KR102153439B1 - Rolling bearing device, and backup roll for rolling mill including the rolling bearing device - Google Patents

Abstract

The rolling bearing device of the present invention is provided with a sealing device that closes the opening of the first annular space between the inner and outer ring members. The sealing device is provided with a core. An exhaust hole is formed in the core for opening the pressure in the first annular space to the second annular space by communicating between the first annular space and the second annular space. When the inside of the first annular space exceeds a predetermined pressure, the second sealing lip is separated from the slinger to open the pressure in the first annular space to the external space through the exhaust hole and the second annular space.

Description

A rolling bearing device, and a backup roll for a rolling mill using the same TECHNICAL FIELD TECHNICAL FIELD [0002] BACKUP ROLLING MILL INCLUDING THE ROLLING BEARING DEVICE

Japanese Patent Application No., filed on January 16, 2013, including specifications, drawings, and abstracts. 2013-005367, the entire content of which is incorporated herein by reference.

The present invention relates to, for example, a rolling bearing device used in a backup roll for supporting a roll of a rolling mill, and a backup roll for a rolling mill using the same.

In a multi-stage rolling mill or the like, a backup roll for supporting a rolling mill roll is constituted with a shaft and a plurality of rolling bearing devices. The rolling bearing device is fitted and fixed to the shaft from the outside and is arranged and arranged in the axial direction. The rolling bearing device is a double-row cylindrical roller provided with an outer ring 101, an inner ring 102, a double-row cylindrical roller 103, and a sealing device 104, as shown in FIG. 5. It consists of bearings. The outer ring 101 is a rotating wheel. The inner ring 102 is fitted and fixed to the shaft from the outside. The cylindrical roller 103 is interposed between the inner and outer rings 101 and 102 so as to be capable of being transmitted. The sealing device 104 seals an annular opening between the inner and outer rings 101 and 102. The sealing device 104 is provided with an annular core metal 105, an annular slinger 106, and an annular sealing lip 107. The core 105 is fixed to the outer ring 101. The slinger 106 is fixed to the inner ring 102 and is disposed opposite to the core 105 in the axial direction. The silver core 105 protrudes from one end face in the axial direction and contacts the end face of the slinger 106 to seal the space between the outer ring 101 and the inner ring 102.

In the rolling bearing device, oil mist mixed with air is supplied under pressure at a predetermined pressure into the space between the inner and outer rings 101 and 102, thereby lubricating each part of the rolling bearing device. In addition, in this rolling bearing device, when the pressure in the space between the inner and outer rings 101 and 102 increases due to oil mist being supplied, the tip of the sealing lip 107 of the sealing device 104 is slightly separated from the slinger 106 , The pressure in the space between the inner and outer rings 101 and 102 is opened toward the outer space so that the inside of the space does not exceed a predetermined pressure (see, for example, Japanese Laid-Open Patent No. 2002-228007).

In the above conventional rolling bearing device, the front end of the sealing lip 107 is separated from the slinger 106 by the pressure in the space between the inner and outer rings 101 and 102, so that the inner and outer rings 101 and 102 There is a risk of foreign substances such as moisture or dust entering the space between them. Such entry of foreign matter into the space becomes a factor that reduces the life of the rolling bearing device. In addition, the release of the pressure in the space between the inner and outer rings 101 and 102 is performed by the sealing lip 107 being separated from the slinger 106. Therefore, when the inner and outer rings 101 and 102 slightly move relative to the axial direction, the contact pressure of the sealing lip 107 with respect to the slinger 106 changes, or the separation of the sealing lip 107 is not performed smoothly. , The pressure in the space between the inner and outer rings 101 and 102 is greatly fluctuated, the supply amount of the oil mist becomes unstable, and there is a concern that lubrication defects may occur.

Japanese Laid-Open Patent No. 2002-228007

An object of the present invention is to provide a rolling bearing device capable of suppressing a fluctuation of pressure in a space between inner and outer rings and more effectively suppressing foreign matter from entering the space, and a backup roll for a rolling mill using the same. There is one.

