KR101467119B1 - Eject and close structure of optical disk drive - Google Patents

Abstract

Disclosed is an eject-and-close structure of an optical disk drive. The optical disk drive includes: a lock lever which rotates to release the lock on a disc tray; an eject lever which is connected to the lock lever to rotate the lock lever; an eject spring which moves by using the elastic force of the eject lever; a link lever which is coupled to the eject lever through the coupling unit; and an optical pick-up device including an optical pick-up assembly coupled to the link lever. The link lever is pressed by the optical pick-up assembly to be rotated. The eject lever can be released from the coupling with the coupling unit through the rotation of the link lever.

Description

Eject and Close Structure of Optical Disc Drive [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ejecting and closing structure of an optical disc drive, and more particularly, to an ejecting and closing structure of an optical disc drive capable of ejecting a disc tray or closing a disc tray without using a solenoid or a separate motor .

An optical disk drive is a device for recording data on an optical disk or reading data recorded on an optical disk.

At this time, the optical disc drive performs an eject operation for taking out the optical disc on which the data is recorded from the optical disc drive using the disc tray on which the optical disc is loaded, or a close operation for inserting the optical disc for recording the data into the optical disc drive . In this case, the closing operation may be an operation of locking the disc tray inserted in the optical disc drive so that the optical disc placed on the disc tray is not moved to the outside of the optical disc drive. In addition, the ejecting operation may be an operation of releasing the locking of the locked disk tray inside the optical disk drive and moving the disk tray to the outside of the optical disk drive.

A conventional optical disc drive uses a separate motor or solenoid for ejecting and closing operations to lock the disc tray or unlock the disc tray.

However, when a separate motor is used, a cost for the motor is generated. Further, since the solenoid requires a configuration for supplying electric power to the coil and a separate configuration for controlling the solenoid, the structure can be complicated.

Therefore, there is a demand for an apparatus capable of ejecting a disc tray or closing a disc tray without using a solenoid or a separate motor.

The present invention can provide an apparatus capable of ejecting a disc tray or closing a disc tray without using a solenoid or a separate motor.

According to an embodiment of the present invention, there is provided an optical disc drive comprising: a lock lever rotatable to release a locking of a disc tray; An eject lever connected to the lock lever to rotate the lock lever; An eject spring for moving the eject lever through elasticity; A link lever which engages with the eject lever via a fastening portion; And an optical pick-up device having an optical pick-up assembly connected to the link lever, wherein the link lever is pushed and rotated by the optical pick-up assembly, and the eject lever is disengaged by rotation of the link lever, .

The eject lever of the optical disc drive according to an embodiment can be rotated due to the elasticity of the eject spring by releasing the engagement of the coupling part due to rotation of the link lever.

The optical pickup device of the optical disc drive according to the embodiment can push the link lever through the optical pickup assembly when moving in the outer direction beyond a predetermined reference distance.

The optical pickup apparatus of the optical disc drive according to an embodiment may move beyond a preset reference distance through an external switch signal provided to the optical disc drive.

According to an embodiment of the present invention, there is provided an optical disc drive comprising: a close lever for rotating an eject lever according to insertion of a disc tray; A lock spring for moving the link lever and the lock lever through elasticity; A lock lever for locking the disc tray by the lock spring when the eject lever is rotated; And a link lever which is rotated by the lock spring and engages with the eject lever.

The optical disc drive may further include an optical pickup unit having an optical pickup assembly connected to the link lever, the link lever is rotated by the lock spring to push the optical pickup assembly in the inner circumferential direction, The optical pickup apparatus can move in the inner circumferential direction due to the pushing of the optical pickup assembly.

According to the embodiment of the present invention, by releasing the locking of the eject lever with the link lever that rotates according to the operation of the optical pick-up device, the disc tray is ejected so that the disc tray can be ejected without using a solenoid or a separate motor have.

According to an embodiment of the present invention, the disk tray can be closed without using a solenoid or a separate motor by locking the eject lever with the link lever rotated by the elasticity of the spring to close the disk tray.

