KR100224616B1 - Fluid bearing apparatus having a groove which fluid goes against the stream - Google Patents

Abstract

The present invention relates to a fluid bearing device, and according to the configuration of the present invention, a shaft having a predetermined length and a predetermined diameter, a support member into which a journal of the shaft is fitted, and a thrust for supporting a magnetic load applied to an end of the shaft A fluid pressure generating unit for generating a predetermined fluid pressure is formed by a dynamic pressure generating groove in which a herringbone-shaped bent portion having a predetermined acute angle is formed in one of a bearing and the shaft and the thrust bearing corresponding to the shaft. In the fluid bearing device, the fluid bearing device includes a fluid pressure generating portion including a plurality of dynamic pressure generating grooves in which the herringbone-shaped bent portion is formed on a circumference spaced a predetermined distance from the center of the thrust bearing; Spiral shape extending from the end of the pressure generating portion to the outer diameter of the thrust bearing It characterized in that it comprises a backflow prevention portion formed of a dynamic pressure generating groove.

Description

FLUID BEARING APPARATUS HAVING A GROOVE WHICH FLUID GOES AGAINST THE STREAM}

The present invention relates to a fluid bearing device, and more particularly, a herringbone dynamic pressure generating groove having a herringbone shape and a spiral dynamic pressure generating groove having a spiral shape are formed in a thrust bearing for supporting a thrust load, thereby exposing fluid by the spiral dynamic pressure generating groove. The present invention relates to a fluid bearing device in which a backflow port is formed which prevents flow back to the outside of the bearing.

Recently, as information technology such as computers, audio systems, and video equipments and media industries have increased, the size of various devices mentioned above has been miniaturized, and according to the miniaturization, there is a demand for components of devices having finer and more precise performance. .

In particular, a spindle motor drive of a hard disk (HDD), which is one of the storage devices for a computer, and a polygon mirror drive device for a laser printer, a laser disk and a compact disc drive device for an audio system, a VCR head and a camcorder for an imaging device, The driving device and the like rotate and rotate the rotating shaft and the rotating body coupled to the driving device at high speed to perform operations such as storing and searching for desired data and reproducing data.

At this time, the rotating shaft rotates at a very high speed, so shaft shaking, shaft shaking, and shaft vibration caused by the high-speed rotation have a fatal effect on the performance of the product. One of the mechanical elements is used for bearings. In particular, a fluid bearing device using air or oil is widely used among various types of bearings for minimizing friction force on a rotating shaft.

Among these fluid bearing devices, the laser mirror's polygon mirror drive device, hard disk (HDD) spintle motor, and VTR head drive device, which require high precision and high speed rotation performance, flow into the dynamic pressure generating groove of the thrust bearing and Some types of incompressible oils, which have higher rigidity than air, are used as the generating fluid. When using such oils, the oil film is formed to prevent contamination by oil leaking to the outside of the devices requiring a high clean environment. It should be sealed by a sealing cover.

1 is a view illustrating a polygon mirror driving apparatus of a conventional laser printer, in which a through hole having a predetermined diameter is formed in a bearing bracket 10, and a sleeve 20 as shown in the through hole is fitted. Thereafter, the bearing bracket 10 is fastened and fixed by the fixing screw 22 or the like, and the shaft 30 is rotatably inserted into the sleeve 20.

The lower end portion 30b of the shaft 30 is interviewed with the thrust bearing 50 receiving the vertical thrust load of the shaft 30, and the upper surface of the thrust bearing 50 has a predetermined shape, for example, herringbone dynamic pressure. The first dynamic pressure generating groove 50b (FIG. 2) of the generation groove shape is formed, and the first dynamic pressure generating groove 50b is bent at a predetermined angle on a predetermined circumference formed on the upper surface of the thrust bearing 50. The herringbone-shaped first dynamic pressure generating groove 50b in which the portion 50a is formed is precisely processed to a depth of several micrometers by various processing machines and processing methods such as etching and plasma etching.

Thus, the thrust bearing 50 in which the first dynamic pressure generating groove 50b is formed is fastened again by the sleeve 20 and the screw 24, and the hub 70 in the middle portion of the shaft 30. Is press-fitted and fixed to the shaft 30, the motor 70, which is shown only in part, is joined to the hub 70, and the shaft 30 rotates together with the motor 60, and the polygon mirror (c) is attached to the hub 70. 80) is attached.

