable dimensions of the surfaces are large, and the minimum allowable dimensions of the outer peripheral surfaces of the pair of small flanges 25a and 25b are larger than the maximum allowable dimensions of the inner peripheral surfaces of the pair of fitting cylinders 37a and 37b. The inner diameter of each of the pair of fitting cylinders 37a and 37b is regulated in relation to the outer diameter of each of the pair of small flanges 25a and 25b so that .

In the free state of the seal member 20, both axial side surfaces of the outer diameter side seal portion 35 (axial end surfaces of the fitting cylinder portions 37a and 37b) are present on a virtual plane perpendicular to the central axis of the seal member 20. and are arranged substantially parallel to each other. Therefore, the axial width W _35x of the radially outer seal portion 35 is constant in the radial direction except for the radially outer end portion of the radially outer seal portion 35 where the chamfered portion 38 is provided.

The inner diameter side seal portion 36 has a rectangular cross-sectional shape in the free state of the seal member 20 . Therefore, the inner peripheral surface 39 of the inner diameter side seal portion 36 is a cylindrical surface having a straight generatrix. A pair of axial side surfaces 40 of the inner diameter side seal portion 36 are annular flat surfaces that exist on a virtual plane orthogonal to the central axis of the seal member 20 and are arranged substantially parallel to each other. However, when implementing the present invention, the cross-sectional shape of the inner diameter side seal portion may be a shape other than a rectangle. In this case, the generatrix shape of the inner peripheral surface of the inner diameter side seal portion can be made non-linear, and the pair of axial side surfaces of the inner diameter side seal portion can be inclined with respect to the central axis of the seal member. can also For example, considering the alignment position of the vulcanization mold, the shape of the inner peripheral surface of the inner diameter side seal portion is such that the axially intermediate portion is a cylindrical surface, and the inner diameter increases as the axially both side portions are separated from the cylindrical surface. A tapered surface is also possible.

The axial width W _36x of the inner diameter side seal portion 36 in the free state of the seal member 20 is defined by the pair of groove inner surfaces 33b of the seal holding groove 33 formed when the butted portions 32 of the pair of inner rings 18a and 18b are in close contact. greater than the axial spacing _W33 between them. In the illustrated example, the axial width W _36x of the inner diameter side seal portion 36 is about 1.3 times the axial interval W ₃₃ of the seal holding groove 33 . Therefore, as shown in FIG. 3A, in the free state of the seal member 20, the pair of axial side surfaces 40 of the inner diameter side seal portion 36, the first annular groove 30a and the second annular groove 30b A gap is formed between the first abutment surface 29a and the second abutment surface 29b in a state in which the axial bottom surfaces of the two are in contact with each other.

The inner diameter of the inner diameter side seal portion 36 in the free state of the seal member 20 is equal to the outer diameter of the radial bottom surface of each of the first annular groove 30a and the second annular groove 30b (=the outer diameter of the groove bottom surface 33a of the seal holding groove 33). diameter)). Therefore, a radial gap 41 is provided over the entire circumference between the inner peripheral surface 39 of the inner diameter side seal portion 36 and the radial bottom surfaces of the first annular groove 30a and the second annular groove 30b. ing. As will be described later, the size (radial width) of the radial gap 41 is such that even when the inner seal portion 36 is sandwiched between the pair of groove inner surfaces 33b of the seal holding groove 33 from both sides in the axial direction, the inner seal The size is set so as to prevent the inner peripheral surface 39 of the portion 36 from coming into contact with the groove bottom surface 33a of the seal holding groove 33 . Specifically, it is set according to the difference between the axial width _W36x of the inner diameter side seal portion 36 and the axial width W33 of the seal holding groove ₃₃ , the material of the seal member 20, and the like. In the illustrated example, the radial gap 41 is approximately 30% of the radial thickness T _36x of the inner seal portion 36 .

<<Elastic Deformation State of Sealing Material>>
By fastening the nut 11 to the male threaded portion 10 provided on the outer peripheral surface of the axle tube 3, as shown in FIG. If the axial clearance between the abutment surface 29a and the second abutment surface 29b is zero, the axial distance between the axial bottom surface of the first annular groove 30a and the axial bottom surface of the second annular groove 30b is the seal The axial width W ₃₃ of the holding groove 33 is decreased. For this reason, the inner diameter side seal portion 36 is elastically sandwiched from both sides in the axial direction by the pair of groove inner surfaces 33 b , and the axial width W _{36 y} matches the axial width W ₃₃ of the seal holding groove 33 . elastically deformed (collapsed). Therefore, the pair of axial side surfaces 40 of the inner diameter seal portion 36 abut against the pair of groove inner surfaces 33b with interference.

