KR20060057858A - Disk damping apparatus for hard disk drive - Google Patents

Abstract

Disc damping device of a hard disk drive is disclosed. Disclosed disc damping device is disposed between a plurality of disks, and provided with a lower disk damper and an upper disk damper stacked at predetermined intervals, and support means for supporting the lower disk damper and the upper disk damper, respectively, to vertically move, When the disc is rotated, the lower disk damper is lowered and the upper disk damper is raised by the air flowing between the lower disk and the upper disk, so that the gap between the lower disk damper and the upper disk damper is widened, so that the lower and upper disk dampers are separated from each other. It is characterized in that the interval between the narrowed. According to such a configuration, the vibration of the disk can be more effectively reduced when the disk is rotated, and the possibility of collision between the disk and the disk damper due to external impact can be reduced when the disk is stopped rotating.

Description

Disk damping apparatus for hard disk drive

1 is a perspective view showing a conventional disk damper installed between the disks.

2 is a vertical cross-sectional view of the disk and the disk damper shown in FIG.

3 is an exploded perspective view showing a hard disk drive having a disk damping device according to a preferred embodiment of the present invention.

4 is an exploded perspective view illustrating an enlarged portion A shown in FIG. 3.

5 is a cross-sectional view of the upper and lower disk dampers along the line X-X 'shown in FIG.

6A and 6B are partial vertical cross-sectional views of the disk and the disk damping device along the line Y-Y 'shown in FIG. 4, and FIG. 6A is a view showing the disk is stopped rotating, and FIG. 6B is a disk rotating. It is a figure which shows the state to make.

<Explanation of symbols for the main parts of the drawings>

111.Base member 112 ... Cover member

114 ... gasket 119 ... fastening screw

120a, 120b ... disk 130 ... spindle motor

132 ... spacer 134 ... disc clamp

140 ... actuator 142 ... slider

144 Suspension 146 Swing arm

147 ... actuator pivot 148 ... voice coil motor

200 ... disk damping device 211 ... lower disk damper

212 Upper disc damper 213,214 Slope

221,222 ... supporting protrusions 223, 224 ... pin insertion holes

230 ... Guide pin 232 ... Thread

234 Screw mounting holes 240 Spacers

251 ... lower spring 252 ... upper spring

260 Screw 271 Boss

272 screw thread

The present invention relates to a hard disk drive, and more particularly, to a disk damping device of a hard disk drive for reducing vibration of a rotating disk.

A hard disk drive (HDD), which is one of information storage devices of a computer, is a device for reproducing data stored on a disc or recording data on a disc using a read / write head. In such a hard disk drive, the head performs its function while being moved to a desired position by an actuator in a state in which the head rises a predetermined height from the recording surface of the rotating disk.

Such a hard disk drive includes a spindle motor, one or a plurality of data storage disks mounted on the spindle motor, and an actuator for moving a read / write head for reproducing and writing data to a predetermined position on the disk. .

The disk, spindle motor and actuator are wrapped by a housing consisting of a base member and a cover member. The base member and the cover member are assembled using a plurality of fastening screws.

On the other hand, in the hard disk drive having such a configuration, fluttering occurs in the rotating disk due to component defects in the spindle motor, eccentric assembly of the disk, irregular air flow in the hard disk drive, and the like. In particular, there is a non-negligible air flow around the high-speed rotating disk, such as the space between the disks, which is the biggest factor causing the vibration of the disk. As the vibration occurs in the disk as described above, the position error signal (PES) increases, which degrades the data recording and reproducing ability of the read / write head, and thus adversely affects the performance of the hard disk drive.

Recently, in order to improve such a problem, a method of providing a thin disk-shaped disk damper between the disks has been proposed.

1 is a perspective view showing a conventional disk damper installed between the disks, and FIG. 2 is a vertical cross-sectional view of the disk and disk damper shown in FIG.

1 and 2 together, a plurality of disks 31 and 32 are mounted on the spindle motor 20 installed on the base member 10 of the hard disk drive, and between the disks 31 and 32. The disk damper 40 is provided in this. If the disk damper 40 is installed between the disks 31 and 32 in this way, the distance between the disks 31 and 32 and the disk damper 40 is narrowed, and thus the disks 31 and 32 and the disks are thus narrowed. Vibration of the disks 31 and 32 can be reduced by the damping effect of the compressed air between the dampers 40.

