KR20020071392A - The tray eject apparatus for disk drive - Google Patents

Abstract

PURPOSE: A tray ejecting device of a disc drive is provided to produce a compact disc drive, efficiently design the inner space of the disc drive, and minimize a space required for operating of an eject plate. CONSTITUTION: A tray ejecting device of a disc drive includes a tray(40) for transferring a disc to the inside and outside of a main base(30), an ejecting unit for selectively fastening the tray in the main base and releasing the tray from the main base according to a separate driving source, and an eject driver. The eject driver is placed under the tray and provides elastic force to the tray to eject the tray from the main base while the tray is being released from the main base. The eject driver has an eject plate(60) and a twisted spring(65). The eject plate is movably placed under the tray and selectively comes into contact with the end of the main base. The twisted spring is placed under the tray and one end of the spring is connected to the eject plate to provide elastic force to the elect plate.

Description

The tray eject apparatus for disk drive

The present invention relates to a disc drive, and more particularly, to a tray ejection apparatus of a disc drive for causing the tray for transferring the disc to protrude to the outside of the disc drive when necessary.

1 to 3 show the configuration of a disk tray ejection apparatus of a slim disk drive according to the prior art. According to this, the main base 10 constitutes the lower appearance of the disk drive. Guide racks 12 for guiding the movement of the tray 20 to be described below are formed at both ends of the main base 10 in the front and rear directions thereof, and the locking jaws 14 at one side of the guide rack 12. Is formed. In addition, a blocking protrusion 16 is formed at one side of the main base 10.

On the other hand, while moving to the inside and outside of the main base 10, the tray 20 for transporting the disk is installed on the main base 10 to be movable. In general, in a slim disk drive, a turntable 21 is installed on the tray 20 to rotate in a state where a disk is seated, and a signal is recorded or recorded by irradiating light to a disk seated on the turntable 21 and rotated. The optical pickup 22 for reading the received signal is installed to enable a straight reciprocating motion in the radial direction of the disk.

The lower surface of the tray 20 is provided with a configuration for ejecting the tray 20. That is, a driving lever 23 is installed on one side of the lower surface of the tray 20 to receive power from components related to the transfer of the optical pickup 22 or a separate driving source.

In addition, the stopper lever 24 is installed on the lower surface of the tray 20 so as to rotate in a predetermined angle in association with the driving lever 23. The stopper lever 24 is rotatably installed about the center of rotation 24 ′ and has a tendency to rotate clockwise with reference to FIG. 1 by a spring 24s. Here, the stopper lever 24 is one side is interlocked with the driving lever 23 and the other side is selectively caught on the locking step 14 of the guide rack 12.

On the other hand, an eject spring 26 is provided at the rear end of the tray 20 to provide a force for the tray 20 to protrude to the outside of the main base. One side of the eject spring 26 is fixed to one side of the lower surface of the tray 20, and the other side is connected to the eject lever 25.

The eject lever 25 is installed on the lower surface of the tray 20 so as to linearly move in the front-rear direction of the tray 20. And the linear movement of the eject lever 25 is guided by the configuration formed in the tray 20. In addition, a guide protrusion 27 is formed on the lower surface of the tray 20 to regulate the movement stroke of the eject lever 25. At this time, the guide protrusion 27 is inserted into the guide slot 25 'formed in the longitudinal direction at the center of the eject lever 25 to guide the movement of the eject lever 25. The eject lever 25 meets the stopping projection 16 before the tray 20 completely enters the inside of the main base 10 so that its movement is limited.

Looking at the operation of the tray ejection apparatus of the disk drive according to the prior art having such a configuration as follows.

In the state where the tray 20 is inside the main base 10, the stopper lever 24 is caught by the locking jaw 14 to serve to fix the tray 20 so as not to be ejected to the outside. .

As the eject lever 25 is no longer allowed to enter the inside by the blocking protrusion 16, the eject spring 26 is extended. Therefore, the eject spring 26 has a force for restoring to its original state, and the restoring force acts as a driving force for protruding the tray 20 to the outside of the main base 10.