A structural feature of the rolling bearing device of one aspect of the present invention is an inner ring having an inner ring raceway surface on an outer circumferential surface, and an outer ring disposed concentrically with the inner ring and facing the inner race raceway surface on the inner circumferential surface. An outer ring having a raceway surface, a plurality of rolling elements disposed so as to be rollable between the inner raceway raceway surface and the outer raceway raceway surface, and the inner ring provided at both ends in the axial direction of the inner ring and the outer ring A pair of sealing devices which close a first space divided by an outer circumferential surface and an inner circumferential surface of the outer ring, and a mist-type lubricating oil mixed with a gas is pressurized and supplied into the first space, and the sealing device includes the inner ring And an annular core fixed to one of the outer rings, an annular slinger fixed to the other of the inner ring and the outer ring and disposed opposite to the core in the axial direction, and a side outside the axial direction of the core. A first sealing lip protruding in a cross section and sealing both ends in the axial direction of the first space by contacting the slinger, and installed radially outward from the first sealing lip, and protruding toward the side end surface of the core, the A second sealing lip is provided that seals the first space together with the first sealing lip by contacting the slinger and forms a second space between the first sealing lip, and in the core, the An exhaust hole communicating between the first space and the second space is formed, and the second sealing lip is spaced apart from the slinger when the inside of the first space exceeds a predetermined pressure to reduce the pressure in the first space, It is to have a pressure control function of maintaining a state in which the first sealing lip is in sliding contact with the slinger by opening to an external space through the exhaust hole and the second space.

The above-described and additional features of the present invention will become apparent from the following description of embodiments with reference to the accompanying drawings, and like reference numerals in the drawings are used to indicate like components.
1 is a cross-sectional view showing a backup roll of a rolling mill according to an embodiment of the present invention.
FIG. 2 is an enlarged partial cross-sectional view of the sealing device in FIG. 1.
3 is an external view when a slit portion is viewed from the inner cross-sectional side.
4 is a cross-sectional view showing the configuration of another aspect of the rolling bearing device.
5 is a cross-sectional view showing a conventional rolling bearing device.

Next, preferred embodiments of the present invention will be described with reference to the accompanying drawings. 1 is a cross-sectional view showing a backup roll of a rolling mill according to an embodiment of the present invention. In the drawing, the backup roll is a roll for supporting these by contacting and driving a work piece roll or an intermediate roll of a rolling mill for rolling a rolled material (not shown). The backup roll includes a single or a plurality of rolling bearing devices 1 and a support shaft T that supports the rolling bearing devices 1 against the rolling mill.

One or more rolling bearing devices 1 are arranged on the support shaft T along the axial direction, and the outer ring member 2 is driven in contact with the outer circumferential surface of a work roll, etc. Support. The rolling bearing device 1 is provided with an outer ring member 2, an inner ring member 3, a cylindrical roller 4, an annular retainer 5, and a pair of sealing devices 10. . The outer ring member 2 constitutes a roll driven by contacting a roll of the rolling mill. The inner ring member 3 is arranged concentrically on the inner peripheral side of the outer ring member 2. The cylindrical roller 4 is a plurality of rolling elements disposed between the outer ring member 2 and the inner ring member 3 so as to be rollable. The retainer 5 holds the plurality of cylindrical rollers 4 in the circumferential direction. The sealing device 10 is fixed to both ends of the rolling bearing device 1.

The inner ring member 3 is configured by combining a pair of cylindrical inner rings 3a in the axial direction. On the outer circumferential surface of the inner ring 3a, an inner ring raceway surface 3a1 on which a plurality of cylindrical rollers 4 roll is formed. The outer ring member 2 is a cylindrical member in which the outer circumferential surface 2a comes into contact with a roll of the rolling mill. On the inner circumferential surface of the outer ring member 2, a pair of outer ring raceways 2b on which the plurality of cylindrical rollers 4 roll is formed to face the inner raceway raceways 3a1 formed on each of the pair of inner rings 3a, have. The plurality of cylindrical rollers 4 are arranged so as to be able to be rolled between the pair of inner raceway surfaces 3a1 and the outer raceway raceways 2b, and thereby, the outer ring member 2 and the inner race member 3, Relative rotation is possible. According to the above configuration, the rolling bearing device 1 supports the outer ring member 2 so as to be rotatable with respect to the support shaft T by fastening and fixing the inner ring member 3 to the support shaft T.

