JP2002050100A - Disk aligning structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a disk aligning structure with which the aligning of a disk placed on a turntable can be reliably performed and the height size of the turntable can be restricted to enable miniaturization and thickness reduction, and which can be used for a disk driving device (motor) without the height space from a disk surface to its upper end. SOLUTION: The disk aligning structure aligns the disk D placed on the turntable 2 rotating together with a shaft 1. The turntable 2 is provided with an aligning pawl part 3 which deforms elastically within a radial plane orthogonal to an axial center L to reduce or enlarge its diameter.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disk alignment structure, and more particularly, to a CD-ROM drive and a DVD-RO.
The present invention relates to a disk alignment structure used for a disk drive such as an M drive, which has no height space from a disk surface to an upper end.

[0002]

2. Description of the Related Art Generally, CD-ROM and DVD-ROM
In a disk drive device that reads and writes information by accessing an information recording medium (hereinafter, referred to as a disk) such as a disk, it is necessary to maintain a high positional relationship between the disk and a pickup that reads and writes information. In addition, if a displacement occurs between the rotating disk and the pickup, it becomes difficult to read and write information, and for example, reproduced music or video is deteriorated.

[0003] Since the disk is generally formed of a synthetic resin, the inner diameter of the center hole of the disk to be mounted on the turntable of the driving device is likely to vary, and depending on the inner diameter of the disk, the disk may not be mounted on the turntable. If the disc is not mounted concentrically, a displacement occurs between the rotating disc and the pickup.

Therefore, conventionally, a disk drive device is provided with a disk alignment structure, and a disk mounted on a turntable is aligned (centered) and arranged at a correct position.
The displacement between the rotating disk and the pickup is suppressed.

More specifically, as shown in FIG. 8, a disk drive 40 comprises a motor section 41 comprising a rotor 41a and a stator substrate 41b, and a turntable 42 on which a disk D is mounted.
And a clamp body 43 for pressing the disk D on the turntable 42. The motor unit 41 is attached to a body frame (not shown) of the disk drive device 40 via a stator substrate 41b, 42 is the rotor 41a
The clamp body 43 is attached to the motor unit 41 via a shaft 44 fixed to the turntable 42, and is attracted to the turntable 42 via a clamp magnet 45 provided on the turntable 42.

In the conventional disk alignment structure, a turntable 42 fixed orthogonally to a shaft 44 is provided with an annular alignment portion 46 in a plan view. The centering pawls 47 are provided. The centering pawls 47 can be swung toward the shaft 44 by elastic deformation, and can be pressed against the inner peripheral edge 48 of the center hole of the disk D. As described above, when the disk D is mounted on the turntable 42, even if there is a slight variation in the inner diameter of the center hole of the disk D, the variation is absorbed by the swing of the centering claw 47, and D is aligned and is securely mounted on the turntable 42.

[0007]

However, the centering claw portion 47 of the conventional disk centering structure is arranged upright in the direction of the axis L (vertical direction), and the upper end thereof is the outer periphery of the centering portion 46. In an axial plane fixed to the upper end and including the axis L,
Since it is configured to be capable of reducing and expanding the diameter, it is necessary to secure the length of the alignment claw portion 47 in order to reliably swing the alignment claw portion 47 using elastic deformation. there were. That is,
It was necessary to lengthen the centering claw portion 47 and increase the height dimension of the centering portion 46.

[0010] As shown in FIG.
In a state of being elastically urged (shown by a solid line) from a free state (shown by a virtual line), the centering claw portion 47 has a displacement ΔA in the axial direction and a displacement ΔR in the radial direction.
Has to be secured in the axial direction.
That is, it is necessary to increase the height dimension of the alignment part 46.
Here, in order to reduce the displacement ΔA in the axial direction, it is necessary to reduce the height of the alignment claw portion 47 and raise the angle, that is, to increase the inclination angle in the circumferential direction. When the inclination angle of the centering claw portion 47 becomes large as described above, it is necessary to apply a large force in the axial direction when mounting the disk D, and the mounting operation of the disk D becomes difficult, and the disk D is not There is a possibility that a floating state may occur, or alignment accuracy may be degraded, resulting in a clamping error.

