KR100505654B1 - Tray locking apparatus for optical disc drive and optical disc drive using the same - Google Patents

Abstract

Disclosed is a tray locking apparatus of an optical disc drive. The disclosed tray locking device includes a tray having a first locking portion provided in a case of an optical disk drive, a solenoid having a reciprocating plunger and a first elastic member applied to the plunger in a direction in which the plunger protrudes, and a tray. Locking lever is installed so as to be rotatable in the one end is coupled to the plunger and rotated by the reciprocating movement of the plunger, and the locking lever is provided in the locking lever and selectively caught in the first locking portion in accordance with the rotation of the locking lever to lock and unlock the tray And a second locking portion to be installed on the tray, and an unlocking prevention device that is freely rotated in a direction in which the locking lever is unlocked in the locked state of the tray to prevent the locking state from being released. According to such a structure, even if a significant impact is applied to the tray from the outside, the locked state of the tray can be maintained more stably, thereby solving the conventional problem of undesirably opening the tray.

Description

Tray locking apparatus for optical disc drive and optical disc drive employing same {Tray locking apparatus for optical disc drive and optical disc drive using the same}

The present invention relates to an optical disc drive, and more particularly, to a tray locking device of a slim optical disc drive having a structure capable of maintaining a more stable locking state of a tray, and an optical disc drive employing the same.

In general, an optical disc drive is a device for recording information or reproducing recorded information by irradiating light onto a recording medium such as a compact disc (CD) or a digital video disc (DVD). Such an optical disk drive is mainly employed in a computer, and especially a notebook computer employs a slim optical disk drive having a very thin thickness.

1 shows a schematic structure of a conventional slim optical disk drive. Referring to FIG. 1, a conventional slim optical disk drive includes a case 10 and a tray 20 installed to be accessible from the case 10. The main base 30 is coupled to the tray 20, and the main base 30 has a spindle motor 40 for rotating the disk, and data to the disk D rotating reciprocally in the radial direction of the disk. An optical pickup unit 50 for recording / reproducing is provided. As such, the tray 20 is provided with a spindle motor 40 and an optical pick-up unit 50, and they enter and exit the case 10 together.

On the other hand, unlike the tray of a conventional optical disk drive that is loaded or unloaded by a separate loading motor, the tray 20 mounted on a slim optical disk drive used in a notebook, etc. is mostly a structure that is manually moved in and out for slimming. Accordingly, the slim optical disk drive requires a locking device 60 that locks or unlocks the tray 120.

2 and 3 illustrate a state in which the tray is locked and a state in which the tray is unlocked by the tray locking device illustrated in FIG. 1.

Referring first to Figure 2, the conventional tray locking device 60, the solenoid 61 having a reciprocating plunger (62), and the plunger 62 is coupled to the reciprocating movement of the plunger 62 Rotating ejecting lever 63, locking lever 65 engaged with ejecting lever 63, spring 69 connected to locking lever 65, locking jaw 67 of locking lever 65 The locking post 68 is provided. The solenoid 61, the ejecting lever 63, the locking lever 65, and the spring 69 are installed on the bottom surface of the tray 20 to move together with the tray 20, and the locking post ( 68 is fixed to the case 10.

The first gear 64 is formed at the rotational center of the ejecting lever 63. In addition, the locking lever 65 is provided with a locking jaw 67 engaged with the locking post 68 and a second gear 66 engaged with the first gear 64 to rotate the locking lever 65. . The spiral spring 69 is connected to one end of the locking lever 65 to apply an elastic force to the locking lever 65 so that the locking lever 65 is rotated in the direction in which the locking post 68 and the locking jaw 67 are coupled. do.

Next, the operation of the conventional tray locking device 60 shown in FIG. 2 will be described with reference to FIG. 3. When the electric current is supplied to the solenoid 61, the plunger 62 is moved in the direction of arrow X by the magnetic force of the solenoid 61, so that the ejecting lever 63 coupled to the plunger 62 rotates clockwise. Done. Then, the locking lever 65 is rotated counterclockwise by the second gear portion 66 meshed with the first gear portion 64, thereby locking the locking jaw 67 and the locking post 68. The state is released. In this state, the tray 20 is manually pulled and unloaded.

When the current supply to the solenoid 61 is stopped, the magnetic force applied to the plunger 62 is lost, so that the locking lever 65 rotates clockwise by the elastic force of the spring 69 and returns to its original position. Then, the ejecting lever 63 is rotated counterclockwise by the clockwise rotation of the locking lever 65, whereby the plunger 62 is moved in the direction of arrow X 'to return to the original position. In this state, when the tray 20 is pushed and loaded by hand, the locking jaw 67 of the locking lever 65 is caught by the locking post 68 due to the elastic force of the spring 69. As shown in FIG. 20) is locked.

