KR100228896B1 - Fluid bearing system - Google Patents

Abstract

The present invention relates to a fluid bearing device applied to a head drum motor, a scanning motor, or a hard disk motor, the bearing action member is pressed into the shaft of the motor having a rotating body, the bearing groove is formed on the upper surface of the bearing action member In the fluid bearing device comprising a portion adjacent to the bearing groove of the rotating body bearing action member to be a bearing action surface, a plurality of bearing grooves are formed radially from the inner side to the outer circumference close to the center, the bearing Provides a fluid bearing device characterized in that it comprises a bearing action member for the groove to be closed at a predetermined distance from the outer periphery, the shaft is always solved by solving the problem that a malfunction occurs even if a slight external force such as minor shaking is applied to the product to which the groove is applied. It is a useful invention to rotate uniformly and stably.

Description

Fluid Bearing Device

The present invention relates to a fluid bearing device applied to a head drum motor, a scanning motor, or a hard disk motor, and more particularly, a fluid bearing which improves the structure of a bearing groove formed in a bearing action member so that the rotor rotates more stably and uniformly. Relates to a device.

Generally, a fluid bearing device is applied to a rotating shaft of a motor that rotates at high speed, such as a video cassette recorder (hereinafter referred to as a VCR), a laser printer, a scanner, a camcorder, a hard disk, and the predetermined surface of the rotating body or a predetermined surface of the shaft. In addition, bearing grooves are formed in the bearing actuating members mounted to the shaft and the rotating body, respectively, so as to be a well-known bearing acting by using the air pressure generated between the outer circumferential surface of the rotating body or the shaft adjacent to the bearing groove.

Thus, in the present invention, the head drum of the VCR will be described as an embodiment. Specifically, a bearing action member is pressed into a fixed shaft, and a bearing groove is formed on a predetermined surface of the bearing action member.

1 is a cross-sectional view of a head drum motor to which a conventional fluid bearing is applied, and FIG. 2 is a plan view and an air pressure distribution diagram illustrating only a bearing action member of the fluid bearing device shown in FIG. 1.

The general head drum 1 has a stator 11 and a lower drum 10 fixed on the deck of the VCR, and a head 22 for reading information recorded on a video tape, and the stator 11 and electronics. The rotor 21 is installed at a predetermined position to perform a miraculous action, and is composed of an upper drum 20 which rotates on the lower drum 10 due to the interaction of the stator 11 and the rotor 21.

In the general head drum 1 as described above, the fluid bearing device conventionally used includes a bearing action member having a bearing groove 12a formed on an upper surface at a predetermined position of a shaft 12 provided on the lower drum 10. 13 is mounted, and the portion of the upper drum 20 rotatably installed on the shaft 12 to be adjacent to the bearing actuating member 13 is formed to be the bearing acting surface 13b.

In the conventional fluid bearing device as described above, when the stator 11 and the rotor 21 of the head drum 1 have an electromagnetic action and the upper drum 20 is rotated in the direction of the arrow in FIG. 2, the bearing groove 13a and The air between the bearing acting surfaces 13b is pushed out of the bearing acting member 13 along the bearing groove 13a surface, and as the upper drum 20 is continuously rotated, the air opens the bearing recess 13a. The air is accumulated on the side wall of the bearing acting surface 13b, which is pushed to the outer circumference of the bearing acting member 13, and eventually comes into close contact with the bearing acting member 13, thereby generating a pressure to float the upper drum 20. Given.

At this time, the distribution of the generated air pressure is as shown in Figure 2, where the air pressure distribution is gradually accumulated by the air is accumulated downward from the portion of the bearing groove (13a) where the air is first introduced to the end You can see that the graph of the curve appears.

In the fluid bearing device as described above, since the air accumulates on the side wall of the bearing action surface, pressure is generated to support the rotating body at both ends as shown in the pressure curve of FIG. Is generated.

When the pressure point for supporting the rotating body is narrow as described above, the rotating body of the VCR equipped with the motor or motor rotates out of position even in the slightest shaking, making it difficult to expect accurate operation of the product. The spacing of the faces is very small because they use a numerical value in μm. When the VCR is subjected to a slight impact from the outside, the rotor and the shaft inside the motor are in contact with each other. Malfunction of the product occurs.

Accordingly, an object of the present invention is to provide a fluid bearing device designed to solve the above problems and to improve the structure of the bearing groove formed in the bearing action member so that the rotor is rotated more stably and uniformly. .

Features of the present invention for achieving the above object more effectively are as follows.

The bearing actuating member is pushed into the shaft of the motor having the rotating body, and the bearing groove is formed on the upper surface of the bearing actuating member, and the portion adjacent to the bearing groove of the bearing actuating member of the rotating body is formed to be the bearing acting surface. In the fluid bearing device comprising a plurality of bearing grooves formed radially from the inner side to the outer circumference close to the center, characterized in that the bearing groove comprises a bearing action member to be closed at a predetermined distance from the outer circumference.

1 is a cross-sectional view of a head drum equipped with a conventional fluid bearing

2 is a plan view and air pressure distribution diagram showing the air pressure distribution of the fluid bearing applied to FIG.

Figure 3 is a cross-sectional view of the head drum to which the present invention is applied

4 is a plan view and air pressure distribution diagram showing the air pressure distribution of the fluid bearing applied to FIG.

* Explanation of symbols for main parts of the drawings

1: Head drum 10: Lower drum

11: stator 12: axis

20: upper drum 21: rotor

30: bearing action member 31: bearing groove

32: bearing working surface

An embodiment of the present invention to which the above features are applied will be described in detail with reference to the accompanying drawings.

3 is a longitudinal sectional view of a head drum to which the present invention is applied.

