KR19990002828A - Disk stack assembly on the hard disk drive - Google Patents

Abstract

A hub that forms a central axis of rotation, a plurality of magnetic disks coupled to the hub for storing data, a clamp for fixing the plurality of magnetic disks to the hub, and a hub that is installed on an outer peripheral surface of the plurality of magnetic disks, A disk stack assembly of a hard disk drive having a spacer member for maintaining a predetermined distance, wherein the group of the plurality of magnetic disks is fixedly fixed to the hub in an arbitrary reference direction and the other group is opposite to the reference direction. The spacer member is characterized in that the eccentric magnetic disk group in the two directions is tightly fixed to the hub in the same direction as that of the magnetic disk group having the smaller number.

According to the present invention as described above, not only static balancing but also dynamic balancing can be maintained, and mass imbalance can be effectively eliminated. Therefore, vibration of the spindle system can be greatly alleviated, and as a result, errors in read / write operations can be reduced, thereby ultimately improving the performance of the hard disk drive.

Description

Disk stack assembly on the hard disk drive

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disk stack assembly of a hard disk drive, and more particularly, to a spindle unbalance due to disc assembly eccentricity, which offsets mass imbalance by using a spacer member between disks to maintain spindle balance. Relates to a disk stack assembly.

The hard disk drive is one of the auxiliary storage devices of the computer, and contributes to the operation of the computer by reading and playing data stored on the magnetic disk by the magnetic head or recording data on the magnetic disk.

In order to meet the demand of high speed, high capacity, and low vibration, such a hard disk drive has been variously developed. In particular, research on a bearing structure supporting a rotating body for high speed and low vibration has been actively conducted.

1 is a plan view schematically showing the configuration of a conventional hard disk drive.

Referring to FIG. 1, a conventional hard disk drive includes a base housing 11, a magnetic disk 12 for storing data, and a data for writing data to or reading data from the magnetic disk 12. It consists of a head coil assembly 14 and a voice coil motor 14 which provides a driving force for reciprocating the head stack assembly 13 in the radial direction of the magnetic disk 12.

Here, the magnetic disk 12 generally has a stack structure of a plurality of magnetic disks, and is fixed to the hub 16 by the clamp 15, and the head stack assembly 13 moves the pivot 13p. The pivoting movement is installed to the center. The head stack assembly 13 includes an actuator 13a, a plate-like load beam 13b having an elastic force, which is extended to and coupled to the actuator 13a, and a load beam 13b. It is composed of a magnetic head 13h fixed to an end to read data recorded on the magnetic disk 12 or to write data on the magnetic disk 12.

In addition, an iron piece 17 of a ferromagnetic material is provided at one end of the actuator 13a opposite to the magnetic head 13h, and on the turning motion trajectory of the iron piece 17 when the hard disk drive is stopped. A latch 18 for fixing the head stack assembly 13 by attracting and sucking the iron piece 17 is installed. Here, the latch 18 is composed of a permanent magnet 18m and a fixing member 18s for fixing the permanent magnet 18m.

2 illustrates a partial extract of a disk stack assembly in a conventional hard disk drive having the above configuration.

As shown in FIG. 2, in the conventional disk stack assembly, three magnetic disks 12a, 12b, and 12c are laminated in a stacked structure by spaced apart from each other by a spacer member 19a and 19b. It is fixed to 16).

In the conventional disk stack assembly as described above, a predetermined gap is provided between the inner circumferential surface of the magnetic disk 12 and the outer circumferential surface of the hub 16 in order to assemble the magnetic disk 12 to the hub 16. (e). Therefore, this gap e causes eccentricity in the spindle. Of course, in order to minimize such eccentricity, the gap e may be made as small as possible. However, when the gap e is made small, processing and assembly become difficult. Therefore, conventionally, as a countermeasure against such eccentricity, the three magnetic disks 12a, 12b, and 12c are fixed to the hub 16 in close contact with each other (arrows) at 120 ° intervals. However, such a method considers only single-sided balancing, and there is a problem that static imbalance can be eliminated, but dynamic imbalance cannot be eliminated. Let's explain this in more detail.

When the static imbalance in the disk stack assembly is U _st and the dynamic imbalance is U _dy , the U _st and U _dy can be expressed as the following equations.

U _st = U _12a + U _12b + U _12c = 0

_{dU dk}

Where U _12a = em _dk ∠240 °, U _12b = em _dk ∠120 °, U _12c = em _dk ∠0 °, U _dk (= em m _dk ) for disk unbalancing, And m _dk represents the mass of the disk, respectively.