By the way, in the above-mentioned conventional tray locking device 60, when a certain amount of external impact or force is applied to the tray 20 in the arrow X direction, the plunger 62 of the solenoid 61 provided in the tray 20 is applied. ) Can move in the direction of arrow X by the inertia force of its own weight. In this case, since the locking lever 65 rotates counterclockwise as described above, the locking state of the locking jaw 67 and the locking post 68 is released and the tray 20 is undesirably opened. This will occur.

The present invention has been made to solve the above problems of the prior art, and in particular, a tray locking apparatus for an optical disk drive having a structure capable of more stably maintaining the locked state of the tray even when a significant impact or force is applied to the tray. It is an object of the present invention to provide an optical disk drive employing the same.

The present invention to achieve the above object,

A tray locking apparatus of an optical disc drive, which is installed in a case and which locks a tray on which a disc is mounted, selectively locks and unlocks a tray in the case.

A first locking part provided in the case;

A solenoid installed on the tray and having a reciprocating plunger and a first elastic member for applying an elastic force to the plunger in a direction in which the plunger protrudes;

A locking lever rotatably mounted to the tray, one end of which is coupled to the plunger and pivoted by reciprocating movement of the plunger;

A second locking part provided on the locking lever to selectively lock onto the first locking part according to rotation of the locking lever to lock and unlock the tray; And

And an unlocking prevention device installed on the tray to prevent the locking state from being released by arbitrarily rotating in the direction in which the locking lever is unlocked in the locked state of the tray. .

The present invention also provides an optical disc drive having a tray locking device having the above-described configuration.

Here, the unlocking device, the inertial force when the inertial force is applied to the housing, a through-hole formed through the housing so that the other end of the locking lever can be inserted, and reciprocating in the housing is actuated It is preferable to have a weight moving in the direction of the blocking the through hole, and a second elastic member for applying an elastic force to the weight so that the weight is moved in a direction not blocking the through hole.

In addition, the weight is preferably arranged such that its moving direction is parallel to the moving direction of the plunger, and its weight is preferably substantially the same as the weight of the plunger.

Preferably, the first elastic member and the second elastic member are compression coil springs, and the elastic force of the second elastic member is preferably equal to or weaker than the elastic force of the first elastic member.

Preferably, the first locking portion is a locking protrusion protruding from a rail guide that is fixed to a corner of the case and guides the reciprocating movement of the tray.

Preferably, the second locking portion is a locking arm that extends from the locking lever, and its rear surface is formed to be inclined with respect to the moving direction of the tray so that the rear surface is in sliding contact with the first locking portion when the tray is loaded. It is preferable that the locking lever can be rotated while being rotated.

The solenoid, the locking lever and the unlocking prevention device may be assembled to a separate bracket to be installed in the tray in the form of an assembly in order to improve assembly.

According to such a structure, even if a significant impact is applied to the tray from the outside, the locked state of the tray can be maintained more stably, thereby solving the conventional problem of undesirably opening the tray.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the tray locking apparatus of the optical disk drive according to the present invention. Like reference numerals in the following drawings indicate like elements.

4 is a plan view showing an optical disk drive employing the tray locking device according to the present invention, Figure 5 is a plan view showing in detail the configuration of the tray locking device according to the present invention shown in FIG.

4 and 5 together, the optical disc drive includes a case 110 and a tray 120 installed in and out of the case 110. The case 110 is fixedly installed in the body of an electronic device employing a slim optical disk drive, such as a computer, in particular a notebook computer. The main base 130 is coupled to the tray 120. The main base 130 is provided with a spindle motor 140 for rotating the disk and an optical pickup unit 150 for reproducing data recorded on the rotating disk reciprocating in the radial direction of the disk. In this way, the spindle motor 140 and the optical pickup unit 150 are installed in the tray 120, and they enter and exit the case 110 together.

In addition, the optical disk drive is provided with a tray locking device 200 for locking and unlocking the tray 120 installed in the case 110. The tray locking device 200 according to the present invention includes a first locking part 210 provided in the case 110, a solenoid 220 installed on the tray 120, a locking lever 230, and an unlocking prevention device ( 250 and a second locking part 240 provided on the locking lever 230.

On the other hand, the solenoid 220, the locking lever 230 and the unlocking device 250 may be installed directly on the tray 120, as shown in Figure 4 is assembled in a separate bracket 260 sub It may also be assembled to the tray 120 in a sub-assembly form. According to the latter case, the process efficiency in the assembling process of the optical disc drive can be improved, and there is an advantage in that it is easy to handle.