The pair of sealing devices 10 are provided at both ends of the outer ring member 2 and the inner ring member 3 in the axial direction. The pair of sealing devices 10 are fixed to each of the openings at both ends of a first annular space (first space) S1, which is an annular space divided into an inner raceway surface 3a1 and an outer raceway raceway surface 2b, , These openings are closed. Therefore, the first annular space S1 is sealed to the outside.

In the abutting portion 3b in which the pair of inner rings 3a are butted to each other, in the first annular space S1 between the inner and outer ring members 2 and 3, a lubrication hole 3c for supplying oil mist is provided. Is formed. Oil mist mixed with gas such as air is pressurized and supplied into the first annular space S1 through the oil supply hole 3c. In the rolling bearing device 1 of the present embodiment, the oil mist is supplied under pressure into the first annular space S1, whereby lubrication of each portion is performed. As the oil mist supplied for lubrication of each part, a mixture of a high-pressure gas and oil mist may be used, or the oil mist itself may be pressurized to increase pressure.

Fig. 2 is a partial cross-sectional view of the sealing device in Fig. 1 on an enlarged scale. In the drawing, the sealing device 10 includes an annular core 11, an annular slinger 12, and a sealing member 13. The core 11 is fixed to the outer ring member 2. The slinger 12 is fixed to the inner ring 3a (inner ring member 3). The sealing member 13 is fixed to the core 11.

The slinger 12 is disposed opposite to the core 11 so as to be positioned outside the inner ring member 3 in the axial direction, which is an end side of the inner ring member 3. The slinger 12 has a cylindrical portion 12a and a flange portion 12b. The cylindrical portion 12a is fitted and fixed to the outer end of the outer peripheral surface of the inner ring 3a from the outside. The flange portion 12b is formed at the outer end of the cylindrical portion 12a. The outer circumferential surface 12c of the flange portion 12b is formed so that a small gap is formed with respect to the inner circumferential surface of the outer ring member 2, and foreign matter is prevented from entering the inner space side of the rolling bearing device 1 rather than the slinger 12. Consists of labyrinth to prevent.

The core 11 is between the snap ring 15 fitted in the circumferential groove 2c formed on the inner circumferential surface of the outer ring member 2 and the stepped portion 2d formed on the inner circumferential surface of the outer ring member 2 The outer peripheral edge is pinched at Thereby, the core 11 is fixed rotatably integrally with the inner peripheral surface of the outer ring member 2.

The sealing member 13 is a member formed and fixed by vulcanization bonding to the core 11 using an elastic material such as nitrile rubber. The sealing member 13 has a base 13a and an annular first sealing lip 13b. The base 13a is along an inner cross-section 11b facing the inner side in the axial direction of the core 11. The first sealing lip 13b protrudes to the outer end surface 11a of the core 11 and slides into contact with the inner end surface 12b1 of the flange portion 12b. The sealing member 13 further has an annular second sealing lip 13c and a joint 13d. The second sealing lip 13c is concentrically installed outside the first sealing lip 13b in the radial direction. The joint (13d) is installed along the outer end surface (11a) facing outward in the axial direction of the core (11), the base end of the first sealing lip (13b) and the base end of the second sealing lip (13c) Connect.

The first sealing lip 13b, the second sealing lip 13c, the base 13a and the like of the sealing member 13 are integrally formed by vulcanization bonding as described above. Therefore, compared to the case of forming each of these parts, it is easy to form each part.

The base 13a is formed so as to cover the outer peripheral surface of the core 11 from the inner end surface 11b of the core 11. The base 13a is interposed between the outer peripheral edge portion of the core member 11 and the step portion 2d of the outer ring member 2, and the outer peripheral edge portion of the outer ring member 2 and the core member 11 It seals the gap with the wealth.

