KR200256748Y1 - Rubrication structure of sintered oilless bearing of small cooling fan - Google Patents

Abstract

The present invention relates to a lubrication structure of a sintered bearing for a small cooling fan. When the lubricating oil of the upper bearing and the lower bearing, which are sintered bearings, is exhausted by the frictional force during the rotation of the fan blades, the upper bearing and the lower bearing have their own characteristics. As a result of absorbing lubricating oil from the upper felt ring and the lower felt ring to perform continuous lubrication, consequently, the present invention provides a lubrication structure of a sintered bearing for a small cooling fan, which can prolong the life of the sintered bearing.

The present invention, in the lubrication structure of the sintered bearing bearing for a small cooling fan in which the bearing guide 42 and the rotor 40 are inserted into the rotation center axis 30 installed in the fan housing 20 to rotate the operation, the bearing The first step 44 is integrally formed on the inner wall of the guide 42 to install the upper bearing 60 and the lower bearing 62 on the upper and lower parts, and the inner wall of the first step 44. The second stepped portion 46 is integrally formed, and is achieved by installing the upper felt ring 64 and the lower felt ring 66 in the upper and lower portions.

Description

Lubrication Structure of Sintered Bearing for Small Cooling Fans {RUBRICATION STRUCTURE OF SINTERED OILLESS BEARING OF SMALL COOLING FAN}

The present invention incorporates a first stepped portion into which an upper bearing and a lower bearing are fitted into an inner wall of a bearing guide, and a second stepped portion into which the upper felt ring and the lower felt ring are fitted. The lubrication structure of the bearing.

In general, the cooling fan is divided into a large cooling fan installed in the car from a small cooling fan installed in the computer, which is operated simultaneously with the operation of the drive unit as a heat source to cool the heat generated from the drive unit, thereby reducing the This is to prevent damage.

The compact cooling fan is provided with a sintered bearing. The sintered oilless bearing refers to a bearing bush in which a large amount of voids remain inside the sintered body and sintered so that most of it passes to the outside, and impregnated with lubricating oil.

Herein, a conventional structure of a sintered bearing as a component of the small cooling fan will be briefly described with reference to FIG. 1.

1 is a cross-sectional view of a small cooling fan in which a sintering bearing of the prior art is installed. As shown in FIG. 1, a schematic structure of the small cooling fan A includes an operating chamber B1 having an upper opening, and the operating chamber. A fan housing (B) having a central protrusion (B2) integrally formed at the bottom of (B1) and an inner annular portion (B3) integrally formed along a circular trajectory to the outside of the central protrusion (B2); A rotational central axis C at which a lower end thereof is fixed to the fixing groove B4 of the central protrusion B2; A rotor (D) inserted from an upper portion of the rotation center axis (C) and positioned inward of the inner annular portion (B3) together with a bearing (D1) and a bearing guide (D2) to be rotatable; It was composed of a fan blade (E) that is coupled to the stator (E1) in the upper portion of the rotation center axis (C) to rotate.

In particular, the sintered bearing has a bearing D1 of the rotational central axis C having a rotating hole D3 therein and a bearing guide D2 fitted around the outer surface of the bearing D1. Was doing.

In the prior art having such a structure, the bearing D1 of the sintered bearing is firstly fitted to the rotational central axis C, and the bearing guide D2 and the rotor D are outside of the bearing D1. ) Is assembled and assembled to the upper end of the rotor (D) by assembling the fan blade (E) by the stator (E1), the fan blade (E) around the rotation center axis (C) It was designed to operate in rotation.

However, since the rotation center axis C and the bearing D1 rotate in contact with each other during the rotation operation of the fan blade E, the lubricating oil impregnated in the bearing D1 is quickly exhausted to extend the life. Because of the shortening, the impregnated lubricant must be supplied again after repeated use for a long time. In other words, there has been a problem that the lubricating oil in the bearing D1 cannot be used for a long time and the life of the bearing D1 is shortened.