When the inner diameter side seal portion 36 is elastically deformed in the axial direction, the materials forming the inner diameter side seal portion 36 move (escape) radially outward and radially inward, respectively. However, in this example, since the radial thickness T35x of the outer diameter side seal portion 35 is set sufficiently larger than the radial direction thickness _T36x of the inner diameter side seal portion ₃₆ , the inner diameter side seal portion 36 is The radially outer seal portion 35 cannot be pushed up radially outward by the material moving radially outward. Therefore, the material that has moved radially outward through the inner diameter side seal portion 36 moves to both sides of the outer diameter side seal portion 35 in the axial direction. As a result, of the inner peripheral surfaces of the pair of fitting tubular portions 37a and 37b that constitute the outer diameter side seal portion 35, the base end portion near the inner diameter side seal portion 36 is oriented radially inward. It tends to protrude (reduce in diameter). Therefore, in this example, when the seal member 20 is in an elastically deformed state after the seal member 20 is mounted in the seal holding groove 33, at least the base ends of the inner peripheral surfaces of the pair of fitting cylinder portions 37a and 37b The side portion abuts on the outer peripheral surface of each of the pair of small flanges 25a and 25b with an interference. As a result, the radial positioning of the seal member 20 with respect to the pair of inner rings 18a and 18b is achieved, and the opening of the seal holding groove 33 is covered over the entire circumference on both sides in the axial direction.

A pair of axial side surfaces of the outer diameter side seal portion 35 (axial end surfaces of the fitting tubular portions 37a and 37b) are inclined in a direction toward each other toward the radially inner side. Therefore, the axial width of the outer diameter side seal portion 35 becomes smaller toward the inner side in the radial direction.

There is no member such as the outer seal portion 35 that hinders the movement of the material inside the inner diameter seal portion 36 in the radial direction. Therefore, when the inner diameter side seal portion 36 is elastically deformed in the axial direction, it bulges inward in the radial direction due to the material moving inward in the radial direction. As a result, the generatrix shape of the inner peripheral surface 39 of the inner diameter side seal portion 36 changes from a straight line to a convex circular arc shape. Also, the inner diameter of the inner diameter side seal portion 36 when the seal member 20 is elastically deformed is smaller than the inner diameter of the seal member 20 when it is in its free state. However, in this example, since the inner diameter of the inner diameter side seal portion 36 in the free state of the seal member 20 is set to be sufficiently larger than the outer diameter of the groove bottom surface 33a of the seal holding groove 33, elastic deformation of the seal member 20 is prevented. The inner diameter of the inner diameter side seal portion 36 in this state is larger than the outer diameter of the groove bottom surface 33 a of the seal holding groove 33 . Therefore, a radial gap 41a having a smaller radial width than before elastic deformation of the seal member 20 is provided between the inner peripheral surface 39 of the inner diameter side seal portion 36 and the groove bottom surface 33a of the seal holding groove 33. ing.

As described above, in this example, with the abutting portions 32 of the pair of inner rings 18a and 18b in close contact and the seal member 20 mounted in the seal holding groove 33, the pair of axial side surfaces 40 of the inner diameter side seal portion 36 are mounted. are brought into contact with each of the pair of groove inner surfaces 33b with interference, and the inner circumferences of the pair of fitting cylinder portions 37a and 37b that constitute the outer diameter side seal portion 35 At least the base end portion of the surface is brought into contact with the outer peripheral surface of each of the pair of small flanges 25a and 25b with an interference. Therefore, according to the rolling bearing device 2 of the present embodiment, foreign matter such as differential oil and contamination existing inside the axle tube 3 and muddy water from the outer space can be prevented from entering the outer peripheral surface of the axle tube 3 and the inner rings 18a and 18b. It is possible to prevent the intrusion into the internal space of the rolling bearing device 2 through the abutting portion 32 after intruding into the gap with the peripheral surface. Therefore, deterioration of the grease sealed inside the rolling bearing device 2 can be prevented.

