JP2008003054A - Multipole magnet encoder, sealing device with multipole magnet encoder, roll bearing equipped with sealing device concerned, and bearing unit for wheel support - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a multipole magnet encoder of excellent in reliability and durability with simple and inexpensive price structure, a sealing device with the multipole magnet encoder, a roll bearing equipped with sealing device, and a bearing unit for wheel support. <P>SOLUTION: In the multipole magnet encoder 1 which composes a rotational speed detection mechanism K prepared at the rotary member side of a rotation support device comprising a rotary member 2 and a fixing member 3 deployed in a concentric fashion and a plurality of rolling elements 11 embedded between the rotary member concerned and the fixing member concerned to detect the rotational speed with concerted efforts of a magnetic sensor S prepared at the fixing member side and comprises an annular core bar 300 of magnetic material at least prepared by being fixed at the rotary member side and an annular encoder part 100 magnetized multipolarly to prepare, by molding vulcanizably, at an external surface of the core bar along the axial direction of the rotary member after mixing magnetic material and rubber, the external surface 100a of the encoder part 100 is equipped with a protection rubber layer 16 and the protection rubber layer 16 concerned is vulcanizably molded simultaneously together with the encoder part 100. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention is provided in a rolling bearing that supports wheels of various vehicles, a multipolar magnet encoder for detecting the rotational speed of a wheel by a magnetic sensor provided on the vehicle body side, a sealing device having a multipolar magnet encoder, and The present invention relates to a rolling bearing and a wheel support bearing unit provided with a sealing device. In this specification, the term “wheel” is used to collectively refer to all the wheels of a railway vehicle regardless of the wheels of an automobile.

For example, an automobile is provided with a rotation detection device that detects the rotation speed (wheel speed) of a wheel. The encoder unit 100 of the multipolar magnet encoder 1 disposed on the rotation side (wheel bearing side), and the encoder unit 100 There is known a sensor composed of a magnetic sensor S arranged on the vehicle body side so as to face the motor. Such rotation detection devices include, for example, a traction control system (abbreviated as TCS), a car navigation system (Satellite navigation system), an anti-lock brake system (Anti-lock).
It is used for brake system, abbreviated ABS).
Conventionally, as shown in FIG. 7, as an encoder unit 100, ferrite powder, rare earth, or the like is mixed with a rubber material (a rubber material as a binder, such as nitrile rubber (NBR) or hydrogenated nitrile rubber (HNBR)). It is known that an annularly formed object is magnetized, and an S pole and an N pole are alternately provided in the circumferential direction, and a reverse L-shaped cross-sectional view constituting a sealing device incorporated in a rolling bearing A magnetic seal is integrally provided on the side peripheral surface of the sealing member (for example, slinger) having a shape facing outward from the bearing. That is, there is an encoder portion 100 that is provided in an exposed shape outside the bearing.

When the rubber encoder unit 100 is arranged in an exposed manner outside the bearing, dust such as earth and sand, and iron scraps (magnetic dust) depending on the road surface condition may be present on the surface of the encoder unit 100. It tends to adhere to the (outer surface 100a facing outward of the bearing). In this way, the foreign matter adheres to the inconvenience that the surface of the encoder unit 100 is worn. When the surface of the encoder unit 100 is worn, the magnetic flux density is reduced and the accuracy of the magnetic flux signal is reduced.
Further, when the magnetic dust adheres to the surface, there is a problem that the signal accuracy is lowered.
In order to eliminate such inconvenience, the periphery of the encoder unit 100 may be designed so that the labyrinth is formed by taking in peripheral components, but a sealing device with a multipolar magnet encoder is provided. Or the rolling bearing incorporating the sealing device is different from the supplier of the suspension peripheral parts. Therefore, the case where the performance of the labyrinth is not sufficient may occur.

As technical means for solving such inconvenience, the encoder unit 100 is sealed inside the sealing device and positioned inside the bearing, and the magnetic signal of the encoder unit 100 is sensed from the outside of the bearing, or the same manufacturer For example, it is possible to arrange in a space protected by a labyrinth whose dimensions are strictly controlled, and sense the magnetic signal of the encoder unit 100 from the outside of the space.
Therefore, recently, as an example of a prior art that can prevent adhesion of dust with a rolling bearing incorporating a sealing device with a multipole magnet encoder, a technique disclosed in, for example, Patent Document 1 or 2 is provided.

  For example, as shown in FIG. 5, Patent Document 1 raises a multipole magnet encoder 1 integrally from the outer diameter of a rotating inner ring 2 in the radial direction and arranges the multipole magnet encoder 1 inside a bearing. A seal member integrally attached to the fixed outer ring 3 so as to shield the end region F between the inner and outer rings 2 and 3 from the outside of the bearing through a predetermined gap (air gap) G1 outside the encoder unit 100. 200, and the sensing is performed by the magnetic sensor S from the outside of the seal member 200.

