KR19980077734A - Axial center compensator of fluid bearing - Google Patents

Abstract

The present invention relates to a shaft center compensator for a fluid bearing, and more particularly, to a shaft of a fluid bearing which automatically corrects an eccentricity generated during assembly of a shaft and a bearing so that the rotation of the shaft and the rotating body is smooth and stable. A center compensator. The present invention for this purpose is to correct the misalignment between the shaft is formed a certain type of groove for generating the fluid pressure and the bearing member is pressed through the shaft so that the center of the shaft is automatically maintained An axial center compensator of a fluid bearing, wherein the bearing member has an inner circumferential surface that is rotatably wrapped in a predetermined circumferential direction in a predetermined circumferential direction thereof, and is guided to guide and support the bearing member when the bearing member rotates in the circumferential direction. Hub means provided with means, the bearing member is provided with eccentricity correction means for loosely coupled to the guide support means for rotating the bearing member to the left and right to correct the eccentricity between the bearing member and the shaft. It is done.

Description

Axial center compensator of fluid bearing

The present invention relates to a shaft center compensator for a fluid bearing, and more particularly, to a shaft of a fluid bearing which automatically corrects an eccentricity generated during assembly of a shaft and a bearing so that the rotation of the shaft and the rotating body is smooth and stable. A center compensator.

In general, the fluid bearing is applied to a rotating shaft of various motor devices that rotate at high speed, such as a drum motor such as a video cassette or camcorder, a scanning motor of a laser printer or scanner, or a motor of a hard disk device. The bearing region is selectively formed on a predetermined surface or a bearing action member mounted to the shaft and the rotating body so that the bearing action is known by utilizing the air pressure generated between the outer peripheral surface of the rotating body or the shaft adjacent to the bearing region.

In the case of such a fluid bearing, this means that the spacing between the shaft and the space where the shaft is installed is very fine, which means that the machining surface must be extremely precise in the shaft and the space where the shaft is installed. The work was very difficult and the machining failure rate was very high.

In addition, when the shaft is press-fitted into a rotating body, a housing, or the like, there have been many cases in which the center of gravity of the shaft is deteriorated due to a predetermined pressing force and a fabrication work. That is, the above problems generated during the fabrication work for the device to which the fluid bearing is applied develops into a fatal problem in the finished product. As follows.

1 is a cross-sectional view of a hard disk motor device to which a conventional fluid bearing is applied, and FIG. 2 is a schematic view showing a representative example of a failure factor that causes a conventional problem.

Referring to FIG. 1, a hard disk motor apparatus 100 to which a conventional fluid bearing is applied includes a shaft 1 serving as a fixed portion, a housing 2 surrounding the outside of the motor apparatus 100, and The thrust bearing 5 and the sealing part which are applied for the thrust load applied to the stator 3, the motor pin 4, and the axis 1 direction which interact with and rotate the rotor 10 to be described later. (7) comprising a journal bearing (6), which acts as a rotating part in the hard disk motor device (100), a hub (8) surrounding the journal bearing (6), and a field yoke (9) , Including the rotor 10. Here, the journal bearing (6) is installed for the load acting perpendicular to the shaft (1), the rotor 10 is rotated of the motor device 100 to rotate in interaction with the stator (3) It acts as a site. And, a predetermined portion of the shaft (1) is formed with a herringbone-shaped groove (11) between the shaft (1) and the journal bearing (6), and between the shaft (1) and the thrust bearing (5). Generates a known fluid pressure.

By the way, in the motor apparatus 100 comprised as mentioned above, the shaft 1 press-fits between the center part of the motor apparatus 100, ie, the thrust bearing 5, the journal bearing 6, the housing 10, etc. 2, the shaft 1 is frequently pressed into a predetermined angle eccentric on the center line thereof, as shown in FIG. When reading the problem there was a problem that adversely affects the data.

Furthermore, when the shaft is press-fitted and fixed, as described above, if the shaft is fixed and press-fitted incorrectly, run-out during rotation of the motor device may deteriorate, which may have a fatal adverse effect on the application system using the motor device. There was a problem.

The present invention has been made to solve the above problems, and by adding a correction means for automatically correcting the shaft even when the axis does not match exactly on a predetermined center line, ie eccentrically press-fixed when fixed An object of the present invention is to provide a shaft center compensator for a fluid bearing to improve the rotational stability of the motor.

It is still another object of the present invention to provide a shaft center compensating device for a fluid bearing to improve run durability of a rotating body by preventing run-out from deteriorating when the rotating body is rotated about an axis. have.

1 is a schematic view showing a motor device including a fluid bearing applied to a general hard disk system;

2 is a configuration diagram showing a state in which a predetermined axis is eccentrically pressed in;

3 is a block diagram illustrating a motor device of a hard disk system to which a shaft center correction device of a fluid bearing according to the present invention is applied;

4 is an operation state diagram for explaining the operation of the axis center correction device of the fluid bearing according to the present invention,

5 and 6 are diagrams showing other embodiments of the axis center correction device of the fluid bearing according to the present invention.