FIG. 1 is a diagram illustrating configurations related to eject and close of an optical disc drive according to an embodiment.
2 is a diagram showing an example of a reference distance set in advance in the optical disc drive according to an embodiment.
3 is a view showing an example of the state of the optical disc drive according to the embodiment at the stage when the eject operation is started.
4 is a view showing an example of a state of the optical disc drive according to an embodiment in the next eject operation step of FIG.
5 is a view showing an example of the state of the optical disc drive according to an embodiment in the next eject operation step of FIG.
6 is a view showing an example of an optical pickup device and a link lever according to an embodiment.
7 is a diagram showing an example of the state of the optical disc drive according to an embodiment in a stage where the close operation is started.
8 is a diagram showing an example of the state of the optical disc drive according to an embodiment in the next closing operation step of FIG.
FIG. 9 is a view showing an example of the state of the optical disc drive according to an embodiment in the next eject operation step of FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a diagram illustrating configurations related to eject and close of an optical disc drive according to an embodiment.

An optical disk drive according to an embodiment may include a disk tray having an outer chassis and a disk, and a disk tray slidably installed in the outer chassis to be inserted into and out of the inner space. At this time, a locking protrusion 110 for locking the disc tray may be coupled to one surface of the outer chassis.

The lock protrusion 110 is engaged with the lock lever 120 of the disc tray to slide on the outer chassis to fix the position of the inserted disc tray. For example, the lock protrusion 110 may be one of a bolt, a screw, or a protrusion protruding from a part of the outer chassis coupled with the outer chassis.

In addition, the disc tray can transfer the optical disc inserted in the optical disc drive to the outside, or move the optical disc from the outside to the inside of the optical disc drive. At this time, the disc tray includes a lock lever 120, a closing spring 121, an eject lever 130, an eject spring 140, a link lever 150, a lock spring 160, an optical pickup device 170, Lt; RTI ID = 0.0 > 180 < / RTI >

The lock lever 120 is engaged with the lock projection 110 to lock the disc tray. Further, the lock lever 120 can be rotated to release the locking of the disc tray. At this time, the unlocked disc tray can be ejected.

Specifically, the lock lever 120 may have a hook-shaped structure 121 that engages with the lock projection 110 at one end as shown in FIG. When the disc tray is inserted into the optical disc drive, the structure 121 of the lock lever 120 can be engaged with the lock protrusion 110 coupled to the outer chassis of the optical disc drive to fix the position of the disc tray. For example, the lock lever 120 may rotate counterclockwise due to the elasticity of the lock spring 170, so that the lock projection 110 and the structure 121 are engaged with each other.

 The process of fixing the position of the disc tray by the lock lever 120 will be described in detail with reference to FIG.

Further, the lock lever 120 can rotate in the direction of releasing the locking of the disk tray as the eject lever 130 rotates. For example, the lock lever 120 may be rotated in a clockwise direction in accordance with the rotation of the eject lever 130 to release the engagement between the structure 121 and the lock projection 110. At this time, as the engagement between the lock protrusion 110 and the lock lever 120 is released, the disc tray including the lock lever 120 can be ejected.

The eject lever 130 may be coupled through the coupling part 151 of the link lever 150. [ In addition, the eject lever 130 may be connected to the lock lever 120 to rotate the lock lever 120.

For example, the engaging portion 131 of the eject lever 130 is engaged with the engaging portion 151 of the link lever 150, as shown in FIG. 1, so that the eject lever 130 is prevented from rotating counterclockwise Locking is possible.

When the link lever 150 rotates, the position of the engaging portion 151 is changed to release the engagement between the engaging portion 151 and the engaging portion 131, so that the locking of the eject lever 130 can also be released have. At this time, the eject lever 130 can rotate in the counterclockwise direction due to the elasticity of the eject spring 140.

In addition, the eject lever 130 rotated in the counterclockwise direction can rotate the lock lever 120 through the first projection 132. At this time, the lock lever 120 rotates in the clockwise direction and the engagement with the lock projection 110 can be released.

When the close lever 180 rotates in a state in which the connection between the fastening portion 131 of the eject lever 130 and the fastening portion 151 of the link lever 150 is released, (180). The lock spring 160 is moved to a position where the engaging portion 131 of the eject lever 130 can engage with the engaging portion 151 of the link lever 150 as the eject lever 130 rotates. The link lever 150 can be moved to engage the engaging portion 131 of the eject lever 130 with the engaging portion 151 of the link lever 150

The ejection spring 140 may be a spring that moves the eject lever 130 through elasticity. Specifically, when the coupling between the coupling portion 131 of the eject lever 130 and the coupling portion 151 of the link lever 150 is released due to the rotation of the link lever 150, the eject spring 140 is elastically ejected By pulling the lever 140, the eject lever 140 can rotate the lock lever 120 in the clockwise direction.