《Installation work and removal work》
The work for attaching the seal member 20 of this example is performed as follows.
First, one small flange portion 25a (25b) provided on the inner ring 18a (18b) is inserted into one of the fitting cylinder portions 37a (37b) constituting the outer diameter side seal portion 35, The joint tube portion 37a (37b) is fitted on one of the small flange portions 25a (25b). Next, by moving the pair of inner rings 18a, 18b closer to each other in the axial direction while coaxially arranged, the other small flange portion 25b (25a) is inserted inside the other fitting cylinder portion 37b (37a). Then, the other fitting cylinder portion 37b (37a) is fitted onto the other small flange portion 25b (25a). Thereafter, while the rolling bearing device 2 is arranged around the axle tube 3, the nut 11 is fastened to the male threaded portion 10 provided on the outer peripheral surface of the axle tube 3, whereby the first abutment surface 29a and the second abutment surface 29a are engaged. The seal member 20 is mounted in the seal holding groove 33 by abutting the surface 29b and elastically holding the inner diameter side seal portion 36 between the pair of groove inner surfaces 33b from both sides in the axial direction.

To remove the seal member 20, the above-described mounting process is reversed. That is, the pair of inner rings 18a, 18b are separated axially while remaining coaxially arranged. As a result, the inner diameter side seal portion 36 is elastically restored, and an axial gap is formed between the first abutment surface 29a and the second abutment surface 29b. Next, one small flange portion 25a (25b) is axially pulled out from the inside of one fitting cylinder portion 37a (37b). Finally, the other small flange portion 25b (25a) is axially pulled out from the inside of the other fitting cylinder portion 37b (37a) to remove the seal member 20. As shown in FIG.

《Connecting ring》
The connecting ring 21 is for axially connecting the pair of inner rings 18a and 18b, and is made of a metal plate. The connecting ring 21 is a partially annular ring having a discontinuous portion in the circumferential direction, and has a substantially U-shaped cross-sectional shape. The connecting ring 21 has a connecting portion 42 having a cylindrical shape in the middle portion in the axial direction, and a pair of engaging portions 43a and 43b each having a substantially U-shaped cross-sectional shape at both ends in the axial direction. have.

The connecting ring 21 is attached to the pair of inner rings 18a and 18b so as to straddle the pair of inner rings 18a and 18b in the axial direction in a reduced diameter state. The connecting ring 21 locks the pair of locking portions 43a and 43b respectively to locking grooves 26a and 26b provided on the inner peripheral surfaces of the pair of inner rings 18a and 18b. there is Specifically, the outer surface of the axially outer locking portion 43a is brought into contact with the inner surface of the locking concave groove 26a of the axially outer inner ring 18a without axial play. In addition, the outer surface of the locking portion 43b on the inner side in the axial direction is brought into contact with the inner surface of the locking groove 26b of the inner ring 18b on the inner side in the axial direction without axial play. Thereby, the connecting ring 21 axially connects the pair of inner rings 18a and 18b. Therefore, according to the rolling bearing device 2 of the present embodiment, the friction acting on the inner rings 18a and 18b when the rolling bearing device 2 is assembled to the axle tube 3 causes the pair of inner rings 18a and 18b to separate from each other or to separate in the axial direction. It is possible to prevent the inner ring 18a from slipping out of the axle tube 3 in the axial direction due to collision between the outer ring 18a and the axle tube 3.

The connecting portion 42 has a constant outer diameter dimension and an inner diameter dimension along the axial direction, and in the free state of the connecting ring 21, the outer diameter is the same as or slightly larger than the inner diameter dimension of the large diameter surface portions 28a and 28b. have dimensions. Therefore, when the connecting ring 21 is fitted (internally fitted) to the pair of inner rings 18a and 18b, the outer peripheral surface of the connecting portion 42 is in contact with the inner peripheral surfaces of the large diameter surface portions 28a and 28b.

《Sealing device》
As shown in FIGS. 1 and 2, the rolling bearing device 2 of this example has openings on both sides in the axial direction of an internal space existing between the inner peripheral surface of the outer ring 17 and the outer peripheral surfaces of the pair of inner rings 18a and 18b. A pair of sealing devices 44a, 44b are further provided to seal the part. One sealing device 44a is arranged between the axially outer portion of the inner peripheral surface of the outer ring 17 and the outer peripheral surface of the large flange portion 24a that constitutes the inner ring 18a arranged axially outside. The other sealing device 44b is arranged between the axially inner portion of the inner peripheral surface of the outer ring 17 and the outer peripheral surface of the large collar portion 24b forming the inner ring 18b arranged axially inward. Such sealing devices 44a and 44b prevent the grease sealed in the internal space of the rolling bearing device 2 from leaking to the external space, and prevent foreign matter such as muddy water existing in the external space from entering the internal space. are preventing.

