KR101961643B1 - A Rolling Bearing with Sealing Device - Google Patents

Abstract

A rolling bearing having a sealing mechanism according to the present invention comprises a ring-shaped outer ring having an outer ring raceway formed therein, a ring-shaped inner ring positioned radially inward of the outer ring and having an inner ring raceway, And a plurality of pockets spaced apart from each other in the circumferential direction are formed between the inner ring and the outer ring so that the rolling bodies are disposed in the respective pockets to maintain the circumferential spacing of the rolling elements And a sealing mechanism provided in an opening formed between the outer ring and the inner ring;
Wherein an outer ring sealing mechanism groove is formed in the widthwise surface of the outer ring and extends along the circumferential direction, the sealing mechanism including an annular sealing mechanism body and a radially outer end portion of the sealing mechanism body, Made of wealth;
Wherein the sealing mechanism is pushed inward in the axial direction so that the sealing mechanism engaging portion is inserted into the groove of the outer ring sealing mechanism to be coupled to the outer ring.

Description

[0001] A Rolling Bearing with Sealing Device [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rolling bearing, and more particularly, to a rolling bearing provided in an opening between an inner ring and an outer ring to provide a sealing mechanism for protecting rolling elements.

Generally, a rolling bearing is a device for rotatably supporting a shaft by rolling contact using a rolling member such as a ball or a roller.

1 and 2, a rolling bearing 1 has a structure in which a plurality of rolling elements 17 are arranged between an inner ring 11 and an outer ring 13 and a plurality of rolling elements 17 arranged between an inner ring 11 and an outer ring 13, And a shield (15) for covering the rolling element (17) by covering the lateral opening.

In Korean Patent Application Publication No. 2002-0093697 (December 16, 2002), a rolling bearing has been disclosed. FIG. 3 is a partial sectional view showing a conventional rolling bearing having a shield, and FIG. 4 is a partial cross-sectional view showing only an outer ring, an inner ring and a shield in FIG. 3 and 4, a conventional rolling bearing 1 includes a retainer 19 for holding a rolling member 17 provided between an inner ring 11 and an outer ring 13 at a predetermined interval .

The shield 15 is annular and has a radially outer side in a bent and curved plate shape. The shield 15 includes a body portion 153, an insertion portion 151, a tail portion 155, and an inclined portion 152.

The inclined portion 152 is bent at an axially outwardly inclined angle at the radially outer end of the body portion 153. The tail portion 155 is formed to bend inward in the axial direction from the radially inner side of the body portion 153.

4, the insertion portion 151 includes a horizontal portion 154, a vertical portion 156, and a curved portion 158. As shown in FIG. The horizontal portion 154 is bent to be radially outward at the radially outer end of the inclined portion 152. The vertical portion 156 is bent to be axially outward at the end of the horizontal portion 154. The curved portion 158 is curved in an arcuate shape so that its end portion is axially inward at an end portion of the vertical portion 154.

The curved portion 158 is provided radially inwardly to the vertical portion 156. And is formed to be axially inwardly open. The outer diameter of the insertion portion 151 (outer diameter of the shield before assembly) is the outer diameter of the vertical portion 156. The outer diameter of the insertion portion 151 before assembly is smaller than the inner diameter of the guide surface 1311 of the outer ring 13.

The insertion part 151 is formed with a slit 15a extending radially to the end thereof so that curling deformation of the insertion part 151 is facilitated.

The insertion portion 151 is plastically deformed as shown by the dotted line in FIG. 4, while the inclined surface P1 of the punch P is pushed downward and outwardly against the curved portion 158 of the insertion portion 151 And inserted into the shield insertion portion 131 to be assembled.

The vertical portion 156 of the insertion portion 151 after insertion is provided in contact with the seating surface 1317 of the shield insertion portion 131 and one side surface of the curved portion 158 is in contact with the surface facing inward in the axial direction of the guide surface 1311 As shown in FIG. A space is formed between the shielding surfaces 1315 of the outer ring 13 after insertion in the radially outer surface of the curved portion 158 before insertion.

Conventionally, the outer ring 13 is deformed due to a pressing load imposed when the shield 15 is press-fitted, and consequently the concentricity and roundness of the bearing track are deteriorated, causing noise during driving of the bearing and shortening the service life.