The link lever 150 can be engaged with and disengaged from the eject lever 130 through the fastening portion 151. At this time, the fastening part 151 is fastened to the eject lever 130 in such a shape as to prevent the eject lever 130 from rotating counterclockwise due to the elasticity of the eject spring 140, (131).

Further, the link lever 150 can be pushed and rotated by the optical pick-up assembly 172 of the optical pickup device 170. When the link lever 150 is pushed and rotated by the optical pick-up assembly 172, the engagement of the coupling part 131 of the eject lever 130 and the coupling part 150 of the link lever 150 due to the rotation of the link lever 150, (151) can be released.

At this time, the shape of the portion of the link lever 150 that contacts the optical pickup assembly 172 may be changed according to the shape of the optical pickup assembly 172. For example, when the optical pickup assembly 172 is in the shape of a bar formed to have a height equal to or greater than the thickness of the link lever 150, a portion of the link lever 150, which contacts the optical pickup assembly 172, It is possible to prevent the optical pick-up assembly 172, which has pushed the link lever 150, from slipping off from the link lever 150.

Further, the link lever 150 can be rotated by the lock spring 160 to engage with the eject lever 130. For example, when the eject lever 130 is rotated clockwise in a state in which the engagement between the eject lever 130 and the link lever 150 is released, the engagement portion 131 of the eject lever 130 is engaged with the link lever 150 to engage with the fastening portion 151 of the fastening portion 151. At this time, the link lever 150 is rotated counterclockwise by the elasticity of the lock spring 160 to engage the engaging portion 151 with the engaging portion 131 of the eject lever 130, Locking is possible.

When the link lever 150 rotates in the counterclockwise direction due to the lock spring 160, the portion of the link lever 150 which is in contact with the optical pick-up assembly 172 can also rotate in the inner circumferential direction. At this time, the optical pick-up assembly 172 in contact with the link lever 150 can be pushed in the inner circumferential direction according to the rotation of the link lever 150.

The lock spring 160 may be a spring having one end connected to the lock lever 120 and the other end connected to the link lever 150. Then, the lock spring can move the lock lever 120 and the link lever 150 through elasticity.

Specifically, the lock spring 160 urges the lock lever 120 to engage with the lock projection 110, and the engagement portion 151 of the link lever 150 is engaged with the engagement portion 131 of the eject lever 130 It may be a spring corresponding to the distance between the lock lever 120 and the link lever 150. [ When the lock lever 120 and the link lever 150 are rotated to eject the disc tray, a portion of the lock lever 120 coupled with the lock spring 160 is moved to the lower left position, and the link lever 150 The portion where the lock spring 160 is engaged can be moved to the upper right. Thus, the lock spring 160 is tensioned and may have elasticity to return to its original length.

In addition, when the eject lever 130 is rotated to close the disc tray, the lock lever 120 and the link lever 150 can move according to the elasticity of the lock spring 160. Therefore, the lock spring 160 can move the lock lever 120 and the link lever 150 to a state before the disc tray is ejected through the elasticity.

The operation of the lock lever 120 and the link lever 150 according to the lock spring in the closing process of the disk tray will be described in detail with reference to FIG.

The optical pickup device 170 is a device that performs a function of recording data on an optical disk or reading recorded data. The optical pickup device 110 moves to a predetermined position of the optical disc according to the data and records the data, or moves to the position where the data is recorded on the optical disc and reads the recorded data at the corresponding position.

The optical pickup device 170 can be coupled to the optical pickup guide device 172. The optical pickup device 170 or the optical pickup guide device 172 may have an optical pickup assembly 172 connected to the link lever 150.

For example, the optical pickup assembly 172 may be formed in a portion of the optical pickup guide device 172, as shown in FIG. 1, in the shape of a bar having a height equal to or greater than the thickness of the link lever 150. In addition, the optical pickup assembly 172 may be formed in a shape as shown in FIG. 1 on a part of the optical pickup device 170, or may be formed in a bar shape protruded from the optical pickup device 170.

The shape of the optical pickup assembly 172 formed in the shape of a bar protruding from the optical pickup device 170 will be described in detail with reference to FIG.

When the optical pick-up device 170 moves in the outer circumferential direction beyond a predetermined reference distance, the optical pick-up device 170 can push the link lever 150 through the optical pick-up assembly 172. At this time, the predetermined reference distance may be a range of a distance at which the optical pick-up apparatus 170 can move the data to the optical disc or read the recorded data.