The first sealing lip 13b extends radially outward from the outer end face 11a of the core 11 toward the axial slinger 12 side. The front end of the sealing lip 13b is in sliding contact with the inner end surface 12b1 of the flange portion 12b, and a first annular space while allowing relative rotation between the outer ring member 2 and the inner ring member 3 The end opening of (S1) is sealed. That is, the first annular space S1 is partitioned by an outer peripheral surface of the inner ring member 3, an inner peripheral surface of the outer ring member 2, and a pair of first sealing lips 13b provided at both ends in the axial direction.

Like the first sealing lip 13b, the second sealing lip 13c protrudes to the outer end surface 11a of the core 11 and is in sliding contact with the inner end surface 12b1 of the flange portion 12b. 1 The 1st annular space S1 is sealed together with the sealing lip 13b. The second sealing lip 13c is disposed concentrically to the outer side in the radial direction of the first sealing lip 13b, and thus is provided on the outer space S3 side than the first sealing lip.

In addition, the second sealing lip 13c is provided concentrically to the outer side in the radial direction of the first sealing lip 13b, so that the second annular space (the second Space) (S2) is formed. Accordingly, the second annular space S2 includes the first sealing lip 13b, the second sealing lip 13c, the core 11 in which the sealing lip 13b, 13c is installed, and the sealing lip ( 13b and 13c are partitioned by the slinger 12 in sliding contact. The first sealing lip 13b and the second sealing lip 13c have a second annular space S2 interposed between the first annular space S1 and the external space S3, and the first annular shape The space S1 is sealed.

In addition, in the core 11, the pressure in the first annular space S1 is opened to the second annular space S2 by communicating between the first annular space S1 and the second annular space S2. The exhaust hole 11c is formed. This exhaust hole 11c is formed in a cylindrical shape in cross section, penetrates the core 11 in the thickness direction, and is formed through the joint 13d. Further, a plurality of exhaust holes 11c are formed along the circumferential direction of the core 11.

The exhaust hole 11c is covered by the base 13a of the sealing member 13 on the side of the inner end surface 11b of the core 11. In other words, the base 13a of the sealing member 13 constitutes a cover that blocks the exhaust hole 11c.

A slit 13a1 is formed in a portion of the base 13a corresponding to the exhaust hole 11c.

3 is an external view of the slit 13a1 as viewed from the inner end surface 11b side. Referring also to FIG. 1, the slit 13a1 is formed in a straight line along a direction orthogonal to the radial direction. The slit 13a1 is formed by inserting a cut-in through the entire thickness direction of the base 13a, and is opened when the pressure in the first annular space S1 exceeds a predetermined pressure P1. .

More specifically, when the pressure in the first annular space S1 is higher than the predetermined pressure P1 and higher than the second annular space S2, the slit 13a1 is opened, and the first annular space S1 is The pressure is opened to the second annular space S2 through the slit 13a1. On the other hand, it is difficult for foreign substances such as moisture or dust to pass through the slit 13a1 which is opened and closed according to the pressure of the first annular space S1. Accordingly, the base 13a as the cover portion is removed from the exhaust hole 11c while allowing the pressure in the first annular space S1 to be opened toward the second annular space S2 by forming the slit 13a1. It is possible to suppress entry of foreign substances into the 1 annular space S1.

In addition, the first sealing lip 13b is not separated from the slinger 12 even when the pressure of the first annular space S1 exceeds the predetermined pressure P1 which is the pressure at which the slit 13a1 is opened. Is set to the contact pressure of. Accordingly, even if the pressure in the first annular space S1 exceeds the predetermined pressure P1, the first sealing lip 13b maintains a state in sliding contact with the slinger 12.

When the pressure in the first annular space S1 exceeds the predetermined pressure P1, the pressure of the first annular space S1 through the exhaust hole 11c is opened to the second annular space S2, the second annular space The pressure in the space S2 increases. When the pressure in the second annular space S2 exceeds the predetermined pressure P2 by the pressure released from the first annular space S1, the second sealing lip 13c is elastically deformed by the pressure, and the slinger It is spaced apart from (12), and the pressure in the second annular space S2 is opened toward the outer space S3.