Therefore, the present invention is to solve the above problems, the technical problem of the present invention is the upper bearing and the lower bearing when the lubricating oil of the upper bearing and the lower bearing, the sintered bearing bearing by the frictional force during the rotation operation of the fan blade Due to its own characteristics, lubricating oil is absorbed from the upper felt ring and the lower felt ring to perform continuous lubrication, and consequently, provides a lubrication structure of a sinter bearing bearing for a small cooling fan that can extend the life of the sinter bearing. It is.

The present invention is a lubrication structure of a sintered bearing bearing for a small cooling fan in which a bearing guide and a rotor are inserted into and rotated by a rotational central axis installed in a fan housing, wherein a first stepped portion is integrally formed on an inner wall of the bearing guide. The upper and lower upper and lower bearings are installed, and the second stepped portion is integrally formed on the inner wall of the first stepped portion, thereby achieving the upper and lower felting rings.

1 is a cross-sectional view of a compact cooling fan installed with a sintered bearing of the prior art.

Figure 2 is an exploded perspective view showing the lubrication structure of the sintered bearing bearing for a small cooling fan according to an embodiment of the present invention.

3 is a cross-sectional view of the coupled state of FIG.

Figure 4 is an exploded perspective view showing an exploded state of the felt ring according to an embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

10: small cooling fan 20: fan housing

22: operating chamber 24: central protrusion

26: inner part 28: fixing groove

30: center axis of rotation 40: rotor

42: bearing guide 44: first stepped portion

46: second step 50: fan blade

52: stator 60: upper bearing

62: lower bearing 64: upper felt ring

66: lower felt ring

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, FIGS.

2 is an exploded perspective view showing a lubrication structure of a sintered bearing for a small cooling fan according to an embodiment of the present invention, Figure 3 is a cross-sectional view of the coupling state of Figure 2, Figure 4 is an exploded view of the felt ring according to an embodiment of the present invention An exploded perspective view showing the state.

'1' is a small cooling fan of the present invention.

As shown in the figure, the small cooling fan 10 is fixed to the lower end of the rotation center axis 30 to the central protrusion 24 formed in the operation chamber 22 of the fan housing 20 to be in an upright position. .

The inner annular portion 26 is formed along the circular trajectory at the bottom of the operating chamber 22 to be in the proximal position of the rotational central axis 30.

The first step 44 is integrally formed on the inner wall of the bearing guide 42 to install the upper bearing 60 and the lower bearing 62 on the upper and lower parts. The upper bearing 60 and the lower bearing 62 are small alloy bearings having a property of absorbing lubricating oil.

The second stepped part 46 is integrally formed on the inner wall of the first stepped part 44, and upper and lower upper felt rings 64 and lower felt rings 66 are installed.

The bearing center 42 is installed on the rotational central shaft 30 so that the upper bearing 60 and the lower bearing 62 may be rotated to operate. The rotor 40 is coupled to the outside of the bearing guide 42, and the fan blade 50 is coupled to the upper portion of the rotor 40.

The upper felt ring 64 and the lower felt ring 66 is a cloth-shaped product made by immersing wool or other animal hair in lubricating oil. This is to be supplied from the upper felt ring 64 and the lower felt ring 66 when the lubricant is exhausted in the upper bearing 60 and the lower bearing 62 to continue the lubrication action.

In the lubrication structure of the sintered bearing for a compact cooling fan of the present invention configured as described above, the first stepped portion 44 and the upper bearing 60 and the lower bearing 62 are fitted into the inner wall of the bearing guide 42. By integrally forming the second stepped portion 46 into which the upper felt ring 64 and the lower felt ring 66 are fitted, the fan blade 50 is rotated in contact with the rotating central shaft 30 during the rotation operation of the fan blade 50. When the lubricating oil of the upper bearing 60 and the lower bearing 62 is exhausted, the lubricating oil impregnated in the upper felt ring 64 and the lower felt ring 66 may be supplied to extend the life of the sintered bearing. It is devised.

Looking at the assembly state of the present invention described in detail the action according to this as follows.