Since the static imbalance U _st is an imbalance caused by the center of mass (m _dk ) of the disk in the state in which the disk is stopped, the centers of mass are maintained at 120 ° intervals as shown in Equation 1 above. The imbalance can be eliminated by letting the vector sum to zero. However, this does not take into account the dynamic imbalance U _dy due to the axial moment of the disk represented by Equation 2 above. This dynamic imbalance (U _dy ) is a type of excitation force like the first natural vibration model of a disk spindle system, which causes more vibration in the system as the spindle speed increases. In addition, such vibration affects the servo control system of the hard disk drive, making the read / write operation of the data unstable, thereby degrading the performance of the system.

Disclosure of Invention The present invention has been made to solve the above problems, and the disk stack of the hard disk drive which maintains spindle balancing by offsetting weight imbalance by using a spacer member between disks due to disk unbalance due to eccentricity in disk assembly The purpose is to provide an assembly.

1 is a plan view schematically showing the configuration of a conventional hard disk drive.

FIG. 2 is a fragmentary perspective view illustrating a disk stack assembly in the hard disk drive of FIG. 1. FIG.

FIG. 3 is a plan view of the disk stack assembly of FIG. 2 showing the disk eccentrically assembled to the hub. FIG.

4 is an external perspective view of a first embodiment of a disk stack assembly of a hard disk drive according to the present invention;

5 is an external perspective view of a second embodiment of a disk stack assembly of a hard disk drive according to the present invention.

Explanation of symbols for the main parts of the drawings

11 ... base housing 12,42,52 ... magnetic disc

13 ... head stack assembly 13a ... actuator

13b ... loaded beam 13h ... magnetic head

13p ... Pivot 14 ... Voice Coil Motor

15,45,55 ... Clamp 16,46,56 ... Hub

17.Iron 18.Latch

18 m.Permanent magnet 18 s.

19a, 19b, 49a, 49b, 59a, 59b, 59c, 59d ... spacer member

In order to achieve the above object, a disk stack assembly of a hard disk drive according to the present invention includes a hub that forms a central axis of rotation, a plurality of magnetic disks coupled to the hub for storing data, and the plurality of magnetic disks. In a disk stack assembly of a hard disk drive having a clamp fixed to an inner side and a spacer member provided on an outer circumferential surface of the plurality of magnetic disks to maintain a predetermined distance between the disks, a group of the plurality of magnetic disks may be any arbitrary. In the reference direction, the other group is tightly fixed to the hub in the direction opposite to the reference direction, and the spacer member is connected to the hub in the same direction as that of the magnetic disk group of the lesser number of the eccentric magnetic disk groups in the two directions. Its feature is that it is tightly fixed.

According to the present invention as described above, not only static balancing but also dynamic balancing can be maintained, and mass imbalance can be effectively eliminated. Therefore, vibration of the spindle system can be greatly alleviated, and as a result, errors in read / write operations can be reduced, thereby ultimately improving the performance of the hard disk drive.

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

4 is an external perspective view showing a first embodiment of a disk stack assembly of a hard disk drive according to the present invention.

Referring to FIG. 4, the disk stack assembly of the hard disk drive according to the present invention includes a hub 46 having a rotational central axis and three magnetic disks 42a and 42b coupled to the hub 46 for storing data. ) 42c, a clamp 45 for fixing the three magnetic disks 42a, 42b and 42c to the hub 46, and the three magnetic disks 42a, 42b and 42c. Spacers 49a and 49b which are provided on the hub outer peripheral surface to maintain a predetermined distance between the disks.

Here, as shown in order to eliminate the static imbalance as well as the dynamic imbalance in the disk stack assembly, the disk 42b located in the middle of the three magnetic disks 42a, 42b, 42c has an arbitrary direction ( In the figure, the right side is eccentric, and the remaining two discs 42a and 42c are eccentrically opposite to the eccentric direction (left side in the figure) of the disc 42b positioned in the center and fixed to the hub 46. The spacer members 49a and 49b are eccentric in the same direction as the eccentric direction of the disk 42b positioned in the center and fixed to the hub 46. In particular, the spacer members 49a and 49b here are designed such that their mass imbalance value is ½ of the disc's mass imbalance value. For this purpose, the outer circumferential surface of the hub 46 and the inner circumferential surface of the spacer members 49a and 49b clearance (e _sp) with is designed to satisfy the following relationship formula.

_Dk = _dk · m _dk e U = 2 · e · _sp m _sp

e _sp =

Here, e _dk represents the gap between the outer circumferential surface of the hub and the inner circumferential surface of the disk, and m _sp represents the mass of the spacer member, respectively.