Therefore, since it is necessary to increase the height H from the upper surface of the disk D mounted on the turntable 42 to the upper end of the turntable 42, a disk drive such as a CD-ROM drive or a DVD-ROM drive is required. It cannot be used for a disk drive (motor) having no height space from the surface to the upper end.

Therefore, the present invention requires that the length of the alignment pawl be long and gently angled in order to improve the alignment accuracy and facilitate the smooth mounting of the disc. Focusing on the space, the disc mounted on the turntable can be reliably aligned, and the height of the turntable can be reduced to make it smaller and thinner. It is an object of the present invention to provide a disk alignment structure that can be used in a disk drive (motor) having no space.

[0011]

In order to achieve the above-mentioned object, a disk alignment structure according to the present invention provides a disk alignment structure for aligning a disk mounted on a turntable rotating integrally with a shaft. In the core structure, the turntable is provided with a core adjusting claw portion that can be elastically deformed in a radial plane orthogonal to the axis to reduce and increase the diameter.

With this configuration, it is possible to surely align the disc mounted on the turntable. In addition, since there is almost no displacement of the alignment claw portion in the axial direction (axial direction), the height of the turntable can be suppressed to make the turntable smaller and thinner, such as a CD-ROM drive or a DVD-ROM drive. Disk drive (motor) with no height space from the disk surface to the top
For a wide range of applications.

[0013] A disk alignment structure according to the present invention is a disk alignment structure for aligning a disk placed on a turntable that rotates integrally with a shaft. Wherein the centering portion has a plurality of centering claws extending in the circumferential direction in an arc shape in plan view, and the centering claw portion is a cantilever in a radial plane orthogonal to the axis. It can be reduced in diameter and expanded in diameter by elastic deformation.

With such a configuration, it is possible to reliably align the disc mounted on the turntable. Also, since there is almost no displacement of the alignment claw portion in the axial direction (axial direction), the height dimension of the turntable is suppressed to enable miniaturization and thinning, and a CD-ROM drive, DVD-ROM drive, etc. Disk drive (motor) with no height space from the disk surface to the top
For a wide range of applications.

In the disk alignment structure according to the present invention, the alignment claw portion is made of resin. Therefore,
The centering claw itself can also be elastically deformed, so that the centering of the disc can be performed more reliably.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail with reference to the drawings showing embodiments.

FIG. 1 is a partially sectional side view showing an embodiment of a disk centering structure of the present invention, FIG. 2 is a plan view, and the structure rotates integrally with a shaft 1. And a centering claw capable of reducing and expanding the diameter by elastically deforming the turntable 2 only in a radial plane perpendicular to the axis L. A part 3 is provided.

The disc D is a CD-ROM or DV.
It is an information recording medium such as a D-ROM, and “to align the disk D mounted on the turntable 2” means that the center of the disk D substantially matches (or matches) the axis L of the shaft 1. This means that the disk D is held on the turntable 2.

This structure is used in a disk drive (motor) 20 for accessing a disk D and reading / writing information by a pickup (not shown). More specifically, the disk drive device 20 includes a motor unit 21 including a rotor 21a and a stator substrate 21b, a turntable 2 on which the disk D is mounted, and a clamp body that presses the disk D on the turntable 2. The motor unit 21 is attached to a main body frame (not shown) of the disk drive device 20 via a stator substrate 21b, and the turntable 2 is fixed to the rotor 21a (around the axis L). The clamp body 22 is attached to the motor unit 21 via the shaft 1 (which rotates), and the clamp body 22 is attracted to the turntable 2 via the clamp magnet 23 provided on the turntable 2.