In addition, as mentioned later, each part is set so that the predetermined pressure P1 may become more than predetermined pressure P2. Accordingly, the pressure of the first annular space S1 is opened to the second annular space S2, the second annular space S2 becomes equal to or higher than the predetermined pressure P2, and the second sealing lip 13c is a slinger. It is separated from (12). That is, the second sealing lip 13c is separated from the slinger 12 when the pressure in the first annular space S1 exceeds a predetermined pressure P1 to reduce the pressure in the first annular space S1, and the exhaust hole 11c ) And the second annular space (S2) to open to the external space (S3) has a pressure control function.

According to the rolling bearing device 1 configured as described above, the second sealing lip 13c is separated from the slinger 12 when the inside of the first annular space S1 exceeds a predetermined pressure P1 and is separated from the first annular space ( The pressure in S1) is opened to the external space S3 through the exhaust hole 11c and the second annular space S2. Accordingly, while opening the pressure in the first annular space S1 toward the outer space S3, the first sealing lip 13b can maintain a state in sliding contact with the slinger 12. That is, in the rolling bearing device 1, the pressure in the first annular space S1 is configured to be opened through the second annular space S2 which is closer to the outer space S3 than the first sealing lip 13b. Thereby, a function (pressure control function) as an exhaust valve for adjusting the pressure in the first annular space S1 and in the second annular space S2 mainly is charged to the second sealing lip 13c, and the first sealing The function of improving the sealing property between the inner and outer ring members 2 and 3 can be mainly applied to the lip 13b.

Thereby, with respect to the 2nd sealing lip 13c, the contact pressure with respect to the slinger 12 can be adjusted so that pressure fluctuation in the 1st annular space S1 may be suppressed. With respect to the first sealing lip 13b, the contact pressure can be adjusted so as to increase the sealing property to the slinger 12. As a result, the sealing property can be improved while suppressing the fluctuation of the pressure in the first annular space S1, and it is possible to more effectively suppress the entry of foreign matter into the first annular space S1.

In this embodiment, the predetermined pressure P1 in the first annular space S1 is the opening pressure of the slit 13a1, and the predetermined pressure P2 in the second annular space S2 is the second sealing lip. (13c) is the opening pressure. When the pressure of the external space S3 is P3, the contact pressure for the slinger 12 of the first sealing lip 13b and the second sealing lip 13c or the slit 13a1, respectively, so as to satisfy the following equation as possible. The dimensions and shape of are adjusted.

P1 ≥ P2> P3

The predetermined pressure P1, which is the opening pressure of the slit 13a1, is determined according to the pressure of the oil mist and the contact pressure of the first sealing lip 13b to the slinger 12, in addition to setting the shape of the slit 13a1. All. In addition, the first sealing lip 13b does not need to release pressure. Therefore, the contact pressure of the first sealing lip 13b with respect to the slinger 12 is set so that a higher sealing property can be obtained as compared to the case where it is necessary to release the pressure, similarly to the conventional example.

In addition, even if the second sealing lip 13c is formed so that the predetermined pressure P2 satisfies the above equation, and the inner ring member 3 and the outer ring member 2 relatively move in the axial direction, the above-described pressure The relationship is set to the shape and contact pressure that can be maintained.

More specifically, in this embodiment, when the pressure P3 of the outer space S3 which is atmospheric pressure is the reference pressure, the predetermined pressure P1 is +10 to 20 kPa, and the predetermined pressure P2 is +5 to 10 kPa. Each part is set so that it may become.

In addition, in this embodiment, the exhaust hole 11c communicates with the 2nd annular space S2 formed between the 1st sealing lip 13b and the 2nd sealing lip 13c. Thereby, the entry of foreign matters into the vicinity of the exhaust hole 11c is suppressed by the second sealing lip 13c. Even if a foreign substance enters the second annular space S2, there is a certain distance in the axial direction from the tip of the second sealing lip 13c to the exhaust hole 11c, so the second sealing The foreign material passing through the tip of the lip 13c does not immediately approach the exhaust hole 11c. As a result, it is possible to suppress entry of foreign substances into the first annular space S1 from the exhaust hole 11c. Even if the foreign matter reaches the vicinity of the exhaust hole 11c, according to the above configuration, while allowing the pressure in the first annular space S1 to be released by the base 13a as the cover portion in which the slit 13a1 is formed, It is possible to suppress entry of foreign substances into the first annular space S1 from the exhaust hole 11c.

