KR20090014896A - Disk drive - Google Patents

Abstract

A disk drive is provided to prevent the deformation of a disk drive and ensure the disk transfer section by supporting the disk insertion opening with a supporting lever. A disk drive comprises a case with an opening in which a disk is loaded and unloaded, a main chassis(30) which is installed on the case and equipped with a driving source, an interlock mechanism which is connected to the driving source and delivers the power, and a supporting lever(59) which is rotated to be perpendicular to the disk insertion direction by the power delivered from the interlock mechanism, and supports the case with selectively shielding a part of the opening depending on the insertion of the disk.

Description

Disk drive

The present invention relates to a disk drive, and more particularly to a disk drive for operating the disk to read or write data.

In general, a disk drive refers to an optical storage medium using optical pickup. A disk drive such as a CD and a DVD is mounted on a turntable and clamped. A recording and reproducing apparatus for reproducing information recorded on a disc or recording new information on a disc by optical pickup moving in the radial direction while rotating the disc.

Such a disk drive is provided with a disk loading device for loading a disk input from the outside onto a turntable. The disc loading device includes a tray type for seating and loading a disc on a tray that is inputted into and out of a disc drive, and a disc is inserted into the front disc insertion slot directly without using a separate tray. There is a slot-in type.

Tray type has been mainly used for inserting a disk into a disk drive. Recently, however, interest in monitor-TV integrated and LCD-display integrated personal computers has increased. In the case of a portable computer such as a notebook, a form having a slim design directly inserted into a disk drive is mainly used.

As described above, in order to maintain a slim design, it is difficult to use a tray type, so a slot in type is used. The disk drive described below relates to a slot in type disk drive.

1A and 1B show a schematic configuration of a disc drive according to the prior art in a front view and a plan view.

As shown in these figures, the entire skeleton of the disc drive is formed by the main chassis 1. On the upper surface of the main chassis 1, a main base (not shown), an optical pickup base (not shown), and an optical pickup (not shown) are sequentially installed. The position corresponding to the upper portion of the main chassis 1 is provided with a configuration such as a PCB required for the disk drive.

The main chassis 1 is provided with a case 3 for forming the appearance of the disk drive. The case 3 protects the components necessary for the operation of the main base, the optical pickup base and the disk drive.

An inlet and outlet 5 is formed at the tip of the case 3. The inside of the entrance and exit port 5 is provided with a configuration for the entry and exit of the disk (D). When the disk D is inserted through the inlet and outlet 5, the optical pickup irradiates light onto the signal recording surface of the disk D to record a signal or to read the recorded signal.

However, the disk drive according to the prior art as described above has the following problems.

First of all, in the prior art, due to the characteristics of the slot-in type disc drive, a rigid structure cannot be applied to the disc transfer section. Therefore, when a deformation caused by an external force occurs in the disc transfer section, interference between the disc and the operating disc may occur. there was. In particular, unlike the tray type, the slot-in type disc drive does not have a separate configuration for supporting the inlet and outlet of the disc, so that the peripheral portion of the inlet and outlet is more susceptible to deformation by external force than the side or rear end of the disc drive.

In addition, in the related art, since a disc inserted in a disc drive cannot be recognized, there is a problem that a physical collision may occur between discs because there is no device blocking the user when a user inserts another disc.

The present invention is to solve the problems of the prior art as described above, it is an object of the present invention to provide a disk drive capable of stably securing the transfer section of the disk therein to prevent interference between the disk and components.

Another object of the present invention is to provide a disk drive which can block the insertion of an additional disk when the disk is inserted.

According to a feature of the present invention for achieving the above object, the present invention comprises a case that is formed in the entrance and exit port for entering and exiting the disk, the appearance; A main chassis installed in the case and provided with a driving source; An interlock mechanism connected to the drive source to transmit power; It receives the power from the interlock mechanism rotatably installed in a direction perpendicular to the entry and exit direction of the disk, and includes a support lever for selectively shielding a part of the entrance and exit and support the case at the same time depending on whether the disc is in and out It is configured by.

The interlock mechanism includes a driving lever that receives power from the driving source and is moved in parallel with an entry and exit direction of the disc, and one end of which is connected to the driving lever so as to rotate in synchronization with the movement of the driving lever, and the other end of which is connected to the support lever. It is configured to include an interlock lever.