4, the lower end of the rotation center shaft 30 is inserted into the fixing groove 28 of the central protrusion 24 formed in the operation chamber 22 of the fan housing 20. Secure it. The stator 52 fits into the inner diameter of the inner annular portion 26 in the operation chamber 22 and is fixed without moving. The assembly of the bearing guide 40 and the rotor 40 is assembled to the central axis of rotation 30. This will be described in more detail as follows.

As shown in an enlarged view in FIG. 4, the bearing guide 42 is fitted into the rotor 40 and fixed to the inner diameter. The upper felt ring 64 and the lower felt ring 66 are fitted into and fixed to the first step 44 of the bearing guide 42. The upper bearing 60 is installed in the upper felt ring 64 installed in this manner, and the lower bearing 62 is in contact with the lower felt ring 66. In this state, the rotation center shaft 30 is described above. The assembly of the rotor 40, the bearing guide 42, the upper bearing 60, the lower bearing 62, the upper felt ring 64 and the lower felt ring 66 is installed. Then, only the upper bearing 60 and the lower bearing 62 are in contact with the outer circumferential surface of the rotation center shaft 30 to be rotatable. Then, the assembly of the rotor 40, the bearing guide 42, the upper felt ring 64 and the lower felt ring 66 is rotated simultaneously with the upper bearing 60 and the lower bearing 62. At this time, the rotor 40 is rotated in a state located close to the inner diameter of the stator 52 fixed to the inner ring portion 26 of the fan housing 20. That is, the stator 52 is stationary without moving, while the rotor 40 is rotated while being fitted to the rotation center axis 30. In particular, the fan blades 50 are assembled on the upper part of the rotor 40, and the fan blades 50 are configured to rotate simultaneously with the rotor 40. As described above, the compact cooling fan of the present invention is assembled. The operation state for the 10 is as follows. When power is applied to the stator 52 by the ON operation of the illustrated power source, a magnetic field is generated in the stator 52, and the generated magnetic field is the rotor 40. Rotate). The rotor 40 then rotates with the bearing guide 42. The upper bearing 60 and the lower bearing 62 coupled to the inner diameter of the bearing guide 42 are rotated in contact with the outer circumferential surface of the rotation center axis 30. At this time, the upper bearing 60 and the lower bearing 62 serves to offset the frictional force by the lubricant when the rotary operation in the state in contact with the outer peripheral surface of the rotation center axis 30. When the lubricant of the upper bearing 60 and the lower bearing 62 is exhausted, the upper bearing 60 and the lower bearing 62 are impregnated in the upper felt ring 64 and the lower felt ring 66 by their characteristics. It is supplied with the lubricating oil to cancel the friction force generated during the rotation operation so that the normal operation can be made.

As described in detail above, according to the lubrication structure of the sintered bearing for a small cooling fan, a first step portion into which the upper bearing and the lower bearing are fitted into the inner wall of the bearing guide and a second fitting portion of the upper felt ring and the lower felt ring are fitted. By integrally forming the stepped portion, when the lubricating oil of the upper bearing and the lower bearing, which are the sintered bearings, is exhausted by the frictional force during the rotational operation of the fan blades, the upper bearing and the lower bearing have their own characteristics from the upper felt ring and the lower felt ring. As a result of absorbing the lubricating oil and performing the continuous lubricating action, it is a useful design that can extend the life of the sintered bearing.

Claims (1)

In the central protrusion 24 of the fan housing 20, a fixing groove 28 is formed to fix the lower end of the rotation center axis 30, and the bearing guide 42 and the rotor are formed on the outer circumferential surface of the rotation center axis 30. In the lubrication structure of a sintered bearing for a compact cooling fan in which 40 is rotated in turn, On the inner wall of the bearing guide 42, the lower end of the first step 44 is formed so that the upper bearing 60 and the lower bearing 62, respectively, on the inner wall of the bearing guide 42, The second stepped portion 46 is formed in succession with the first stepped portion 44, and the second felted portion 46 is provided with an upper felt ring 64 and a lower felt ring 66, respectively. Lubrication structure of the sintered bearing for compact cooling fan, characterized in that.