That is, when the optical pick-up device 170 moves in order to record data on the optical disc or read the recorded data, the optical pick-up device 170 moves within the predetermined reference distance, (150). When the disc tray is to be ejected, the optical pick-up device 170 moves in the outer circumferential direction beyond the reference distance and can push the link lever 150 through the optical pick-up assembly 172. At this time, the link lever 150 is pushed by the optical pick-up assembly 172 and rotates. When the eject lever 130, which is disengaged between the engaging portions by the rotation of the link lever 150, rotates the lock lever 120, The disc tray fixed by the lock protrusion 110 coupled with the lever 120 can be ejected.

At this time, the optical pickup device 170 can move beyond a predetermined reference distance through an external switch signal provided to the optical disc drive. At this time, the external switch signal may be a signal to eject the disc tray.

When the link lever 150 rotates counterclockwise due to the elasticity of the lock spring 160, the link lever 150 can push the optical pickup assembly 172 in the inner circumferential direction. At this time, the optical pick-up device 170 which has moved in the outer circumferential direction beyond the reference distance can move in the inner circumferential direction due to the pushing of the optical pick-up assembly 171 by the link lever 150.

A close-lever 180 can rotate the eject lever 130 as the disc tray is inserted. Specifically, when the disc tray is inserted, the close lever 180 is rotated counterclockwise in contact with the lock projection 110, and the rotated close lever 180 can push the eject lever 130 in the clockwise direction have. At this time, the eject lever 130 can be rotated in the clockwise direction by being pushed by the close lever 180.

2 is a diagram showing an example of a reference distance set in advance in the optical disc drive according to an embodiment.

The reference distance 200 preset in the optical disc drive according to an embodiment is a distance that the optical pickup device 170 can move to read data from or write data to the optical disc, Lt; / RTI > The maximum value in the outer circumferential direction at the reference distance 200 may be a position immediately before the optical pickup assembly 172 of the optical pickup device 170 contacts the link lever 150 as shown in FIG.

Therefore, when the optical pick-up device 170 moves within the reference distance 200, the optical pick-up assembly 172 of the optical pick-up device 170 does not contact the link lever 150, The link lever 150 can be prevented from being pushed.

When the optical disc drive desires to eject the disc tray, the optical disc drive moves the optical pick-up device 170 further away from the reference distance 200 in the outer circumferential direction, 150).

At this time, the link lever 150 is pushed by the optical pick-up assembly 172 and rotates. When the eject lever 130, which is disengaged between the engaging portions by the rotation of the link lever 150, rotates the lock lever 120, The disc tray fixed by the lock protrusion 110 coupled with the lever 120 can be ejected.

3 is a view showing an example of the state of the optical disc drive according to the embodiment at the stage when the eject operation is started.

3 is a view showing the operation of the link lever 150 when the optical pick-up device 170 moves farther in the outer direction than the reference distance.

The optical pick-up assembly 172 of the optical pick-up device 170 can push the contacted link lever 150 in the lower right direction when the optical pick-up device 170 moves farther in the peripheral direction than the reference distance.

The link lever 150, which is pushed downward at the right end portion, rotates in the clockwise direction as shown by an arrow in FIG. 3, Can be released.

At this time, as the coupling between the coupling part 131 and the coupling part 151 is released, the eject lever 130 is released from the locking by the link lever 150 and can be rotated.

4 is a view showing an example of a state of the optical disc drive according to an embodiment in the next eject operation step of FIG.

FIG. 4 is a view showing the operation of the eject lever 130 in which the locking by the link lever 150 is released in FIG.

The eject lever 130 with the locked state by the link lever 150 can be rotated in the counterclockwise direction as shown by the arrow in FIG. 4 due to the elasticity of the eject spring 140. At this time, the first projection 132 of the eject lever 130 can push the lock lever 120 downward in accordance with the rotation of the eject lever 130.

The lock lever, which is pushed downward by the first protrusion 132 of the eject lever 130, may be rotated clockwise as shown by the arrow in FIG. 4 to release the engagement with the lock protrusion 110.

At this time, the portion where the lock spring 160 is engaged in the lock lever 120 is moved to the lower left, and the portion where the lock spring 160 is engaged in the link lever 150 is moved to the upper right in FIG. Lt; RTI ID = 0.0 > 160 < / RTI >

5 is a view showing an example of the state of the optical disc drive according to an embodiment in the next eject operation step of FIG.