  For example, as shown in FIG. 6, Patent Document 2 discloses a cross-sectional view L that includes a cylindrical portion 5 and a disc portion 6 that is continuously raised in a circumferential direction from a bearing outer end portion of the cylindrical portion 5. The bearing inner ring 2 has a slinger 4 that is press-formed into a letter shape, an encoder portion 100 that is integrally disposed on the outer surface 6a of the disk portion of the slinger 4, and an outer diameter 8a that can be fitted into the cylindrical inner diameter 5a of the slinger 4. The cross-sectional view reverse L which consists of the cylindrical part 8 which has the internal diameter 8b which can be fitted to the outer diameter 2a of this, and the disk part 9 raised continuously from the bearing outer end part of the cylindrical part 8 in the circumferential direction A technology is disclosed in which the cover member 7 is formed by covering a surface (outer surface) 100a of the encoder unit 100 facing the outside of the bearing, with a cover member 7 press-molded into a letter shape. That is, the cylindrical portion 5 of the slinger 4 is fitted to the cylindrical portion 8 of the cover member 7 and the encoder portion 100 is sandwiched between the disc portion 6 of the slinger 4 and the disc portion 9 of the cover member 7. In this state, the cylindrical portion inner diameter 8b of the cover member 7 is fitted to the inner ring outer diameter 2a and disposed in the bearing end region F.

However, in the technique disclosed in Patent Document 1, as shown in FIG. 5B, between the encoder unit 100 and the magnetic sensor S, 1) the axial clearance (between the encoder unit 100 and the seal member 200) Air gap) G1, 2) thickness W of the seal member (core metal) 200, and 3) an axial gap (air gap) G2 between the seal member 200 and the magnetic sensor S.
Thus, since the distance (G1 + W + G2) from 1) to 3) is between the encoder unit 100 and the magnetic sensor S, the magnetic signal becomes weak and the reliability of the magnetic signal accuracy is inferior.

Moreover, according to such a prior art, the following problems were also held.
That is, the magnetic flux is not uniform, and as shown in FIG. 5 (b), the center region A1 is higher, and it is preferable in terms of accuracy to place the magnetic sensor S in the higher region A1 for sensing. It is. For this reason, in order to increase the accuracy, it is necessary to set the detection region to the higher region A1.
However, according to the technique disclosed in Patent Document 1, as shown in FIG. 5B, the seal lip regions of the encoder unit 100 and the seal member 200 are arranged side by side in the radial direction. Due to the limitation of the direction, the encoder unit 100 must be disposed in a narrow space region, and the current situation is that only the encoder unit 100 having a narrow radial width can be necessarily disposed.
Therefore, the highly accurate detection region (center region A1) becomes a narrower region as shown in FIG. 5B, and the reliability of detection accuracy may be deteriorated.
Furthermore, the region of the seal member 200 is also restricted in the radial direction, and there is a problem that the sealing performance must be satisfied in a narrow region.

Further, the technique disclosed in Patent Document 2 requires a technique with a high degree of processing difficulty in which two pressed parts, the slinger 4 and the cover member 7 are fitted.
JP-A-10-160744 JP 2002-333033 A

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a multipole magnet encoder having a simple and inexpensive structure and excellent in reliability and durability, and a sealing device including the multipole magnet encoder. Another object of the present invention is to provide a rolling bearing and a wheel support bearing unit provided with the sealing device.

  In order to achieve such an object, a first invention of the present invention includes a rotating member and a fixing member arranged concentrically, and a plurality of rolling elements incorporated between the rotating member and the fixing member. A rotation speed detection mechanism configured to detect a rotation speed together with a magnetic sensor provided on the fixed member side of the rotation support device is configured and configured to be fixed at least on the rotation member side. A multi-pole magnet comprising an annular cored bar and a multi-pole magnetized annular encoder unit provided by mixing a magnetic material with rubber and vulcanizing and forming the outer surface of the cored bar in the axial direction of the rotating member An encoder is provided with a rubber protective layer on the outer surface of the encoder part, and the rubber protective layer is a multipolar magnet encoder that is vulcanized simultaneously with the encoder part. is there.

A second invention is characterized in that, in the first invention, the protective layer of the encoder section constituting the multipolar magnet encoder is configured in an ebonite shape by adjusting the amount of carbon black and a cross-linking material mixed therein. This is a multi-pole magnet encoder.
That is.

  According to a third aspect of the present invention, in the first aspect of the invention, the non-magnetic hard granule material is mixed in the protective layer of the encoder portion constituting the multipolar magnet encoder. It is that.