One end of the interlocking lever is provided with a guide pin inserted into the guide groove formed in the driving lever, and the other end of the interlocking lever is provided with an interlocking pin that is moved in a direction opposite to the moving direction of the guide pin.

The guide groove extends to one side closer to the entrance and exit.

The support lever is formed with a link hole through which the interlocking pin is inserted.

The link hole may include a support release part formed parallel to the longitudinal direction of the support lever, a connection part connected to the support release part at an inclined upward angle at a predetermined angle, and connected to the connection part in parallel with the support release part. It comprises a support for allowing the support lever to support the case when the interlocking pin is located.

The other end of the interlocking lever opposite to the link hole is formed to protrude a support end for selectively shielding a part of the entrance and exit and supporting the bottom of the case.

First, according to the present invention, by supporting the inlet and outlet of the disk without a separate support structure by using the support lever in the characteristics of the slot-in type disk drive, it is possible to prevent the deformation of the disk drive, and to secure the transport section of the disk stably. There is.

In addition, in the present invention, since the support lever blocks the inlet and outlet of the disk after insertion of the disk to prevent the insertion of additional disks, there is an effect of preventing data loss due to physical collisions between the disks.

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

FIG. 2 is a plan view showing the configuration of a preferred embodiment of the disk drive according to the present invention, and FIG. 3 is a plan view showing the main components of the disk drive constituting the embodiment of the present invention.

As shown in these figures, the entire skeleton of the disc drive is formed by the main chassis 30. The main chassis 30 is provided with a boundary portion 30 ′ parallel to the entry and exit direction of the disk D. Inside the boundary portion 30 ′, a configuration for transmitting a driving force transmitted from the driving motor 41 to be described below to the pivoting arm 97 to be described below is provided.

On one side of the main chassis 30, the optical pickup base 31 is installed obliquely. The optical pickup base 31 is installed so that its tip is lifted with respect to the main chassis 30.

A spindle motor 33 for rotating the disk D is installed at a position adjacent to the tip of the optical pickup base 31. The rotary shaft of the spindle motor 33 is provided with a turntable 35 on which the disk D is seated and rotated by the spindle motor 33.

The optical pickup base 31 is formed with an optical pickup window 36 having a predetermined width and length. At a position corresponding to both ends of the optical pickup window 36, the guide shaft (not shown) is installed in the longitudinal direction in parallel. The optical pickup 37 is installed on the guide shaft to perform a linear reciprocating motion on the optical pickup window 36. The optical pickup 37 is a portion for recording a signal by reading light onto the signal recording surface of the disk D or reading the recorded signal.

A lifting guide pin 39 for guiding the lifting of the optical pick-up base 31 is provided at the tip of the optical pick-up base 31. The elevating guide pin 39 elevates the optical pickup base 31 in association with the rotation of the elevating guide 45 to be described below.

As illustrated in FIGS. 6A and 6B, a case 40 constituting an external appearance of the disc drive is provided at an upper portion of the main chassis 30. The case 40 shields an internal space in which parts are installed in the main chassis 30. The case 40 constitutes an upper appearance or an overall appearance of the disk drive, which may vary depending on design conditions. The case 40 is fastened to the main chassis 30 by a conventional method in the art, so a detailed description thereof will be omitted. An inlet and outlet 40 ′ is formed at the front end of the case 40. The entry and exit port 40 'is a space in which the disk D is input and exited.

4A and 4B, a driving motor 41 is installed at one side of the main chassis 30. The drive motor 41 is provided with a drive shaft 41 ′ and transmits a driving force to the gear part 43. As shown in FIG. 3, the gear part 43 sequentially rotates the first gear 43a, the second gear 43b, the third gear 43c, and the fourth gear 43d so as to transmit a driving force. Interlocked.

When the drive shaft 41 rotates, the first gear 43 meshes with the drive shaft 41 to rotate, and the second gear 43b, the third gear 43c, and the fourth gear 43d are in turn. It rotates as it transmits the driving force.

One side of the main chassis 30 is provided with a driving lever 45 to be connected to the fourth gear 43d. The drive lever 45 is formed long in a substantially bar shape. A thread 47 is formed at one side of the driving lever 45 adjacent to the fourth gear 43d. The thread 47 is engaged with the fourth gear 43d to transmit a driving force so that the driving lever 45 can move in the insertion direction of the disk D.