FIG. 5 is a view showing the operation of the lock projection 110 in which the engagement with the lock lever 120 is released in FIG.

4, when the coupling between the lock lever 120 and the lock protrusion 110 is released, the disc tray including the lock lever 120 can be ejected downward.

At this time, the lock protrusion 110 coupled to the outer chassis of the optical disc drive does not move. However, when the disc tray moves downward, the lock lever 120, the closing spring 121, the eject lever 130, the eject spring 140, the link lever 150, the lock spring 160, the optical pick- 170 and the close lever 180, the lock projection 110 may appear to move upward as shown in FIG.

Further, the lock projection 110 may contact the close lever 180 to rotate the close lever 180 in the clockwise direction.

2 to 5, the optical disc drive releases the locking of the eject lever by the link lever which rotates in accordance with the operation of the optical pickup device, thereby ejecting the disc tray. Thus, without using a solenoid or a separate motor, The tray can be ejected.

6 is a view showing an example of an optical pickup device and a link lever according to an embodiment.

The optical pickup device 170 of the optical disc drive according to one embodiment may include a bar-shaped optical pickup assembly 600 as shown in FIG.

At this time, the portion of the link lever 150, which contacts the optical pickup assembly 600, may be formed in a shape corresponding to the shape of the optical pickup assembly 600.

Further, the length of the optical pickup assembly 600 may be determined according to the angle at which the link lever 150 is rotated. For example, in order to prevent the link lever 150 and the optical pick-up assembly 600 from being separated from each other during the rotation of the link lever 150 when the link lever 150 is rotated a lot, Can be made longer.

7 is a diagram showing an example of the state of the optical disc drive according to an embodiment in a stage where the close operation is started.

The release lever 120, the eject lever 130, the eject spring 140, the link lever 150, the lock spring 160, and the lock spring 160 when the disc tray is inserted into the optical disc drive. The optical pickup device 170 and the close lever 180 can be moved upward in the direction in which the outer chassis of the optical disc drive is located.

At this time, as the disc tray is inserted into the outer chassis, the lock protrusion 110 coupled to the outer chassis in the disc tray may appear to move downward as shown in FIG.

The lock protrusion 110 which has moved downward can contact the first protrusion 181 of the close lever 180 which has been rotated in the clockwise direction in Fig.

8 is a diagram showing an example of the state of the optical disc drive according to an embodiment in the next closing operation step of FIG.

8 is a view showing the operation of the close lever 180 in contact with the lock projection 110 in FIG.

The close lever 180 in contact with the lock protrusion 110 can be rotated counterclockwise as the lock protrusion 110 moves downward and the first protrusion 181 is pushed downward. At this time, the second projection 182 of the close lever 180 can push the eject lever 130 in the clockwise direction as shown in FIG.

The eject lever 130 pushed by the second projection 182 of the close lever 180 is rotated clockwise to a position where the coupling portion 151 of the link lever 150 can engage with the coupling portion 131 can do.

FIG. 9 is a view showing an example of the state of the optical disc drive according to an embodiment in the next eject operation step of FIG.

FIG. 9 is a view showing the operation of the lock lever 120 and the link lever 150 according to the eject lever 130 rotated in FIG.

When the eject lever 130 rotates, the first protrusion 132 of the eject lever 130 also rotates upward, so that the lock lever 120 can be rotated in the counterclockwise direction by the lock spring 160. 4, the lock lever 120 is pushed downward to rotate the lock lever 120. Then, until the eject lever 130 rotates clockwise as shown in FIG. 8, It may be possible to prevent the rotating shaft 120 from rotating counterclockwise.

At this time, when the first projection 132 rotates upward, the lock lever 120 is rotated in the counterclockwise direction as shown in FIG. 9 due to the elasticity of the lock spring 160, which was tensioned in FIG. 4, can do. Then, the lock lever 120 rotated in the counterclockwise direction engages with the lock projection 110, thereby locking the disc tray.

Also, the lock spring 160 can rotate the link lever 150 together with the lock lever 120 through the elasticity in a counterclockwise direction.

At this time, the link lever 150 rotates in the counterclockwise direction to move the engaging portion 151 to a position corresponding to the engaging portion 131 of the eject lever 130. Also, as the link lever 150 moves in the counterclockwise direction, the optical pick-up assembly 172 in contact with the link lever 150 can also be pushed counterclockwise to the left. At this time, the upper left direction in which the optical pickup assembly 172 is pushed may be the inner peripheral direction. When the optical pickup assembly 172 is pushed in the inner circumferential direction, the optical pickup device 170 coupled with the optical pickup assembly 172 can move in the inner circumferential direction as shown in FIG.

