JP7344697B2 - Sealing device and sealing structure - Google Patents

Description

The present invention relates to a sealing device and a sealing structure.

Rolling bearings, such as ball bearings, are well known and are used, for example, in automobile hubs. A sealing device for sealing the inside of a rolling bearing is described in Patent Document 1. This sealing device includes an annular body fixed to the outer ring of a rolling bearing, a radial lip (grease lip) extending radially inward from the annular body, and two side lips (axial lips) extending laterally from the annular body. Be prepared. The radial lip has the function of sealing the lubricant (grease) inside the bearing by contacting the outer peripheral surface of the inner ring of the bearing or the outer peripheral surface of a component fixed to the inner ring, and the two side lips have the function of sealing the lubricant (grease) inside the bearing. It has the function of sealing to prevent foreign substances such as water and dust from entering the bearing from the outside.

Patent No. 3991200

When this type of sealing device is used in an environment with a lot of water (including muddy water or salt water), it is required to improve its ability to protect water from entering the sealed object (e.g. bearing). be done. Furthermore, even if water enters the sealing device, it is desirable to be able to drain the water quickly.

Therefore, the present invention provides a sealing device and a sealing structure that have high water discharge performance and high water protection performance for the sealed object.

A sealing device according to an aspect of the present invention is a sealing device that is arranged between an inner member and an outer member that rotate relatively, and seals a gap between the inner member and the outer member, a first seal member attached to the outer member and having an annular portion, the annular portion extending radially inward toward the inner member; and a first seal member attached to the inner member and having a flange portion. and a second seal member, the flange portion of which extends radially outward and faces the annular portion of the first seal member. A plurality of water discharge protrusions are supported on the rotating seal member of the first seal member and the second seal member. The plurality of water discharge protrusions protrude into a space located between the annular portion of the first seal member and the flange portion of the second seal member, and are arranged in a circumferential direction. Each water discharge protrusion has a base portion fixed to the rotating seal member and a tip portion spaced apart from the base portion, and is attached to the flange portion such that the tip portion is located radially outward than the base portion. It is slanted against.

In this sealing device, water may enter the space between the annular portion of the first sealing member and the flange portion of the second sealing member. However, a plurality of water discharge protrusions protrude within this space, and as the inner member and outer member rotate relative to each other, water in the space is splashed by the water discharge protrusions supported by the rotating member. It is quickly evacuated from the space. Therefore, the sealing device has a high ability to protect the sealed object from water. Since each water discharge protrusion is inclined with respect to the flange portion so that the tip portion is located radially outward from the base portion, water that has entered the space can be promptly discharged. Since the plurality of water discharge protrusions protrude into the space between the annular portion of the first seal member and the flange portion of the second seal member, there is no need to enlarge the sealing device for the water discharge protrusions.

A sealing structure according to an aspect of the present invention includes: an inner member having a cylindrical portion; a flange extending radially outward from the cylindrical portion; an outer member rotating relative to the inner member; a sealing member attached to the inner member and having an annular portion extending radially inwardly toward the cylindrical portion of the inner member and opposing the flange of the inner member. A plurality of water discharge protrusions are supported on a rotating member of the inner member and the seal member. The plurality of water discharge protrusions protrude into a space located between the annular portion of the seal member and the flange of the inner member, and are arranged in a circumferential direction. Each water discharge protrusion has a base fixed to the rotating member, and a distal end remote from the base, and is arranged relative to the flange such that the distal end is located radially outward from the base. It's sloped.

In this sealing structure, water may enter the space between the annular portion of the sealing member and the flange of the inner member. However, a plurality of water discharge protrusions protrude within this space, and as the inner member and outer member rotate relative to each other, water in the space is splashed by the water discharge protrusions supported by the rotating member. It is quickly evacuated from the space. Therefore, the sealed structure has a high ability to protect the sealed object from water. Each water discharge protrusion is inclined with respect to the flange so that the distal end is located radially outward from the base, so that water that has entered the space can be promptly discharged. Since the plurality of water drainage projections protrude into the space between the annular portion of the sealing member and the flange of the inner member, there is no need to enlarge the sealing structure for the water drainage projections.

1 is a partial cross-sectional view of an example of a rolling bearing in which a sealing device according to an embodiment of the present invention is used. FIG. 1 is a partial cross-sectional view of a sealing device according to a first embodiment of the present invention. It is a front view of the 2nd sealing member of the sealing device concerning a 1st embodiment. FIG. 2 is a sectional view of the sealing device according to the first embodiment. It is a partial sectional view of the sealing device concerning the modification of a 1st embodiment. FIG. 6 is a front view of a second sealing member of the sealing device according to a modification of FIG. 5; It is a front view of the 2nd sealing member of the sealing device concerning other modifications of a 1st embodiment. It is a front view of the 2nd sealing member of the sealing device concerning other modifications of a 1st embodiment. It is a partial sectional view of the sealing device concerning yet another modification of a 1st embodiment. 10 is a front view of a second sealing member of the sealing device according to a modification of FIG. 9. FIG. FIG. 7 is a partial cross-sectional view of a sealing structure according to a second embodiment of the present invention. FIG. 7 is a partial cross-sectional view of a sealing structure according to a modification of the second embodiment.

Hereinafter, various embodiments of the present invention will be described with reference to the accompanying drawings. The drawings are not necessarily to scale and some features may be exaggerated or omitted.