At this time, the narrower the space between the disks 31 and 32 and the disk damper 40, the more rigid the air therebetween, and the vibration reduction effect of the disks 31 and 32 becomes higher. However, when the hard disk drive is subjected to an impact when the hard disk drive is not in operation or during the impact test process of the hard disk drive, the smaller the distance between the disks 31 and 32 and the disk damper 40, the more the disk 31 , 32) and the disk damper 40 is likely to collide. As such, when the disks 31 and 32 collide with the disk damper 40, the data recording surfaces of the disks 31 and 32 may be damaged, and an error may occur during a read / write operation.

Recently, as the data storage capacity of the disks 31 and 32 is rapidly increasing, the track per inch (TPI) is also steadily increasing. In this case, the vibrations of the disks 31 and 32 have a greater influence on the PES. However, reducing the distance between the disks 31 and 32 and the disk damper 40 to reduce the vibrations of the disks 31 and 32 is a collision between the disks 31 and 32 and the disk damper 40 as described above. There is a limitation due to the problem.

The present invention has been made to solve the problems of the prior art as described above, in particular, when the disk is rotated to reduce the vibration of the disk more effectively by narrowing the distance between the disk and the disk damper and when the disk stops rotating It is an object of the present invention to provide a disk damping device for a hard disk drive having a configuration that can increase the distance between the disk and the disk damper to reduce the possibility of collision between the disk and the disk damper due to external impact.

Disc damping device of a hard disk drive according to the present invention for achieving the above technical problem,

To reduce the vibration of a plurality of disks mounted on the spindle motor of the hard disk drive,

A lower disk damper and an upper disk damper, which are disposed between the plurality of disks and are stacked at predetermined intervals; And support means for supporting the lower disk damper and the upper disk damper to be vertically movable, respectively.

When the disk is rotated, the lower disk damper is lowered and the upper disk damper is raised by the air flowing between the lower disk and the upper disk, so that the gap between the lower disk damper and the upper disk damper is widened, so that the lower and upper disk It is characterized in that the gap between each of the dampers and the disk is narrowed.

In the present invention, the support means, a protrusion formed on the outer periphery of the lower disk damper and the upper disk damper and having a pin insertion hole; A guide pin fixed to the base member of the hard disk drive and inserted into the pin insertion hole to guide vertical movement of the lower disk damper and the upper disk damper; It is preferable to include an elastic member coupled to the guide pin to provide an upper elastic force to the lower disk damper and a lower elastic force to the upper disk damper.

Further, it is more preferable that a spacer is disposed between the lower disk damper and the upper disk damper to maintain a minimum gap therebetween. In this case, the spacer may be fixed to the middle portion of the guide pin.

In addition, the guide pin may be screwed to the base member.

In the present invention, a screw is fastened to the upper end of the guide pin, the elastic member is a lower spring coupled to the outer circumference of the guide pin to be disposed between the support projection of the lower disk damper and the base member, and the upper disk It may be provided with an upper spring coupled to the outer circumference of the guide pin to be disposed between the support protrusion of the damper and the head of the screw.

In the present invention, the lower disk damper and the upper disk damper preferably has a ring shape with a portion open.

In the present invention, a plurality of supporting means may be provided at predetermined intervals along the outer circumference of the lower disk damper and the upper disk damper.

In the present invention, it is preferable that the inclined surfaces of the lower disk damper and the upper disk damper are formed so as to face each other.

According to the present invention as described above, the vibration of the disk can be reduced more effectively when the disk is rotated, and the possibility of collision between the disk and the disk damper due to external impact can be reduced when the disk is stopped rotating.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the following drawings indicate like elements.

3 is an exploded perspective view showing a hard disk drive having a disk damping device according to a preferred embodiment of the present invention, Figure 4 is an exploded perspective view showing an enlarged portion A shown in Figure 3, Figure 5 is Sectional drawing of the upper and lower disk dampers along the line X-X '.

3 to 5, the hard disk drive includes a plurality of data storage disks 120a and 120b, a spindle motor 130 for rotating the disks 120a and 120b, and a read / write head. Actuator 140 is provided for moving the to a predetermined position on the disk (120a, 120b).