The head drum 1 is composed of a lower drum 10 that is largely fixed on the VCR deck and an upper drum 20 that is rotated above the lower drum 10 to read the recorded contents of the video tape.

The lower drum 10 has a shaft 12 having a plurality of bearing grooves 12a formed on its outer circumferential surface at the center thereof vertically, and has a stator 11 and the stator 11 at an upper end of the shaft 12. The plate body 15 for fastening to 12 is mounted.

The upper drum 20 is fitted to the shaft 12 installed in the lower drum 10, the upper surface is equipped with a rotor 21 for electromagnetic action with the stator 11, the bottom surface read the recording of the video tape A plurality of heads 22 to be mounted are mounted, and the bushing 23 is mounted to be installed on the shaft 12 in a more stable manner.

Here, the fluid bearing device applied to the head drum 1 has a bearing action member 30 having a plurality of bearing grooves 31 radially formed on a top surface thereof at a predetermined position of a shaft 12 provided on the lower drum 10. A portion of the upper drum 20 that is press-fitted and rotatably installed on the shaft 12 is formed to be a bearing acting surface 32 in close proximity to the bearing groove 31 of the bearing acting member 30.

At this time, the bearing groove 31 is a spiral-shaped groove, and finishes at a certain distance from the outer circumference of the bearing action member 30 to the center side.

The meaning of the finish is that the bearing groove 31 is processed only to a certain distance from the inner circumference to the outer circumferential side in which the bearing 12 is fitted on the bearing action member 30, and the remaining portion is in the unprocessed state, so that the bearing groove 31 The outward end of the means that the upper surface and the jaw of the bearing action member 30 is built.

Reference numerals 14 and 24 are upper and lower rotary transformers.

Hereinafter, the operation of the present invention having the configuration of the above embodiment will be described in detail.

When the video drum (not shown) is in close contact with the outer surfaces of the upper and lower drums 20 and 10, the head drum 1 has the upper drum 20 due to the mutual electromagnetic action of the stator 11 and the rotor 21. As the upper drum 20 is rotated, the head 22 mounted on the upper drum 20 reads the recording contents of the video tape, and the recording contents read from the head 22 are the upper rotary transformer 24. Is applied to the outside of the head drum (1) through the lower rotary transformer (14).

At this time, when the upper drum 20 is rotated, the air present in the inner surface of the bearing groove 12a and the bushing 23 formed in the shaft 12 flows into the bearing groove 12a, thereby maintaining a constant pressure. And the pressure causes the shaft 12 and the upper drum 20 to rotate without contact.

In addition, a bearing action is also performed between the bearing action surface 32 of the upper drum 20 and the bearing groove 31 of the bearing action member 30 at the same time as the above-described bearing action. same.

When the upper drum 20 is rotated, the air between the bearing groove 31 and the bearing operating surface 32 of the bearing operating member 30 is outside the bearing operating member 30 along the bearing groove 31 surface. As the upper drum 20 is continuously rotated, the air is pushed to the finished portion of the bearing groove 31 through the bearing groove 31, so that the air accumulates at the outside of the bearing action member 30. do.

At this time, the distribution of the generated air pressure is as shown in Figure 4, from one end of the bearing groove 31 to which air is first introduced from the end of the bearing groove 31 to the end portion over the entire surface of the groove 31 Air gradually accumulates and becomes a downwardly depressed curve, and parallel curves are drawn due to the uniform pressure on the portion where the bearing groove 31 is closed and the outer circumferential surface of the bearing action member 30 in which the groove 31 is not formed. You lose.

Due to the curve as described above, the pressure point for supporting the rotating body, that is, the upper drum 20, supports the bearing working surface more widely, so that the upper drum 20 rotates more stably.

[Other embodiments of the present invention]

In the above-described drum motor, another embodiment of the present invention is to form a bearing groove formed in the bearing action member on the bearing action surface, referring to the configuration with reference to Figure 3 as follows.

The upper surface of the bearing acting member 30 has an extremely fine surface roughness, and a bearing groove 31 is formed on the bearing acting surface 32 opposite to the upper surface of the bearing acting member 30, wherein the bearing groove 31 is formed. ) Is formed outward from the inner circumferential portion in which the shaft 12 is installed, and ends with a predetermined distance from the outer end.

The fluid bearing device configured as described above can achieve the same effect as the present invention. In the fluid bearing device of the present invention, only when the rotating body, that is, the upper drum 20 is rotated, the bearing action member 30 is upper Unlike pushing the drum 20, the bearing acting surface 32 of the upper drum 20 is pushed and supported by the upper surface of the bearing acting member 30.

As described above, the present invention allows the air pressure concentration on the bearing member to be formed more widely, thereby eliminating the problem of malfunction even when an external force such as slight shaking is applied to the product to which the product is applied, so that the shaft is always uniform and stable. It is a useful invention to be rotated.

Claims (2)

The bearing actuating member is pushed into the shaft of the motor having the rotating body, and the bearing groove is formed on the upper surface of the bearing actuating member, and the portion adjacent to the bearing groove of the bearing actuating member of the rotating body is formed to be the bearing acting surface. In the fluid bearing device comprising, a plurality of bearing grooves are formed radially from the inner side to the outer circumference close to the center, the fluid bearing comprising a bearing action member for closing the bearing groove at a predetermined distance from the outer circumference Device. In the fluid bearing device comprising a bearing actuating member is pressed into the shaft of the motor having a rotating body, the portion proximate to the upper surface of the bearing actuating member in the rotating body to be a bearing acting surface formed with a bearing groove, the center of the A plurality of bearing grooves are formed radially from the inner side to the outer side in proximity to the outer side, wherein the bearing groove includes a bearing action surface for closing the outer end at a predetermined distance.

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