FIG. 1 shows a hub bearing for an automobile, which is an example of a rolling bearing in which a sealing device according to an embodiment of the present invention is used. However, the application of the present invention is not limited to hub bearings, and the present invention is also applicable to other rolling bearings. In addition, in the following explanation, the hub bearing is a ball bearing, but the application of the present invention is not limited to ball bearings, but includes other rolling bearings having other types of rolling elements, such as roller bearings and needle bearings. The present invention is also applicable to The present invention is also applicable to rolling bearings used in machines other than automobiles.

This hub bearing 1 includes a hub (inner member) 4 having a hole 2 into which a spindle (not shown) is inserted, an inner ring (inner member) 6 attached to the hub 4, and an outer ring disposed outside these. an outer ring (outer member) 8, a plurality of balls 10 arranged in a row between the hub 4 and the outer ring 8, a plurality of balls 12 arranged in a row between the inner ring 6 and the outer ring 8; It has a plurality of retainers 14 and 15 that hold the balls in place.

While the outer ring 8 is fixed, the hub 4 and inner ring 6 rotate as the spindle rotates.

A common central axis Ax of the spindle and hub bearing 1 extends in the vertical direction in FIG. In FIG. 1, only the left side portion with respect to the central axis Ax is shown. Although not shown in detail, the upper side of FIG. 1 is the outer side (outboard side) where the wheels of the automobile are arranged, and the lower side is the inner side (inboard side) where differential gears and the like are arranged. The outside and the inside shown in FIG. 1 mean the outside and the inside in the radial direction, respectively.

The outer ring 8 of the hub bearing 1 is fixed to the hub knuckle 16. The hub 4 has an outboard side flange 18 that projects radially outward from the outer ring 8. A wheel can be attached to the outboard side flange 18 with hub bolts 19.

A sealing device 20 for sealing the gap between the outer ring 8 and the hub 4 is arranged near the outboard side end of the outer ring 8, and a sealing device 20 is arranged inside the inboard side end of the outer ring 8. , a sealing device 21 for sealing the gap between the outer ring 8 and the inner ring 6 is disposed. The action of these sealing devices 20 and 21 prevents grease, that is, lubricant, from flowing out from inside the hub bearing 1, and prevents foreign matter (water (including muddy water or salt water) from entering the inside of the hub bearing 1 from the outside. and dust) are prevented from entering. In FIG. 1, arrow F indicates an example of the direction of flow of foreign matter from the outside.

The sealing device 20 is arranged between the rotating hub 4 of the hub bearing 1 and the outboard side cylindrical end 8A of the fixed outer ring 8, and seals the gap between the hub 4 and the outer ring 8. do. The sealing device 21 is disposed between the rotating inner ring 6 of the hub bearing 1 and the inboard end 8B of the fixed outer ring 8, and seals the gap between the inner ring 6 and the outer ring 8.

First Embodiment As shown in FIG. 2, the sealing device 21 is arranged in a gap between the inboard side end 8B of the outer ring 8 of the hub bearing 1 and the inner ring 6 of the hub bearing 1. Although the sealing device 21 is annular, only its left-hand portion is shown in FIG.

As is clear from FIG. 2 , the sealing device 21 has a composite structure including a first sealing member 24 and a second sealing member 26 .

The first seal member 24 is a fixed seal member that is attached to the outer ring 8 and does not rotate. The first seal member 24 is a composite structure having a resilient ring 28 and a rigid ring 30. The elastic ring 28 is made of an elastic material, such as an elastomer. Rigid ring 30 is made of a rigid material, such as metal, and reinforces elastic ring 28. Rigid ring 30 has a substantially L-shaped cross-sectional shape. A portion of the rigid ring 30 is embedded in the elastic ring 28 and is in close contact with the elastic ring 28.

The first seal member 24 has a cylindrical portion 24A, an annular portion 24B, and lips 24C, 24D, and 24E. The cylindrical portion 24A constitutes an attachment portion that is attached to the outer ring 8. Specifically, the cylindrical portion 24A is fitted into the end portion 8B of the outer ring 8 in an interference fit manner (ie, press-fitted). The annular portion 24B has an annular shape, is arranged radially inward of the cylindrical portion 24A, and expands radially inward toward the inner ring 6. The cylindrical portion 24A and the annular portion 24B are composed of a rigid ring 30 and an elastic ring 28.

The lips 24C, 24D extend from the inner end of the annular portion 24B toward the second sealing member 26, and the tips of the lips 24C, 24D contact the second sealing member 26. The lip 24E extends from the annular portion 24B toward the second sealing member 26, and the tip of the lip 24E contacts the second sealing member 26. The lips 24C, 24D, and 24E are composed of elastic rings 28.

The second seal member 26 may also be referred to as a slinger or rotating seal member. The second seal member 26 is attached to the inner ring 6, and when the inner ring 6 rotates, the second seal member 26 rotates together with the inner ring 6 and splashes foreign matter flying from the outside.

In this embodiment, the second seal member 26 is also a composite structure having a resilient ring 32 and a rigid ring 34. Rigid ring 34 is formed from a rigid material, such as metal.

Rigid ring 34 has a substantially L-shaped cross-sectional shape. Specifically, it includes a cylindrical sleeve portion 34A and an annular flange portion 34B that extends radially outward from the sleeve portion 34A. The sleeve portion 34A constitutes an attachment portion that is attached to the inner ring 6. Specifically, the end portion of the inner ring 6 is fitted into the sleeve portion 34A by an interference fit (that is, press-fitted).