In addition, the sleeve 20 has a vent hole 20a formed at the portion where the thrust bearing 50 and the shaft 30 are interviewed, and the shaft 30 is inserted into the hole of the sleeve 20. A second dynamic pressure generating groove 30a having a herringbone shape is formed in the shaft 30 or the sleeve 20 of the surface in which the inner diameter of the sleeve 20 faces, and thus the second dynamic pressure generating groove 30a is formed. The groove angle is generally about 30 degrees, and the depth of the second dynamic pressure generating groove 30a is about several micrometers.

Referring to Figures 1 and 2 attached to the operation of the polygon mirror driving device of the laser printer having a conventional thrust bearing device as described above are as follows.

First, when power is applied to the motor 60 shown only in part, the motor 60 gradually increases the angular velocity in a state where the angular velocity is 0, and reaches a maximum angular velocity after a predetermined time, whereby the angular velocity becomes constant. 30 also rotates at the same angular speed as the motor 60.

At this time, a predetermined fluid flows into the fluid inflow portions on both sides of the bent portion 50a on the basis of the bent portion 50a of the first dynamic pressure generating groove 50b, thereby forming a fluid pressure to float the shaft 30. Since the area of the shaft 50 and the lower end portion 30a of the shaft and the shaft weight and the shaft are unchanged, the fluid pressure increases in proportion to the angular velocity of the shaft 30, and the shaft 30 reaches a predetermined number of revolutions per minute. When the fluid pressure becomes larger than the self-weight and the axial load of the shaft 30, the shaft 30 rises to the top of the first dynamic pressure generating groove 50b while forming a constant gap from the first dynamic pressure generating groove 50b, and then equilibrates. State is achieved.

However, the fluid flowing into the herringbone-shaped first dynamic pressure generating groove formed in the conventional thrust bearing to generate a predetermined fluid pressure to support the thrust load is generated by the centrifugal force generated by the ultra-high rotation of the thrust bearing. Due to the centrifugal force, the fluid does not flow into the bent portion of the thrust bearing and leaks to the outer diameter portion of the thrust bearing, thereby reducing the magnitude of the fluid pressure in response to the amount of leakage, thereby preventing sufficient dynamic pressure from occurring to support the thrust load.

Accordingly, the present invention has been made in view of the above-described conventional problems, and an object of the present invention is to show a position where a bent portion is formed among a herringbone-shaped dynamic pressure generating groove formed in the thrust bearing. The present invention provides a fluid bearing device in which a backflow port is formed so as to correspond to a relationship of a shaft (fitting or simple insertion) to be fitted into the shaft to prevent leakage to the thrust bearing inner diameter portion or leakage to the thrust bearing external portion.

1 is a cross-sectional view showing a polygon mirror driving device of a laser printer to which a conventional fluid bearing device is applied.

FIG. 2 is a plan view of the thrust bearing of FIG. 1. FIG.

3 is a plan view showing a thrust bearing according to the present invention.

Figure 4 is a plan view showing another embodiment of the present invention.

Explanation of symbols for the main parts of the drawings

50: thrust bearing 50a: bend

50c: Herringbone dynamic pressure generating groove 50d: Spiral dynamic pressure generating groove

Such a fluid bearing device having a backflow port for achieving the object of the present invention includes a shaft having a predetermined length and a predetermined diameter;

A support member to which the journal of the shaft is fitted and supported;

A thrust bearing for supporting a magnetic load applied to an end of the shaft;

A fluid bearing device having a fluid pressure generating portion for generating a predetermined fluid pressure by a dynamic pressure generating groove having a plurality of herringbone-shaped bent portions having a predetermined acute angle on one of the shaft and the thrust bearing corresponding to the shaft. To;

The fluid bearing device includes: a fluid pressure generating unit including a plurality of dynamic pressure generating grooves in which a herringbone-shaped bent portion is formed on a circumference spaced apart from a center of the thrust bearing by a predetermined distance;

And a backflow prevention portion formed by a spiral-shaped dynamic pressure generating groove extending from the end of the fluid pressure generating portion to the outer diameter portion of the thrust bearing.

Hereinafter, a fluid bearing device having a backflow port of the present invention will be described with reference to the accompanying drawings, except for the thrust bearing, which is a key part of the present invention. Are omitted and the same reference numerals and the same names will be used for the same parts as in the related art.

3 is a plan view of the thrust bearing 50 according to the present invention, and a circle G is formed at a predetermined distance from the midpoint O of the thrust bearing 50 and is virtually spaced apart from the circle G at a predetermined distance. Circle E is formed and circle F is again formed in the middle of G and E.