The disks 120a and 120b, the spindle motor 130, and the actuator 140 are wrapped and protected by the base member 111 and the cover member 112. The base member 111 and the cover member 112 are coupled to each other by a plurality of fastening screws 119. At this time, a gasket 113 is inserted between the base member 111 and the cover member 112 to prevent dust or moisture from flowing into the hard disk drive. The gasket 113 is generally made of viscoelastic material, such as rubber, to also function to dampen vibrations of the hard disk drive.

The disks 120a and 120b are recording media for recording data, and a plurality of disks 120a and 120b are mounted on the spindle motor 130 to be rotated by the spindle motor 130.

The spindle motor 130 is for rotating the disks 120a and 120b and is installed on the base member 111. When the plurality of disks 120a and 120b are mounted on the spindle motor 130 as described above, a ring-shaped spacer 132 for maintaining the gap between the disks 120a and 120b is provided with the disks 120a. , And a disk clamp 134 is coupled to the upper end of the spindle motor 130 to prevent the disks 120a and 120b from being separated from each other.

The actuator 140 is used to move a read / write head for recording data on the discs 120a and 120b or reproducing the recorded data to a predetermined position on the discs 120a and 120b. The base member 111 It is installed to be rotatable on the phase. In detail, the actuator 140 includes a swing arm 146 rotatably coupled to an actuator pivot 147 installed on the base member 111, and is mounted at one end of the swing arm 146 to mount the head. And a suspension 144 for elastically biasing the slider 142 to the surfaces of the disks 120a and 120b, and a voice coil motor VCM for rotating the swing arm 146.

The voice coil motor 148, controlled by a servo control system, causes the swing arm 146 to rotate in a direction conforming to Fleming's left hand law by the interaction of a current input to the VCM coil with a magnetic field formed by the magnet. do. That is, when the power of the hard disk drive is turned on and the disk 120a 120b starts to rotate, the voice coil motor 148 rotates the swing arm 146 to mount the read / write head slider 142. ) Is moved onto the data recording surfaces of the discs 120a and 120b. The slider 142 rises a predetermined height from the surfaces of the disks 120a and 120b, that is, the data recording surface, by lift generated by the rotating disks 120a and 120b, and is mounted on the slider 142 in such a state. The used head performs a function of reproducing or recording data on the recording surfaces of the discs 120a and 120b. Conversely, when the hard disk drive is not operating, i.e., when the rotation of the disks 120a and 120b is stopped, the voice coil motor 148 rotates the swing arm 146 to move the head mounted slider 142. The data is recorded off the data recording surfaces of the discs 120a and 120b.

In addition, the disk damping device 200 according to the present invention for reducing the vibration of the disk (120a, 120b) is provided in the hard disk drive having the configuration as described above. Disc damping device 200 according to the present invention, the lower disk damper 211 and the upper disk damper 212 disposed between the disk (120a, 120b), the lower disk damper 211 and the upper disk damper ( And support means for supporting 212 each so as to be movable vertically.

The lower disk damper 211 and the upper disk damper 212 each have a thin plate shape. In addition, the lower disk damper 211 and the upper disk damper 212 preferably have a large enough area so as not to interfere with other components of the hard disk drive, for example, the actuator 140. This is because, as the mutually opposing areas of the lower disk damper 211, the upper disk damper 212, and the disks 120a and 120b are larger, more efficient air damping effect can be obtained. Specifically, the lower disk damper 211 and the upper disk damper 212 has a ring shape in which a portion including the operating range of the actuator 140 is opened. The lower disk damper 211 and the upper disk damper 212 may be manufactured by press working of aluminum sheet, aluminum die casting or plastic injection molding.

The lower disk damper 211 and the upper disk damper 212 having the above-described shapes are stacked at predetermined intervals from each other. That is, the lower disk damper 211 and the upper disk damper 212 are paired and disposed between the disks 120a and 120b. As shown in the drawing, when the two disks 120a and 120b are mounted on the spindle motor 130, a pair of disk dampers 211 and 212 are disposed between the two disks 120a and 120b. When three or more disks are mounted on the spindle motor 130, a pair of disk dampers are disposed between the disks adjacent to each other.

The lower disk damper 211 and the upper disk damper 212 are supported to be vertically movable by the support means. The support means may be provided in plural, for example, three, at predetermined intervals along the outer circumference of the lower disk damper 211 and the upper disk damper 212.

