KR20010048140A - Tray apparatus of slim type disk drive - Google Patents

Abstract

The present invention relates to a tray device of a slim disk drive, and the present invention is installed in the main frame to move back and forth, the tray for loading / unloading the disk, and the spindle for providing power for rotating the disk loaded in the tray A motor, a spindle motor printed circuit board for controlling the operation of the spindle motor, and a flexible printed circuit electrically connecting the spindle motor printed circuit board and the main board printed circuit board, wherein the tray is configured to seat a disk. The disc seat is formed of a concave upper plate and side plates formed on both left and right sides of the upper plate to enable forward and backward movement of the tray, and the upper and lower surfaces of the tray contacting the flexible printed circuit when the tray is opened or closed. Surface of flexible printed circuit by edge of disk seat And a flexible printed circuit protection means for minimizing abrasion to prevent damage of the flexible printed circuit, so that the crack of the lead portion of the flexible printed circuit due to the accumulation of the fatigue load is suppressed to the maximum by the flexible printed circuit protection means. Its overall performance is improved and its life is extended.

Description

Tray device for slim disk drive {TRAY APPARATUS OF SLIM TYPE DISK DRIVE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tray device of a slim disk drive applied to a slim drive field such as a CD-ROM / DVD-ROM for a notebook, and in particular, to contact a lower portion of the tray when the tray is opened / closed. It relates to a tray device of a slim disk drive in which the lower structure of the tray is changed to protect the flexible printed circuit.

The slim disk drive according to the related art has a sled system which performs a function of playing / recording a signal inherently included in the disk D, as shown in FIGS. 1 and 2, and a disk by the sled system ( D) A loading system for loading the disk D into the system to enable reproduction / recording of signals, and a control system for controlling the operation of the sled system and the loading system.

The sled system includes a pickup 1 which is an optical recording information reproducing part, a spindle motor 3 which rotates the reproduction / Giroxy disc D of the disk D signal by the pickup 1, and the spindle. The spindle motor printed circuit board 5 for controlling the operation of the motor 3 and the pickup (D) so that the reproduction / recording function of the disk D signal by the pickup 1 is performed over the front surface of the disk D. And a sled base 7 on which the above-mentioned components are mounted, and a pick-up transfer part for linearly moving 1) in the radial direction of the disk D.

In addition, the loading system is installed on the main frame 11 and the main frame 11 to form the exterior of the drive so as to be movable back and forth to load / unload the disk (D) and the sled base (7) Left and right rack guides that are assembled to the assembled tray 13 and to both sides of the main frame 11 to guide the movement of the tray 13 so that the tray 13 enters into position of the main frame 11. Left and right slide racks 17a and 17b provided between the trays 16a and 16b and between the tray 13 and the respective rack guides 16a and 16b to assist the smooth movement of the tray 13 back and forth. It is configured to include.

3 and 4, the tray 13 has a top plate 14 having a recessed disc seating portion 14a for seating the disc, and left and right sides of the top plate 14, respectively. It is formed and is coupled to the slide rack (17a) (17b) to the lower end thereof is composed of side plates (15a) (15b) to enable the front and rear movement of the tray 13, the disk seat of the upper plate (14) The portion 14a is formed to be stepped with the edge portion 14b around it.

In addition, the control system is configured to include a main board printed circuit board 21 for supplying power to the system, and the main board printed circuit board 21 for interfacing with an external device during the reproduction / recording process of the disk (D) signal. .

Here, the main board printed circuit board 21 is connected to the spindle motor printed circuit board 5 and the flexible printed circuit (23) so as to control the operation of the sled system at the same time the tray It is provided with a loading switch 25 that can detect when the 13 is completely inserted into the main frame 11 is closed.

In the disk drive configured as described above, when the tray 13 is first taken out of the main frame 11 and opened, the disk D is placed on the turntable 4 of the spindle motor 3 installed at the center of the tray 13. After seating, push the tray 13 completely into the main frame 11 again.

