KR20230148025A - Optical disc drive - Google Patents

Abstract

The present specification relates to an optical disk drive. The optical disk drive according to one embodiment includes: a chassis and a top cover which form the body of the optical disk drive; and a tray containing an optical disk which can be pulled out/into the body in a sliding manner. A fan-shaped depression may be formed in the top cover. When the tray is inserted, the depression may be formed in a predetermined radius range from the center position corresponding to the rotation axis of the spindle motor mounted on the tray and a predetermined circumferential angle range centered on the circumferential angle connecting the central position and the objective lens of the optical pickup mounted on the tray.

Description

Optical disc drive

This specification relates to an optical disk drive, and more specifically, to a slim optical disk drive with a structure that prevents the disk from lifting.

An optical disk drive is a device that records data on standard optical disks such as CD, DVD, and BD, or reads and reproduces data from the optical disk.

There are two types of optical disk drives: one in which the tray containing the optical disk is slideably coupled to the body, and the turntable and pickup are installed inside the body, and the other in which the tray is slideably coupled to the body, and the turntable and pickup are installed in the tray. The former is It is used for desktop computers, and the latter is used for laptop computers because it is thin.

Recently, as laptop computers become thinner, external optical disk drives are becoming more popular than internal optical disk drives. An external optical disk drive can be connected to a computer, TV, or various AV devices through a USB (Universal Serial Bus) interface to exchange data, allowing one external optical disk drive to be used as a peripheral device in multiple computers or AV devices. There is an advantage to being able to do this.

For portability, external optical disk drives are mainly released in a slim form in which the tray on which the turntable and pickup are installed slides into the body.

As the recording and playback speed of a slim optical disk drive increases, the rotation speed of the optical disk also increases, and when the optical disk rotates at a high speed, the optical disk tends to float upward.

When an optical disk rotating at high speed rises upward, the objective lens of the optical pickup for reading or recording data recorded on the optical disk must also rise upward to maintain the distance to the optical disk. However, the movable range of the actuator that drives the objective lens is limited, so if the degree of injury to the optical disk is large, data recording and reproduction performance may deteriorate.

This specification takes this situation into consideration, and the purpose of this specification is to provide a slim optical disc drive that prevents an optical disc rotating at high speed from floating upward.

An optical disk drive according to an embodiment of the present specification for realizing the above-described problem includes a chassis and a top cover that form the body of the optical disk drive; and a tray that holds the optical disk and can be pulled out/into the body in a sliding manner, and is characterized in that a fan-shaped depression is formed in the top cover.

Therefore, it is possible to suppress the phenomenon in which an optical disk rotating at high speed rises and moves away from the optical pickup.

In addition, it is possible to prevent an optical disk rotating at high speed from floating, thereby preventing deterioration of data recording and reading performance for the optical disk.

Figure 1 shows an exploded perspective view of a conventional slim optical disk drive.
Figure 2 shows an exploded perspective view of an optical disk drive according to an embodiment of this specification;
Figure 3 compares the position of the depression formed in the top cover of the optical disk drive according to the embodiment of this specification with the position of the optical pickup operating in the tray;
Figure 4 shows a cross-section of a depression formed in the top cover of an optical disk drive according to an embodiment of this specification.

The above-described objects, features and advantages of the present invention will become more apparent through the following detailed description in conjunction with the accompanying drawings. However, since the present invention can make various changes and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail below. The same reference numerals refer to essentially the same elements throughout the specification. Additionally, if it is determined that a detailed description of a known function or configuration related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. In addition, numbers (e.g., first, second, etc.) used in the description of this specification are merely identification symbols to distinguish one component from another component.

Hereinafter, the optical disk drive of this specification will be described in more detail with reference to the drawings. The suffixes “module” and “part” for the components used in the following description are given or used interchangeably only for the ease of preparing the specification, and do not have distinct meanings or roles in themselves.

Figure 1 shows an exploded perspective view of a conventional slim optical disk drive. It is a tray-type slim optical disk drive in which a tray on which a turntable and a pickup are installed slides into the main body.