When the user presses the eject button to eject the tray 20 to the outside of the main base 10 in the above state, the drive lever 23 is operated and the stopper lever 24 is rotated to the center of rotation 24 '. Rotate slightly counterclockwise around. At this time, the stopper lever 24 is rotated while overcoming the restoring force of the spring 24s.

When the stopper lever 24 is rotated, the stopper lever 24 is separated from the locking step 14. In this case, while the fastening structure between the tray 20 and the main base 10 is released, the tray 20 is partially taken out of the main base 10 by the restoring force of the eject spring 26. At this time, the eject lever 25 is moved by the restoring force of the eject spring 26 so that the guide protrusion 27 is located on the other side of the guide slot 25 '.

Meanwhile, when the tray 20 is inserted back into the main base 10, the user may push the tray 20 into the main base 10. In this case, as the tray 20 is moved, the stopper lever 24 rotates counterclockwise about the rotation center 24 ′ while touching the tip of the locking jaw 14. At this time, the stopper lever 24 is rotated while overcoming the elastic force of the spring (24s). Rotation of the stopper lever 24 is continued until the stopper lever 24 passes the catching jaw 14, and the stopper 24 passes the stopper 14 at the moment when the stopper lever 24 passes the catching jaw 14. As the lever 24 rotates clockwise by the restoring force of the spring 24s, as shown in FIG. 1, the lever 24 is caught by the locking jaw 14.

On the other hand, at the same time as the above operation is made between the eject lever 25 and the stopping projection (16). That is, when the tray 20 enters the inside of the main base 10 to some extent, the eject lever 25 comes into contact with the stopping protrusion 16, and the eject spring 26 starts to increase. Of course, at this time, the guide protrusion 27 starts to move along the guide slot 25 '. And at the moment when the stopper lever 24 is caught by the catching jaw 14, the guide protrusion 27 comes to one side end (state of FIG. 1) of the guide slot 25 'and maintains this state. do.

However, the prior art as described above has the following problems.

In the related art, a relatively large amount of space is required for the operation of the configuration for providing an elastic force that allows the tray 20 to protrude to the outside of the disc drive, thereby reducing the design freedom of the disc drive and obstructing the thin and short size. There is a problem.

That is, the blocking protrusions 16 for preventing the movement of the driving lever 23 provided on the lower surface of the tray 20 are formed to protrude upward from the inner side of the main base 10. At this time, the stopping projection 16 is formed to a height that can reach the driving lever 23 without touching the lower surface of the tray (20). In addition, the driving lever 23 should also protrude to the lower surface of the tray 20 to reach the blocking protrusion 16. In addition, the spring 24s for applying the elastic force to the drive lever 23 is a coil spring, which also protrudes from the lower surface of the tray 20.

Due to the characteristics of such a configuration, the blocking protrusion 16, the driving lever 23, and the spring 24s occupy a predetermined space on the inner upper surface of the main chassis 10 of the disk drive.

In addition, in order for the tray 20 to move in and out of the disk drive, the driving lever 23 and the spring 24s and the surrounding components must not interfere with each other, so that the driving lever 23 and the spring 24s are moved. Some space is needed for the area.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to provide a lighter and thinner disk drive.

Another object of the present invention is to more efficiently design the internal space of a disk drive.

Another object of the present invention is to increase the design freedom of the disk drive.

1 is a plan view showing a configuration of a disk drive provided with a tray ejection apparatus according to the prior art.

2 is a cross-sectional view showing the configuration of a tray ejecting apparatus for a disk drive according to the prior art;

Figure 3 is a plan view showing the main configuration of the conventional tray ejection apparatus.

Figure 4 is a schematic plan view showing the configuration of a disk drive provided with a preferred embodiment of the tray ejection apparatus according to the present invention.

5 is a schematic cross-sectional view of a disk drive having an embodiment of the present invention.