  4th invention is provided in the rotation member side of the rotation support apparatus comprised by the rotation member and fixing member which were distribute | arranged to the concentric circle, and the several rolling element integrated between this rotation member and fixing member. Together with a magnetic sensor provided on the fixed member side to constitute a rotational speed detection mechanism for detecting the rotational speed, and at least a magnetic annular metal core provided fixed on the rotary member side and a rubber mixed with a magnetic material. A multi-pole magnet encoder comprising a multi-pole magnetized annular encoder portion provided by vulcanization molding on the outer surface of the core metal in the axial direction of the rotating member, and the encoder portion after vulcanization molding This is a multi-pole magnet encoder characterized in that the hardness is increased by impregnating the outer surface with a cross-linking material and heating to advance cross-linking in the vicinity of the outer surface.

  A fifth invention is a sealing device for sealing an annular inner space formed between the rotating member and the fixing member in an end region between the rotating member and the fixing member arranged concentrically. The first seal member that is fixed to the rotating member side, rotates, and forms a contact or non-contact seal area with the fixed member side, and is fixed to the fixed member side and contacts with the rotating member side Or a second seal member that forms a non-contact seal region. The first seal member includes a first cylindrical portion fixed to the rotating member and a radial direction extending from the first cylindrical portion. A core member made of a magnetic material composed of a first disk part provided, and an encoder part provided on the outer surface of the first disk part, and the second seal member is fixed to the fixing member A second cylindrical portion and a second disc portion extending radially from the second cylindrical portion. The end portion of the second disc portion forms a seal region that is in contact with or non-contact with one or both of the peripheral surface of the first cylindrical portion and the peripheral surface of the rotating member, This sealing member is a sealing device with a multipole magnet encoder, wherein the multipole magnet encoder according to any one of the first to fourth inventions is used.

  In a sixth aspect based on the fifth aspect, the second seal member is an L-shaped cored bar in section view composed of a second cylindrical part and a second disc part, and a part of the cored bar Or a rubber or soft resin material covering the whole, wherein the rubber or soft resin material has one or more annular seal lips formed in the end region of the second disc portion. This is a sealing device with a multipolar magnet encoder.

  According to a seventh aspect of the present invention, the rotating member is an inner ring and the fixed member is an outer ring. A sealing device is incorporated in an end region between the inner ring and the outer ring, and the wheel speed is controlled by a magnetic sensor provided near the outside of the sealing device. The rolling bearing to be detected is a rolling bearing characterized in that the sealing device with a multipolar magnet encoder of the fifth or sixth invention is used as the sealing device.

  An eighth invention comprises a hub having one or more rows of raceway surfaces, and an inner ring fitted on the inboard side of the hub and having one or more rows of raceway surfaces adjacent to the raceway surfaces. Or a rotating member that is fitted on the outer periphery of the hub and includes an inner ring having a plurality of rows of raceway surfaces, and a plurality of rows of raceway surfaces facing the plurality of rows of raceway surfaces of the rotation members. An internal space of the bearing is formed by incorporating a fixed member, a plurality of rolling elements incorporated between the raceway surface of the rotating member and the raceway surface of the fixed member, and an end region between the rotary member and the fixed member. In a sealing device for sealing and a wheel support bearing unit that detects a wheel speed by a magnetic sensor provided in the vicinity of the outside of the sealing device, the sealing device with a multipolar magnet encoder according to the fifth or sixth invention is used as the sealing device. Special feature of using the device Is that in which the wheel supporting bearing unit according to.

  According to a ninth aspect, in the eighth aspect, at least the rotating member is provided with a flange to which the braking member and the wheel are fixed, or the fixing member is provided with a flange to be fixed to the vehicle body side. This is a wheel support bearing unit.

  According to the present invention, a multipolar magnet encoder having a simple and inexpensive structure and excellent in reliability and durability, a sealing device with the multipolar magnet encoder, a rolling bearing provided with the sealing device, and a wheel support bearing unit are provided. did it.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings. Note that the present embodiment is merely an embodiment of the present invention, and is not construed as being limited thereto. The design can be changed within the scope of the present invention. In the present embodiment, the description will be given with the wheel of an automobile as an example of the wheel, but it is merely an example and may be another wheel such as a wheel of a railway vehicle.
"Example 1"

FIG. 1 is a longitudinal sectional view showing an example of a rolling bearing for supporting a wheel of an automobile as an example of the rolling bearing according to the present invention.
The rolling bearing according to the present embodiment includes an inner ring 2 as a rotating member arranged in a concentric circle and a relatively rotatable member, an outer ring 3 as a fixed member, a raceway surface 2 b provided on an outer diameter 2 a of the inner ring 2, and an outer ring 3. A plurality of rolling elements (balls) 11 incorporated through a cage 10 between the raceway surface 3b provided on the inner diameter 3a, and inner and outer rings 2, incorporated in end regions F of the inner ring 2 and the outer ring 3. It is comprised with the sealing device M which seals the annular | circular bearing inner space between three. In this embodiment, balls are employed as the rolling elements 11, but it is also within the scope of the present invention to employ rollers.
A broken line in the figure is a magnetic sensor S that is arranged on the fixed member side (vehicle body side) toward the encoder unit 100 of the multipolar magnet encoder 1 and senses a magnetic signal of the encoder unit 100, and is a multipolar magnet encoder. 1 constitutes a rotation speed detection mechanism K that detects the rotation speed.