At this time, when the tray 13 is pushed into the main frame 11, the tray 13 and the slide racks 17a and 17b are together along the rack guides 16a and 16b to form the interior of the main frame 11. When the slide racks 17a and 17b are caught and stopped by the slide rack stoppers formed at the rear ends of the rack guides 16a and 16b, only the tray 13 is moved along the slide racks 17a and 17b. Completely into the frame 11;

When the tray 13 is closed as described above, the rear end portion of the tray 13 presses the loading switch 25 installed on the main board PCB 21 and the tray 13 is closed by the loading switch 25. When the state of closing the train 13 is recognized by the loading switch 25, the spindle motor 3 is operated to rotate the disk D.

As described above, when the disk D is rotated, data transfer occurs between the disk D and the pickup 1, so that a signal inherent in the disk D is reproduced / recorded. At this time, the pickup 1 is linearly moved in the radial direction of the disc D so that the data reproduction / recording function can be performed on the front surface of the disc D. FIG.

However, since the drive configured and operated as described above is configured in a very narrow space, the flexible printed circuit 23 repeatedly rubs with the lower part of the tray 13 when the tray 13 is opened / closed. The bending portion B repeats a very severe bending operation, which causes severe surface abrasion of the flexible printed circuit 23.

In particular, in the conventional slim disk drive, the flexible printed circuit 23 is in line contact with the edge portion 14a 'of the disc seat 14a of the tray 13 when the tray 13 is opened or closed. Since the friction and abrasion between the flexible printed circuit 23 and the tray 13 are increased, and the edge portion 14a 'of the disk seat 14a forms an arc, the flexible printed circuit 23 is a disk. The surface of the flexible printed circuit 23 is twisted when the bending portion B is bent while contacting with a predetermined time difference with each point of the edge portion 14a 'of the seating portion 14a.

Therefore, the slim disk drive according to the related art has a surface friction and abrasion between the lower tray 13 and the flexible printed circuit 23 and the torsional bending of the flexible printed circuit 23. Since the fatigue load accumulates in the inner lead portion, cracks, etc., occur in the lead portion, thereby increasing the inner line resistance of the lead portion, which causes a problem in smooth signal transmission through the flexible printed circuit 23. As a result, there was a fatal problem that the performance of the entire system is reduced and the life is shortened.

The object of the present invention devised in view of the above problems is caused by the contact with the tray by changing the lower structure of the tray to protect the flexible printed circuit in contact with the bottom of the tray when the tray is opened / closed. The present invention provides a tray apparatus of a slim disk drive which minimizes surface friction and wear of the flexible printed circuit and at the same time prevents torsional bending of the flexible printed circuit so that the signal transmission function of the flexible printed circuit is improved and its life is extended.

1 is a block diagram showing a tray open state of a slim disk drive according to the prior art,

2 is a block diagram showing a tray closed state of the slim disk drive according to the prior art,

3 is a plan view showing the structure of a tray according to the prior art,

4 is a cross-sectional view taken along the line A-A of FIG.

5 is a configuration diagram showing a tray open state of the slim disk drive according to the present invention;

6 is a plan view showing a structure of a tray according to the present invention;

7 is a cross-sectional view taken along the line B-B in FIG.

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

51: mainframe 53: tray

54: top plate 54a: disk seat

54a ': corner portion of the disc seat 55: side plate

57: protruding rib 59: spindle motor

60: spindle motor printed circuit board 64: flexible printed circuit

65: main board printed circuit board

In order to achieve the object of the present invention as described above, the main frame is installed so as to be movable back and forth, the tray for loading / unloading the disk, the spindle motor for providing power for rotating the disk loaded in the tray, A spindle motor printed circuit board for controlling the operation of the spindle motor, and a flexible printed circuit electrically connecting the spindle motor printed circuit board and the main board printed circuit board, wherein the tray includes a disk seating portion for seating a disk. And a side plate formed on both left and right sides of the top plate to enable forward and backward movement of the tray. The disc seat may be disposed on the bottom surface of the tray that contacts the flexible printed circuit when the tray is opened or closed. By minimizing the surface friction and wear of the flexible printed circuit by the edges The tray device of the thin-disk drive, characterized in that the flexible printed-circuit protection means to prevent damage to the flexible printed circuit group having a are provided.

