KR102286932B1 - A Rolling Bearing equipped with Half-Wave Type Pre-Load Spring - Google Patents

Abstract

A rolling bearing with a preload spring according to the present invention includes a bearing and a preload spring coupled to the bearing; The preload spring includes a spring body in which mountains and valleys are repeated, and a plurality of spring coupling protrusions extending outward from the outer side of the spring body and spaced apart from each other; the bearing includes an inner ring, an outer ring, and a plurality of rolling elements arranged in a circumferential direction between the outer ring and the inner ring; An outer ring is inserted between the spring coupling protrusions, and the spring body relates to a rolling bearing with a preload spring, characterized in that it is provided to face the width of one side of the outer ring.

Description

{A Rolling Bearing equipped with Half-Wave Type Pre-Load Spring}

The present invention relates to a rolling bearing equipped with a preload spring, and more particularly, to prevent noise or vibration due to relative motion by coupling the preload spring to the outer ring of the bearing, and to facilitate preload management of the accumulated tolerance between the bearing and the preload spring. It relates to a rolling bearing equipped with a spring.

In general, the rotating shaft of various rotating bodies, such as a motor, is supported by a bearing. These bearings are one of the important parts that determine the performance and lifespan of the motor, and high rigidity is required to reduce vibration and noise. do.

1 is a view showing the bearing support of the motor, a rotating shaft 10 is fitted in the central portion of the rotor (not shown) rotatably inserted into the stator, and one end of the rotating shaft 10 smoothly rotates the rotor. The bearing 12 is press-fitted and fixed in order to rotate the bearing 12 , and the bearing 12 is accommodated in the bearing support 16 integrally formed under the motor housing 14 .

A plain washer 18 made of a fiber material is inserted into the bottom surface of the bearing support 16 as shown in FIG. 2 , and the bearing 12 and the plain washer 18 accommodated in the bearing support 16 are A preload spring 20 for preloading the bearing 12 is interposed therebetween.

The preload spring 20 is annular and has three to four peaks 20a and troughs 20b repeatedly formed in the circumferential direction to form a wavy shape and has elasticity in the plane direction. The portion (20a) is in surface contact with the outer ring of the bearing 12 from the lower portion, and the corrugated trough (20b) portion is in surface contact with the plain washer (18).

The conventional bearing preload spring configured in this way press-fits and fixes the bearing 12 to one end of the rotating shaft 10 press-fitted into the rotor, and then the plain washer 18 and the preload spring 20 and the bearing in the bearing support 16. (12) is inserted sequentially. At this time, the preload spring 20 is the outer ring of the bearing 12 and the plain washer 18 by the pressing force of the bearing 12 in which the corrugated mountain 20a and the valley 20b are inserted into the bearing support 16, respectively. It retains elasticity that expands and contracts in the central direction of the rotary shaft 10 by being pressed, and a preload corresponding to this elasticity acts on the bearing 12 in the axial direction, thereby minimizing vibration and noise generated during rotation of the rotor. will be.

However, as described above, since it is necessary to insert the plain washer and the preload spring for preloading the bearing in the bearing support, the number of parts increases, and it is difficult to manage the accumulated tolerance between the preload spring and the outer ring of the bearing. There was a problem in that friction vibration and noise were generated during rotation of the rotor as they contacted, thereby degrading the performance of the bearing.

Republic of Korea Registration No. 20-0187350 Registered Utility Model Gazette

The present invention has been proposed to solve the problems of the prior art, and it is easy to manage the tolerance between the bearing and the preload spring, and by coupling the preload spring to the outer ring of the bearing, noise or vibration due to relative motion is prevented, and in the assembly process An object of the present invention is to provide a rolling bearing provided with a preload spring that reduces the assembly time of parts.

A rolling bearing with a preload spring according to the present invention includes a bearing and a preload spring coupled to the bearing;

The preload spring includes a spring body in which mountains and valleys are repeated, and a plurality of spring coupling protrusions extending outward from the outer side of the spring body and spaced apart from each other;

the bearing includes an inner ring, an outer ring, and a plurality of rolling elements arranged in a circumferential direction between the outer ring and the inner ring;

An outer ring is inserted between the spring coupling protrusions, and the spring body provides a rolling bearing with a preload spring, characterized in that it is provided to face the width of one side of the outer ring.

In the above, the outer ring is formed with a plurality of outer ring engaging portions concave on the outer diameter side on one side in the axial direction and spaced apart along the circumferential direction, and the spring engaging projection is inserted into the outer ring engaging portion.

In the above, the outer ring coupling portion is formed concavely on the edge portion of one side in the width direction on the outer diameter side of the outer ring, the first surface facing the axial direction, the second surface is located radially inside the first surface and faces outward in the radial direction , having third surfaces located on both sides in the circumferential direction;

The spring engaging projection is formed of an extension extending radially outwardly from the spring body, and a bent portion bent toward the outer ring at an end of the extension;

The bent portion is inserted between the third surfaces so that the end faces the first surface, and the second surface is positioned radially inside the bent portion.