The first locking part 210 is provided on the right side of the case 110. When the loading of the tray 120 is completed, the first locking unit 210 is locked by the second locking unit 240 to be described later, so that the tray 120 is locked in the case 110. The first locking portion 210 may be fixedly installed at the right corner of the case 110 to protrude a predetermined height in the form of a protrusion at a front end portion of the rail guide 112 that guides the reciprocating movement of the tray 120. Since the rail guide 112 is typically made of a plastic injection molding, the first locking portion 210 may be integrally formed with the rail guide 112. Meanwhile, the first locking portion 210 may be manufactured as a separate component from the rail guide 112 and may be coupled to the rail guide 112.

The solenoid 220 has a reciprocating plunger 222 and a first elastic member 224 for applying an elastic force to the plunger 222 in the direction in which the plunger 222 protrudes. As the first elastic member 224, it is preferable to use a compression coil spring. Leaf springs and other types of springs may be used. Therefore, in the state where the current is not supplied to the solenoid 220, the plunger 222 is always protruded by the elastic force of the first elastic member 224. However, when a current is supplied to the solenoid 220, the plunger 222 overcomes the elastic force of the first elastic member 224 by the magnetic force generated inside the solenoid 220 and moves inside the solenoid 220. . As such, the plunger 222 of the solenoid 220 is to be reciprocated depending on whether or not a current is supplied.

The locking lever 230 is installed on the tray 120 to be rotatable. To this end, the rotation shaft 232 is fixedly installed on the tray 120, and an intermediate portion of the locking lever 230 is coupled to the rotation shaft 232. In addition, a coupling hole 234 into which the plunger 222 is inserted is formed at one end of the locking lever 230. Therefore, the locking lever 230 is able to rotate clockwise or counterclockwise about the rotation shaft 232 according to the reciprocating movement of the plunger 222 as described above. On the other hand, the other end of the locking lever 230 is provided with an insertion portion 236 to be inserted into the through hole 258 of the unlocking prevention device 250 to be described later.

The second locking part 240 is provided on the locking lever 230 to rotate together with the rotation of the locking lever 240. By this rotation, the second locking part 240 is selectively caught by the first locking part 210. Specifically, in the state in which the locking lever 230 is rotated in the counterclockwise direction, the second locking part 240 is caught by the first locking part 210, and thus the tray 120 is in the case 110. Is locked. On the contrary, when the locking lever 230 rotates in the clockwise direction, the second locking unit 240 also rotates in the clockwise direction, thereby deviating from the first locking unit 210, and thus the locking state of the tray 120 is Is released.

The second locking portion 240 may be formed in the form of an arm that protrudes from an approximately middle portion of the locking lever 230. The second locking part 240 may be integrally formed by plastic injection together with the locking lever 230. In addition, the second locking part 240 may have a rear surface thereof inclined with respect to the moving direction of the tray 120. This allows the tray 120 to be easily inserted into the case 110. This will be described in detail later.

The unlocking device 250 serves to prevent the locking lever 230 from rotating arbitrarily in a direction in which the locking lever 230 is unlocked by interfering with the insertion part 236 provided at the other end of the locking lever 230. . The unlocking device 250 is fixed to the tray 120 and has a housing 252 having a predetermined internal space. In the housing 252, a weight 254 having a predetermined weight is installed to reciprocate, and a second elastic member 256 is provided to apply a predetermined elastic force to the weight 254. In addition, a through hole 258 is formed in the housing 252 so that the insertion portion 236 may be inserted at a position corresponding to the insertion portion 236 of the locking lever 230.

The weight 254 is preferably arranged such that its moving direction is parallel to the moving direction of the plunger 222 of the solenoid 220. Therefore, when the impact is applied to the tray 120 in the direction of arrow X, when the plunger 222 moves in the direction of arrow X by its inertial force, the weight 254 can also move in the direction of arrow X by its inertial force. In addition, the weight of the weight 254 is preferably substantially the same as the weight of the plunger 222. This is because, when an impact is applied to the tray 120, the operations of the plunger 222 and the weight 254 need to be matched.

The second elastic member 256 applies an elastic force to the weight 254 to allow the weight 254 to move in a direction that does not block the through hole 258. Therefore, since the weight 254 is normally moved in the direction of arrow X 'by the second elastic member 256, the through hole 258 is opened so that the insertion portion of the locking lever 230 can freely enter and exit. As the second elastic member 256, a compression coil spring may be used, and the elastic force thereof is preferably equal to or weaker than that of the first elastic member 224. When the elastic force of the second elastic member 256 is stronger than the elastic force of the first elastic member 224, the weight 254 of the weight 254 is moved even when the plunger 222 is moved when an external impact is applied to the tray 120. This is because the movement may not occur.