According to the rolling bearing device 2 of the present embodiment as described above, it is possible to ensure the sealing performance of the abutting portion 32 between the pair of inner rings 18a and 18b and to ensure the workability of attaching and removing the seal member 20. It is possible to achieve both.
That is, with the seal member 20 mounted in such a manner that the abutting portions 32 of the pair of inner rings 18a and 18b are in close contact with each other, the pair of axial side surfaces 40 of the inner diameter side seal portion 36 are respectively attached to the pair of groove inner surfaces 33b. At least the base end portion of each of the inner peripheral surfaces of the pair of fitting cylinder portions 37a and 37b that make up the outer diameter side seal portion 35 and are brought into contact with each other with an interference margin The pair of small flanges 25a and 25b can be brought into contact with each other with an interference. Therefore, the seal member 20 can ensure the sealing performance of the butted portion 32 .

Moreover, in this example, the inner diameters of the pair of fitting tubular portions 37a and 37b in the free state of the seal member 20 are set to the inner peripheral surfaces of the pair of fitting tubular portions 37a and 37b and the pair of smaller inner diameters. The fitting with the outer peripheral surface of the flanges 25a and 25b is regulated to a size that provides a loose fit or an intermediate fit. Therefore, when the seal member 20 is mounted, in which the inner diameter side seal portion 36 is elastically sandwiched between the pair of groove inner surfaces 33b of the seal holding groove 33, the inner diameters of the pair of fitting cylindrical portions 37a and 37b are small. The diameter of the flanges 25a and 25b is reduced from the size in the free state in which they are in a clearance fit or intermediate fit relationship. The inner diameter is the dimension in the free state. Therefore, when the sealing member 20 is attached, the work of inserting the pair of small flanges 25a and 25b into the pair of fitting cylinders 37a and 37b does not require a large force and prevents the lip from curling. It can be easily performed without causing such as. Further, when the seal member 20 is removed, the pair of small flanges 25a and 25b can be pulled out from the inside of the pair of fitting cylinders 37a and 37b without requiring a large amount of force. . Therefore, it is possible to improve the workability of attaching and detaching the seal member 20 .

As described above, according to the rolling bearing device 2 of the present embodiment, the inner diameters of the pair of fitting cylindrical portions 37a and 37b are adjusted according to the mounting state of the seal member 20 and the mounting and removing operations of the seal member 20. Therefore, it is possible to ensure both the sealing performance of the abutting portion 32 between the pair of inner rings 18a and 18b and the workability of attaching and removing the seal member 20. . Therefore, according to the rolling bearing device 2 of this embodiment, when the axial clearance is measured by the conventionally known measuring method as shown in FIG. 7, the working efficiency of the measuring work can be improved. can.

In addition, since the sealing member 20 has a symmetrical shape with respect to the axial direction, it is possible to eliminate directionality regarding the mounting direction of the sealing member 20 . From this aspect as well, the workability of attaching the seal member 20 can be improved.

Further, in this example, a radial gap 41 a is formed between the inner peripheral surface 39 of the inner diameter side seal portion 36 and the groove bottom surface 33 a of the seal holding groove 33 . Therefore, it is possible to prevent a part (diameter direction inner portion) of the seal member 20 from being caught in the abutting portion 32 .

In addition, in this example, since the sealing member 20 is composed only of an elastic material and does not use a metal core, the cost and weight of the sealing member 20 can be reduced.

[Second example of embodiment]
A second example of the embodiment will be described with reference to FIG.

The rolling bearing device 2a of this example differs from the structure of the first example of the embodiment only in the structure of the seal member 20a.