A herringbone dynamic pressure generating portion 50c having a predetermined area in a herringbone shape having a predetermined area between G and E is connected at an angle of β (preferably β ≒ 30 °) to generate a herringbone dynamic pressure at F. The bent portion 50a formed while the grooves 50c are interconnected is positioned and the fluid inlet portion is formed in two arcs arc and cd.

The spiral ab pressure generating part, which is a spiral spiral pressure generating groove 50d, is connected to the arc ab, which is a fluid inlet portion formed on the line E, and the spiral dynamic pressure generating groove 50d is formed by the herringbone dynamic pressure generating groove 50c extending to the outer diameter part. The spiral dynamic pressure generating groove 50d is formed in the same number as the herringbone dynamic pressure generating groove 50c and corresponds one-to-one.

The herringbone dynamic pressure generating groove 50c and the spiral dynamic pressure generating groove 50 connected to each other become the first dynamic pressure generating groove, among which the spiral dynamic pressure generating groove 50d becomes a backflow port.

Referring to the accompanying drawings, the operation of the polygon mirror driving apparatus of the laser printer to which the thrust bearing having the backflow port is applied is as follows.

First, when power is applied to the motor 60 and the motor 60 starts to rotate, the shaft 30 coupled to the motor 60 also rotates at the same angular speed as the motor 60, in which case the shaft 30 Vortex is formed at the lower end portion 30b of the shaft in response to the rotational speed of the shaft, and the vortices are formed through the first dynamic pressure generating grooves 50c and 50d of the upper surface of the thrust bearing 50 facing the lower end portion 30b of the shaft. It is introduced while turning inward, and at the end, the introduced fluids gather to generate a predetermined pressure of the fluid.

At this time, the first dynamic pressure generating groove 50c formed on the upper surface of the thrust bearing 50 in order to minimize the friction generated between the thrust bearing 50 while supporting and rotating the thrust load of the shaft 30. The fluid introduced into the spiral dynamic pressure generating groove 50d of the 50d passes through the communication portion of the spiral dynamic pressure generating groove 50d and the herringbone dynamic pressure generating groove 50c.

At this time, the fluid introduced from the other side of the herringbone dynamic pressure generating groove (50c) is gathered at the bent portion (50a) of the herringbone dynamic pressure generating groove (50c) to generate a peak fluid pressure of a predetermined size in the F portion and the thrust bearing 50 The spiral dynamic pressure generating groove 50d prevents the fluid flowing into the herringbone dynamic pressure generating groove 50c by the centrifugal force generated by the high speed rotation of the back flow toward the outer diameter portion.

4 is a view showing another embodiment of the present invention. In the above-mentioned embodiment, the herringbone dynamic pressure generating groove 50c and the spiral dynamic pressure generating groove 50d are interconnected to each other. Even if the portions in which the dynamic pressure generating grooves 50c and the spiral dynamic pressure generating grooves 50d are formed as discontinuous portions by the interval t will have the same effect as the above-mentioned embodiment.

As described in detail above, two types of dynamic pressure generating grooves, ie herringbone dynamic pressure generating grooves and thrust dynamic pressure generating grooves, are formed on the upper surface of the disc-shaped thrust bearing for supporting the thrust load. The amount of fluid leaking from the herringbone dynamic pressure generating groove to the outer diameter side is reduced to increase the rigidity of the thrust bearing supporting the rotating object, thereby increasing rotational stability.

Claims (3)

An axis having a predetermined length and a predetermined diameter; A support member to which the journal of the shaft is fitted and supported; A thrust bearing for supporting a magnetic load applied to an end of the shaft; A fluid bearing device having a fluid pressure generating portion for generating a predetermined fluid pressure by a dynamic pressure generating groove having a plurality of herringbone-shaped bent portions having a predetermined acute angle on one of the shaft and the thrust bearing corresponding to the shaft. To; The fluid bearing device includes: a fluid pressure generating unit including a plurality of dynamic pressure generating grooves in which a herringbone-shaped bent portion is formed on a circumference spaced apart from a center of the thrust bearing by a predetermined distance; And a backflow prevention portion formed by a spiral-shaped dynamic pressure generating groove extending from the end of the fluid pressure generating portion to the outer diameter portion of the thrust bearing. The fluid bearing device according to claim 1, wherein the herringbone-like dynamic pressure generating groove and the spiral-shaped dynamic pressure generating groove are formed in the same number. The fluid bearing according to claim 1 or 2, wherein a portion where the herringbone-shaped dynamic pressure generating groove and the spiral-shaped dynamic pressure generating groove communicate with each other has a cut portion formed so that a discontinuous portion is formed. Device.