According to the tray locking device 200 having the above-described configuration, when the impact is applied to the tray 120 in the arrow X direction, the weight 254 together with the plunger 222 is also moved in the arrow X direction by the inertia force. As a result, the through hole 258 is closed by the weight 254. Therefore, since the insertion portion 236 of the locking lever 230 interferes with the weight 254, the unlocking direction of the locking lever 230, that is, the clockwise rotation does not occur.

6 to 8, the operation of the tray locking device according to the present invention having the configuration as described above will be described. 6 to 8 are views for explaining the locking state release operation, the locking operation and the operation of the locking device when an external shock is applied to the tray by the tray locking device according to the present invention shown in FIG. 4, respectively.

First, as shown in FIG. 6, when a current is applied to the solenoid 220, the plunger 222 overcomes the elastic force of the first elastic member 224 by the magnetic force of the solenoid 220 and moves in the arrow X direction. Bounce. Accordingly, the locking lever 230 coupled to the plunger 222 rotates clockwise while the second locking unit 240 also rotates clockwise to release the locking state with the first locking unit 210. At this time, since the weight 254 of the unlocking prevention device 250 is moved in the direction of arrow X 'by the elastic force of the second elastic member 256, the through hole 258 is open. Therefore, since the insertion portion 230 of the locking lever 230 may be inserted into the through hole 258, the clockwise rotation of the locking lever 230 may occur. In this state, if the tray 120 is manually pulled in the arrow F direction, the tray 120 may be unloaded from the case 110.

Referring to FIG. 7, when the current applied to the solenoid 220 is interrupted while the tray 120 is unloaded, the magnetic force of the solenoid 220 is extinguished, so that the plunger 222 of the first elastic member 224 is removed. It protrudes in the direction of arrow X 'by the elastic force. Accordingly, the locking lever 230 also rotates counterclockwise to a state as shown in FIG. 5. When the tray 120 is pushed in the arrow R direction in this state, the inclined rear surface of the second locking part 240 contacts the first locking part while the locking lever 230 moves in the arrow R direction. At this time, the locking lever 230 is rotated slightly in the clockwise direction by contacting the second locking part 240 and the first locking part 210, so that the second locking part 240 continues to move in the arrow R direction. Can be. When the tray 120 is completely loaded in the case 110, the second locking portion 240 returns to its original position by the elastic force of the first elastic member 224 as described above, and thus the first locking portion ( 210 and locked.

Next, referring to FIG. 8, when the tray 120 is loaded and locked in the case 110 and the impact is applied to the tray 120 in the arrow X direction, the plunger 222 of the solenoid 220 is also weighed. It can move in the direction of arrow X by the inertia force. However, according to the present invention, since the weight 254 of the unlocking prevention device 250 also moves in the direction of arrow X by the inertial force due to its weight, the through hole 258 formed in the housing 252 is the weight ( 254). Therefore, since the insertion portion 236 of the locking lever 230 is not inserted into the through hole 258, the locking lever 230 is suppressed in the clockwise rotation. As a result, the second locking portion 240 is prevented from randomly deviating from the first locking portion 210, so that the locked state of the tray 120 can be stably maintained even when an impact is applied from the outside.

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

According to the tray locking apparatus of the optical disk drive according to the present invention as described above, even if a significant impact is applied to the tray from the outside in the moving direction of the plunger, the locked state of the tray is not released. Thus, the locked state of the tray can be kept more stable, so that the conventional problem of undesirably opening the tray does not occur.

1 is a plan view schematically showing the structure of a conventional slim optical disk drive.

FIG. 2 is a plan view illustrating a state in which a tray is locked by the tray locking device shown in FIG. 1.

3 is a plan view illustrating a state in which a tray is unlocked by the tray locking device illustrated in FIG. 1.

4 is a plan view showing an optical disk drive employing a tray locking device according to the present invention.

5 is a plan view showing in detail the configuration of the tray locking device according to the present invention shown in FIG.

FIG. 6 is a view for explaining an operation of releasing a locked state of a tray by the tray locking device according to the present invention shown in FIG. 4.

7 is a view for explaining the operation of the tray is locked by the tray locking apparatus according to the present invention shown in FIG.

8 is a view for explaining the operation of the tray locking device according to the present invention when an external impact is applied to the tray.