The optical disk drive 1 consists of a main chassis 10 and a top cover 30, and the tray 50 on which the optical disk is mounted is installed to slide on the main chassis 10. ) and the top cover 30 may be inserted into the space (body) formed and pulled out of the body.

The tray 50 includes a spindle motor 51 for rotating the mounted optical disk, an optical pickup 52 for recording data on or reading data from the optical disk by shining a laser beam on the optical disk, and an optical pickup ( A lead screw 54 for transporting 52) in the radial direction of the optical disk, a step motor 53 for rotating the lead screw 54, a main shaft 55 for guiding the transport of the optical pickup 52, and It may include a guide feeder 57 that engages the pick-up transfer unit including the sub-shaft 56 and the lead screw 54 and transmits the rotational force of the step motor 53 as a straight force to the optical pickup 52. The guide feeder 57 can be considered a part belonging to the optical pickup 52.

On the back of the tray 50, there is a device for locking the tray 50 to the main chassis 10 while it is inserted into the body of the optical disk device 1 or unlocking the locking state to extract the tray 50 from the body. A locking module (not shown) may be installed.

A door (not shown) may be installed on the front of the tray 50 to seal the optical disk drive 1 when the tray 50 is inserted into the body.

In the slim optical disk drive, the optical disk rotates with the rotation axis of the spindle motor 51 with its central hole inserted into the center cone of the spindle motor 51 and placed on the turntable of the spindle motor 51.

In the half-inch type optical disk drive built into the body of a desktop computer, when the tray with the optical disk on it enters the inside of the drive, the feeding assembly including the optical pickup, spindle motor, and pickup transfer unit rises. The optical disk is placed on the turntable of the spindle motor, and the feeding assembly is further raised so that the upper surface of the optical disk touches the fixing member provided on the lower surface of the top cover, so that the optical disk is fixed to the spindle motor.

In this way, in the half-inch type optical disk drive, the optical disk is firmly fixed to the turntable of the spindle motor and the fixing member of the top cover, so even if the optical disk rotates at high speed compared to a slim optical disk drive, surface vibration of the optical disk occurs less. And, the damage to the optical disk may be relatively minor.

On the other hand, in a slim optical disk drive, the optical disk is fixed to the rotation axis of the spindle motor 51 only by the coupling force between the central hole of the optical disk and the center cone of the spindle motor 51, so that the half-inch type optical disk when rotating The plane vibration of an optical disk is bound to be greater than that of a drive, and when an optical disk rotates at high speed, it may float upward.

An optical disk drive according to an embodiment of this specification is a slim optical disk drive. In order to prevent the optical disk from floating upward when it rotates at high speed, a depression is provided in the top cover and a space between the optical disk and the top cover is provided. By reducing the gap, the pressure above the optical disk can be increased.

The depression may be formed in a position corresponding to the data area of the optical disk. It may be formed in the entire circumferential direction, or may be formed only in a position corresponding to the area where the optical pickup 52 moves inward and outward based on the circumferential direction. You may.

Figure 2 shows an exploded perspective view of an optical disk drive according to an embodiment of this specification.

The optical disk drive in FIG. 2 is substantially the same as the optical disk drive in FIG. 1, except that a recess 31 is formed in the top cover 30.

A depression 31 is formed in a portion of the top cover 30 in a downward direction from the upper surface of the top cover 30. As shown in FIG. 2, the depression may be formed in a fan shape. From the central position corresponding to the spindle motor 51, a fan-shaped depression 31 is formed between the first radius and the second radius in the radial direction and at a predetermined angle in the circumferential direction.

Figure 3 compares the position of the depression formed in the top cover of the optical disk drive according to an embodiment of this specification with the position of the optical pickup operating in the tray, and Figure 4 shows the position of the optical disk drive according to the embodiment of this specification. This shows a cross-section of the depression formed in the top cover.

As the optical disk rotates, plane vibration occurs according to the vibration mode of the circular thin plate corresponding to the shape of the disk. There are rising and falling positions in the radial direction, and rising and falling positions in the circumferential direction. there is.