The turntable 2 includes a support portion 4 on which the disk D is mounted, an alignment portion 5 on which the disk D is aligned,
The support portion 4 includes a cylindrical portion 4a fixed to the shaft 1 so as to be fitted externally, and a lower surface of the disk D fixed to an outer flange at the lower end of the cylindrical portion 4a via an annular non-slip member 6. And an annular flange portion 4b mounted thereon. Note that the upper end of the shaft 1 does not protrude from the upper end of the cylindrical portion 4a.

The centering portion 5 has an inner periphery formed by the cylindrical portion 4 of the support portion 4.
a and is fixed on the flange portion 4b of the support portion 4 in a mounted state. In addition, a circular concave portion 7 centering on the axis L is provided on the upper surface of the centering portion 5, and an annular clamp magnet 23 is fitted in the concave portion 7.

In short, the turntable 2 (the support portion 4 and the centering portion 5) and the clamp magnet 23 rotate around the axis L together with the shaft 1.

The centering portion 5 has a plurality of centering claws 3 extending circumferentially in an arc shape in plan view.
Are elastically deformed into a cantilever shape in a radial plane perpendicular to the axis L, so that the diameter can be reduced and increased.

More specifically, the perspective view of FIG.
As shown in the plan view, the centering portion 5 is configured such that a flat plate-shaped centering claw portion 3 and a protrusion 10 having an arc shape in a plan view are alternately arranged along an outer peripheral edge 9 around the axis L. , A plurality (three in this embodiment).

One end of the centering claw 3 is fixed to the outer peripheral edge 9 via a connecting piece 11, and a plurality (three) of centering claw portions 3... In this embodiment,
(120 °) at equal intervals.

The centering claw portion 3 is disposed so as to be gradually (further) away from the outer peripheral edge 9 along the other end, and the outer circumferential edge on the other end side of the centering claw portion 3. Is the axis L
Is inscribed in a first virtual circle C ₁ centered at. The radius r ₁ of the first virtual circle C ₁ is set to be larger than the radius of the center hole of the disk D.

The centering claw portion 3 arranged in a cantilever manner as described above is elastically deformed by the connecting piece 11 (and the centering claw portion 3).
The other end side (tip side) of the centering claw portion 3 swings to form an outer peripheral edge 9.
Can be approached (or contact). In short, the alignment claw 3
However, it can be elastically deformed into a cantilever shape in a radial plane perpendicular to the axis L and can be reduced in diameter and expanded. In other words,
The bending direction of the alignment claw portion 3 was provided in the radial direction (radial direction) of the alignment portion 5. Further, it is desirable that the alignment nail 3 is made of a resin, and the alignment nail 3 itself is surely elastically deformed, so that the alignment nail 3 can more reliably approach the outer peripheral edge 9.

The projection 10 has its inner peripheral edge fixed to the outer peripheral edge 9. A plurality (three) of the projections 10 have a predetermined center angle (about 120 in the present embodiment). °), they are arranged at equal intervals. In addition, the outer peripheral edge of the projections 10 is aligned with the axis L.
And is configured such that the second inscribed in the imaginary circle C ₂ centered at. The radius r ₂ of the second virtual circle C ₂ is set smaller than the radius of the center hole of the disk D.

Next, a method of fitting the disk D into the centering unit 5 configured as described above will be described. That is, disk D
When the disk D is brought closer to the turntable 2 (from above) with the center of the circle substantially coincident with the axis L, the first virtual circle C
_First radius r ₁ is because it is set larger than the radius of the center hole of the disk D, as shown in FIG. 5 (A), the inner peripheral edge 8 of the disk D, adjusting Shintsume portion 3 (on the distal end side ) Abuts on the upper corner 12. Since the upper end corner 12 is formed so as to be inclined so that the lower side expands in diameter, when the disk D is further pushed downward, as shown in FIG. While sliding on the upper end corner 12, the centering claw 3 (the distal end side) is moved radially inward (the outer peripheral edge 9).
5), the diameter is reduced (bent) in a pressing manner toward FIG.
As shown in (C), the lower surface of the disk D is
, And the disc D is fitted into the alignment part 5.