The support means may include support protrusions 221 and 222 provided on the lower disk damper 211 and the upper disk damper 212, and guide pins 230 fixed to the base member 111 of the hard disk drive. It is provided with an elastic member coupled to the guide pin 230.

The support protrusions 221 and 222 protrude from the outer circumferences of the lower disk damper 211 and the upper disk damper 212, respectively. Pin support holes 223 and 224 into which the guide pin 230 is inserted are formed in the support protrusions 221 and 222, respectively.

The guide pin 230 is inserted into the pin insertion holes 223 and 224 to guide the vertical movement of the lower disk damper 211 and the upper disk damper 212. The guide pin 230 may be fixed by screwing to the base member 111. To this end, a threaded portion 232 is formed at the lower end of the guide pin 230, and a threaded fastening hole 272 to which the threaded portion 232 of the guide pin 230 is fastened to an upper surface of the base member 111. Excitation boss 271 may be formed to protrude.

The elastic member serves to provide elastic force in different directions to each of the lower disk damper 211 and the upper disk damper 212. Specifically, the elastic member, the lower spring 251 is coupled to the outer circumference of the guide pin 230 to be disposed between the support protrusion 223 of the lower disk damper 211 and the boss 271 of the base member 111. And an upper spring 252 coupled to the outer circumference of the guide pin 230 to be disposed on the support protrusion 224 of the upper disk damper 212. In addition, a screw fastening hole 234 is formed at an upper end of the guide pin 230, and a screw 260 having a screw head having a diameter larger than that of the upper spring 252 is fastened thereto. Accordingly, the upper spring 252 is fitted between the support protrusion 224 of the upper disk damper 212 and the screw head of the screw 260.

In addition, a spacer 240 is disposed between the lower disk damper 211 and the upper disk damper 212 to maintain a minimum gap therebetween. Specifically, the spacer 240 may be fixed to the middle portion of the guide pin 230.

According to the configuration as described above, the upper elastic force is applied to the lower disk damper 211 by the lower spring 251, and the lower elastic force is applied to the upper disk damper 212 by the upper spring 252. do. Accordingly, the elastic force is applied to the lower disk damper 211 and the upper disk damper 212 in a direction in which the lower disk damper 212 is in close contact with each other, but a constant distance is maintained by the spacer 240.

Meanwhile, the inclined surfaces 213 and 214 may be formed to face each other at an air inlet side end of each of the lower disk damper 211 and the upper disk damper 212. By the inclined surfaces 213 and 214, as shown in FIG. 5, the inflow of air between the lower disk damper 211 and the upper disk damper 212 may occur more smoothly.

6A and 6B, the operation of the disk damping device according to the present invention having the configuration as described above will be described.

6A and 6B are partial vertical cross-sectional views of the disk and the disk damping device along the line Y-Y 'shown in FIG. 4, and FIG. 6A is a view showing the disk is stopped rotating, and FIG. 6B is a disk rotating. It is a figure which shows the state to make.

Referring first to FIG. 6A, when the hard disk drive is not operated, that is, when the rotation of the disks 120a and 120b is stopped, the lower disk damper 211 and the upper disk damper 212 have a lower spring 251 and An elastic force is applied in the direction in which the upper spring 252 is in close contact with each other. Accordingly, the lower disk damper 211 and the upper disk damper 212 maintain the gap as much as the thickness of the spacer 240. At this time, the space G ₁ between the lower disk damper 211 and the upper disk damper 212 may be set to a size such that 0.1 mm to 0.3 mm is enough to allow air to smoothly flow therebetween.

In addition, the gap G ₂ between the lower disk damper 211 and the lower disk 120a corresponding thereto and the upper disk damper 212 and the upper disk 120b corresponding thereto is shown in FIG. 2. The distance between the damper 40 and the disks 31 and 32 may be set equal to or greater than. That is, the gap G ₂ may be set to 0.4 mm to 0.5 mm or larger. As described above, according to the present invention, since the distance G ₂ between the disks 120a and 120b and the disk dampers 211 and 212 can be kept relatively wide, the impact test of the hard disk drive when the hard disk drive is inactive or not. When a shock is applied to the hard disk drive in the process, the possibility of collision between the disks 120a and 120b and the disk dampers 211 and 212 may be reduced.