The sealing device M is provided on the inboard side (vehicle body side) and the outboard side (wheel side), and the sealing device 12 with a multipolar magnet encoder of the present invention is employed as the sealing device on the inboard side. Although the illustration of the sealing device 24 on the outboard side is omitted, the lubricant (for example, grease, oil) enclosed in the bearing leaks to the outside of the bearing, or foreign matter (for example, water, dust) enters the inside of the bearing. A well-known sealing device capable of preventing the occurrence of contact, for example, a contact seal or a non-contact seal (including a shield) is appropriately selected within the scope of the present invention. In addition, the design of the presence or absence of a metal core or a seal lip can be changed.
Thus, the rolling bearing of the present embodiment has a characteristic configuration in the sealing device 12 with a multipole magnet encoder incorporated on the inboard side, and is a well-known form in other bearing configurations. Hereinafter, the sealing device 12 with a multipolar magnet encoder, which is a specific configuration of the present invention, will be specifically described, and description of other bearing configurations will be limited to the above-described degree.
In the present embodiment, the multipole magnet encoder 1 is used as the first seal member 13, and the sealing device 12 with a multipole magnet encoder constituted by the first seal member 13 and the second seal member 17 will be described. However, it is also possible to employ an inboard-side sealing device that is constituted only by the first seal member 13 made of the multipolar magnet encoder 1.
Although not particularly illustrated, the present invention can also be applied to a double-row angular ball bearing or a double-row tapered roller bearing (first generation) in which the outer ring of the back combination bearing is integrated.
In this embodiment, the inner ring rotation is used, but the present invention can be applied to the case of outer ring rotation.

  FIG. 2A is a partially enlarged sectional view showing an example of the sealing device 12 with a multipolar magnet encoder of the present invention.

  The sealing device 12 with a multipolar magnet encoder includes a first seal member 13 that is fixed to the inner ring 2 and a second seal member 17 that is fixed to the outer ring 3. And the second seal member 17 are provided as a so-called pack seal configured in a substantially rectangular shape in cross section. In this embodiment, as the first seal member 13, an example using the multipole magnet encoder 1 is adopted.

  The first seal member 13 (multipole magnet encoder 1) in the present embodiment includes a cored bar 300 made of a magnetic material, an encoder unit 100 provided in the cored bar 300, and an outer surface of the encoder unit 100. It is comprised by the protective layer 16 with which 100a is equipped.

The core metal 300 includes a first cylindrical portion 14 that is fixed to the outer diameter end region of the inner ring 2, and a first disc (annular) portion that extends radially outward from the first cylindrical portion 14. 15, a so-called slinger formed in an L-shaped cross-sectional view is employed in this embodiment.
The core metal (slinger) 300 is made of a magnetic material and has good bending workability, and is made of, for example, low carbon steel, martensitic stainless steel, etc., and the first cylindrical portion 14 has an inner ring outer diameter 2a. A predetermined labyrinth gap L1 is formed between the first disc portion 15 and the second seal member 17 that is fixed to the outer ring inner diameter 3a when assembled. It is made into the disk shape which forms.

The encoder unit 100 is vulcanized and formed into a disc (annular) shape in the same region as the region of the outer surface 15a of the first disc portion 15 with respect to the outer surface 15a of the first disc portion 15 of the core metal 300. Yes. The encoder unit 100 is the same as the conventional structure shown in FIG.
In other words, the inner diameter of the encoder part 100 extends to the vicinity of the inner diameter of the first cylindrical part 14 on the outer surface 15a of the first disk part 15, and the radial end part 100b is connected to the radial end part 15b of the first disk part 15 and A predetermined labyrinth gap L <b> 2 is formed between the second sealing member 17 and the second disc member 15 in the same plane.
The encoder unit 100 is provided in the end region F of the bearing with its magnetic pole surface (outer surface 100a) facing outward from the bearing.

The protective layer 16 is made of a rubber having the same chemical structure as that of the rubber used as the binding material of the encoder unit 100, and the outer layer 100 a of the encoder unit 100 has a disk ( It is configured in an annular shape, and is vulcanized and formed simultaneously with the encoder unit 100. For example, nitrile rubber (NBR), hydrogenated nitrile rubber (HNBR), and the like can be given as representative examples of the rubber material constituting the protective layer 16.
The axial thickness of the protective layer 16 is preferably as thin as possible within a range that does not affect the strength and the like. That is, the distance between the magnetic pole surface 100a of the encoder unit 100 and the magnetic sensor S (the thickness W of the protective layer 16 + the air gap formed by the gap G2 between the protective layer 16 and the magnetic sensor S) is minimized. Therefore, the protective layer 16 should not be too thick.
In the present embodiment, the radial end portion 16b of the protective layer 16 is flush with the radial end portion 15b of the first disc portion 15, and the second disc portion 15 and the encoder portion 100, as in the second disc. A predetermined labyrinth gap L <b> 3 is formed between the seal member 17 and the seal member 17.