Figure 6 is an operating state showing the loading complete state in the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

30: main base 32: guide rack

34: Jam Jaw 35: Slide Rack

36: rear fence 40: tray

42: guide protrusion 45: fixed protrusion

47: support hanger 50: stopper lever

52: fastening jaw 60: eject plate

62: connecting projection 65: torsion spring

66: fixed center portion 67: fixed leg portion

68: movable leg portion 69: guide portion

According to a feature of the present invention for achieving the object as described above, the present invention is to selectively engage and release the tray inside the main base by a separate drive source and a tray for transporting the disk into and out of the main base; An ejecting mechanism part and a lower surface of the tray, which are hooked to an end of the main base to provide an elastic force to the tray to eject the tray to the outside of the main base in a state in which the tray is released. It is configured to include an eject drive unit.

The eject driver is installed on the lower surface of the tray to be moved a predetermined distance, the eject plate is selectively contacted to the end of the main chassis, and the lower surface of the tray is connected to the eject plate and one end is connected to the eject plate It is configured to include a torsion spring to provide an elastic force in the direction of the end of the main chassis.

The eject plate is moved while being guided by a guide protrusion to be integrally formed on the lower surface of the tray.

The movable leg portion constituting one end of the torsion spring is provided with a guide portion for guiding one side of the eject plate and is elastically deformed while being relatively moved in connection with one side of the eject plate.

According to the tray ejection apparatus of the disk drive according to the present invention having such a configuration, there is an advantage that the space inside the disk drive can be freely made, so that the light and small size can be reduced and the design freedom can be increased.

Hereinafter, a preferred embodiment of a tray ejecting apparatus for a disk drive according to the present invention as described above will be described in detail with reference to the accompanying drawings.

4 and 5 show a preferred embodiment of the tray ejection apparatus of the embodiment of the present invention.

As shown in the drawing, the main base 30 constitutes the lower appearance of the disk drive. The main base 30 has guide racks 32 for guiding movement of the tray 40 to be described below in both front and rear directions thereof, and a locking step 34 is formed at one side of the guide rack 32. It is. When the tray 40 protrudes out of the main base 30, a slide rack 35 supporting the tray 40 is provided between the tray 40 and the guide rack 32.

At the rear end of the main base 30, a rear end fence 36 forming a space in the main base 30 is formed to be upright with respect to the upper surface of the main base 30. In the exemplary embodiment of the present invention, the rear end fence 36 constituting the external appearance of the disk drive is formed in the main base 30, but it is not necessary to do so, but the upper chassis (not shown) forms the upper external appearance of the disk drive. It may be formed.

On the other hand, while moving to the inside and outside of the main base 30, the tray 40 for transferring the disk is installed on the main base 30 to be movable. In general, a slim disk drive is provided with a turntable (not shown) that rotates the disk 40 while seated on the tray 40, and records or records a signal by irradiating light to the disk that is seated on the turntable and rotated. An optical pickup (not shown) for reading out a signal is installed to enable a straight reciprocating motion in the radial direction of the disc.

And the lower surface of the tray 40 is provided with a configuration for ejecting the tray 40. First, a plurality of guide protrusions 42 supporting the eject plate 60 to be described below and guiding movement are formed. In addition, a fixing protrusion 45 and a support hook 47 for fixing the torsion spring 65 to give elastic force to the eject plate 60 are formed on the lower surface of the tray 40, respectively.

Next, the eject plate 60 is installed between the guide protrusions 42. The eject plate 60 is installed to protrude to the rear end of the tray 40 so as to contact the rear end fence 36. Here, the eject plate 60 is moved by a predetermined distance while being guided by the guide protrusion 42, and the guide protrusion 42 does not necessarily guide both ends of the eject plate 60. That is, the slot may be formed in the eject plate 60 in the longitudinal direction, and the guide protrusion may be positioned in the slot to guide and support the movement of the eject plate 60.

One end of the eject plate 60 is formed with a contact protrusion 61 in contact with the rear end fence (36). The contact protrusion 61 is formed to have a narrower width than the other portions of the eject plate 60. And at the opposite end of the contact projection 61 is formed a connecting projection 62 for connection with the torsion spring 65 to be described below. The eject plate 60 of this configuration is formed in a plate shape having a rigidity not to be deformed by the tray 40 when the tray 40 is inserted into the disc drive.