The body portion 153 and the tail portion 155 of the shield 15 are deformed axially outwardly in accordance with the state of the insertion portion 151 that is press-fitted into the shield insertion portion 131 of the outer ring 13 after assembly There is a problem that interference with peripheral parts occurs when projecting out of the bearing or interference with the bearing parts occurs when the bearing penetrates into the bearing and foreign matter is easily infiltrated.

Korean Unexamined Patent Publication No. 2002-0093697

The present invention has been made in order to solve the problems of the related art as described above, and it is an object of the present invention to provide a sealing mechanism having a simple shape and easy to manufacture, an outer ring sealing mechanism groove to which a sealing mechanism is coupled, The present invention relates to a rolling bearing having a sealing mechanism capable of manufacturing a precision bearing with a small outer ring heat treatment deformation and capable of preventing deterioration in outer ring raceway quality due to assembly of a sealing mechanism.

A rolling bearing having a sealing mechanism according to the present invention comprises a ring-shaped outer ring having an outer ring raceway formed therein, a ring-shaped inner ring located radially inward of the outer ring and having an inner ring raceway, And a plurality of pockets spaced apart from each other in the circumferential direction are formed between the inner ring and the outer ring so that the rolling bodies are disposed in the respective pockets to maintain the circumferential spacing of the rolling elements And a sealing mechanism provided in an opening formed between the outer ring and the inner ring;

Wherein an outer ring sealing mechanism groove is formed in the widthwise surface of the outer ring and extends along the circumferential direction, the sealing mechanism including an annular sealing mechanism body and a radially outer end portion of the sealing mechanism body, Made of wealth;

And the sealing mechanism is pushed inward in the axial direction so that the sealing mechanism engaging portion is inserted into the groove of the outer ring sealing mechanism to be coupled to the outer ring.

In the above, the outer ring sealing mechanism groove is formed so as to be radially inwardly inclined so as to be located radially inward of the portion where the inner end is opened; And the sealing mechanism engaging portion is inserted in the outer ring sealing mechanism groove and radially inwardly deformed.

In the above, the outer ring sealing mechanism groove is formed so as to be radially outwardly inclined so that the inner end thereof is positioned radially outwardly than the opened portion; And the sealing mechanism engaging portion is inserted in the outer ring sealing mechanism groove and is radially outwardly deformed.

In the above, the sealing mechanism engaging portion is inserted into the groove of the outer ring sealing mechanism, and the inner surface of the sealing mechanism body faces the widthwise surface of the outer ring positioned radially inward of the groove of the outer ring sealing mechanism.

In this case, the outer ring sealing mechanism groove is formed to be deeper than the width, and the sealing mechanism engaging portion is formed by a part of the radially outer end of the sealing mechanism body portion being formed by being axially inwardly bent, ; The angle of inclination of the sealing mechanism engaging portion before assembling with respect to the axial direction is smaller than the inclination angle of the outer ring sealing mechanism groove and inserted into the groove of the outer ring sealing mechanism to be guided and deformed by the outer ring sealing mechanism groove.

In the above, the axial length of the sealing mechanism engaging portion is formed to be larger than the depth of the groove of the outer ring sealing mechanism, and the sealing mechanism engaging portion is inserted into the outer ring sealing mechanism groove so that the sealing mechanism engaging portion is continuously pressed after contacting the end portion of the groove of the outer ring sealing mechanism And the sealing mechanism engaging portion is plastically deformed in the outer ring sealing mechanism groove to be seated in the outer ring sealing mechanism groove.

The sealing mechanism engaging portion is formed with a concave sealing mechanism groove at a position spaced apart from the end portion. When the sealing mechanism engaging portion is pressed against the end of the outer ring sealing mechanism groove, the sealing mechanism groove portion is bent and deformed .

In this case, the sealing mechanism groove is formed on the radially outer side and is formed in the shape of a 'V' in cross section, and the most concave portion of the 'V' shape is bent and the sealing mechanism groove, And the mechanism-engaging end abuts against the outer surface of the outer ring sealing mechanism groove forming the radially outer surface of the outer ring sealing mechanism groove.

The rolling bearing with the sealing mechanism according to the present invention is easy to manufacture due to the simple shape of the sealing mechanism, the outer ring sealing mechanism groove to which the sealing mechanism is coupled is small, the shape is simple, the processing is easy, And it is possible to prevent deterioration of the roundness of the outer ring track due to the assembly of the sealing mechanism.