The flange portion 34B is disposed radially outward of the sleeve portion 34A, extends radially outward, and faces the annular portion 24B of the first seal member 24. In this embodiment, flange portion 34B is a flat plate and lies in a plane perpendicular to the axis of sleeve portion 34A. In this embodiment, the flange portion 34B of the second seal member 26 is parallel to the annular portion 24B of the first seal member 24.

The elastic ring 32 is in close contact with the flange portion 34B of the rigid ring 34. In this embodiment, the elastic ring 32 is provided to measure the rotational speed of the inner ring 6. Specifically, the elastic ring 32 is made of an elastomer material containing magnetic metal powder and ceramic powder, and has a large number of south poles and north poles due to the magnetic metal powder. In the elastic ring 32, a large number of S poles and N poles are alternately arranged at equal angular intervals in the circumferential direction. The rotation angle of the elastic ring 32 can be measured by a magnetic rotary encoder (not shown). Since the material of the elastic ring 32 contains metal powder, it has higher hardness than normal elastomer materials and is less susceptible to damage by foreign objects.

The elastic ring 32 is fixed to both sides of the flange portion 34B. That is, the elastic ring 32 not only covers the inboard side surface of the flange portion 34B, but also covers the outer peripheral end of the outboard side surface.

The lip 24C of the first seal member 24 is a radial lip extending radially inward and outboard from the inner end of the annular portion 24B. The lip 24C extends toward the sleeve portion 34A of the second seal member 26, and the tip of the lip 24C contacts the sleeve portion 34A. The lip 24C is a grease lip that mainly serves to prevent lubricant from flowing out from inside the hub bearing 1.

The lip 24D is a radial lip extending radially inward and inboard from the inner end of the annular portion 24B. The lip 24D also extends toward the sleeve portion 34A of the second seal member 26, and the tip of the lip 24D contacts the sleeve portion 34A. The lip 24D is a dust lip that mainly serves to prevent foreign matter from flowing into the hub bearing 1 from the outside.

The lip 24E is a side lip, that is, an axial lip, extending radially outward and inboard from the middle of the annular portion 24B. The side lip 24E extends toward the flange portion 34B of the second seal member 26, and the tip of the lip 24E contacts the flange portion 34B. The side lip 24E is also a dust lip that mainly plays a role in reducing foreign matter flowing into the hub bearing 1 from the outside.

However, the side lip 24E is not necessarily essential. Even when the side lip 24E is provided, the thickness of the side lip 24E is small and easily deforms.

While the first seal member 24 is attached to the fixed outer ring 8, the inner ring 6 and the second seal member 26 rotate, so that the lips 24C, 24D are attached to the sleeve portion 34A of the second seal member 26. The lip 24E slides against the flange portion 34B of the second seal member 26.

As shown in FIG. 2, an annular gap 36 is provided between the inboard side tip of the cylindrical portion 24A of the first seal member 24 and the outer edge of the second seal member 26. . Foreign matter may enter the space 38 between the annular portion 24B of the first seal member 24 and the flange portion 34B of the second seal member 26 through the gap 36. Conversely, foreign matter within the space 38 can be evacuated through the gap 36. The side lip 24E divides the space 38 into a radially inner section and a radially outer section.

A plurality of water discharge protrusions 40 that protrude toward the annular portion 24B of the first seal member 24 are supported on the second seal member 26. These water discharge protrusions 40 have the same shape and size, and are arranged at equal angular intervals in the circumferential direction. These water discharge projections 40 project into the radially inner compartment of the space 38 . The water discharge protrusion 40 serves to discharge water from the space 38. The water discharge protrusion 40 can also be called a water discharge vane.

In this embodiment, the plurality of water discharge protrusions 40 are integrally attached to an elastic ring 42 fixed to the outboard side surface of the flange portion 34B of the rigid ring 34 of the second seal member 26. That is, each water discharge protrusion 40 is a part of the elastic ring 42. Water drainage protrusion 40 and elastic ring 42 are formed from an elastomeric material. Water drainage protrusion 40 and elastic ring 42 may be formed from the same material as elastic ring 32, ie, an elastomeric material containing magnetic metal powder and ceramic powder.

Each water discharge protrusion 40 has a base portion fixed to the second seal member 26, which is a rotating seal member, and a tip portion spaced apart from the base portion, such that the tip portion is located radially outward than the base portion. , is inclined with respect to the flange portion 34B. Each water discharge protrusion 40 is a thin plate and has two inclined surfaces 40a and 40b. Surface 40a is a radially outer surface, and surface 40b is a radially inner surface.

In this embodiment, as shown in FIG. 3, each water discharge protrusion 40 has a spiral shape when viewed from a direction perpendicular to the flange portion 34B. In FIG. 3, an arrow R indicates the main rotation direction of the inner ring 6 and thus the second seal member 26. The "main rotation direction" is the direction in which the inner ring 6 and the second seal member 26 mainly rotate, and is the rotation direction when the automobile in which the hub bearing 1 is provided moves forward. Each water discharge protrusion 40 has a spiral shape whose diameter gradually decreases as it advances in the main rotation direction R. In other words, each water discharge protrusion 40 has a spiral shape whose diameter gradually increases as it progresses in a direction opposite to the main rotation direction R. Therefore, for example, even if a foreign substance enters the gap between the water discharge protrusions 40, the foreign substance will quickly move along the water discharge protrusion 40 as the second seal member 26 rotates in the main rotation direction R. be discharged.

In this embodiment, the number of water discharge protrusions 40 is three, but the number of water discharge protrusions 40 may be two or four or more.