When the spacer members 49a, 49b and the disks 42a, 42b, 42c are assembled to the hub 46 by the above gap e _sp condition, the disks 42a, 42b are assembled. The static imbalance U _st 'and the dynamic imbalance U _dy ' by 42c and the spacer members 49a and 49b may be expressed by the following equations, respectively.

U _st '= (U _42c + U _42a )-(U _49b + U _42b + U _49a ) = 0

U _dy '= d · (U _42c -U _42a ) + ½d · (U _49b -U _49a ) + 0U _42b = 0

Where U _42a = U _42b = U _42c = 2U _49a = 2U _49b

As can be seen from the above Equations 4 and 5, the static imbalance (U _st ') and the dynamic imbalance (U _dy ') in the disk stack assembly according to the present invention shows that the value is completely removed as 0. Can be.

On the other hand, Figure 5 is an external perspective view showing a second embodiment of a disk stack assembly of a hard disk drive according to the present invention.

As shown in FIG. 4, the second embodiment is basically the same as that of the first embodiment except for two more disks and two spacer members than the first embodiment of FIG. Do. Therefore, the description of each component will be omitted, and only the features described will be described.

Referring to FIG. 5, in the disk stack assembly of the second embodiment of the present invention, among the five magnetic disks 52a to 52e, the disk 52c located in the center is eccentric in an arbitrary direction (left side in the drawing), and the disk The two disks 52b and 52d immediately adjacent to the 52c are eccentrically opposed to the eccentric direction (right in the drawing) of the disk 52c positioned in the center and fixed to the hub 56, and the remaining two The disks 52a and 52e are eccentric in the eccentric direction of the two disks 52b and 52d immediately adjacent to the centered disk 52c and in the opposite direction (the left side in the drawing), respectively, to the hub 56. The spacer members 59a to 59d are eccentric in the same direction (right side in the drawing) as the eccentric direction of the two disks 52b and 52d immediately adjacent to the disk 52c positioned in the center, and the hub 56 is fixed. Is fixed to. Reference numeral 55 denotes a clamp.

The disk stack assembly of the second embodiment having the above configuration is also designed such that the mass imbalance value of the spacer members 59a to 59d is ¼ of the mass imbalance value of the magnetic disks 52a to 52e. Therefore, even in this case, the static imbalance and the dynamic imbalance are completely eliminated as zero.

As described above, the disk stack assembly of the hard disk drive according to the present invention can maintain dynamic balancing as well as static balancing, thereby effectively eliminating mass imbalance. Therefore, vibration of the spindle system can be greatly alleviated, and as a result, errors in read / write operations can be reduced, thereby ultimately improving the performance of the hard disk drive.

Claims (5)

A hub that forms a central axis of rotation, a plurality of magnetic disks coupled to the hub for storing data, a clamp for fixing the plurality of magnetic disks to the hub, and a hub that is installed on an outer peripheral surface of the plurality of magnetic disks, In a disk stack assembly of a hard disk drive having a spacer member for maintaining a predetermined distance, One group of the plurality of magnetic disks is fixedly fixed to the hub in an arbitrary reference direction, the other group is opposite to the reference direction, and the spacer member is the magnetic disk of the lesser number of the eccentric magnetic disk groups in the two directions. The disk stack assembly of the hard disk drive, characterized in that tightly fixed to the hub in the same direction as the direction of the group. The method of claim 1, When there are three magnetic disks, the centrally located disk is eccentric in any direction, and the remaining two disks are eccentrically opposite to the eccentric direction of the centrally located disk and are fixed to the hub, and the spacer member is fixed to the center. A disk stack assembly of a hard disk drive, wherein the disk is eccentric in the same direction as the eccentric direction of the disk and is fixed to the hub. The method of claim 1, When there are five magnetic disks, the centrally located disk is eccentric in an arbitrary direction, and the two disks immediately adjacent to the disk are eccentrically opposite to the eccentric direction of the centrally located disk and are fixed to the hub. The two disks are eccentric in the opposite direction to the eccentric direction of the two disks immediately adjacent to the disk located in the middle, and fixed to the hub, and the spacer member is eccentric of the two disks immediately adjacent to the disk located in the middle. A disk stack assembly of a hard disk drive, characterized by being eccentric in the same direction and being fixed to the hub. The method of claim 2, And the mass imbalance value of the spacer member is ½ of the mass imbalance value of the magnetic disk. The method of claim 3, And the mass imbalance value of the spacer member is ¼ of the mass imbalance value of the magnetic disk.