Next, referring to FIG. 6B, when the hard disk drive is operated and the disks 120a and 120b start to rotate, the air in the direction of arrow F shown in FIGS. 4 and 5 as the disks 120a and 120b rotate. The flow is created. This air flow is not only between the lower disk damper 211 and the lower disk 120a and between the upper disk damper 212 and the upper disk 120b, but also at a predetermined distance from the lower disk damper 211 and the upper disk damper 212. It also flows in between. At this time, as described above, since the inclined surfaces 213 and 214 are formed at the air inflow end portions of the lower disk damper 211 and the upper disk damper 212, the lower disk damper 211 and the upper disk damper 212. The inflow of air between them can be much smoother.

As such, the lower disk damper 211 moves downward and the upper disk damper 212 moves upward by the pressure of the air introduced between the lower disk damper 211 and the upper disk damper 212. The gap G ₁ becomes wider. Accordingly, the gap G ₂ between the lower disk damper 211 and the lower disk 120a and between the upper disk damper 212 and the upper disk 120b is narrowed. At this time, the narrowed gap G _{2 preferably} has a gap between the conventional disk damper and the disk, that is, a size smaller than 0.4 mm to 0.5 mm, for example, about 0.1 mm to 0.3 mm. This spacing G ₂ is the area under which air pressure, ie the area and weight of the lower and upper disk dampers 211 and 212 and the spacing G ₁ between them, the lower and upper springs 251 and 252. It can be appropriately adjusted according to various conditions such as the elastic force of the.

As described above, when the gap G ₂ between each of the lower and upper disk dampers 211 and 212 and the disks 120a and 120b becomes narrower as the disks 120a and 120b rotate, Since the pressure is increased to increase the rigidity of the air, the vibration of the disks 120a and 120b can be more effectively reduced.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the appended claims.

As described above, according to the present invention, when the disc rotates, the gap between the disc and the disc damper is narrowed and the air pressure therebetween increases, so that the vibration of the disc is more effectively reduced. In addition, when the disc stops rotating, the distance between the disc and the disc damper is widened, thereby reducing the possibility of collision between the disc and the disc damper due to external impact, thereby protecting the data recording surface of the disc from external impact. have.

Claims (9)

In the disk damping device of a hard disk drive for reducing vibration of a plurality of disks mounted on the spindle motor of the hard disk drive, A lower disk damper and an upper disk damper, which are disposed between the plurality of disks and are stacked at predetermined intervals; And And support means for supporting the lower disk damper and the upper disk damper so as to be movable vertically, respectively. When the disk is rotated, the lower disk damper is lowered and the upper disk damper is raised by the air flowing between the lower disk and the upper disk, so that the gap between the lower disk damper and the upper disk damper is widened, so that the lower and upper disk Disk damping device of a hard disk drive, characterized in that the gap between each of the dampers and the disk is narrowed. The method of claim 1, wherein the support means, A support protrusion protruding from an outer circumference of the lower disk damper and the upper disk damper and having a pin insertion hole; A guide pin fixed to the base member of the hard disk drive and inserted into the pin insertion hole to guide vertical movement of the lower disk damper and the upper disk damper; And an elastic member coupled to the guide pin to provide an upper elastic force to the lower disk damper and a lower elastic force to the upper disk damper. The method of claim 2, And a spacer arranged between the lower disk damper and the upper disk damper to maintain a minimum gap therebetween. The method of claim 3, wherein And the spacer is fixed to an intermediate portion of the guide pin. The method of claim 2, The guide pin is a disk damping device of the hard disk drive, characterized in that screwed to the base member. The method of claim 2, A screw is fastened to the upper end of the guide pin, The elastic member may include a lower spring coupled to an outer circumference of the guide pin to be disposed between the support protrusion of the lower disk damper and the base member, and the guide pin to be disposed between the support protrusion of the upper disk damper and the head of the screw. Disk damping device for a hard disk drive, characterized in that it has an upper spring coupled to the outer circumference. The method of claim 1, And the lower disk damper and the upper disk damper have a ring shape with a portion open. The method according to claim 1 or 7, The support means is a disk damping device of a hard disk drive, characterized in that a plurality of which is provided at predetermined intervals along the outer periphery of the lower disk damper and the upper disk damper. The method of claim 1, And an inclined surface of each of the lower disk damper and the upper disk damper at an air inlet side thereof is formed to face each other.

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