The torsion spring 65 is installed on the eject plate 60. The torsion spring (35) has a fixed center portion (66) fixed to the fixing protrusion (45) at the center thereof, and the fixed leg portion (67) and the movable leg portion on both sides with respect to the fixed center portion (66), respectively. (68) is extended long.

The fixing leg portion 67 is fixed to the support hanger 47. And the end of the movable leg 68 is bent to form a guide portion 69, the guide portion 69 is formed in a 'U' shape, the connection projections in the guide portion 69 62 is located. In this way, the connecting protrusion 62 is guided along the guide portion 69 while the movable leg portion 68 is elastically deformed with respect to the fixed center portion 66 to impart an elastic force to the tray 40.

Hereinafter, the operation of the tray ejecting device of the disk drive according to the present invention having the configuration as described above will be described in detail.

4 and 5, the torsion spring 65 is not elastically deformed, that is, the tray 40 partially protrudes out of the disk drive. At this time, the torsion spring 65 is restored to a circular shape and the tray 40 protrudes outward by the force.

In such a state, the disc is seated in the tray 40 and the user inserts the tray 40 back into the disc drive to the state of FIG. 4, and then continuously applies a force to the tray 40. The movable leg portion 68 of the spring 65 is elastically deformed in the counterclockwise direction about the fixed center portion 66.

Therefore, the position of the connecting protrusion 62 of the eject plate 60 in the guide portion 69 of the movable leg portion 68 gradually moves in the direction of the fixed center portion 66. At this time, the movable leg portion 68 is actually moved.

Meanwhile, FIG. 5 illustrates a state in which the fastening jaw 52 of the stopper lever 50 is caught by the catching jaw 34, that is, a loading completion state. In this state, the tray 40 is fixed inside the disk drive, and the tray 40 tends to be ejected to the outside of the disk drive by elastic deformation of the movable leg portion 68 of the torsion spring 65. Has In this state, recording and reading of signals are performed while rotating the disk.

Next, the tray 40 is ejected. When the stopper lever 50 is forcibly driven in an eject command or in an emergency, the fastening jaw 52 is released from the fastening jaw 34. As such, when the fastening state of the tray 40 is released, the elastic restoring force of the torsion spring 65 acts on the tray 40 so that a part of the tray 40 is moved out of the disk drive as shown in FIG. 4. Ejected.

As described above, when the tray 40 partially protrudes, the user pulls the tray 40 by hand to protrude the disk 40 to the outside of the disk drive. Then, when mounting of the disk is completed, the tray 40 may be inserted into the disk drive again.

In the tray ejection apparatus of the disk drive according to the present invention as described in detail above, a relatively thin plate-like ejection plate and a torsion spring having a low height are used, so the space occupied by the configuration providing elastic force for ejecting the tray is relatively small. You lose. And since the structure for supporting the eject plate is at one end rather than inside the upper surface of the main base, it is possible to minimize the space required for the operation of the eject plate.

In addition, since the space used for the eject plate and the torsion spring is minimized as described above, the component arrangement design of the inside of the disk drive can be simplified, thereby increasing the design freedom of the disk drive.

Claims (4)

A tray for transferring the disk into and out of the main base, Eject mechanism part for selectively engaging and releasing the tray inside the main base by a separate drive source, It is installed on the lower surface of the tray, and the end portion of the main base to provide an elastic force to the tray to include the eject drive unit for ejecting the tray to the outside of the main base in the state that the engagement of the tray is released Tray ejector device of a disk drive, characterized in that configured. The method of claim 1, wherein the eject drive unit, An eject plate provided on the lower surface of the tray to be movable at a predetermined distance and selectively contacting an end portion of the main chassis; And a torsion spring installed at a lower surface of the tray and having one end connected to the eject plate to provide an elastic force to the eject plate in the direction of the end of the main chassis. 3. The tray ejection apparatus of claim 2, wherein the eject plate is moved while being guided by a guide protrusion to be integrally formed on the lower surface of the tray. According to claim 2 or 3, wherein the movable leg portion constituting one end of the torsion spring is provided with a guide portion for guiding one side of the eject plate is connected to one side of the eject plate is relatively deformed while being elastically deformed Eject device for disk drives.