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

5 is a configuration diagram showing a tray open state of the slim disk drive according to the present invention, Figure 6 is a plan view showing the structure of the tray according to the present invention, Figure 7 is a cross-sectional view taken along the line B-B of FIG.

The tray device of the slim disk drive according to the present invention will be described with reference to FIGS. 5 to 7 as follows.

First, a tray 53 for loading / unloading a disk D is installed on the main frame 51 forming the exterior of the drive so as to be movable back and forth, and the tray 53 is loaded below the tray 53. A spindle motor 59 for providing power for rotating the disk D and a spindle motor printed circuit board 60 for controlling the operation of the spindle motor 59 are installed, and the spindle motor printed circuit board 60 is provided. Is connected to the main board printed circuit board 65 by the flexible printed circuit (64).

Here, the tray 53 is formed on the upper plate 54 in which the disk seating portion 54a for recessing the disk D is concave, and formed on both left and right sides of the upper plate 54 to move forward and backward of the tray 53. It is composed of side plates (55a, 55b) to enable, the disc seat portion 54a of the upper plate 54 is to be formed stepped with the edge portion 54b around it.

In addition, when the tray 53 is in contact with the flexible printed circuit 64, the portion of the upper surface 54 of the tray 53 which is in contact with the flexible printed circuit 64 when the tray 53 is opened or closed. Flexible printed circuit protection means for minimizing the surface friction and wear of the flexible printed circuit 64 to prevent damage to the flexible printed circuit (64) is provided.

The flexible printed circuit protection means includes at least one protruding rib 57 formed on the lower surface of the upper plate 54 of the tray 53 at the same height as the edge portion 54a 'of the disc seating portion 54a.

In this case, the protruding ribs 57 are formed long in the front and rear movement direction of the tray 53, that is, in the bending direction of the flexible printed circuit 64.

In addition, the protruding ribs 57 include the edge portion 54a 'of the disk seat 54a and the flexible printed circuit 64 from the corner 54a' and the protruding rib 57 of the disk seat 54a. It is formed up to the point (S) in contact with the end of the same time.

The tray device of the slim disk drive according to the present invention configured as described above is operated as follows.

First, when the tray 53 is pulled out of the main frame 51 to be opened, the disk D is seated on the turntable 58 of the spindle motor 59 installed at the center of the tray 53, and then the tray ( 53) completely push into the mainframe 51.

At this time, when the tray 53 is pushed into the main frame 51, the tray 53 and the slide racks 61a and 61b are together along the rack guides 63a and 63b to form the interior of the main frame 51. When the slide racks 61a and 61b are caught by the slide rack stoppers formed at the rear ends of the rack guides 63a and 63b, only the tray 53 is moved along the slide racks 61a and 61b. Completely into the frame 51;

When the tray 53 is closed as described above, the rear end of the tray 53 presses the loading switch 66 installed on the motherboard PCB 65 so that the tray 53 is closed by the loading switch 66. Is recognized, and when the train 53 is closed by the loading switch 66, the spindle motor 59 is operated to rotate the disk D.

As described above, when the disk D is rotated, data transfer occurs between the disk D and the pickup 67, so that a signal inherent in the disk D is reproduced / recorded.

The drive having the tray device of the present invention constructed and operated as described above is configured in a very narrow space, so that the flexible printed circuit 64 is repeatedly formed with the lower portion of the tray 53 when the tray 53 is opened / closed. Although friction occurs, the flexible printed circuit 64 due to contact with the tray 53 is brought into contact with the tray 53 because the lower portion of the tray 53 and the flexible printed circuit 64 are in point contact by the protruding ribs 57. Surface friction and wear are minimized.

