KR101875750B1 - Slim type optical disc drive - Google Patents

Abstract

The slim type optical disc drive according to the present invention is a slim type optical disc drive in which, for example, when a tray eject operation is performed, the optical pickup unit is moved in the inner circumferential direction of the disc and a link arm unit Unit can be additionally provided so that the hook formed at the end portion of the lock arm is separated from the state of engagement with the shaft so that the tray can be efficiently ejected without using a high- It is possible to reduce the manufacturing cost and simplify the slim optical disk drive.

Description

[0001] Slim type optical disc drive [0002]

The present invention relates to a slim type optical disc drive in which a high-priced solenoid for eliminating (ejecting) a tray from a tray or inserting the tray therein is eliminated.

2. Description of the Related Art Various types of optical disc drives (ODDs) for recording or reproducing data on optical discs such as a CD, a DVD and a BD are widely used.

For example, a slim type optical disk drive, which is mainly used in a portable computer such as a notebook computer, is provided with a solenoid (not shown) for inserting or ejecting a tray, 10, a plunger arm 11, a plunger arm spring 12, a reset arm 13, a lock arm 14, a lock arm spring 15, a shaft 16, and the like.

On the other hand, in the slim optical disk drive 100 configured as described above, when the tray is ejected, the power applied to the solenoid 10 is turned off, Likewise, due to the contracting action of the plunger arm spring 12, the plunger arm 11 is rotated counterclockwise.

Since the lock arm 14 rotates in the clockwise direction in conjunction with the rotation operation of the plunger arm 11, a hook formed at the end of the lock arm 14, Is detached from the state of engagement with the shaft 16, so that the tray can eventually be ejected to the outside.

On the other hand, when the tray is inserted, since the solenoid 10 is turned on, the plunger arm spring 12 expands, so that the plunger arm 11 rotates clockwise .

Since the lock arm 14 rotates in the counterclockwise direction in conjunction with the rotation operation of the plunger arm 11, the hook formed at the end portion of the lock arm 14, The tray 16 can be inserted and fixed to the inside of the tray 16. In order to eject or insert the tray as described above, a high-priced solenoid must be used.

In the present invention, for example, when performing a tray eject operation, the optical pickup unit is moved in the inner circumferential direction of the disk, and a link arm unit that rotates in conjunction with the moved optical pickup unit is additionally installed The present invention provides a slim type optical disk drive in which a hook formed at the end portion of a lock arm is separated from a state of engagement with a shaft so that the tray can be efficiently ejected without using an expensive solenoid .

The slim optical disk drive according to the present invention may further include a link arm unit that moves the optical pickup unit in an inner circumferential direction of the disk and rotates in conjunction with the optical pickup unit when the tray eject operation is performed, , The hook of the lock arm is changed from the engagement state with the shaft to the disengaged state by the separation operation from the plunger arm, thereby ejecting the tray,

The link arm unit may include a first link arm, a second link arm, and a third link arm. A damper for contacting the optical pick-up unit may be installed at one end of the first link arm And a second hinge for interlocking with the second link arm is provided at the other end of the second link arm and a second hinge for rotating the fixed link about the fixed axis is provided at an intermediate portion of the second link arm, Wherein the third link arm is in contact with or separated from the third link arm, and the third link arm is fixedly fastened to the plunger arm,

The damper provided at one end of the first link arm rotates and moves in the inner circumferential direction of the slider motor by contact with the optical pickup unit,

The first hinge may be configured to connect and interlock the first link arm and the second link arm and have a rectangular shape and have fluidity at a predetermined interval when the first link arm rotates do.

The slim type optical disc drive according to the present invention is a slim type optical disc drive in which, for example, when a tray eject operation is performed, the optical pickup unit is moved in the inner circumferential direction of the disc and a link arm unit Unit can be additionally provided so that the hook formed at the end portion of the lock arm is separated from the state of engagement with the shaft and the tray can be efficiently ejected without using a high-priced solenoid, Thereby simplifying the optical disc drive and reducing manufacturing costs.

1 shows an embodiment of a general slim optical disk drive,
FIG. 2 shows an embodiment in which a tray of a general slim optical disk drive is ejected,
FIG. 3 illustrates an embodiment of a slim optical disk drive according to the present invention,
FIG. 4 illustrates an embodiment in which the tray of the slim optical disc drive according to the present invention is ejected.

Hereinafter, preferred embodiments of a slim optical disk drive according to the present invention will be described in detail with reference to the accompanying drawings.

First, in the slim optical disk drive according to the present invention, instead of deleting a high-priced solenoid used for ejecting or inserting a tray, the optical pickup unit OPU is moved in the inner circumferential direction of the disk And a link arm unit that rotates in conjunction with the moving optical pick-up unit is additionally provided.