That is, in the present embodiment, the rubber for the encoder unit 100 and the rubber for the protective layer 16 are kneaded separately, and then are preliminarily formed by extending into a sheet shape.
Thereafter, two sheets are stacked one by one, placed in a vulcanization mold, and compression molded integrally with the first disk portion 15 of the cored bar 300.
In the case of the present embodiment, after vulcanization molding is integrally performed in this way, the outer surface 100a of the encoder unit 100 in contact with the inner surface 16c of the protective layer 16 is magnetized from the outer surface 16a side of the protective layer 16. .

  The second seal member 17 includes a second cylindrical portion 18 that is fixed to the inner diameter end region of the outer ring 3, and a second disc portion 19 that extends radially inward from the second cylindrical portion 18. And a rubber seal lip 21 vulcanized and formed on the inner diameter end portion 19a of the second disc portion 19 of the metal core 20. In addition, the present embodiment employs a nose gasket type in which the outer surface region of the second disc portion 19 of the core metal 20 and the inner diameter region and end region of the second cylindrical portion 18 are covered with an elastic member 25 such as rubber. However, this is not to be construed as limiting in any way.

  According to this embodiment, the seal lip 21 is provided with a first lip 21a functioning as a dust seal and a second lip 21b functioning as an oil seal in an annular shape, and the lips 21a and 21b are respectively provided on the first seal member 13. Contacting the outer diameter of the first cylindrical portion 14, contact seal regions 22 and 23 are formed. Further, in the present embodiment, a conical side seal lip 21 c extending in an inclined manner from the elastic member 25 covering the outer surface side of the second disc portion 19 toward the inner diameter direction of the second cylindrical portion 18. The side seal lip 21 c forms a contact seal region 36 with the inner surface of the first disc portion 15 constituting the first seal member 13.

Note that the number of the seal lips 21 may be one or a plurality, and the number is not limited. The shape of the seal lip 21 is not particularly limited to the illustrated form, and a known form is appropriately selected. In this embodiment, the seal lip 21 is made of a rubber material. However, the seal lip 21 may be made of a soft resin material. In this embodiment, each seal lip 21a, 21b, 21c is described as a contact seal region 22, 23, 36. However, these seal lips 21a, 21b, 21c are non-contact seals. A region may be formed, and the design can be changed within the scope of the present invention.
In this embodiment, the seal lips 21a and 21b are in contact with the outer diameter of the first cylindrical portion 14 to form the seal regions 22 and 23. However, the axial length of the first cylindrical portion 14 is shortened. It is also possible to adopt a mode in which one or both of the seal lips 21a and 21b are brought into contact with the inner ring outer diameter 2a by increasing the length of the second cylindrical portion 18 in the axial direction.

According to the present embodiment, the nonmagnetic material protective layer 16 is provided on the magnetic pole surface 100a side of the encoder portion 100, which is a magnetic material, so that the encoder portion 100 can be disposed outside the core metal 300 in the axial direction. The protection of the magnetic pole surface 100a of the encoder unit 100, that is, the possibility that foreign matter or the like adheres to the magnetic pole surface 100a of the encoder unit 100 and the wear of the magnetic pole surface 100a of the encoder unit 100 proceeds is eliminated. Further, since the protective layer 16 is made of a solid rubber material such as nitrile rubber (NBR) or hydrogenated nitrile rubber (HNBR), it is stronger and more durable than the magnetic rubber of the encoder unit 100. Therefore, the magnetic pole surface 100a of the encoder unit 100 can be protected over a long period of time.
Further, since it can be brought close to the magnetic sensor S, the distance between the encoder unit 100 and the magnetic sensor S (the thickness W of the protective layer 16 + the gap G2 between the protective layer 16 and the magnetic sensor S). The air gap) can be shortened and the magnetic signal is not weakened, so that the reliability of the magnetic signal accuracy can be obtained.
Furthermore, according to the present embodiment, the encoder unit 100 and the protective layer 16 are characterized by the fact that the same chemical structural rubber is used and vulcanized and molded at the same time to be firmly integrated by crosslinking.

In this embodiment, as described above, the vulcanization molding is performed simultaneously with the encoder unit 100, but the protective layer 16 and the encoder unit 100 are integrally vulcanized and molded. After magnetizing, it may be fixed to the outer surface 15a of the first disc portion 15 of the cored bar 300 via the magnetic force.

  Further, according to the present embodiment, one non-contact seal area 35 composed of the labyrinth gaps L1 to L3 described above and three contact seal areas 22, 23, 36 by the three contact seal lips 21a, 21b, 21c. The inside of the bearing is sealed.