A guide groove 49 is formed in the driving lever 45 by a long recess. The guide groove 49 is formed in the drive lever 47 in parallel to the entry and exit direction of the disk D, and the closer to the entrance and exit 40 'provided with the drive motor 41, the gear portion ( 43) is biased in the direction. That is, the guide groove 49 extends parallel to the entry and exit direction of the disk D, and extends at an end of the main chassis 30 at an obtuse angle away from the boundary portion 30 '.

An interlocking lever 51 is rotatably installed around the hinge 53 at the tip of the driving lever 45. Both ends of the interlocking lever 51 alternately approach the boundary part 30 ′ when the interlocking lever 51 rotates about the hinge 53.

One end of the interlocking lever 51 is provided with a guide pin 55 to be guided by the guide groove 49. The guide pin 55 moves along the guide groove 49 when the driving lever 45 moves in the rear end direction of the main chassis 30. The guide pin 55 moves in a direction away from the boundary portion 30 ', and in conjunction with this, the interlock lever 51 rotates counterclockwise.

The other end of the interlocking lever 51 is provided with an interlocking pin 57. The interlocking pin 57 approaches or moves away from the boundary portion 30 ′ as the interlocking lever 51 rotates. The interlocking pin 57 is inserted into the link hole 63 of the support lever 59 to be described below to guide the rotation of the support lever 59.

5A and 5B, a support lever 59 is installed perpendicularly to the interlocking lever 51 at the other end of the interlocking lever 51 provided with the interlocking pin 57. That is, the support lever 59 is rotatably installed in a direction perpendicular to the entry and exit direction of the disk D. The support lever 59 is positioned at the front end of the main chassis 30 and the case 40 to selectively shield the entrance and exit 40 'and supports the front end of the case 40. One end of the support lever 59 is formed by drilling a link hole (63).

The linking pin 57 is inserted into the link hole 63. As shown in FIG. 5, the link hole 63 is composed of a release support part 63a, a connection part 63b, and a support part 63c from a left side relative to the drawing.

The support release portion 63a is formed parallel to the longitudinal direction (left and right direction relative to the drawing) of the support lever 59. When the interlocking pins 57 are positioned on the support release portion 63a, the support levers 59 are maintained in parallel with the bottom surface of the main chassis 30 so that the interlocking pins 57 are not in contact with the case 40. 40 'is also open. The connecting portion 63b is inclined upwardly at a predetermined angle with respect to the release portion 63a.

The support portion 63c is formed at the end of the connection portion 63b, and is formed parallel to the support release portion 63a. When the interlocking pins 57 are positioned on the support part 63c, the support lever 59 rotates clockwise to protrude to the other end of the support lever 59 so that the support end 65 is raised. . The support end 65 supports the case 40 to prevent deformation of the case due to external force. In addition, the support end 65 serves to block the insertion of the additional disk (D) in advance by shielding a part of the entrance and exit 40 '.

In other words, the support end 65 is positioned on the main chassis 30 outside the inlet and outlet 40 'to prevent interference with the disk D before the disk D is inserted, and the disk D is After insertion, the case 40 is supported while shielding the entrance and exit 40 '.

Referring back to FIG. 2, a lifting gear 73 is provided at the rear end of the driving lever 45. The driving force is transmitted to the lifting gear 73 through components such as the driving motor 41, the gear part 43, and the driving lever 45. In addition, although not shown in detail in this drawing, the driving motor 41 is connected to one end of the pivot arm 97 to be described below by a connecting member to control the rotation of the pivot arm 97.

On one side of the main chassis 30, a lifting guide 75 for lifting the optical pickup base 31 is rotatably installed. The lifting guide 75 rotates in engagement with the lifting gear 73. The lifting guide 75 lowers the tip of the optical pick-up base 31 when the disk D is discharged, thereby preventing interference between the turntable 35 and the disk D, and when the disk D is inserted. The tip of the optical pickup base 31 is raised.

The guide arm 76 is rotatably installed in the main chassis 30. A guide roller 77 is rotatably provided at one end of the guide arm 76. Then, the other end of the guide arm 76 is provided with a spring 78 to provide an elastic force to move in the direction in which the guide roller 77 is in close contact with the disk (D). A guide rail 79 is installed at a position corresponding to the opposite side of the guide roller 47 to the main chassis 30. The guide roller 77 and the guide rail 79 serve to guide the entry and exit of the disk (D).

One side of the main chassis 30, the lever unit 80 is installed to move back and forth. The lever unit 80 guides the entry and exit of the disc D, and serves to prevent forced insertion of the disc D by the user.