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

110 ... case 112 ... rail guide

120 ... Tray 130 ... Main Base

140 ... spindle motor 150 ... optical pickup unit

200 ... tray locking device 210 ... 1st locking part

220 Solenoid 222 Plunger

224 ... First elastic member 230 ... Locking lever

232 ... Rotating shaft 234 ... Joining hole

236 ... insert 240 ... second lock

250 ... Unlocking device 252 ... Housing

254 ... weight 256 ... second elastic member

258 ... Through hole 260 ... Bracket

Claims (22)

delete A tray locking apparatus of an optical disc drive, which is installed in a case and which locks a tray on which a disc is mounted, selectively locks and unlocks a tray in the case. A first locking part provided in the case; A solenoid installed on the tray and having a reciprocating plunger and a first elastic member for applying an elastic force to the plunger in a direction in which the plunger protrudes; A locking lever rotatably mounted to the tray, one end of which is coupled to the plunger and pivoted by reciprocating movement of the plunger; A second locking part provided on the locking lever to selectively lock onto the first locking part according to rotation of the locking lever to lock and unlock the tray; And And an unlocking prevention device installed in the tray and preventing rotation of the locking state by randomly rotating in the direction in which the locking lever is unlocked in the locked state of the tray. The anti-locking device is provided with a through hole formed in the housing so that the other end of the locking lever can be inserted therein, and installed in the housing so as to be reciprocated in the direction of inertial force when the inertial force is applied. And a second elastic member configured to move to block the through hole and to apply an elastic force to the weight such that the weight moves in a direction in which the weight does not block the through hole. The method of claim 2, And the weight is arranged such that its moving direction is parallel to the moving direction of the plunger. The method of claim 2, And the weight of the weight is substantially the same as the weight of the plunger. The method of claim 2, The second elastic member is a tray locking device of the optical disk drive, characterized in that the compression coil spring. The method of claim 2, And the elastic force of the second elastic member is equal to or weaker than the elastic force of the first elastic member. The method of claim 2, And the first locking portion is a locking protrusion which is fixedly installed at a corner of the case and protrudes from a rail guide for reciprocating movement of the tray. The method of claim 2, The first elastic member is a tray locking device of the optical disk drive, characterized in that the compression coil spring. The method of claim 2, And said second locking portion is a locking arm extending from said locking lever. The method of claim 2, And the second locking part is formed to be inclined with respect to the moving direction of the tray so that the locking lever can be rotated while the back is in sliding contact with the first locking part when the tray is loaded. Tray lock on drive. The method of claim 2, The solenoid, the locking lever and the unlocking device is assembled to a separate bracket, the tray locking device of the optical disk drive, characterized in that installed in the tray in the form of an assembly. delete An optical disc drive comprising a case, a tray removably installed in the case, and a tray on which a disc is mounted, and a tray locking device for selectively locking and unlocking the tray in the case. The tray locking device, A first locking part provided in the case; A solenoid installed on the tray and having a reciprocating plunger and a first elastic member for applying an elastic force to the plunger in a direction in which the plunger protrudes; A locking lever rotatably mounted to the tray, one end of which is coupled to the plunger and pivoted by reciprocating movement of the plunger; A second locking part provided on the locking lever to selectively lock onto the first locking part according to rotation of the locking lever to lock and unlock the tray; And And an unlocking prevention device installed in the tray and preventing rotation of the locking state by randomly rotating in the direction in which the locking lever is unlocked in the locked state of the tray. The unlocking device includes a housing, a through hole formed through the housing so that the other end of the locking lever can be inserted therein, and installed in the housing so as to be reciprocated so that the inertial force is applied in the direction of the inertia force. And a second elastic member which moves to block the through hole and applies an elastic force to the weight so that the weight moves in a direction not to block the through hole. The method of claim 13, And the weight is arranged such that its moving direction is parallel to the moving direction of the plunger. The method of claim 13, The weight of the weight is substantially equal to the weight of the plunger. The method of claim 13, And the second elastic member is a compression coil spring. The method of claim 13, And the elastic force of the second elastic member is equal to or weaker than the elastic force of the first elastic member. The method of claim 13, And the first locking portion is a locking protrusion fixedly installed at a corner of the case and protruding from a rail guide for reciprocating the tray. The method of claim 13, And said first elastic member is a compression coil spring. The method of claim 13, And the second locking portion is a locking arm extending from the locking lever. The method of claim 13, And the second locking part is formed to be inclined with respect to the moving direction of the tray so that the locking lever can be rotated while the back is in sliding contact with the first locking part when the tray is loaded. drive. The method of claim 13, The solenoid, the locking lever and the unlocking device are assembled to a separate bracket and installed in the tray in the form of an assembly.