According to the present embodiment, the encoder unit 100 and the seal members (seal lips 21a, 21b, 21c) can be arranged in parallel in the axial direction. Therefore, since the radial width of the encoder part 100 can be secured to the maximum in the outer surface area of the first disc part 15 of the slinger in the bearing end area, the encoder part 100 having a wide radial width can be disposed. Therefore, in comparison with FIG. 5B showing the conventional center region A1, in the case of the present embodiment, a highly accurate detection region (center region A2) is wide as shown in FIG. 2A. Since it becomes a region, the reliability of detection accuracy can be obtained.
Further, since the seal region is not restricted in the radial direction, the seal performance can be satisfied sufficiently and easily.
"Modification 1"

In the above embodiment, the protective layer 16 is made of only a rubber material such as nitrile rubber (NBR) or hydrogenated nitrile rubber (HNBR). However, in this modification, the properties after vulcanization are greatly increased by the additive. This is an example in which the protective layer 16 of Example 1 is further strengthened by utilizing the changing properties of rubber.
That is, the protective layer 16 of the present example was configured in an ebonite shape by adjusting the mixing amount of carbon black and a crosslinking material. The present modification has a feature in the structure of the protective layer 16, and other structures and operational effects are the same as those in the first embodiment. Therefore, the same portions are denoted by the same reference numerals, and the description thereof is omitted.

The feature of adopting this modification is that the resistance to temperature change is superior to that of a hard encoder such as a resin encoder or a sintered material, and the details are as follows.
That is, the metal core 300 used in this type of multipolar magnet encoder 1 needs to be a magnetic material and a material with good bending workability as described above, so that a lot of metals such as low carbon steel and martensitic stainless steel are used. Has been. However, since the resin material and the sintered material are greatly different in linear expansion coefficient from the metal, there is a possibility that the adhesive layer is broken or the encoder part itself is cracked when the temperature change is repeated. According to the present embodiment, the outer surface 16a of the protective layer 16 is strengthened in an ebonite form, and stress due to a temperature change is absorbed by the encoder unit 100 having rubber elasticity, so that the ebonite protective layer 16 is cracked. There is no fear.
"Modification 2"

In the present modification, the protective layer 16 provided on the outer surface (magnetic pole surface) 100a of the encoder unit 100 is characterized in that a non-magnetic hard granule such as silica is mixed therein. This is an example of another embodiment in which the protective layer 16 is further strengthened, in particular, the wear resistance is enhanced.
In addition, since this modification has the characteristics in the structure of the protective layer 16, and other structures and effects are the same as those in the first embodiment, the same portions are denoted by the same reference numerals, and the description thereof is omitted. To do.
"Example 2"

  FIG. 2B is a schematic cross-sectional view showing an example of the sealing device 12 with a multipolar magnet encoder of the second embodiment. In this embodiment, a protective layer is separately provided on the outer surface (magnetic pole surface) 100 a of the encoder unit 100. In this example, the outer surface 100a of the encoder unit 100 is reinforced.

In order to strengthen the outer surface 100a of the rubber encoder unit 100, it is conceivable to adopt the following method known as a surface hardening method such as general sealing or packing.
For example, it is possible to employ (1) mixing a powder of resin or the like in a rubber material, (2) mixing oil in the rubber material, (3) impregnating a monomer compatible with rubber and polymerizing it. However, the “(1) mixing the powder of resin etc. into the rubber material” is not preferable because the amount of ferrite powder mixed in the encoder portion is reduced, and the “(2) mixing the oil into the rubber material” is not preferable. The method of “(3) impregnating and polymerizing a monomer compatible with rubber”, which is not effective because it is a member for sliding, can be an effective means if there is an appropriate monomer. Nitrile rubber (NBR) and hydrogenated nitrile rubber (HNBR) used as encoder binders have poor compatibility with marketable silicon monomers and fluorine monomers, making it difficult to obtain suitable monomers. .

  Accordingly, in this embodiment, the outer surface 100a of the encoder unit 100 after vulcanization is impregnated with a known general cross-linking material such as sulfur and heated to advance cross-linking in the vicinity of the outer surface 100a. The hardness on the outer surface 100a side of the portion 100 was increased. Specifically, the outer surface 100a of the vulcanized encoder unit 100 is a mixture of ferrite powder and a rubber material, and thus has a rough structure. Therefore, fine powdery sulfur powder is rubbed into the outer surface 100a of the encoder unit 100 after vulcanization molding or impregnated with a paste, and then reheated to proceed with crosslinking in the vicinity of the outer surface 100a. As a result, the hardness of the outer surface 100a is increased. In FIG. 2B, the portion indicated by x on the outer surface (magnetic pole surface) 100 a of the encoder unit 100 is a region where hardness is increased. The region for increasing the hardness is not particularly limited to the portion indicated by the x mark, and any design change can be made within the scope of the present invention as long as the hardness of the region of the outer surface 100a which is at least the magnetic pole surface can be increased. is there.