The lever unit 80 is provided with a spring 82. The spring 82 acts as a buffer so that the disk D can be smoothly drawn in and out, and prevents the disk D from being forcedly inserted into the disk D.

The eject arm 91 is rotatably installed on the main chassis 30 by the rotation shaft 92. The other end of the eject arm 91 is provided with an interlocking pin 91 ′. The interlocking pin 91 ′ rotates the eject arm 91 while moving along an interlocking cam (not shown) formed on the lever unit 50.

The eject arm 91 is a portion that directly guides the entry and exit of the disc D. FIG. One end of the eject arm 91 is provided with a guide plate 93 on which the disk D is seated when the disk D is input and output. The roller 95 is provided on the upper surface of the guide plate 93. The roller 95 guides the side end of the disk D at the time of entering and exiting the disk D.

On the other hand, the main arm 30, the pivoting arm 97 is installed by the rotation shaft 98 so as to be rotatable. One end of the pivot arm 97 is provided with an interlocking pin 97 'to move on the lever unit 50. In addition, the pivot arm 97 is formed at a height slightly lower than that of the eject arm 91 so that interference with the eject arm 91 does not occur when the eject arm 91 rotates.

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

4A and 4B are plan views showing the operation of the drive lever and the interlock lever in the preferred embodiment of the present invention, and FIGS. 5A and 5B are front views showing the operation of the support lever in the embodiment of the present invention. 6A and 6B are front views showing the operation of the support lever in the disk drive according to the embodiment of the present invention.

First, a process of inserting the disk D into the disk drive will be described.

When the user inserts the disk D into the main chassis 30, the disk D is guided by the guide roller 77 and the guide rail 79. The guide roller 77 is guided in contact with the side end of the disk (D) in accordance with the movement of the disk (D), because it acts in the direction in which the elastic force of the spring 78 is in close contact with the disk (D) to be.

As the disk D is inserted, the eject arm 91 is rotated counterclockwise by the force of the disk D pushing the roller 95. When the eject arm 91 rotates and contacts the switch provided in the main chassis 30, the driving motor 41 is operated.

When the driving motor 41 is operated, a driving force is transmitted to the driving lever 45 through the gear part 43 connected to the driving motor 41. When the driving force is transmitted by engaging the fourth gear 43d of the gear part 43 and the thread 47 of the driving lever 45, the driving lever 45 is moved upward based on FIG. 4.

The pivot arm 97 rotates in a counterclockwise direction in association with the movement of the drive lever 45, and the lever unit 50 moves downward. When half of the disk D inserted by the above operation is inserted, the remaining portion is completely inserted by the elastic force of the spring 78.

When the disk D is inserted, the lifting gear 73 rotates to rotate the lifting guide 75 clockwise. Then, the elevating guide pin 39 is guided by the elevating guide 45 to raise the tip of the optical pick-up base 31, and the disk D and the turntable 35 are chucked.

Before the disc D is inserted, the interlocking pins 57 are positioned on the support release portion 63a, and the support end 65 is positioned on the main chassis 30 to interfere with the entry and exit of the disc D. This does not happen.

However, as described above, when the disk D is inserted, the guide pin 55 is guided by the guide groove 49 when the drive lever 45 moves, and is separated from the boundary part 30 '. At this time, the interlocking lever 51 rotates counterclockwise around the hinge 53, and the interlocking pin 57 is closer to the boundary portion 30 ′ as opposed to the guide pin 55.

In addition, the guide pin 55 is moved from the release portion 63a to the support portion 63c via the connection portion 63b. As the interlocking pin 57 moves to the support part 63c, the support lever 59 rotates clockwise about the rotation shaft 61. At this time, the support end 65 provided at the other end of the support lever 59 supports the case 40.

As the support end 65 supports the lower portion of the case 40, deformation of the case 40 is prevented even when an external force is transmitted. In particular, it is effective to prevent the front end of the main chassis 30 and the case 40, that is, the entry and exit 40 ', which does not have a separate support structure for the entry and exit of the disk (D).

Since the transfer section of the disk D is secured as the deformation of the case 40 is prevented, interference between the case 40 and the disk D does not occur, thereby preventing damage or deformation of the disk D. In addition, since the support end 65 prevents the insertion section of the disk D, that is, the entry and exit of the disk D to prevent the insertion of additional disk (D), it is possible to prevent the physical collision between the disk (D). .

Next, the process of ejecting the disk D from the disk drive will be described.