In the above, when the outer ring is inserted between the spring engaging projections, the bent portion is characterized in that the outward deformation in contact with the second surface.

In the above, the outer ring is formed with an outer ring coupling portion extending along the circumferential direction on the outer diameter side to one side in the axial direction; The outer ring engaging portion includes an annular annular portion extending radially inwardly from the outer diameter surface of the outer ring, and a cylindrical portion extending in the axial direction from the inside of the annular portion in the radial direction;

The spring engaging projection is formed of an extension extending radially outwardly from the spring body, and a bent portion bent toward the outer ring at an end of the extension;

The cylindrical part is inserted into the inside of the bent part, and the end of the bent part is characterized in that it faces the annular part.

In the above, when the outer ring is inserted between the spring engaging projection, the bent portion is characterized in that the outward deformation in contact with the cylindrical portion.

In the rolling bearing with a preload spring according to the present invention, since the preload spring is coupled to the outer ring, relative motion is suppressed to prevent noise or vibration caused by relative motion between the outer ring and the spring body, and a rolling bearing equipped with a preload spring Width fluctuation control has a high precision because the width fluctuation is small compared to the cumulative width fluctuation of each part, and since the number of parts to be managed in the assembly process is reduced, time is shortened and management efficiency is improved.

1 is a partially separated perspective view showing a conventional bearing preload spring together with a bearing support part of a motor;
2 is a perspective view showing a rolling bearing provided with a preload spring according to the present invention;
Figure 3 is a half cross-sectional view showing a section AA of Figure 2,
4 is a perspective view showing the outer ring of the rolling bearing;
5 is a half cross-sectional view showing the outer ring of the rolling bearing;
6 is a half cross-sectional view showing a modified example of the outer ring of the rolling bearing in FIG.

Hereinafter, a rolling bearing with a preload spring according to the present invention will be described in detail with reference to the drawings.

2 is a perspective view showing a rolling bearing provided with a preload spring according to the present invention, FIG. 3 is a half cross-sectional view showing a rolling bearing provided with a preload spring according to the present invention, and FIG. 4 is an outer ring of the rolling bearing It is a perspective view, FIG. 5 is a half cross-sectional view showing the outer ring of the rolling bearing, and FIG. 6 is a half cross-sectional view showing a modified example of the outer ring of the rolling bearing in FIG.

As shown in FIG. 2 , the rolling bearing 100 provided with a preload spring according to the present invention includes a bearing 110 and a preload spring 120 .

The bearing 110 includes an inner ring 111 , an outer ring 113 , a rolling element 115 , and a retainer 117 .

The inner ring 111 is provided in a ring shape. A concave inner ring track 111-1 is formed on the outer diameter surface of the inner ring 111 .

The outer ring 113 is provided in a ring shape. A concave outer ring track 113 - 1 is formed on the inner diameter surface of the outer ring 110 . The outer raceway 113-1 and the inner raceway 111-1 are formed to face each other.

The rolling element 115 is a ball, and is provided in plurality. The rolling element 115 may be provided with various types of rolling elements. The rolling elements 150 are arranged in a circumferential direction between the outer raceway 111 and the inner raceway 131 .

The retainer 117 is provided between the outer ring 113 and the inner ring 111 . The retainer 117 serves to maintain the circumferential spacing of the plurality of rolling elements 115 . A cage (not shown) may be provided instead of the retainer 117 .

4 and 5, the outer ring 113 is formed with a plurality of outer ring coupling portions 113-3 spaced apart along the circumferential direction. The outer ring coupling part 113-3 is formed in three or more. The outer ring coupling portion 113-3 is concavely formed on the outer diameter side of the outer ring 113 in the axial direction. The outer ring coupling portion 113 - 3 is concavely formed in a corner portion of one side of the outer ring 113 in the width direction on the outer diameter side.

The outer ring coupling part 113-3 has a first surface 113-31 facing the axial direction, and a second surface 113- 33) and third surfaces 113-35 located on both sides of the first surface 113-31 and the second surface 113-33 in the circumferential direction. An axially outer end of the second surface 113-33 is formed to be curved.

The preload spring 120 is annular and is made of a steel material. The preload spring 120 includes a spring body 121 and a spring coupling protrusion 123 .

The spring body 121 has an annular shape, and is a corrugated spring in which valleys 121-1 and mountains 121-3 are alternately and repeatedly provided. The valley 121-1 is a portion in contact with the width surface 113-7 of the outer ring 113 when coupled to the outer ring 113, and the mountain 121-3 is the width surface 113-7 of the outer ring 113. part separated from it. The valley 121-1 is in contact with the width surface 113-7 of the outer ring 113 in surface contact.

The spring coupling protrusion 123 extends outward from the radial direction outside of the spring body 121 and is provided in plurality while being spaced apart from each other in the circumferential direction. The spring coupling protrusion 123 is provided with the same number of the outer ring coupling parts 113-3.

The spring coupling protrusion 123 is provided in the valley 121-1. For example, when three valleys 121-1 are formed, the spring coupling protrusions 123 are provided in the three valleys 121-1, and when 6 valleys 121-1 are formed, the spring coupling protrusions ( 123 may be provided in all of the six valleys 121-1, and may be provided in the valleys 121-1 on both sides with one valley 121-1 interposed therebetween.