In this example, in the free state of the seal member 20a, the inner peripheral surfaces of the pair of fitting cylinder portions 37c and 37d forming the outer diameter side seal portion 35a are tapered surfaces. Specifically, the inner peripheral surface of each of the pair of fitting tubular portions 37c and 37d has a smaller inner diameter as it approaches the inner diameter side seal portion 36 in the axial direction. In other words, the inner peripheral surface of each of the pair of fitting tubular portions 37c and 37d has an inner diameter that decreases from the distal end side to the proximal end side. The angle of inclination of the inner peripheral surfaces of the pair of fitting cylinders 37c and 37d with respect to the central axis of the seal member 20a can be set, for example, within a range of greater than 0 degrees and less than 20 degrees. It is possible and in the example shown is approximately 15 degrees. 4 shows the shape of the seal member 20a in a free state.

In this example, the inner diameters of the pair of fitting cylinders 37c and 37d in the free state of the seal member 20a are respectively defined by the inner peripheral surfaces of the pair of fitting cylinders 37c and 37d and the pair of small flanges. The fitting with the outer peripheral surface of each of 25a and 25b has an interference fit relationship in a portion near the inner diameter side seal portion 36 in the axial direction, and a clearance fit relationship in a portion far from the inner diameter side seal portion 36 in the axial direction. It is regulated to the size that becomes

Specifically, the fitting between the proximal end portion of the inner peripheral surfaces of the pair of fitting cylinders 37c and 37d and the outer peripheral surfaces of the pair of small flanges 25a and 25b is tightened. In order to set the fitting, the outer peripheral surface of each of the pair of small flanges 25a and 25b is larger than the maximum allowable dimension of the proximal end portion of the inner peripheral surfaces of each of the pair of fitting cylinders 37a and 37b. The inner diameters of the base end portions of the pair of fitting cylinders 37a and 37b are regulated in relation to the outer diameters of the pair of small flanges 25a and 25b so that the minimum allowable dimension of is doing. In this example, in order to prevent the force required to insert the small flange portion 25a (25b) inside the fitting cylinder portion 37c (37d) from becoming excessive, the inner peripheral surface of the fitting cylinder portion 37c (37d) is The size of the interference between the base end side portion of and the outer peripheral surface of the small flange portion 25a (25b) is set small. Specifically, the size of the maximum interference between the proximal end portion of the inner peripheral surface of the fitting cylinder portion 37c (37d) and the outer peripheral surface of the small flange portion 25a (25b) is set to 0 mm to 0 mm. .6 mm.

Further, the fitting between the tip end portion of the inner peripheral surfaces of the pair of fitting cylinders 37c and 37d and the outer peripheral surfaces of the pair of small flanges 25a and 25b is set to be a clearance fit. Therefore, the maximum allowable dimension of each of the outer peripheral surfaces of the pair of small flanges 25a and 25b is larger than the minimum allowable dimension of the distal end portion of the inner peripheral surfaces of each of the pair of fitting cylinders 37a and 37b. The inner diameters of the tip end portions of the pair of fitting cylinders 37a and 37b are regulated in relation to the outer diameters of the pair of small flanges 25a and 25b so as to be smaller.

Therefore, in this example, in the elastically deformed state of the seal member 20a, in which the inner diameter side seal portion 36 is elastically sandwiched by the pair of groove inner surfaces 33b from both sides in the axial direction, the pair of fitting cylinder portions 37c and 37d are in contact with each other. The interference of the base end portion of the inner peripheral surface with respect to the outer peripheral surface of each of the pair of small flanges 25a and 25b can be made larger than in the structure of the first example of the embodiment.

In the present example as described above, since the interference at the proximal end portion of the inner peripheral surfaces of the pair of fitting cylindrical portions 37c and 37d can be increased, the sealing performance of the sealing member 20a can be further improved. be able to.

In addition, since the inner peripheral surfaces of the pair of fitting cylinders 37c and 37d are tapered, the small flanges 25a and 25b can be easily inserted into the fitting cylinders 37c and 37d. The inner diameters of the pair of fitting cylinders 37c, 37c in the free state of the seal member 20a are defined by the inner peripheral surfaces of the pair of fitting cylinders 37c, 37c, the pair of small flanges 25a The fitting with the outer peripheral surface of 25b is an interference fit only at the portion near the inner diameter side seal portion 36 in the axial direction, which is located on the far side in the insertion direction of the small flange portions 25a and 25b, and in the axial direction. The tip side portion far from the inner diameter side seal portion 36 is regulated to have a clearance fit relationship. Therefore, when the sealing member 20a is attached, the work of inserting the pair of small flanges 25a and 25b into the pair of fitting cylinders 37c and 37d does not require a large amount of force, and the lip portion does not need much force. It can be easily done without causing curling or the like. Further, when removing the seal member 20a, the work of pulling out the pair of small flanges 25a and 25b from the inside of the pair of fitting cylinders 37c and 37d does not require a large force and can be easily performed. . Therefore, it is possible to improve the workability of attaching and detaching the sealing member 20a.