In the loading state of the disc D, when the eject signal is transmitted to the disc drive, the driving motor 41 operates in the opposite direction as when the disc D is inserted.

When the driving motor 41 is operated, a driving force is transmitted to the driving lever 45 through the gear part 43 connected to the driving motor 41. When the driving force is transmitted by engaging the fourth gear 43d of the gear part 43 and the thread 47 of the driving lever 45, the driving lever 45 moves downward based on FIG. 4.

When the driving lever 45 moves, the guide pin 55 is guided by the guide groove 49 to approach the boundary portion 30 ′. At this time, the interlocking lever 51 rotates clockwise around the hinge 53, and the interlocking pin 57 is moved away from the boundary portion 30 ′ as opposed to the guide pin 55.

The guide pin 55 is moved from the support part 63c to the support release part 63a via the connection part 63b. As the linking pin 57 moves to the support release portion 63a, the support lever 59 rotates counterclockwise about the rotation shaft 61. At this time, the support end 65 provided at the other end of the support lever 59 moves downward to be separated from the case 40. Therefore, no interference occurs with the support end 65 when the disc D is ejected.

As such, when the support end 65 is removed from the discharge path of the disk D, the lifting gear 73 is rotated as opposed to when the disk D is inserted, and the lifting guide 75 is half Rotate clockwise.

The lifting guide pin 39 lowers the tip of the optical pickup base 31 in association with the rotation of the lifting guide 75. Thus, the chucking of the disk D and the turntable 35 is released. Then, as the driving lever 45 descends, the pivot arm 97 rotates clockwise.

The lever unit 50 is moved upward by the rotation of the pivoting arm 97, and the ejector arm 91 rotates clockwise to discharge the disk D in association with the rotational arm 97. As shown in FIG.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

1A and 1B are a front view and a plan view showing the structure of a disk drive according to the prior art;

Figure 2 is a plan view showing the configuration of a preferred embodiment of a disk drive according to the present invention.

3 is a plan view showing the main components of a disk drive in the embodiment of the present invention;

4a and 4b is a plan view showing the operation of the drive lever and the interlock lever in a preferred embodiment of the present invention.

5a and 5b is a front view showing the operation of the support lever in the embodiment of the present invention.

6a and 6b are front views showing the operation of the support lever in the disk drive according to the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

30: main chassis 31: optical pickup base

33: spindle motor 35: turntable

37: optical pickup 41: drive motor

43: gear 45: drive lever

47: thread 49: guide groove

51: interlocking lever 53: hinge

55: guide pin 57: interlock pin

59: support lever 61: rotating shaft

63: link hole 65: support end

75: lifting guide 76: guide arm

77: guide roller 79: guide rail

80: lever unit 91: eject arm

93: guide plate 95: roller

97: stony rock

Claims (7)

A case having an entrance and exit port through which the disc is input and output and constituting an appearance; A main chassis installed in the case and provided with a driving source; An interlock mechanism connected to the drive source to transmit power; It receives the power from the interlock mechanism rotatably installed in a direction perpendicular to the entry and exit direction of the disk, and includes a support lever for selectively shielding a part of the entrance and exit and support the case at the same time depending on whether the disc is in and out Disk drive, characterized in that the configuration. The method of claim 1, wherein the linkage mechanism, A drive lever which receives power from the drive source and moves in parallel with an entry and exit direction of the disc; And one end connected to the driving lever and the other end connected to the support lever so as to rotate in association with the movement of the driving lever. According to claim 2, One end of the interlocking lever is provided with a guide pin is inserted into the guide groove formed in the drive lever, the other end of the interlocking lever interlocking pin to be moved in the opposite direction to the movement direction of the guide pin Disk drive characterized in that it is provided. The disk drive of claim 3, wherein the guide groove extends toward one side as the guide groove is closer to the inlet and outlet. The disk drive according to claim 3 or 4, wherein the support lever is formed with a link hole through which the interlocking pin is inserted. The method of claim 5, wherein the link hole, A support release part formed parallel to the longitudinal direction of the support lever; A connection part connected to the support release part to be inclined upward at a predetermined angle; And a support part connected to the connection part in parallel with the support release part so that the support lever supports the case when the interlocking pin is positioned. 7. The disk drive according to claim 6, wherein the other end of the interlocking lever opposite to the link hole is formed to protrude a support end for selectively shielding a part of the entrance and exit and supporting the bottom of the case.

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