According to the present embodiment, the magnetic pole surface 100a of the encoder section 100 can be protected even if the outer surface (magnetic pole surface) 100a of the encoder section 100 is not provided with the protective layer 16 as in the first embodiment.
That is, according to the present embodiment, the distance between the magnetic pole surface 100a of the encoder unit 100 and the magnetic sensor S (the air gap formed by the gap G2 between the encoder unit 100 and the magnetic sensor S) can be further shortened. Further, since the magnetic signal is not weakened, further reliability of the magnetic signal accuracy can be obtained.
Further, since the other structures and operational effects are the same as those of the first embodiment, the same reference numerals are given to the same portions, and the description thereof is omitted. In addition, according to the present embodiment, as a matter of course, unlike the first embodiment, since the protective layer 16 is not provided, the labyrinth gap L3 does not exist, and one non-contact seal region 35 also has the labyrinth gap. It consists of L1 and L2.
"Example 3"

FIG. 3 shows an example of the wheel support bearing unit of the present invention incorporating the sealing device with a multipolar magnet encoder of the present invention. A broken line in the figure indicates a magnetic sensor S that is arranged on the fixed side (vehicle body side) toward the encoder unit 1 and senses a magnetic signal of the encoder unit 1.
The wheel support bearing unit of the present invention can be used in various vehicles such as automobiles and railway vehicles, but here, as an example, a wheel support bearing unit incorporated in a drive wheel of an automobile will be described. A wheel support bearing unit incorporated in the driven wheel is also a target.

  As shown in FIG. 3, the wheel support bearing unit of the present embodiment has a hub 31 having a row of raceway surfaces 32a and a row that is fitted on the inboard side outer periphery of the hub 31 and is adjacent to the raceway surface 32a. An inner member 32 composed of an inner ring (separate inner ring) 2 having a plurality of raceway surfaces 2a, and a plurality of rows of raceway surfaces 33a, 33a facing the plurality of rows of raceway surfaces 2a, 32a of the inner member 32. And a plurality of rolling elements (balls) 11 incorporated between the raceway surfaces 2a and 32a of the inner member 32 and the raceway surfaces 33a and 33a of the outer member 33. The sealing device 12 with a multipolar magnet encoder of the present invention is incorporated in the end region F on the inboard side of the inner member 32 and the outer member 33.

The wheel support bearing unit of this embodiment shown in the figure is distinguished from the so-called third generation (also referred to as HUBIII) in which the inner member 32 and the outer member 33 are provided with flanges 32b and 33b, respectively. It is.
Specifically, for example, the sealing device 12 with a multipole magnet encoder disclosed in the first and second embodiments is incorporated.

In the sealing device 24 on the outboard side, the lubricant (for example, grease or oil) sealed in the bearing leaks to the outside of the bearing, or foreign matter (for example, water or dust) enters the inside of the bearing. A well-known sealing device capable of preventing the occurrence of contact, for example, a contact seal or a non-contact seal (including a shield) is appropriately selected within the scope of the present invention. In addition, the design of the presence or absence of a metal core or a seal lip can be changed.
Further, the wheel support bearing unit is not limited to the illustrated embodiment, and all units within the scope of the present invention are applicable.
In addition, since it is as having demonstrated the structure and effect of the sealing device 12 with a multipolar magnet encoder in Example 1 and 2, description here is abbreviate | omitted.
In this embodiment, an example in which the outer member 33 is a stationary wheel and the inner member 32 is a rotating wheel will be described. However, the outer member 33 is a rotating wheel and the inner member 32 is a stationary wheel. It may be within the scope of the present invention.
"Modification 1"

  FIG. 4 shows another embodiment of the wheel support bearing unit according to the present invention, a double-row tapered roller bearing (second assembly) having a flange 34b on the outer periphery of the outer ring 34 (including the raceway surface 34a) of the rear combination bearing. Generation) as an example. That is, the sealing device 12 with a multipolar magnet encoder disclosed in the first and second embodiments can be applied to the sealing device incorporated on the inboard side in the present embodiment. The same applies to a double-row angular contact ball bearing.

It is a schematic longitudinal cross-sectional view which abbreviate | omits and shows one Example of this invention rolling bearing. BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic sectional drawing which abbreviate | omits one example of implementation of the sealing apparatus with a multipolar magnet encoder of this invention, (a) is an example provided with the protective layer on the outer surface of an encoder part, (b) is the outer surface of an encoder part This is an example of strengthening the hardness. It is a schematic sectional drawing which shows an example of the Example of this invention wheel support bearing unit. It is a schematic sectional drawing which shows an example of other implementation of this invention wheel support bearing unit. It is a schematic sectional drawing which shows an example of the conventional structure which prevents dust adhesion to a multipolar magnet encoder. It is a schematic sectional drawing which shows an example of the conventional structure which prevents dust adhesion to a multipolar magnet encoder. It is the schematic of a multipole magnet encoder.