1 is a perspective view showing a conventional rolling bearing,
FIG. 2 is a perspective view of a conventional rolling bearing partially cutaway,
3 is a cross-sectional view showing a conventional rolling bearing having a shield,
4 is a partial sectional view showing only the outer ring, the inner ring and the shield portion in FIG. 3,
5 is a sectional view showing a rolling bearing having a sealing mechanism according to the present invention,
6 is a cross-sectional view showing a sealing mechanism of a rolling bearing having a sealing mechanism according to the present invention,
7 is a cross-sectional view showing a modified example of a rolling bearing having a sealing mechanism according to the present invention,
8 is an enlarged cross-sectional view of part A of Fig. 7,
9 is a cross-sectional view showing a modified example of a rolling bearing having a sealing mechanism according to the present invention.

Hereinafter, a rolling bearing having a sealing mechanism according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 5 is a sectional view showing a rolling bearing having a sealing mechanism according to the present invention, FIG. 6 is a sectional view showing a sealing mechanism of a rolling bearing having a sealing mechanism according to the present invention, and FIG. FIG. 8 is an enlarged cross-sectional view of portion A of FIG. 7, and FIG. 9 is a cross-sectional view of a rolling bearing having a sealing mechanism according to the present invention Sectional view.

In Fig. 5, the horizontal direction will be referred to as "axial direction" and the vertical direction will be referred to as "radial direction".

5, a rolling bearing 100 having a sealing mechanism according to the present invention includes an outer ring 110, an inner ring 120, a rolling member 130, a retainer 140, (150).

The outer ring 110 is formed in a ring shape. A concave outer ring raceway 111 is formed inside the outer ring 110 in the radial direction. On both sides in the axial direction about the outer ring raceway 111, an inner ring inner diameter portion 113 is formed.

And outer ring sealing mechanism grooves 115 are formed on both widthwise sides of the outer ring 110 in the axial direction. The outer ring sealing mechanism groove 115 extends in the circumferential direction and is formed concavely. The outer ring sealing mechanism groove 115 is formed in a deeper axial depth than the width. The outer ring sealing mechanism groove 115 is formed so as to be radially inwardly inclined so as to be located radially inward of the portion where the axially inner end portion is opened.

The outer ring sealing mechanism groove 115 may be formed so as to be radially outwardly inclined so as to be radially outward of the portion where the axially inner end portion is opened.

The width of the outer ring 110 located radially inward of the outer ring sealing mechanism groove 115 is located axially inwardly away from the width of the outer ring 110 located radially outward of the outer ring sealing mechanism groove 115 . The width of the outer ring 110 located radially inward of the outer ring sealing mechanism groove 115 is formed axially inwardly away from the width of the outer ring 110 located radially outward of the outer ring sealing mechanism groove 115 The axially outer portion 1151a of the outer ring sealing mechanism groove outer surface 1151 forming the radially outer surface of the outer ring sealing mechanism groove 115 is exposed. A sealing mechanism (150) is provided in contact with the width of the outer ring (110) located radially inward of the outer ring sealing mechanism groove (115).

The inner ring 120 is provided in a ring shape. The inner ring 120 is concentric with the outer ring 110 and is located radially inward of the outer ring 110. A concave inner ring raceway 121 is formed on the outer side of the inner ring 120 in the radial direction. On both sides in the axial direction about the inner ring raceway 121, an inner ring outer diameter portion 123 is formed. As shown in FIG. 7, the inner ring outer diameter portion 123 may have a radially outwardly concave groove 123a. The groove 123a extends along the circumferential direction.

The rolling member 130 is provided in a ball shape. The rolling members 130 are spaced apart from each other in the circumferential direction between the outer ring raceway 111 and the inner ring raceway 121.

The retainer 140 is provided between the inner ring 120 and the outer ring 110. The retainer 140 has a plurality of pockets spaced apart in the circumferential direction, and the rolling members 130 are positioned in the respective pockets to maintain a circumferential spacing of the rolling members 130.

The sealing mechanism 150 is formed in an annular shape. The sealing mechanism 150 is provided in an opening formed between the outer ring 110 and the inner ring 120.

5 and 6, the sealing mechanism 150 includes a sealing mechanism body 151, a sealing mechanism engaging portion 153, and a sealing mechanism bending portion 155.

The sealing mechanism body 151 is formed in an annular shape.