* Explanation of symbols for the main parts of the drawings

1: axis 30: eccentricity correction auxiliary member

40: ball member 50: rubber elastic member

60: journal bearing 62: eccentricity correction groove

80: hub 82: guide support

In order to achieve the above object, the axial center compensator of a fluid bearing according to the present invention comprises a misalignment between an axis in which a groove of a predetermined form for generating fluid pressure is formed and a bearing member through which the axis is press-fitted. (C) wherein the bearing member has an inner circumferential surface that is rotatably wrapped in a predetermined circumferential direction in a predetermined circumferential direction so that the center of the shaft is automatically maintained. Hub means including a guide support means for guiding and supporting it when rotating in the circumferential direction, wherein the bearing member is loosely coupled to the guide support means to right and left the bearing member so that eccentricity between the bearing member and the shaft is corrected. Eccentricity correction means that rotates There is.

In a preferred embodiment of the present invention, the bearing member is a journal bearing, and the guide support means and the eccentricity correction means are each made of a fin.

In a preferred embodiment of the present invention, it may further include an eccentricity correction auxiliary means interposed between the hub and the journal bearing to facilitate the rotation for the shaft center correction of the journal bearing.

In order to achieve the above object, a shaft center compensator for a fluid bearing according to another embodiment of the present invention is provided between a shaft in which a groove of a predetermined form for generating a fluid pressure is formed and a bearing member through which the shaft is press-fitted. An apparatus for correcting a shaft center of a fluid bearing for correcting misalignment of a shaft so that the center of the shaft is automatically maintained, comprising: a hub means positioned on an outer circumferential surface of the bearing member and having a plurality of predetermined recesses formed therein; And a ball member rotatably inserted into the recess to allow the bearing member to rotate left and right according to the eccentricity of the shaft, wherein the remaining part of the ball member is rotatably inserted into the bearing member. A plurality of grooves are formed to allow the member to rotate left and right according to the eccentricity of the shaft. There are those characterized by.

In addition, the shaft center correction device of a fluid bearing according to another embodiment of the present invention for achieving the above object, the shaft is formed with a groove of a predetermined form for generating a fluid pressure and the bearing member is passed through the shaft A shaft center correction apparatus for a fluid bearing that corrects misalignment between the shafts so that the center of the shaft is automatically maintained, comprising: a hub means positioned on an outer circumferential surface of the bearing member, and connecting the hub means and the bearing member; And it is characterized in that it comprises a rubber elastic member for rotating the bearing member in accordance with the eccentricity of the shaft.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the axis center correction device of the bearing according to the present invention. For convenience of description, the same reference numerals and the same names will be used for the same member as the conventional member.

3 to 6 are cross-sectional views showing a part of a hard disk system in which a shaft center compensator of a bearing according to the present invention is used, and parts not shown in the drawings are the same as in the conventional configuration, and description thereof will be omitted.

The shaft center correction apparatus of the bearing according to the embodiment of the present invention corrects the eccentricity between the shaft 1 and the bearing member that is press-fitted through the shaft 1, that is, the journal bearing 60, so that the shaft 1 It is to maintain the center of the automatic, the journal bearing 60 has an inner circumferential surface that is wrapped in a predetermined circumferential rotation in a predetermined circumferential direction therein and when the journal bearing 60 rotates in the circumferential direction And a hub 80 having a guide support 82 for guiding and supporting the guide bearing 82. The journal bearing 60 is loosely coupled to the guide support 82, between the journal bearing 60 and the shaft 1. An eccentricity correction recess 62 is provided which rotates the bearing member from side to side so that the eccentricity of the shaft is corrected. Here, the axis center correction device of the present invention is interposed between the hub 80 and the journal bearing 60, as shown in Figure 4 to rotate for the center (1) of the journal bearing 60 correction An eccentricity correction auxiliary member 30 may be preferably provided. In addition, in the present invention, the guide support 82 and the eccentricity correction recess 62 are each preferably made of 凸凹 as shown.

Referring to Figures 3 and 4 the operation of the shaft center correction device of the bearing according to the present invention configured as described above are as follows.