As described above, foreign matter (including water and dust) enters the space 38 (see FIG. 2) between the annular portion 24B of the first seal member 24 and the flange portion 34B of the second seal member 26. It's possible. However, a plurality of water discharge protrusions 40 protrude into this space 38, and as the inner ring 6 and outer ring 8 rotate relative to each other, the water in the space 38 is discharged to the water discharge protrusions 40 supported by the rotating member. It is splashed and promptly discharged from the space 38. Therefore, the sealing device 21 has a high ability to protect the sealed object from water. Moreover, the deterioration of the sealing device 21 itself, which is accelerated by the presence of water (including muddy water or salt water), is reduced. Since the gap 36 is annular, water flows out from the space 38 through a part of the gap 36, while air outside the sealing device 21 flows into the space 38 through another part of the gap 36. do. The air flowing into the interior of the space 38 facilitates the outflow of water from the space 38. Further, the possibility that the interior of the space 38 becomes negative pressure and the lips 24C, 24D, and 24E deform unexpectedly is reduced.

Since each water discharge protrusion 40 is inclined with respect to the flange portion 34B so that the tip thereof is located radially outward from the base, water that has entered the space 38 can be promptly discharged. For example, even if water droplets WD adhere to the lower part of the water discharge protrusion 40 in FIG. 4 when the second seal member 26 stops rotating, the water droplets WD will flow along the inclined water discharge protrusion 40 and fall. . In this embodiment, the fallen water droplet WD is received by the side lip 24E, but since the side lip 24E extends radially outward and is easily deformed as described above, the tip of the side lip 24E and the flange portion 34B It is easy to pass through the gap between and be discharged from the space 38.

Further, each water discharge protrusion 40 has a spiral shape when viewed from a direction perpendicular to the flange portion 34B, and the diameter gradually increases as it progresses in a direction opposite to the main rotation direction R. Therefore, water that has entered the space 38 is quickly discharged along the spiral water discharge protrusion 40 as the second seal member 26 rotates in the main rotation direction R.

Since each water discharge protrusion 40 is a thin plate, the volume of the water discharge protrusion 40 within the space 38 is small. In other words, a plurality of water discharge protrusions 40 that become an obstacle to foreign matter entering the space 38 can be arranged so as to overlap in the radial direction. Therefore, even if foreign matter enters the space 38, there is little risk that the foreign matter will reach the dust lip 24D.

A plurality of water drainage protrusions 40 protrude into the space 38 between the annular portion 24B of the first seal member 24 and the flange portion 34B of the second seal member 26. Therefore, as is clear from FIGS. 2 and 4, the plurality of water discharge protrusions 40 are arranged within the maximum diameter of the first sealing member 24. Therefore, there is no need to enlarge the sealing device 21 and hence the hub bearing 1.

5 and 6 show a modification of this embodiment. In this modification, the second seal member 26 supports a plurality of water discharge protrusions 45 that protrude toward the annular portion 24B of the first seal member 24. These water discharge protrusions 45 have the same shape and size, and are arranged at equal angular intervals in the circumferential direction. These water discharge protrusions 45 project into the radially inner compartment of the space 38 . The water discharge protrusion 45 plays the role of discharging water from the space 38. The water discharge protrusion 45 can also be called a water discharge blade. The plurality of water discharge protrusions 45 are integrally attached to an elastic ring 42 fixed to the outboard side surface of the flange portion 34B of the rigid ring 34 of the second seal member 26.

Each water discharge protrusion 45 has a base fixed to the second seal member 26, which is a rotating seal member, and a distal end separated from the base, and the distal protrusion 45 is arranged so that the distal end is located radially outward from the base. , is inclined with respect to the flange portion 34B. Each water discharge protrusion 45 is a thin plate and has two inclined surfaces 45a and 45b. Surface 45a is a radially outer surface, and surface 45b is a radially inner surface.

In this modification, as shown in FIG. 6, each water discharge protrusion 45 has a rectangular shape when viewed from a direction perpendicular to the flange portion 34B, and is inclined with respect to the circumferential direction of the second seal member 26. ing. The inclination direction of each water discharge protrusion 45 is a direction that gradually approaches the center of the second seal member 26 as it advances in the main rotation direction R. Therefore, even if foreign matter enters the space 38, the foreign matter is quickly discharged along the water discharge protrusion 45 as the second seal member 26 rotates in the main rotation direction R.

FIG. 7 shows a second seal member 26 according to another modification of the embodiment. In this modification, the main rotation direction R is opposite to that in FIG. 6, and the direction of inclination of each water discharge protrusion 45 is opposite to that in FIG. 6 when viewed from the direction perpendicular to the flange portion 34B. Other features are the same as the modifications of FIGS. 5 and 6.

Although not shown, when the main rotation direction R of the spiral water discharge protrusion 40 shown in FIG. 3 is opposite to that shown in FIG. 3, it is preferable that the direction of the spiral is reversed to that shown in FIG.

FIG. 8 shows a second seal member 26 according to another modification of the embodiment. In this modification, water discharge protrusions 45 shown in FIG. 6 and water discharge protrusions 45 shown in FIG. 7 are arranged alternately in the circumferential direction on the flange portion 34B. Therefore, no matter which direction the second seal member 26 rotates, foreign matter that has entered the space 38 is quickly discharged from the space 38. Other features are the same as the modifications of FIGS. 5 and 6.