The spring coupling protrusion 123 is provided on the radially outer side of the valley 121-1. The spring coupling protrusion 123 is radially outwardly extended from the valley 121-1, and the end is bent in the axial direction toward the outer ring 113 .

The spring coupling protrusion 123 includes an extension portion 123-1 and a bent portion 123-3. The extension portion 123 - 1 extends radially outward from the spring body 121 . The bent portion 123-3 is bent toward the outer ring 113 at the end of the extension portion 123-1.

When the preload spring 120 and the outer ring 113 are coupled, the outer ring 113 is inserted between the plurality of spring coupling protrusions 123, and the spring body 121 has one side width surface 113- of the outer ring 113. 7) is provided facing. One side width surface 113-7 of the outer ring 113 is provided in contact with the valley 121-1 of the spring body 121.

The bent part 123-3 of the spring coupling protrusion 123 is inserted into the outer ring coupling part 113-3. The bent portion 123-3 is inserted between the third surfaces 113-35 of the outer ring coupling portion 113-3 so that the end of the bent portion 123-3 faces the first surface 113-31, , the second surface 113-33 is located on the radially inner side of the bent portion 123-3.

When the outer ring 113 is inserted between the spring coupling protrusions 123, the bent portion 123-3 expands and is deformed outwardly in contact with the second surface 113-33 to be coupled. The preload spring 120 is formed between the outer ring 113 and the spring body 121 by being firmly coupled to the outer ring coupling portion 113-3 of the outer ring 113 as the bent portion 123-3 is expanded and deformed. It has the effect of preventing noise or vibration due to relative motion.

The outer ring 113 may be formed with an outer ring coupling portion 113 - 5 extending in the circumferential direction on one side of the axial direction as in the modified example shown in FIG. 6 .

The outer ring coupling portion 113-5 includes an annular annular portion 113-51 extending radially inward from the outer diameter surface of the outer ring 113, and radially inside the annular portion 113-51 in the axial direction. It consists of an extended cylindrical portion (113-53). The outer end of the cylindrical portion 113-53 in the axial direction is curved.

The spring coupling protrusion 123 has a cylindrical portion 113-53 inserted into the bent portion 123-3, and an end of the bent portion 123-3 faces the annular portion 113-51. When the outer ring 113 is inserted between the spring coupling protrusions 123, the bent portion 123-3 is expanded in contact with the cylindrical portion 113-53 and is deformed outwardly so that the preload spring 120 and the outer ring 113 are formed. tightly coupled The preload spring 120 is firmly coupled to the outer ring 113 to prevent noise or vibration due to the relative motion occurring between the outer ring 113 and the spring body 121 .

The rolling bearing 100 with a preload spring according to the present invention is provided by combining the bearing 110 and the preload spring 120, so that the number of parts to be managed in the assembly process is reduced, thereby shortening the assembly time and improving the management efficiency. It works.

100: rolling bearing with preload spring 110: bearing
111: inner ring 113: outer ring
113-3: outer ring coupling part
120: preload spring 121: spring body
123: spring coupling projection

Claims (6)

a bearing 110 and a preload spring 120 coupled to the bearing 110;
The preload spring 120 includes a spring body 121 in which mountains 121-3 and valleys 121-1 are repeated, and a plurality of spring coupling protrusions extending outwardly from the outside of the spring body 121 and spaced apart from each other. (123);
The bearing 110 includes an inner ring 111, an outer ring 113, and a plurality of rolling elements 115 arranged in a circumferential direction between the outer ring 113 and the inner ring 111;
The outer ring 113 is inserted between the spring coupling protrusions 123, and the spring body 121 is provided to face the width surface 113-7 of one side of the outer ring 113;
The outer ring 113 has a plurality of outer ring coupling portions 113-3 that are concave on the outer diameter side on one side in the axial direction and spaced apart along the circumferential direction are formed, and the spring coupling protrusion 123 is the outer ring coupling portion 113-3. ) is inserted;
The outer ring coupling portion 113-3 is concavely formed in a corner portion of one side in the outer diameter side width direction of the outer ring 113, a first surface 113-31 facing the axial direction, and the first surface 113- 31) having a second radially outwardly facing second surface (113-33) and a third surface (113-35) positioned on both sides in the circumferential direction;
The spring coupling protrusion 123 includes an extension 123-1 extending radially outwardly from the spring body 121, and a bent portion bent toward the outer ring 113 at the end of the extension 123-1 ( 123-3), the bent part 123-3 is inserted between the third surfaces 113-35 so that the end faces the first surface 113-31, and the second surface 113-33 ) is a rolling bearing 100 provided with a preload spring, characterized in that it is located inside the radial direction of the bent portion 123-3. delete delete The preload spring according to claim 1, wherein when the outer ring 113 is inserted between the spring coupling protrusions 123, the bent portion 123-3 is deformed outwardly in contact with the second surface 113-33. Equipped rolling bearing (100). delete delete

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