The sealing mechanism engaging portion 153 is provided at a radially outer end of the sealing mechanism body 151. The sealing mechanism engaging portion 153 is provided to be inclined from the radially outer end of the sealing mechanism body 151 to be axially inwardly and radially inwardly bent. The sealing mechanism engaging portion 153 is formed to have a longer axial length than a thickness in a cross section.

The inclined angle of the sealing mechanism engaging portion 153 with respect to the axial direction before the sealing engaging portion 153 is assembled into the outer ring sealing mechanism groove 115 is formed to be smaller than the inclination angle of the outer ring sealing mechanism groove 115 . The sealing engagement portion 153 is inserted into the outer ring sealing mechanism groove 115 while being guided and deformed by the outer ring sealing mechanism groove outer surface 1151 of the outer ring sealing mechanism groove 115.

The sealing engagement portion 153 may be formed with a slit 157. The slit 157 extends axially from the end of the sealing engagement portion 153. The slit 157 may extend to the sealing mechanism body 151. The slits 157 are formed in a plurality of distances along the circumferential direction. The slit 157 prevents the sealing mechanism body 151 from being deformed when the sealing mechanism 150 is assembled.

The sealing mechanism bend portion 155 is provided at a radially inner end of the sealing mechanism body 151. The sealing mechanism bending portion 155 is provided to be axially inwardly bent from a radially inward end of the sealing mechanism main body 151.

When the rolling bearing 100 is assembled, the sealing mechanism 150 is pushed axially inward and the sealing mechanism engaging portion 153 is inserted into the outer ring sealing mechanism groove 115, Lt; / RTI >

The sealing mechanism body 151 has an axially inner surface facing the width of the outer ring 110 positioned radially inward of the outer ring sealing mechanism groove 115, And is provided so as to face and face the outer diameter portion 123.

The sealing mechanism engaging portion 153 is formed in the outer ring sealing mechanism groove 115 so that when the axially inner end portion of the outer ring sealing mechanism groove 115 is formed so as to be radially inward of the portion radially inward, The engaging portion 153 is inserted and radially inwardly deformed and assembled.

When the axially inner end of the outer ring sealing mechanism groove 115 is formed so as to be radially outwardly inclined so as to be positioned radially outward of the opened portion, the sealing mechanism engaging portion 153 is inserted into the outer ring sealing mechanism groove 115 Radially outwardly deformed and assembled.

A modified example of the rolling bearing 100 having the sealing mechanism 150 according to the present invention will be described below.

As shown in FIG. 7, an outer ring sealing mechanism groove 115 is formed on the outer side in the axial direction of the outer ring 110. The outer ring sealing mechanism groove 115 is formed to be concave extending along the circumferential direction. The width of the outer ring sealing mechanism groove 115 is formed to be larger than the thickness of the sealing mechanism engaging portion 153.

7 to 9, the sealing mechanism engaging portion 153 is formed to extend axially inwardly from the sealing mechanism body 151. As shown in Fig. The axial length of the sealing mechanism engaging portion 153 is formed to be larger than the depth of the outer ring sealing mechanism groove 115.

The sealing mechanism engaging portion 153 is formed with a sealing mechanism groove 153-2 on the radially outer side. The sealing mechanism groove 153-2 is recessed at a position spaced apart from the end of the sealing mechanism engaging portion 153. [ The sealing mechanism groove 153-2 extends in the circumferential direction. The end surface of the sealing mechanism groove 153-2 is formed in a V shape.

An inclined surface 153-4 may be further formed in the sealing mechanism engaging end portion 153-1 which is an axially inner end portion of the sealing mechanism groove 153-2. The inclined surface 153-4 extends along the circumferential direction on the inner diameter side of the sealing mechanism engaging end portion 153-1. The inclined surface 153-4 is provided in contact with the outer ring sealing surface outer diameter surface 1151 when the outer ring sealing mechanism groove 115 is inserted.

The sealing engagement portion 153 may be formed with a slit 157. The slit 157 extends axially from the end of the sealing engagement portion 153. The slit 157 may extend to the sealing mechanism body 151. The slits 157 are formed in a plurality of distances along the circumferential direction. The slit 157 prevents the sealing mechanism body 151 from being deformed when the sealing mechanism 150 is assembled.

When the rolling bearing (100) is assembled, the sealing mechanism (150) is pressed and assembled in the axial direction of the sealing mechanism body (151).