9 and 10 show still another modification of the embodiment. In this modification, each water discharge protrusion 50 is a thin plate extending along the radial direction of the second seal member 26, and has a rectangular shape when viewed from a direction perpendicular to the flange portion 34B. Since each water discharge protrusion 50 extends along the radial direction of the second seal member 26, foreign matter that has entered the space 38 can be quickly removed from the space 38 no matter which direction the second seal member 26 rotates. is discharged.

Each water discharge protrusion 50 has a base portion fixed to the second seal member 26, which is a rotating seal member, and a tip portion separated from the base portion, with the tip portion being located radially outward than the base portion. , is inclined with respect to the flange portion 34B. Each water discharge protrusion 50 has two inclined end surfaces 50a and 50b. The end surface 50a is a radially outer end surface, and the end surface 50b is a radially inner end surface. Other features are the same as the modifications of FIGS. 5 and 6.

Second Embodiment The first embodiment described above relates to the sealing device 21 on the inboard side of the hub bearing 1. A second embodiment of the present invention relates to a sealing structure including a sealing device 20 on the outboard side of the hub bearing 1.

As shown in FIG. 11, the sealing device (sealing member) 20 is disposed in a gap between the outboard side end 8A of the outer ring 8 of the hub bearing 1 and the hub 4 of the hub bearing 1. Specifically, the sealing device 20 includes a cylindrical end 8A on the outboard side of the outer ring 8 of the hub bearing 1, an outer circumferential surface 4A of the cylindrical portion of the hub 4 of the hub bearing 1 near the balls 10, and a hub It is arranged in a space surrounded by a flange surface 4B that extends radially outward from the outer circumferential surface 4A of No. 4, and an arcuate surface 4C that connects the outer circumferential surface 4A and the flange surface 4B. The flange surface 4B is the inboard side surface of the outboard side flange 18. Although the sealing device 20 is annular, only its left-hand portion is shown in FIG.

The sealing device 20 is a composite structure having a resilient ring 164 and a rigid ring 165. The elastic ring 164 is made of an elastic material, such as an elastomer. Rigid ring 165 is made of a rigid material, such as metal, and reinforces elastic ring 164. A portion of the rigid ring 165 is embedded in the elastic ring 164 and is in close contact with the elastic ring 164.

Elastic ring 164 has a cylindrical portion 164A, an inclined connecting portion 164B, an annular portion 164C, and lips 172, 174, 176. The cylindrical portion 164A is fitted into the inner circumferential surface of the end portion 8A of the outer ring 8 in an interference fit manner (that is, press-fitted). The inclined connecting portion 164B is arranged radially inside the cylindrical portion 164A. The annular portion 164C connects the cylindrical portion 164A and the inclined connecting portion 164B. The lips 172, 174, 176 extend from the inclined connecting portion 164B towards the hub 4 of the hub bearing 1.

The annular portion 164C has an annular shape and extends radially inward from one end of the cylindrical portion 164A toward the outer circumferential surface 4A of the cylindrical portion of the hub 4 so as to be perpendicular to the central axis Ax of the hub bearing 1. It has spread. Further, the annular portion 164C faces the flange surface 4B of the outboard side flange 18. In this embodiment, a surface 164E of the annular portion 164C facing the flange surface 4B is parallel to the flange surface 4B.

In this embodiment, the inclined connecting portion 164B extends diagonally from the annular portion 164C toward the radial inner side and inboard side, is bent, and is further radially perpendicular to the central axis Ax of the hub bearing 1. Extending inward.

Each of the lips 172, 174, and 176 is formed only from an elastic material, and is a thin plate-shaped ring extending from the inclined connecting portion 164B, and the tip of each lip contacts the hub 4. While the sealing device 20 is attached to a fixed outer ring 8, the hub 4 rotates so that the lips 172, 174, 176 slide relative to the hub 4.

The lip 172 is a radial lip, a grease lip, and extends from the innermost edge of the inclined connecting portion 164B toward the cylindrical portion of the hub 4 near the ball 10. The tip of the radial lip 172 is a cylindrical lip. It contacts the outer circumferential surface 4A of the part. The radial lip 172 extends radially inward and toward the inboard side, and mainly serves to prevent lubricant from flowing out from inside the hub bearing 1 .

The lips 174, 176 extend laterally (outboard side) and radially outward from the inclined connecting portion 164B. The lip 174 is an axial lip or a side lip, and extends toward the flange surface 4B of the hub 4, and the tip of the axial lip 174 contacts the flange surface 4B or the circular arc surface 4C. The lip 176 is called an axial lip or an intermediate lip, and extends toward the arcuate surface 4C, and the tip of the intermediate lip 176 contacts the arcuate surface 4C. The lips 174 and 176 are dust lips that mainly serve to prevent foreign matter from flowing into the hub bearing 1 from the outside. The intermediate lip 176 has a backup function of blocking foreign matter that has passed through the axial lip 174 and flowed in.

Rigid ring 165 has a cylindrical portion 165A, an annular portion 165B, a connecting portion 165C, and an annular portion 165D. The cylindrical portion 165A is fitted into the inner peripheral surface of the end portion 8A of the outer ring 8. The annular portion 165B is arranged radially inside the cylindrical portion 165A, and is arranged perpendicular to the central axis Ax of the hub bearing 1. The connecting portion 165C connects the cylindrical portion 165A and the annular portion 165B. When the rigid ring 165 is fitted into the inner peripheral surface of the end portion 8A of the outer ring 8, the cylindrical portion 165A is compressed radially inward by the end portion 8A and elastically deforms. FIG. 11 shows cylindrical portion 165A in a compressed state.