8, the distance between the fastening portion 131 and the fastening portion 151 of the link lever 150 may be short. In addition, when the eject lever 130 is rotated clockwise as shown in FIG. At this time, the eject lever 130 can be rotated counterclockwise by the elasticity of the eject spring 140 until the coupling part 131 and the coupling part 151 of the link lever 150 are engaged and engaged. At this time, as the eject lever 130 rotates counterclockwise, the close lever 180 connected to the eject lever 130 rotates in the clockwise direction and can move to the default position as shown in FIG.

Since the eject lever 130 can no longer rotate in the counterclockwise direction after the engaging portion 131 is engaged and engaged with the engaging portion 151 of the link lever 150, Can be locked by the link lever (150).

As shown in FIGS. 7 to 9, the optical disc drive closes the disc tray by locking the eject lever with a link lever that is rotated by the elasticity of the spring, thereby making it possible to close the disc tray without using a solenoid or a separate motor have.

The optical disk drive according to the embodiment can prevent the ejection lever from being locked by the link lever that rotates in accordance with the movement of the optical pick-up device or the elasticity of the spring or by releasing the locking of the eject lever by using a solenoid or a separate motor, The tray can be ejected or closed.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

110:
120: Lock lever
130: eject lever
140: Eject spring
150: Link lever
160: Rock spring
170: Optical pickup device
180: Close lever

Claims (17)

A lock lever which rotates so as to release the locking of the disc tray;
An eject lever connected to the lock lever to rotate the lock lever;
An eject spring for moving the eject lever through elasticity;
A link lever which engages with the eject lever via a fastening portion; And
And an optical pickup assembly having an optical pickup assembly connected to the link lever
Lt; / RTI >
The link lever is pushed and rotated by the optical pickup assembly,
Wherein the eject lever is disengaged from the engagement portion due to the rotation of the link lever,
The optical pickup apparatus described in
And pushes the link lever through the optical pickup assembly when moving in an outer direction beyond a preset reference distance. The method according to claim 1,
The eject lever
And the engagement of the coupling portion is released due to the rotation of the link lever, thereby rotating due to the elasticity of the eject spring. delete A lock lever which rotates so as to release the locking of the disc tray;
An eject lever connected to the lock lever to rotate the lock lever;
An eject spring for moving the eject lever through elasticity;
A link lever which engages with the eject lever via a fastening portion; And
And an optical pickup assembly having an optical pickup assembly connected to the link lever
Lt; / RTI >
The link lever is pushed and rotated by the optical pickup assembly,
Wherein the eject lever is disengaged from the engagement portion due to the rotation of the link lever,
The optical pickup apparatus described in
Wherein the optical disk drive moves beyond a predetermined reference distance through an external switch signal provided in the optical disk drive. An eject lever for rotating a lock lever for releasing locking of the disc tray; And
And a link lever that engages with the eject lever via a fastening portion.
Lt; / RTI >
The link lever
When the optical pickup device moves in the outer circumferential direction, the coupling of the coupling portion is released by the optical pickup assembly of the optical pickup device,
Wherein when the engagement of the coupling portion is released, the eject lever is rotated to rotate the lock lever, and rotated by pivoting due to the assembly of the optical pickup device moving beyond a predetermined reference distance. delete 6. The method of claim 5,
The eject lever
And the lock lever is rotated by the elasticity of the eject spring when the engagement of the engagement portion is released. A lock lever which rotates so as to release the locking of the disc tray;
An eject lever connected to the lock lever to rotate the lock lever;
An eject spring for moving the eject lever through elasticity; And
And a link lever that engages with the eject lever via a fastening portion.
Lt; / RTI >
The link lever
When the optical pick-up apparatus moves in the outer circumferential direction beyond a predetermined reference distance, it is pushed and rotated by the optical pick-up assembly of the optical pick-up apparatus,
Wherein the eject lever releases the engagement of the engagement portion due to the rotation of the link lever. 9. The method of claim 8,
The eject lever
And the engagement of the coupling portion is released due to the rotation of the link lever, thereby rotating due to the elasticity of the eject spring. delete delete delete delete delete delete delete delete

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