Explanation of symbols

1 Multi-Pole Magnet Encoder 100 Encoder Unit 2 Rotating Member (Inner Ring)
3 Fixing member (outer ring)
12 sealing device with multipolar magnet encoder 13 first seal member 14 first cylindrical portion 15 first disc portion 16 protective layer 17 second seal member 18 second cylindrical portion 19 second disc portions 21a, 21b, 21c Seal lip 22, 23, 36 Contact seal area F End area S Magnetic sensor

Claims (9)

Provided on the rotating member side of the rotation support device composed of a rotating member and a fixing member arranged concentrically and a plurality of rolling elements incorporated between the rotating member and the fixing member. A rotational speed detection mechanism that detects the rotational speed together with the magnetic sensor provided,
An annular cored bar made of a magnetic material fixed at least on the rotating member side; and
A multi-pole magnet encoder comprising a multi-pole magnetized annular encoder portion that is provided by mixing a magnetic material with rubber and vulcanizing and forming the outer surface of the core in the axial direction of the rotating member,
A rubber protective layer is provided on the outer surface of the encoder unit.
The multi-pole magnet encoder, wherein the rubber protective layer is vulcanized simultaneously with the encoder portion.   The multipolar magnet encoder according to claim 1, wherein the protective layer is formed in an ebonite shape by adjusting an amount of carbon black and a cross-linking material mixed therein.   The multipolar magnet encoder according to claim 1, wherein the protective layer is mixed with non-magnetic hard granule material. Provided on the rotating member side of the rotation support device composed of a rotating member and a fixing member arranged concentrically and a plurality of rolling elements incorporated between the rotating member and the fixing member. A rotational speed detection mechanism that detects the rotational speed together with the magnetic sensor provided,
An annular cored bar made of a magnetic material fixed at least on the rotating member side; and
A multi-pole magnet encoder comprising a multi-pole magnetized annular encoder portion that is provided by mixing a magnetic material with rubber and vulcanizing and forming the outer surface of the core in the axial direction of the rotating member,
A multipolar magnet encoder, wherein the outer surface of the encoder portion after vulcanization is impregnated with a crosslinking material and heated to increase the hardness by proceeding with crosslinking in the vicinity of the outer surface. A sealing device that seals an annular inner space formed between the rotating member and the fixing member in an end region between the rotating member and the fixing member arranged concentrically,
A first seal member that is fixed on the rotating member side and rotates to form a contact or non-contact seal area with the fixed member side, and is fixed to the fixed member side and contacts with the rotating member side or A second sealing member that forms a non-contact sealing region;
The first seal member is a cored bar made of a magnetic body composed of a first cylindrical portion fixed to the rotating member and a first disc portion extending in a radial direction from the first cylindrical portion; An encoder part provided on the outer surface of the first disc part,
The second seal member includes a second cylindrical portion fixed to the fixing member, and a second disc portion extending radially from the second cylindrical portion, and an end of the second disc portion. The portion forms a seal region that is in contact with or non-contact with either or both of the peripheral surface of the first cylindrical portion and the peripheral surface of the rotating member;
A sealing device with a multipole magnet encoder, wherein the first seal member uses the multipole magnet encoder according to any one of claims 1 to 4. The second seal member includes a core metal having an L-shaped cross-sectional view constituted by a second cylindrical part and a second disk part, and a rubber or soft resin material covering a part or all of the core metal. ,
6. The multipolar magnet encoder according to claim 5, wherein the rubber or the soft resin material is formed with one or a plurality of annular seal lips in an end region of the second disc portion. Sealing device. In a rolling bearing in which a rotating member is an inner ring, a fixed member is an outer ring, a sealing device is incorporated in an end region between the inner ring and the outer ring, and a wheel speed is detected by a magnetic sensor provided near the outside of the sealing device.
A rolling bearing using the sealing device with a multipolar magnet encoder according to claim 5 or 6 as the sealing device. A hub having one or more rows of raceway surfaces, and an inner ring fitted with the outer periphery of the hub on the inboard side and having one or more rows of raceway surfaces adjacent to the raceway surface, or a hub A rotating member configured with an inner ring having a plurality of rows of raceway surfaces,
A fixing member having a plurality of rows of raceways facing the rows of raceways of the rotating member;
A plurality of rolling elements incorporated between the raceway surface of the rotating member and the raceway surface of the fixed member;
A sealing device that is incorporated in an end region between the rotating member and the fixed member and seals the internal space of the bearing;
In the wheel support bearing unit for detecting the wheel speed by a magnetic sensor provided near the outside of the sealing device,
A wheel-supporting bearing unit using the sealing device with a multipolar magnet encoder according to claim 5 or 6 as the sealing device. At least the rotating member has a flange to which the braking member and the wheel are fixed,
9. The wheel support bearing unit according to claim 8, wherein the fixing member is provided with a flange fixed to the vehicle body side.

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