In addition, the present invention is not limited to each of the above embodiments. In the above embodiment, a case in which the exhaust hole 11c is formed in a cylindrical cross-sectional shape has been exemplified, but the cross-sectional shape of the cross-sectional shape, such as a cross-sectional square or elliptical shape, can be appropriately changed. In addition, in the above embodiment, the case where the base 13a of the sealing member 13 functions as a cover portion for blocking the exhaust hole 11c has been described, but a configuration without this cover portion may be employed. However, in this case, since the first annular space S1 and the second annular space S2 have substantially the same pressure, the pressure of the first annular space S1 is the opening pressure of the second sealing lip 13c. When the predetermined pressure (P2) is exceeded, the second sealing lip (13c) is separated from the slinger (12), and the pressure in the first annular space (S1) is transferred to the outside through the exhaust hole (11c) and the second annular space (S2). It opens to the space S3.

In addition, in the above embodiment, the case where the slit 13a1 formed on the base 13a is formed in a straight line, for example, may be formed by intersecting two slits, and several slits 13a1 are arranged. You may form it. Moreover, the thickness of the slit 13a1 can also be adjusted suitably.

In addition, in the above embodiment, a case in which the base 13a is used as a cover portion only on the inner end surface 11b of the core 11 is shown, but, for example, as shown in FIG. 4, the outer side of the core 11 Also on the end face 11a side, a cover portion in which the slit 13a1 is formed may be provided. In this case, the cover part on the side of the outer end surface 11a is constituted by a joint 13d connecting the first sealing lip 13b and the second sealing lip 13c. In this way, by providing the cover portions on both end surfaces 11a and 11b of the core 11, it is possible to more effectively suppress the intrusion of foreign substances into the first annular space S1.

According to the rolling bearing device of the present invention and the backup roll for a rolling mill using the same, it is possible to more effectively suppress a foreign matter from entering the space while suppressing fluctuations in pressure in the space between inner and outer rings.

Claims (4)

In the rolling bearing device,
An inner ring having an inner ring raceway surface on the outer peripheral surface;
An outer ring disposed concentrically with the inner ring and having an outer ring raceway surface facing the inner ring raceway surface on an inner circumferential surface;
A plurality of rolling elements disposed between the inner raceway surface and the outer raceway raceway so as to be capable of being transmitted; And
A pair of sealing devices installed at both ends of the inner ring and the outer ring in the axial direction and closing a first space partitioned between the inner ring outer peripheral surface and the outer ring inner peripheral surface;
Including,
The mist type lubricating oil mixed with the gas is pressurized and supplied into the first space,
The sealing device,
An annular core fixed to either of the inner ring and the outer ring;
An annular slinger fixed to the other of the inner ring and the outer ring and disposed opposite to the core in the axial direction, which is the outer space side of the bearing device;
A first sealing lip protruding from a side end surface of the core in the axial direction outside and in contact with the slinger to seal an axial end opening of the first space; And
It is installed radially outward than the first sealing lip, protrudes to the side end surface of the core and contacts the slinger to seal the first space together with the first sealing lip, and at the same time, the first sealing lip and A second sealing lip forming a second space between the two;
Including,
An exhaust hole communicating between the first space and the second space is formed in the core,
When the inside of the first space exceeds a predetermined pressure, the second sealing lip is spaced apart from the slinger to open the pressure in the first space to an external space through the exhaust hole and the second space, so that the first sealing lip Having a pressure control function to maintain a state in sliding contact with the slinger,
Rolling bearing device. The method of claim 1,
Further comprising a cover portion blocking the exhaust hole,
The rolling bearing device, wherein a slit that opens when the inside of the first space exceeds a predetermined pressure is formed in the cover portion. The method of claim 2,
The first sealing lip, the second sealing lip, and the cover portion are integrally formed of an elastic material. It includes a rolling bearing device for supporting the work roll by rolling in contact with the outer peripheral surface of the work roll for rolling a rolled material,
The rolling bearing device is the rolling bearing device according to any one of claims 1 to 3,
Backup roll for rolling mill.

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