For example, as shown in FIG. 3, in the slim optical disk drive 200 according to the present invention, instead of eliminating the high-priced solenoid 10 used in the past, the solenoid 10 is interlocked with the movement of the optical pickup unit 21 A link arm unit including a first link arm 23 rotating in the inner circumferential direction of the spindle motor, a second link arm 24, and a third link arm 25 is additionally provided.

4, a rotatable damper 22 is provided at one end of the first link arm 23, and the first link arm 23 The first hinge 26 is connected to the second link arm 24 and is interlocked with the second link arm 24.

4, a second hinge 27, which rotates about a fixed axis, is provided at an intermediate portion of the second link arm 24, The first hinge 26 for connecting and interlocking the second link arm 24 and the second link arm 24 has a rectangular shape and fluidity at a predetermined interval.

The other end of the second link arm 24 contacts or is separated from the third link arm 25. For example, the third end of the third link arm 25 is connected to the third link arm 25, When the link arm 25 contacts the other end of the second link arm 24, the plunger arm spring 27 is kept in the expanded state.

On the other hand, when the third link arm 25 is separated from the other end of the second link arm 24, the plunger arm spring 27 is changed from the expanded state to the contracted state.

The plunger arm 11 rotates in the counterclockwise direction by the contracting force of the plunger arm spring 27 and the lock arm 14 is rotated clockwise by the plunger arm 11 in cooperation with the plunger arm 11. [ The hooks formed at the end portion of the lock arm 14 are separated from the state of engagement with the shaft 16 so that the trays can eventually be ejected to the outside, The process of ejecting the tray will be described in detail as follows.

First, in the slim optical disk drive according to the present invention, for example, when receiving a tray eject command from various types of hosts such as a personal computer or pushing the eject button when the user is exposed to the outside , The optical pickup unit 21 spaced apart from the sled motor 20 by a predetermined distance is moved in the inner circumferential direction of the disk as shown in FIG.

A part of the optical pickup unit 21 moving in the inner circumferential direction of the disk as described above comes into contact with the damper 22 provided at the end of the first link arm 23. At this time, 22 are obliquely contacted with a part of the optical pickup unit 21 at an inclination angle of a predetermined angle.

Accordingly, the damper 22 is not pushed back, but is rotated and moved in the inner circumferential direction of the spindle motor, and the first link arm 23 provided with the damper 22 is rotated counterclockwise .

When the first link arm 23 is rotated in the counterclockwise direction as described above, the second hinge 27 provided at the intermediate portion of the second link arm 24 serves as a fixed shaft, The arm 24 is rotated in the counterclockwise direction so that the third link arm 25 which has been in contact with the end portion of the second link arm 24 is detached and separated.

The plunger arm 11 fastened below the third link arm 25 is rotated in the counterclockwise direction by the contracting force of the plunger arm spring 12 so that the lock arm 14, So that the hook formed at the end of the lock arm 14 is separated from the state of engagement with the shaft 16 and the tray is ejected to the outside.

Therefore, since the tray can be ejected to the outside without using a high-priced solenoid, the manufacturing cost of the slim optical disk drive can be efficiently reduced.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. , Alteration, substitution, addition, or the like.

100,200: Slim optical disk drive 10: Solenoid
11: plunger arm 12: plunger arm spring
13: reset arm 14: lock arm
15: lock arm spring 16: shaft
20: spindle motor 21: optical pick-up unit 22: damper 23: first link arm
24: second link arm 25: third link arm 26: first hinge 27: second hinge

Claims (4)

Spindle motor;
An optical pickup unit;
A sled motor which moves the optical pickup unit in an inner circumferential direction of the optical disc when the tray is ejected;
A link arm unit that rotates in conjunction with the optical pickup unit when the tray is ejected;
A plunger arm which is in contact with the link arm unit and is separated from the link arm unit when the tray is ejected and is rotated by a plunger arm spring; And
The hook formed in the end portion by the elastic force of the lock arm spring maintains the state of engagement with the shaft fixing the tray, and the lock arm, which is rotated by the rotation of the plunger arm when the tray is ejected, And,
Wherein the link arm unit includes a first link arm, a second link arm, and a third link arm,
Wherein the damper is hinged to the second link arm at one end and the damper is hinged to the second link arm so that the damper slants at a predetermined angle from the optical pick- The first link arm is rotated in the inner circumferential direction of the motor,
In the second link arm, the second link arm is hinged to the other end of the first link arm in the form of a rectangular slot so that the second link arm rotates about the fixed axis of the intermediate portion and has fluidity at one end, The other end of the second link arm is separated from the third link arm when the tray is ejected,
Wherein the third link arm is fixedly coupled with the plunger arm when in contact with the second link arm to maintain the plunger arm spring in an inflated state. delete delete delete

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