The cylindrical portion 165A of the rigid ring 165 and the cylindrical portion 164A of the elastic ring 164 constitute a mounting portion 166 that is fitted into the inner peripheral surface of the end portion 8A of the outer ring 8. The connecting portion 165C of the rigid ring 165 is in close contact with the cylindrical portion 164A of the elastic ring 164, and the annular portion 165B is in close contact with the annular portion 164C of the elastic ring 164.

The annular portion 165D is in close contact with the inclined connecting portion 164B of the elastic ring 164. The annular portion 165D has a bent shape substantially similar to the shape of the bent inclined connecting portion 164B.

In this embodiment, an annular gap 180 is provided between the end portion 8A of the outer ring 8 and the flange surface 4B of the hub 4. Foreign matter may enter the space 182 between the annular portion 164C and the flange surface 4B of the sealing device 20 (the space between the surface 164E of the annular portion 164C and the flange surface 4B) through the gap 180. Conversely, foreign matter within space 182 can be discharged through gap 180.

In this embodiment, a plurality of water discharge protrusions 40 are supported on the outboard side flange 18 of the hub 4 and project toward the annular portion 164C of the sealing device 20. These water discharge protrusions 40 have the same shape and size, and are arranged at equal angular intervals in the circumferential direction. These water discharge projections 40 project into the space 182.

The plurality of water discharge protrusions 40 are integrally attached to an elastic ring 42 fixed to the outboard side flange 18. That is, each water discharge protrusion 40 is a part of the elastic ring 42. Water drainage protrusion 40 and elastic ring 42 are formed from an elastomeric material.

However, the plurality of water discharge protrusions 40 may be integrally attached to the outboard side flange 18 of the sealing device 20. That is, the water discharge protrusion 40 may be a part of the outboard side flange 18. In this case, the water discharge protrusion 40 is made of the same rigid material as the outboard flange 18, for example a metal material.

Each water discharge protrusion 40 has a base portion fixed to the second seal member 26, which is a rotating seal member, and a tip portion spaced apart from the base portion, such that the tip portion is located radially outward than the base portion. , is inclined with respect to the flange surface 4B.

The water discharge protrusion 40 of the second embodiment may be any type of water discharge protrusion 40, 45, or 50 of the first embodiment or the modified example.

As mentioned above, foreign matter (including water and dust) may enter the space 182 between the annular portion 164C of the seal 20 and the outboard flange 18 of the hub 4. However, a plurality of water discharge protrusions 40 protrude into the space 182, and as the hub 4 and outer ring 8 rotate relative to each other, water in the space 182 splashes onto the water discharge protrusions 40 supported by the rotating member. and is promptly discharged from the space 182. Therefore, the sealed structure has a high ability to protect the sealed object from water. Moreover, the deterioration of the sealing device 20, which is accelerated by the presence of water (including muddy water or salt water), is reduced. Since the gap 180 is annular, water flows out from the space 182 through a part of the gap 180, while air outside the sealing device 20 flows into the interior of the space 182 through another part of the gap 180. do. Air flowing into the space 182 facilitates the outflow of water from the space 182. Furthermore, the possibility that the lips 174, 176 will deform unexpectedly due to negative pressure inside the space 182 is reduced.

Since each water discharge protrusion 40 is inclined with respect to the flange surface 4B so that the tip portion is located radially outward from the base portion, water that has entered the space 38 can be promptly discharged.

FIG. 12 shows a sealing structure according to a modification of the second embodiment. In this modification, a rotary seal member 167 that rotates together with the hub 4 is fixed around the hub 4, although this is not essential. Rotary seal member 167 is formed from a rigid material, such as metal. Although the sealing device 20 and rotary seal member 167 are annular, only their left side portions are shown in FIG.

The sealing device 20 is a composite structure having a resilient ring 168 and a rigid ring 169. Elastic ring 168 is made of an elastic material, such as an elastomer. Rigid ring 169 is made of a rigid material, such as metal, and reinforces elastic ring 168.

A portion of the rigid ring 169 is embedded in the elastic ring 168 and is in close contact with the elastic ring 168. The portion of the rigid ring 169 having a U-shaped cross section is fitted (that is, press-fitted) into the inner circumferential surface of the end portion 8A of the outer ring 8 in an interference fit manner.

Elastic ring 168 has an annular portion 168A, a sloped connecting portion 168B, and lips 172,174. The annular portion 168A has an annular shape and is brought into contact with the end surface of the end portion 8A of the outer ring 8, and is perpendicular to the central axis Ax of the hub bearing 1. It expands radially inward towards. Further, the annular portion 168A faces the flange surface 4B of the outboard side flange 18.

The inclined connecting portion 168B is arranged radially inward of the annular portion 168A. In this modification, the inclined connecting portion 168B extends obliquely from the annular portion 168A toward the radially inward and inboard side, is bent, and is further radially perpendicular to the central axis Ax of the hub bearing 1. Extending inward.

The lips 172, 174 extend from the inclined coupling portion 168B towards the hub 4 of the hub bearing 1. Each of the lips 172 and 174 is formed only from an elastic material, and is a thin plate-shaped ring extending from the inclined connecting portion 168B, and the tip of each lip contacts the rotary seal member 167. While the sealing device 20 is attached to the fixed outer ring 8, the hub 4 rotates so that the lips 172, 174 slide against the rotating seal member 167 fixed to the hub 4. The lip 172 is a radial lip, that is, a grease lip, and extends radially inward and toward the inboard side, and mainly serves to prevent lubricant from flowing out from inside the hub bearing 1. The lip 174 is a dust lip that mainly serves to prevent foreign matter from flowing into the hub bearing 1 from the outside.