Furthermore, by adjusting the inclination angles of the inner peripheral surfaces of the fitting cylinder portions 37c and 37d, the inner peripheral surfaces of the pair of fitting cylinder portions 37c and 37d and the pair of small flange portions 25a and 25b can be adjusted. can easily adjust the contact state with the outer peripheral surface of the. For example, if the inclination angle of the inner peripheral surfaces of the fitting cylindrical portions 37c and 37d is set small, the range of contact with the outer peripheral surfaces of the pair of small flange portions 25a and 25b with interference is increased. can do. On the other hand, if the inclination angle of the inner peripheral surfaces of the fitting cylindrical portions 37c and 37d is set large, the range of contact with the outer peripheral surfaces of the pair of small flange portions 25a and 25b with interference is provided. can be made smaller. Thus, according to the sealing member 20a of this example, it is possible to easily adjust the sealing performance.
Other configurations and effects are the same as those of the first embodiment.

When carrying out the present invention, as a modification of the second example of the above-described embodiment, the inner peripheral surface of each of the pair of fitting cylinders is configured such that the inner diameter increases with increasing distance from the inner diameter side seal portion in the axial direction. A reduced tapered surface is also possible. Then, the inner diameter of each of the pair of fitting cylinders in the free state of the seal member is fitted between the inner peripheral surface of each of the pair of fitting cylinders and the outer peripheral surface of each of the pair of small flanges. However, it is also possible to regulate the dimensions so that a clearance fit relationship is provided in the axially nearer portion to the inner diameter side seal portion and an interference fit relationship is provided in an axially farther portion from the inner diameter side seal portion.

Although the embodiment of the present invention has been described above, the present invention is not limited to this and can be modified as appropriate without departing from the technical idea of the invention. In addition, the structures of the respective examples of the embodiments can be implemented in combination as appropriate as long as there is no contradiction.

When carrying out the present invention, the respective shapes of the outer diameter side seal portion and the inner diameter side seal portion that constitute the seal member are not limited to the shapes shown in the respective examples of the embodiments, and can be changed as appropriate. . For example, the seal member may be shaped asymmetrically with respect to the axial direction, with the axially outer half and the axially inner half having different shapes. Further, in this case, the axially outer half portion and the axially inner half portion of the outer diameter side seal portion can be fitted in different relation to the small flange portion. Moreover, when carrying out the present invention, the structure of the connecting ring is not limited to the structure of each example of the embodiment, and can be changed as appropriate. Further, the rolling bearing device of the present invention is not limited to the drive wheel support device, and can be used by being incorporated in the rotation support portion of various mechanical devices including the driven wheel support device.

Reference Signs List 1 drive wheel support device 2, 2a rolling bearing device 3 axle tube 4 hub wheel 5 drive shaft 6 drive wheel 7 braking rotor 8 cylindrical surface portion 9 step surface 10 male screw portion 11 nut 12 flange 13 bolt 14 fitting surface 15 rotating flange 16 Coupling member 17 Outer rings 18a, 18b Inner rings 19a, 19b Rolling elements 20, 20a Sealing members 21, 21a Connecting rings 22a, 22b Outer ring raceways 23a, 23b Inner ring raceways 24a, 24b Large flanges 25a, 25b Small flanges 26a, 26b Engagement Lock grooves 27a, 27b Small diameter surface portions 28a, 28b Large diameter surface portion 29a First abutment surface 29b Second abutment surface 30a First annular groove 30b Second annular groove 31a First ridge portion 31b Second ridge portion 32 Abutment Part 33 Seal holding groove 33a Groove bottom surface 33b Groove inner surface 34a, 34b Cage 35 Outer diameter side seal part 36 Inner diameter side seal part 37a, 37b, 37c, 37d Fitting cylindrical part 38 Chamfered part 39, 39a Inner peripheral surface 40 Axial direction Side faces 41, 41a Radial gap 42 Connecting parts 43a, 43b Locking parts 44a, 44b Sealing device 100 Rolling bearing device 101 Axle tube 102 Hub wheel 103 Drive shaft 104 Flange 105 Drive wheel 106 Braking rotor 107, 107x Outer ring 108a, 108b, 108x, 108y Inner ring 109a, 109b, 109x, 109y Rolling element 110 Sealing member 111 Connecting ring 112a, 112b Outer ring raceway 113a, 113b Inner ring raceway 114 Butting portion 115 Seal holding groove 116 Core metal 116a Cylindrical portion 116b 7 Outward flange portion 11 Portion 117a Lip portion 118 Connecting portion 119 Locking portion 120a, 120b Locking concave groove 121 Reference surface 122 Displacement meter