Therefore, rather than forming the depression 31 to prevent the optical disk from floating upward at all positions corresponding to the data area of the optical disk, it is advantageous to form it near the operating range of the optical pickup 52. You can.

In a slim optical disk drive, the optical pickup 52 mounted on the tray 30 must access the data area of the optical disk, and is moved to the inner and outer periphery of the optical disk by the pickup transfer unit.

Accordingly, the recessed portion 31 is positioned in the top cover 30 from the central position of the rotation axis of the spindle motor 51 when the tray 50 is inserted into the optical disk drive 1, in the radial direction. The pickup 52 is formed in a range that moves by the pickup transfer unit, that is, a range corresponding to the data area of the optical disk, and in the circumferential direction, in a predetermined angle range centered on the circumferential angle at which the objective lens of the optical pickup 52 is located. It can be formed into a fan-shaped shape.

As shown in FIG. 4, the recessed portion 31 is formed by drilling a hole corresponding to the planar shape of the recessed portion 31 in the top cover 30 and forming a plate of a predetermined thickness corresponding to the planar shape of the recessed portion 31. It can be formed by attaching it to the lower surface of the top cover 30.

Alternatively, the top cover 30 may be pressed to fit the planar shape of the depression 31 to form a step of a predetermined thickness.

As shown in FIG. 4, the central position of the depression 31 may correspond to the position of the objective lens of the optical pickup 52.

As shown in FIG. 4, since the depression 31 is formed at a position corresponding to the objective lens of the optical pickup 52, the gap between the optical disk and the top cover 30 at the objective lens position is narrowed, thereby removing the air above the optical disk. Since the pressure can be relatively increased, it is possible to suppress the optical disk from floating upward.

Accordingly, even if plane vibration occurs in the optical disk due to high-speed rotation, the width of the vibration can be reduced to within the movable range of the objective lens near the objective lens, which causes the optical pickup 52 to be unable to access the optical disk due to plane vibration. can be reduced.

The optical disk drive described in this specification can be described as follows.

An optical disk drive according to an embodiment includes a chassis and a top cover that form the body of the optical disk drive; and a tray that holds the optical disk and can be pulled out/into the body in a sliding manner, and a fan-shaped depression may be formed in the top cover.

In one embodiment, the depression has a circumferential angle between the central position and the objective lens of the optical pickup mounted on the tray and a predetermined radial range from the central position corresponding to the rotation axis of the spindle motor mounted on the tray when the tray is inserted. It can be formed in a predetermined circumferential angle range as the center.

In one embodiment, the predetermined radius range may correspond to a data area of the optical disk.

In one embodiment, the depression may be formed as a step of a predetermined thickness in the downward direction of the top cover.

In one embodiment, the depression may be formed by pressing the top cover.

The present invention is not limited to the described embodiments, and it is obvious to those skilled in the art that various modifications and changes can be made without departing from the spirit and scope of the present invention. Accordingly, such modifications or variations should be considered to fall within the scope of the claims of the present invention.

1: Optical disk drive 10: Main chassis
30: Top cover 31: Recessed portion
50: Tray 51: Spindle motor
52: Optical pickup 53: Step motor
54: lead screw 55: main shaft
56: subshaft 57: guide feeder

Claims (5)

A chassis and top cover forming the body of an optical disk drive; and
It includes a tray that holds an optical disk and can be pulled out/into the body in a sliding manner,
An optical disk drive, wherein a fan-shaped depression is formed in the top cover. According to claim 1,
When the tray is inserted, the depression has a predetermined radius range from the central position corresponding to the rotation axis of the spindle motor mounted on the tray and a circumferential angle connecting the central position and the objective lens of the optical pickup mounted on the tray. An optical disk drive characterized in that it is formed in a predetermined circumferential angle range as the center. According to clause 2,
The optical disk drive, wherein the predetermined radius range corresponds to a data area of the optical disk. According to claim 1,
The optical disk drive, wherein the depression is formed downward of the top cover by a step of a predetermined thickness. According to clause 4,
An optical disk drive, wherein the depression is formed by pressing the top cover.

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