In this modification, an annular gap 180 is provided between the end portion 8A of the outer ring 8 and the flange surface 4B of the hub 4. Foreign matter may enter the space 182 between the annular portion 168A and the flange surface 4B of the sealing device 20 (in this modification, the space between the annular portion 168A and the rotary seal member 167) through the gap 180. Conversely, foreign matter within space 182 can be discharged through gap 180.

In this modification, a plurality of water discharge projections 40 are supported on the outboard side flange 18 of the hub 4 and project toward the annular portion 168A of the sealing device 20. These water discharge protrusions 40 have the same shape and size, and are arranged at equal angular intervals in the circumferential direction. These water discharge projections 40 project into the space 182.

In this modification, the plurality of water discharge protrusions 40 are integrally attached to an elastic ring 186 attached to the outboard side flange 18. Water drainage protrusion 40 and elastic ring 186 are formed from an elastic material, such as an elastomeric material. The water discharge protrusion 40 and the elastic ring 186 may be formed from a resin material, an elastomer material, a resin material containing at least one of metal powder and ceramic powder, or an elastomer material containing at least one of metal powder and ceramic powder. . When the water discharge protrusion 40 and the elastic ring 186 contain at least one of metal powder and ceramic powder, the water discharge protrusion 40 and the elastic ring 186 have high durability against impact from hard foreign objects and high wear resistance. .

The elastic ring 186 covers the outer edge of the rotary seal member 167 and further covers a part of the surface of the rotary seal member 167 on the flange surface 4B side. An annular seal projection 188 is formed in this portion of the elastic ring 186. The annular seal protrusion 188 is sandwiched between the rotary seal member 167 and the flange surface 4B, and prevents or reduces water from coming into contact with the flange surface 4B. This suppresses the occurrence of rust on the hub 4.

Each of the water discharge protrusions 40 in this modification may be of any type of the water discharge protrusions 40, 45, and 50 in the first embodiment and the modification. Therefore, each water discharge protrusion 40 has a base fixed to the second seal member 26, which is a rotating seal member, and a distal end separated from the base, with the distal end located radially outward from the base. As shown, it is inclined with respect to the flange surface 4B.

The sealing device 20 has an annular outer labyrinth slip 192 . The outer labyrinth slip 192 projects from the annular portion 168A of the elastic ring 168 toward the outboard flange 18 of the hub 4, but does not contact either the hub 4 or the rotating seal member 167. The outer labyrinth slip 192 is radially aligned with the plurality of water discharge protrusions 40 and is arranged radially outward of the plurality of water discharge protrusions 40 .

Other Variations While the invention has been illustrated and described with reference to preferred embodiments of the invention, it will be appreciated by those skilled in the art that variations in form and detail can be made without departing from the scope of the invention as claimed. It will be understood that modifications are possible. Such changes, alterations, and modifications are intended to be included within the scope of this invention.

For example, in the above embodiment, the hub 4 and the inner ring 6, which are the inner members, are rotating members, and the outer ring 8, which is the outer member, is a stationary member. However, the present invention is not limited to the above embodiments, and may be applied to sealing a plurality of members that rotate relative to each other. For example, the inner member may be stationary and the outer member may rotate, or all of these members may rotate. In this case, the water discharge protrusions 40, 45, 50 are supported by rotating members.

The application of the invention is not limited to the sealing of hub bearings 1. For example, the sealing device or sealing structure according to the present invention may also be applied to a differential gear mechanism or other power transmission mechanism of an automobile, a bearing or other support mechanism of a drive shaft of an automobile, a bearing or other support mechanism of a rotating shaft of a pump, etc. can be used.

Although the rigid ring 30 of the sealing device 21 of the first embodiment is a single component, the rigid ring 30 may be replaced with a plurality of rigid rings separated from each other in the radial direction. Although the rigid ring 165 of the sealing device 20 of the second embodiment is a single component, the rigid ring 165 may be replaced by a plurality of rigid rings separated from each other in the radial direction.

Aspects of the invention are also described in the numbered sections below.

Clause 1. A sealing device disposed between an inner member and an outer member that rotate relatively, the sealing device sealing a gap between the inner member and the outer member,
a first seal member attached to the outer member and having an annular portion, the annular portion extending radially inward toward the inner member;
a second seal member attached to the inner member and having a flange portion, the flange portion extending radially outwardly and opposing the annular portion of the first seal member;
A plurality of water discharge protrusions are supported on the rotating seal member of the first seal member and the second seal member, and the plurality of water discharge protrusions are arranged in the annular shape of the first seal member. protruding into a space located between the flange portion and the flange portion of the second sealing member, and arranged in a circumferential direction;
Each water discharge protrusion has a base portion fixed to the rotating seal member and a tip portion spaced apart from the base portion, and is attached to the flange portion such that the tip portion is located radially outward than the base portion. A sealing device characterized by being inclined with respect to the air.

Clause 2. 2. The sealing device according to clause 1, wherein each of the water discharge protrusions has a spiral shape when viewed from a direction perpendicular to the flange portion.

According to this provision, water that has entered the space is quickly discharged along the spiral water discharge protrusion.