Claims (4)

an outer ring having a double-row outer ring raceway;
a pair of inner rings each having a single-row inner ring raceway and a small flange portion disposed adjacent to a small-diameter side portion of the inner ring raceway;
a plurality of rolling elements arranged between the outer ring raceway and the inner ring raceway;
a sealing member that seals the butted portion between the pair of inner rings;
A connecting ring that connects the pair of inner rings,
the pair of inner rings has seal retaining grooves on the radially outer side of the abutting portions, the seal retaining grooves including a pair of axially opposed groove inner surfaces and a radially outward groove bottom surface;
The seal member is made of an elastic material having a substantially T-shaped cross section, and has an annular shape as a whole. and an inner diameter side seal portion that is
The inner diameters of both axial side portions of the outer diameter side seal portion in the free state of the seal member are equal to the inner peripheral surfaces of the axial both side portions of the outer diameter side seal portion and the pair of inner rings. The fitting with the outer peripheral surface of the provided small flange portion is regulated to a dimension that results in a clearance fit or an intermediate fit,
The sealing member elastically sandwiches the inner diameter side seal portion from both sides in the axial direction by the pair of groove inner surfaces, so that the inner peripheral surfaces of the outer diameter side seal portion on both sides in the axial direction are: At least a portion near the inner diameter side seal portion in the axial direction is brought into contact with the outer peripheral surface of the small flange portion provided on each of the pair of inner rings with an interference, and the inner diameter side seal portion A radial gap is provided between the inner peripheral surface and the bottom surface of the groove,
Rolling bearing device. an outer ring having a double-row outer ring raceway;
a pair of inner rings each having a single-row inner ring raceway and a small flange portion disposed adjacent to a small-diameter side portion of the inner ring raceway;
a plurality of rolling elements arranged between the outer ring raceway and the inner ring raceway;
a sealing member that seals the butted portion between the pair of inner rings;
A connecting ring that connects the pair of inner rings,
the pair of inner rings has seal retaining grooves on the radially outer side of the abutting portions, the seal retaining grooves including a pair of axially opposed groove inner surfaces and a radially outward groove bottom surface;
The seal member is made of an elastic material having a substantially T-shaped cross section, and has an annular shape as a whole. and an inner diameter side seal portion that is
the inner peripheral surfaces of both sides in the axial direction of the outer diameter side seal portion are tapered surfaces whose inner diameters become smaller as they approach the inner diameter side seal portion in the axial direction;
The inner diameters of both axial side portions of the outer diameter side seal portion in the free state of the seal member are the inner peripheral surfaces of the axial both side portions of the outer diameter side seal portion and the inner rings of the pair of inner rings. The fitting with the outer peripheral surface of the small flange provided in the is an interference fit relationship in a portion close to the inner diameter side seal portion in the axial direction, and a gap is formed in a portion far from the inner diameter side seal portion in the axial direction. It is regulated to the dimensions that are related to fitting,
The sealing member elastically sandwiches the inner diameter side seal portion from both sides in the axial direction by the pair of groove inner surfaces, so that the inner peripheral surfaces of the outer diameter side seal portion on both sides in the axial direction are: At least a portion near the inner diameter side seal portion in the axial direction is brought into contact with the outer peripheral surface of the small flange portion provided on each of the pair of inner rings with an interference, and the inner diameter side seal portion A radial gap is provided between the inner peripheral surface and the bottom surface of the groove,
Rolling bearing device. 3. The rolling bearing device according to claim 1, wherein the radial thickness of said outer diameter side seal portion is greater than the radial thickness of said inner diameter side seal portion. The outer ring is a rotating ring that rotates with the wheel during use,
The pair of inner rings are stationary rings that do not rotate during use,
each of the plurality of rolling elements is a tapered roller,
A rolling bearing device according to any one of claims 1 to 3.

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