For example, as shown in FIG. 4A, the shaft 1 is eccentrically pressed into the journal bearing 60 at a predetermined angle θ, and the device including the same, that is, as shown in FIG. 3. When the disk system is operated, the shaft may be rotated by the rotation of the eccentric correction recess 62 of the journal bearing 60 and the guide support 82 of the hub 80 and the eccentric correction auxiliary member 30 provided in accordance with the present invention. The eccentric indentation state of 1) is corrected as shown in FIG. 4B. In more detail, when the journal bearing 60 or the shaft 1 rotates, a herringbone groove 11 formed in the shaft 1 is formed between the journal bearing 60 and the shaft 1. The fluid pressure is generated. When the fluid pressure is generated as described above between the journal bearing 60 and the shaft 1 while the shaft 1 is eccentrically pressed into the journal bearing 60, the fluid pressure is equal to the amount of the eccentricity of the shaft 1. Will cause a difference. When a difference in fluid pressure occurs between the journal bearing 60 and the shaft 1, the journal bearing 60 is used to eliminate the difference in the fluid pressure, that is, to achieve an equilibrium state of the fluid pressure. Will rotate as The journal bearing 60 rotates until the fluid pressure between the shaft 1 and the journal bearing 60 is in equilibrium, whereby the center of the shaft 1 is accurately corrected.

In addition, the shaft center correction device of the bearing of another embodiment according to the present invention, as shown in Figure 5 is located in the outer peripheral portion of the journal bearing 60, the hub having a predetermined plurality of grooves (84) ( 80 and a predetermined portion of the ball member 40 is rotatably inserted into the groove 84 to allow the journal bearing 60 to rotate left and right according to the eccentricity of the shaft 1. In addition, in another embodiment of the present invention, the remaining predetermined portion of the ball member 40 is rotatably inserted into the journal bearing 60 so that the journal bearing 60 is left and right according to the eccentricity of the shaft 1. A plurality of grooves 64 are formed to allow rotation. The axis center correction device according to another embodiment of the present invention having such a configuration automatically corrects the eccentricity of the shaft 1 as described with reference to FIG. 4, which has the advantage of making the configuration simpler. Will have

Moreover, the shaft center compensator of the bearing of another embodiment according to the present invention, as shown in Figure 6, the hub 80, which is located in the outer peripheral portion of the journal bearing 60, the hub 80 and the journal It comprises a rubber elastic member (50) connecting the bearings (60) and allowing the journal bearing (60) to rotate left and right according to the eccentricity of the shaft (1). In the shaft center compensator of another embodiment of the present invention having such a configuration, the eccentricity of the shaft 1 is automatically corrected by the rubber elastic member 50. That is, the rubber elastic member 50 of FIG. 6 replaces the eccentric correction recess 62, the guide support 82, and the eccentric correction auxiliary member 30, which act as the axis center correction means of FIG. Eccentricity will be corrected automatically. Therefore, according to such a structure, it has the advantage that it becomes much simpler in the structure.

As described above, the shaft center compensator of the fluid bearing according to the present invention has correction means for automatically correcting the shaft even when the shaft does not exactly match the predetermined center line when the shaft is press-fitted. By adding it, the effect which can improve the rotational stability of a rotating body is provided.

Claims (7)

Correction of the axis center of the fluid bearing which corrects the misalignment between the shaft where a certain type of groove is formed for generating the fluid pressure and the bearing member through which the shaft is press-fitted. 21. An apparatus comprising: a hub means having an inner circumferential surface which is rotatably wrapped in a predetermined circumferential direction in a predetermined circumferential direction therein and provided with guide supporting means for guiding and supporting the bearing member as it rotates in the circumferential direction; And the eccentric correction means which is loosely coupled to the guide support means and rotates the bearing member from side to side to correct the eccentricity between the bearing member and the shaft is provided in the bearing member. Compensator. The apparatus of claim 1, wherein the bearing member is a journal bearing. The axial center compensating device for a fluid bearing according to claim 1, wherein the guide supporting means has a shape of 凸. The axial center compensating device of a fluid bearing according to claim 1, wherein said eccentricity correction means has a shape of 凹. 5. An eccentricity correction aid according to any one of claims 1 to 4, further comprising an eccentricity correction aid interposed between the hub means and the bearing member to smoothly rotate for the shaft center correction of the bearing member. Axial center compensator for fluid bearings. In the axis center correction device of a fluid bearing to correct the eccentricity between the shaft is formed a groove of a certain type for generating a fluid pressure and the bearing member which is pushed through the shaft to automatically maintain the center of the shaft And a hub means positioned on an outer circumferential surface of the bearing member and having a predetermined plurality of recesses formed therein, and the predetermined portion being rotatably inserted in the recess to rotate the bearing member left and right according to the eccentricity of the shaft. And a ball member, wherein the bearing member has a plurality of grooves formed to rotatably insert the remaining portion of the ball member so that the bearing member can rotate left and right according to the eccentricity of the shaft. Axis center compensator. In the axis center correction device of a fluid bearing to correct the eccentricity between the shaft is formed a groove of a certain type for generating a fluid pressure and the bearing member which is pushed through the shaft to automatically maintain the center of the shaft And a hub means positioned on an outer circumferential surface of the bearing member, and a rubber elastic member connecting between the hub means and the bearing member and allowing the bearing member to rotate left and right according to the eccentricity of the shaft. Axial center compensator for bearings.