Then, in a state where the disk D is fitted into the centering portion 5, as shown in FIG. 6, the inner peripheral edge 8 of the disk D is brought into contact with (the distal end side of) the centering claw portion 3 whose diameter is reduced. It is pressed radially outward by the elasticity of the centering claw 3 (and the connecting piece 11). That is, the disk D is aligned with the alignment pawls 3. Further, since the centering claw portion 3 (and the connecting piece 11) is elastically urged, the disc D is securely mounted and held.

Therefore, even if there is a slight variation in the inner diameter of the center hole of the disk D, the variation does not occur.
.. Are absorbed by swinging (deflecting), and the disc D is aligned and is securely mounted on the turntable 2.

As shown in FIG. 7, the centering claw 3 is
In the state of being elastically urged (shown by the solid line) from the free state (shown by the phantom line), there is only the displacement ΔR in the radial direction, and there is no displacement ΔA in the axial direction (the direction of the axis L). A space for securing the axial displacement ΔA of the core claw portion 3 is not required, and the height dimension H from the upper surface of the disk D to the upper end of the turntable 2 can be set small as shown in FIG. Yes, this structure is CD-
It can be used for a disk drive (motor) such as a ROM drive or a DVD-ROM drive, which has no height space from the disk surface to the upper end.

When the disk D is removed from the centering portion 5, the disk D is moved against the resilient force of the centering claws 3.
It can be removed by pulling it away from the turntable 2. Then, as shown in FIG. 5A, the centering claw portion 3 is again in a free state in which the diameter is expanded.

The present invention is not limited to the above-described embodiment. The number of the alignment pawls 3 may be four or more so that the disk D is securely mounted on the turntable 2. By using an elastic body such as a spring or the like, the diameter of the centering claw portion 3 may be reduced or increased only in the radial plane. Further, the shape of the centering claw portion 3 may be the same as that of the present invention. The design can be changed without departing from the scope.

[0035]

According to the present invention, the centering claw portion is elastically deformed on a radial plane perpendicular to the axis so that the diameter can be reduced and expanded, so that the centering can be performed even if there is no space in the axis direction. By increasing the length of the claw part and taking a gentle angle, it can be bent easily, making it easier to mount the disc and ensuring stable alignment accuracy. It is possible to reliably align the disc mounted on the disc. In addition, the height dimension of the turntable is suppressed to enable miniaturization and thinning. In particular, a disk drive device such as a CD-ROM drive or a DVD-ROM drive having no height space from the disk surface to the upper end ( Motor).

[Brief description of the drawings]

FIG. 1 is a partially sectional side view showing an embodiment of the present invention.

FIG. 2 is a plan view of the present invention.

FIG. 3 is a perspective view of a centering unit.

FIG. 4 is a plan view of the alignment part.

FIG. 5 is an explanatory diagram of an operation of mounting a disk.

FIG. 6 is a plan view showing a mounted state of a disk.

FIG. 7 is an operation explanatory view of the centering claw portion.

FIG. 8 is a partial cross-sectional side view showing a conventional example.

FIG. 9 is an operation explanatory view of a conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Shaft 2 Turntable 3 Alignment claw part 5 Alignment part D Disc L Axis

Claims (3)

[Claims] 1. A disk alignment structure for aligning a disk placed on a turntable that rotates integrally with a shaft, wherein the turntable is elastically deformed in a radial plane orthogonal to the axis and contracted. A disc centering structure comprising a centering claw portion capable of increasing the diameter and diameter. 2. A disk alignment structure for aligning a disk mounted on a turntable that rotates integrally with a shaft, wherein the turntable has an alignment portion, and the alignment portion is viewed in a plan view. It has a plurality of centering claws extending in the circumferential direction in an arc shape, and the centering claw is elastically deformed into a cantilever shape in a radial plane orthogonal to the axis to reduce and expand the diameter. A disk alignment structure characterized in that it can be used. 3. The disk alignment structure according to claim 1, wherein the alignment claw portion is made of a resin.