Clause 3. an inner member having a cylindrical portion and a flange extending radially outward from the cylindrical portion;
an outer member that rotates relative to the inner member;
a seal member attached to the outer member and having an annular portion, the annular portion extending radially inward toward the cylindrical portion of the inner member and facing the flange of the inner member; Prepare,
A plurality of water discharge protrusions are supported on a rotating member of the inner member and the seal member, and the plurality of water discharge protrusions are arranged between the annular portion of the seal member and the flange of the inner member. They protrude into the space located at and are arranged circumferentially,
Each water discharge protrusion has a base fixed to the rotating member, and a distal end remote from the base, and is arranged relative to the flange such that the distal end is located radially outward from the base. A sealed structure characterized by an inclined slope.

Clause 4. 4. The sealing structure according to clause 3, wherein each of the water discharge protrusions has a spiral shape when viewed from a direction perpendicular to the flange.

According to this provision, water that has entered the space is quickly discharged along the spiral water discharge protrusion.

1 Hub bearing 4 Hub (inner member)
4A Outer peripheral surface of cylindrical part 4B Flange surface 4C Arc surface 6 Inner ring (inner member)
8 Outer ring (outer member)
18 Outboard side flange 20 Sealing device (sealing member)
21 Sealing device 24 First sealing member 24A Cylindrical portion 24B Annular portion 24C Grease lip 24D Dust lip 24E Side lip 26 Second sealing member 34 Rigid ring 34A Sleeve portion 34B Flange portion 36 Gap 38 Space 40, 45, 50 Water discharge Product 164 Budgeting Ring 164A cylindrical part 164b 164B inclined part 164C cylindrical part 165 rigid ring 165A cylindrical part 165B cylindrical part 165C cohesion part 68 Elastic Ring 169 rigidity Ring 168A Annular portion 168B Slanted connecting portion 186 Elastic ring

Claims (9)

A sealing device disposed between an inner member and an outer member that rotate relatively, the sealing device sealing a gap between the inner member and the outer member,
a first seal member attached to the outer member and having an annular portion, the annular portion extending radially inward toward the inner member;
a second seal member attached to the inner member and having a flange portion, the flange portion extending radially outwardly and opposing the annular portion of the first seal member;
The first seal member has a side lip that extends from the annular portion toward the flange portion of the second seal member and contacts the flange portion,
A plurality of water discharge protrusions are supported on the rotating seal member of the first seal member and the second seal member, and the plurality of water discharge protrusions are radially inner than the side lip; and protrude into a space located between the annular portion of the first seal member and the flange portion of the second seal member, and are arranged in a circumferential direction;
Each water discharge protrusion has a base fixed to the rotating seal member, a tip remote from the base , a radially outer first surface, and a radially inner second surface; The sealing device is characterized in that the second surface is inclined with respect to the flange portion such that the tip portion is located radially outward than the base portion. 2. The sealing device according to claim 1, wherein each of the water discharge protrusions has a spiral shape when viewed from a direction perpendicular to the flange portion. each water discharge protrusion has a circumferential length that is greater than a radial length;
The sealing device according to claim 1 or 2, wherein the first surface is inclined with respect to the flange portion so that the tip portion is located radially outward than the base portion. The plurality of water discharge protrusions are supported by the second seal member and extend toward the annular portion of the first seal member.
The sealing device according to any one of claims 1 to 3, characterized in that: an inner member having a cylindrical portion and a flange extending radially outward from the cylindrical portion;
an outer member that rotates relative to the inner member;
a seal member attached to the outer member and having an annular portion, the annular portion extending radially inward toward the cylindrical portion of the inner member and facing the flange of the inner member; Prepare,
The outer member has an end that projects further toward the flange of the inner member than the annular portion of the seal member,
The sealing member has an axial lip extending toward and contacting the inner member,
A plurality of water discharge protrusions are supported on the rotating member of the inner member and the seal member, and the plurality of water discharge protrusions are radially inner than the end portion and radially inner than the axial lip. protruding outward and into a space located between the annular portion of the sealing member and the flange of the inner member, and arranged in a circumferential direction;
Each water discharge protrusion has a base fixed to the rotating member, a tip remote from the base, a radially outer first surface, and a radially inner second surface ; The sealing structure is characterized in that the second surface is inclined with respect to the flange so that the tip portion is located radially outward than the base portion. an inner member having a cylindrical portion and a flange extending radially outward from the cylindrical portion;
an outer member that rotates relative to the inner member;
a seal member attached to the outer member and having an annular portion, the annular portion extending radially inward toward the cylindrical portion of the inner member and opposing the flange of the inner member;
Equipped with
The sealing member has an annular outer labyrinth lip that protrudes toward the flange of the inner member than the annular portion, and a dust lip that extends toward the inner member and contacts the inner member,
A plurality of water discharge protrusions are supported on the rotating member of the inner member and the seal member, and the plurality of water discharge protrusions are radially inner than the outer labyrinth slip and radially inner than the dust lip. projecting outward in the direction and into a space located between the annular portion of the sealing member and the flange of the inner member, and arranged in a circumferential direction;
Each water discharge protrusion has a base fixed to the rotating member, a tip remote from the base, a radially outer first surface, and a radially inner second surface; The second surface is inclined with respect to the flange such that the tip portion is located radially outer than the base portion.
Sealed structure characterized by: 7. The sealing structure according to claim 5 , wherein each of the water discharge protrusions has a spiral shape when viewed from a direction perpendicular to the flange. each water discharge protrusion has a circumferential length that is greater than a radial length;
8. The first surface is inclined with respect to the flange so that the tip portion is located radially outward than the base portion. Sealed structure. The plurality of water discharge protrusions are supported by the inner member and extend toward the annular portion of the seal member.
The sealing structure according to any one of claims 5 to 8.

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