In addition, the flexible printed circuit 64 is brought into contact with the corner portion 54a 'of the disk seat 54a and the end of each protruding rib 57, so that the flexible printed circuit 64 is bent. The torsion that may appear on the surface of the flexible printed circuit 64 is suppressed so that the torsional bending of the flexible printed circuit 64 is prevented.

Therefore, the present invention minimizes surface friction and abrasion between the lower tray 53 and the flexible printed circuit 64 by the protruding ribs 57, and at the same time prevents the bending of the flexible printed circuit 64 to prevent the drive. Even if it is used for a long time, the occurrence of cracks or the like in the lead portion due to the fatigue load accumulated in the inner lead portion of the flexible printed circuit 64 is suppressed as much as possible.

In addition, when the crack of the conductive wire part due to the fatigue load accumulation of the conductive wire part of the flexible printed circuit 64 is suppressed to the maximum, the signal transmission through the flexible printed circuit 64 is smoothly performed, thereby improving the performance of the entire drive. At the same time, the life of the drive is extended.

In order to support this effect, the results of the life test of the conventional drive to which the protrusion rib 57 is not applied and the drive of the present invention to which the protrusion rib 57 is applied are shown in Table 1 below.

Drive without protruding rib Extruded Rib Drive Number of tray open / close life tests passed 20000 times or less More than 60000 Lead resistance of flexible printed circuit (Ω) Before life test 0.6 or less 0.6 or less After life test 15 to 30 1.0 or less

Looking at Table 1 above, it can be seen that the drive to which the protrusion rib 57 is applied according to the present invention can withstand at least 40000 or more life tests than the drive that is not. In addition, it can be seen that the average drive resistance of the flexible printed circuit 64 also increases by about 14.4 to 29.4 (Ω) when the conventional drive undergoes a life test. .

As described above, the tray device of the slim disk drive according to the present invention, the flexible printing on the lower surface of the upper plate 54 of the tray 53 in contact with the flexible printed circuit 64 when the tray 53 is opened / closed. The at least one protruding rib 57 formed for the protection of the circuit 64 minimizes surface friction and wear of the flexible printed circuit 64 and prevents torsional bending, thereby preventing the flexible printed circuit 64 from accumulating fatigue loads. The crack in the lead wire is suppressed as much as possible, which improves the overall performance of the drive and extends its life.

Claims (4)

A tray that is installed to move back and forth on the mainframe to load / unload a disk, a spindle motor that provides power to rotate the disk loaded on the tray, and a spindle motor printed circuit board that controls the operation of the spindle motor. And a flexible printed circuit electrically connecting the spindle motor printed circuit board and the main board printed circuit board. The tray is composed of a top plate formed with a recessed disc mounting portion for seating the disk, and the side plate is formed on both left and right sides of the top plate to enable the front and rear movement of the tray, Flexible printed circuit that prevents damage to the flexible printed circuit by minimizing the surface friction and wear of the flexible printed circuit by the edge portion of the disc seating portion on the upper surface of the tray that is in contact with the flexible printed circuit when the tray is opened / closed Tray device of a slim disk drive, characterized in that the protective means is provided. The method of claim 1, The flexible printed circuit protection means of the tray device of a slim disk drive, characterized in that composed of at least one protruding rib formed on the upper surface of the tray at the same height as the edge portion of the disk seat. The method of claim 2, The protruding ribs are formed to be long in the front and rear movement direction of the tray, that is, in the bending direction of the flexible printed circuit. The method of claim 2, The protruding rib is a tray device of a slim disk drive, characterized in that formed from the edge portion of the disc seat portion to the point where the flexible printed circuit is in contact with the edge portion of the disc seat portion and the end of the protruding rib at the same time.