The sealing mechanism engaging portion 153 of the sealing mechanism 150 is inserted in contact with the inner ring surface 1153 of the outer ring sealing mechanism groove forming the radially inner surface of the outer ring sealing mechanism groove 115. The sealing mechanism engaging portion 153 is inserted into the outer ring sealing mechanism groove 115 and continues to be pressed after the sealing mechanism engaging portion 153 contacts the end portion of the outer ring sealing mechanism groove 115 so that the sealing mechanism engaging portion 153 And is plastically deformed in the outer ring sealing mechanism groove 115 to be seated in the outer ring sealing mechanism groove 115 and assembled.

When the sealing mechanism engaging portion 153 is pressed against the end of the outer ring sealing mechanism groove 115, the sealing mechanism groove 153-2 is bent and deformed and assembled. The sealing mechanism groove 153-2 is bent at the most concave portion of the 'V' shape.

The inclined surface 153-4 formed on the sealing mechanism engaging end portion 153-1 at the time of assembling abuts against the outer diameter surface 1151 of the outer ring sealing mechanism and the outer diameter sealing surface groove outer surface 1151 is pressed radially outward . The bending portion of the sealing mechanism engaging portion 153 where the sealing mechanism groove 153-2 is located abuts on the inner ring surface 1153 of the outer ring sealing mechanism and the inner ring surface 1153 of the outer ring sealing mechanism is pressurized radially inward do.

Since the outer ring sealing mechanism groove 115 is pressurized radially inward and outwardly by the sealing mechanism engaging portion 153 that is bent and deformed, the inner ring sealing mechanism groove 115 is tightly coupled, Deterioration in quality is prevented.

Although the rolling bearing with the sealing mechanism according to the present invention has been described with reference to the embodiments shown in the drawings, it is merely an example, and various modifications and equivalent embodiments can be made by those skilled in the art I will understand. Accordingly, the scope of the true technical protection should be determined by the technical idea of the appended claims.

100: Rolling bearing with sealing mechanism
110: outer ring 111: outer ring raceway
113: Inner ring inner diameter portion 115: Outer ring sealing mechanism groove
120: inner ring 121: inner ring raceway
123: inner ring outer diameter portion 130: rolling body
140: retainer 150: sealing mechanism
151: sealing mechanism body 153: sealing mechanism engaging portion
155: sealing mechanism bending portion 157: slit

Claims (6)

A ring-shaped inner ring 120 positioned radially inward of the outer ring 110 and having an inner ring raceway 121 formed thereon; A plurality of pockets formed between the inner ring 120 and the outer ring 110 and spaced apart in the circumferential direction are formed between the inner ring 120 and the inner ring raceway 121, A retainer 140 for retaining the rolling elements 130 in the respective pockets and maintaining a distance in the circumferential direction of the rolling elements 130 and a sealing ring 140 provided in an opening formed between the outer and inner rings 110 and 120, Mechanism 150;
The outer ring 110 is formed with an outer ring sealing mechanism groove 115 which is concave and extends along the circumferential direction. The sealing mechanism 150 includes an annular sealing mechanism body 151, the sealing mechanism body 151, And an axially inwardly facing sealing mechanism engaging portion (153) provided at the radially outer end of the engaging portion
The sealing mechanism 150 is pushed inward in the axial direction so that the sealing mechanism engaging portion 153 is inserted into the outer ring sealing mechanism groove 115 and is engaged with the outer ring 110;
The axial length of the sealing mechanism engaging portion 153 is formed to be larger than the depth of the outer ring sealing mechanism groove 115 so that the sealing mechanism engaging portion 153 is inserted into the outer ring sealing mechanism groove 115, The sealing mechanism engaging portion 153 is plastically deformed in the outer ring sealing mechanism groove 115 to be seated in the outer ring sealing mechanism groove 115 while being continuously pressed even after the piston 153 is in contact with the end of the outer ring sealing mechanism groove 115 A rolling bearing (100) with a sealing mechanism. delete delete delete delete The sealing mechanism according to claim 1, wherein the sealing mechanism engaging portion (153) is formed with a concave sealing mechanism groove (153-2) at a position spaced apart from the end portion, and the sealing mechanism engaging portion (153) And a portion of the sealing mechanism groove (153-2) is bent and deformed when being pressed against the end of the rolling mechanism (100).

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