KR101101534B1 - Disc Chucking Device - Google Patents

Abstract

There is provided a thin disk chucking device for fixing a (optical) disk.
The thin disk chucking device includes: a device housing which is supported on a disk while being installed on a motor mechanism and includes a chucking member insert; And a disk chucking member elastically received to enable disk chucking to the chucking member insertion portion of the device housing, wherein the device housing constitutes an outer wall forming the chucking member insertion portion and is thin in shape. It further comprises a gradient thin forming surface and a gradient inner surface corresponding to the thin forming surface, the disk chucking member further comprises a corresponding surface corresponding to the thin forming surface and the inner surface. do.
According to the present invention, it is possible to reduce the size of the product by realizing the device thin through the thinning of the device housing, and to maintain the strength of the chucking drive in spite of the thinning.

Description

Thin Disk Chucking Device {Disc Chucking Device}

The present invention relates to a disk chucking device of a (optical) disk drive, and more particularly, to realize device compactness through thinning of the device housing, which enables the miniaturization of the product, and in spite of the thinning, the chucking member, in particular, the driving support part. Strength retention relates to a thin disk chucking device that is made possible.

Generally, a spindle motor installed in an optical disk drive functions to rotate a disk so that the optical pickup unit can read data written to the disk.

Such optical disk drivers are required to be light and thin, and in particular, in the case of ultra-thin slim motors used in notebook PCs, the magnetic circuit for driving the motors is also reduced.

Here, the ultra-thin slim motor must generate sufficient torque to rotate the optical disk and at the same time the rotation of the disk must be stable.

Accordingly, the disk is fixed by a chucking device (assembly) as a means for stably seating the disk.

On the other hand, as described above, as the product is required to be thinner and slimmer, the optical disk drive is also required to be thinner. In the related art, the device housing of the disk chucking device, in particular, the chucking device, can be simply implemented through structural improvement. No technology has been proposed.

In particular, when the thinning of the disk chucking device is implemented, the height of the components of the disk chucking member is lowered, and in this case, the strength of the chucking member may be weak, and thus, the disk may not be firmly fixed.

Therefore, since the chucking instability of the disk leads to a problem that the data stored in the disk cannot be read normally, a technique for maintaining the strength of the component, in particular, the disk chucking member, while reducing the thickness of the disk chucking device is required. come.

Accordingly, the applicant of the present invention has proposed an invention in which the strength of the chucking member can be maintained while reducing the thickness of the disk chucking device.

The present invention has been proposed in order to solve the conventional problems as described above, the object of the aspect is to implement a device thin through the thinning of the device housing to enable the miniaturization of the product, despite the thinning it is possible to maintain the strength of the chucking drive unit To provide a thin disk chucking device.

As a technical aspect for achieving the above object, the present invention, the disk is supported while being installed on the motor mechanism, the device housing including a chucking member insert; And,

A disk chucking member elastically received to enable disk chucking to the chucking member insertion portion of the device housing;

Consists of including

The device housing further comprises a gradient thin forming surface that forms an outer wall forming the chucking member inserting portion and is provided to enable device thinness, and a gradient inner surface corresponding to the thin forming surface, wherein the disk chucking member includes: It provides a thin disk chucking device further comprising a thin forming surface and a corresponding surface corresponding to the inner surface.

Preferably, the device housing is installed on the rotor case of the motor mechanism, and includes a horizontal surface and a disk support surface, wherein the thin formed surface is provided as a gradient surface integrally formed between the horizontal surface and the disk support surface. .

More preferably, the chucking member includes a disk contact portion and a driving support portion provided at both sides thereof, and the corresponding surface is provided as a chamfered surface formed in the driving support portion at a position corresponding to the thin formed surface of the device housing. Will be.

More preferably, the gradient surface angle Θ1 of the thin formed surface provided in the device housing is larger than the chamfer angle Θ2 of the corresponding surface provided in the drive support.

According to such a thin disk chucking device of the present invention, it is possible to provide a thin disk chucking device that realizes device thinning through a simple structure improvement of the device housing and ultimately enables product thinning.

In particular, the present invention implements a thin device to enable the miniaturization of the product, while maintaining the strength of the chucking member, in particular the driving support, despite the thinning of the device.

1 is a schematic cross-sectional view showing a motor mechanism including the chucking device of the present invention,
2 is a perspective view showing a thin disk chucking device according to the present invention,
3 is a perspective view illustrating main parts of a device housing of the present invention chucking device of FIG. 2;
Figure 4 is a plan view showing the present invention thin disk chucking device of Figure 2,
5 is a bottom view of FIG. 4,
Fig. 6 is a structural diagram showing in detail the thin formed surface of the device housing of the device of the present invention and the corresponding surface of the driving support;
7A and 7B are structural diagrams showing angles of the thin formed surface and the driving support of FIG. 6;
8 is a perspective view showing a conventional disk chucking device

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

First, in FIG. 1, the motor mechanism 100 which is an optical disk drive mechanism in which the thin disk chucking apparatus 1 of this invention is mounted is shown by schematic sectional drawing.

That is, as shown in FIG. 1, the motor mechanism 100 according to an embodiment of the present invention includes a stator 110, a rotor case 120, a bearing assembly 130, and a chucking device 1. can do.

The stator 110 is a fixed structure including a winding coil 112 generating a certain magnitude of electromagnetic force when power is applied and a plurality of cores 114 to which the winding coil 112 is wound. The winding coil 112 is electrically connected to the flexible printed circuit board so that external power is supplied.

Here, the stator 110 is coupled by the shaft 132 of the bearing assembly 130, and is positioned such that the magnet 122 and the winding coil 112 attached to the inner side of the rotor case 120 face each other.

The rotor case 120 is a rotating structure rotatably provided with respect to the stator 110, and may have an inner circumferential surface of a ring-shaped magnet 122 corresponding to each other at a predetermined interval from the core 114. have. In addition, the magnet 122 is provided with a permanent magnet in which the N pole and the S pole are alternately magnetized in the circumferential direction to generate a magnetic force of a predetermined intensity.

At this time, the portion of the rotor case 120 is coupled to the shaft 132 is formed long in the longitudinal direction can form a long contact surface with the shaft 132 can increase the extraction force.

In addition, the upper surface of the rotor case 120 is seated on the disk (D) may be formed of a turntable 150 made of rubber or the like to contact the bottom surface of the disk.

The turntable 150 may function to fix and support the disk by generating a frictional force to prevent slippage of the disk when the disk is driven by a motor.

In addition, the bearing assembly 130 may include a base 134, a shaft 132, a sleeve 136, and a thrust plate 138. The sleeve 136 may be assembled by pressing the lower end of the body into the receiving hole of the base 134.

The shaft 132 may be inserted into the shaft hole of the sleeve 136 to be rotated and may be formed long in the rotation axis direction. Here, the thrust plate 138 is provided on the bottom of the shaft 132 to reduce the friction force with the shaft 132 generated during rotation. In addition, the shaft 132 may be formed such that one end contacting the thrust plate 138 has a radius of curvature.

A ring-shaped stopper 140 is provided at an upper portion of the thrust plate 138, and a ring-shaped recess is formed at an outer circumferential surface portion of the shaft 132 corresponding to the stopper 140 as a central axis of the shaft 132. The locking path 142 may be formed.

The locking path 142 is inserted into the inner circumferential surface side of the stopper 140, which prevents the shaft 132 from being separated above the sleeve 136. A support plate 144 is positioned below the thrust plate 138, and the support plate 144 is coupled to the base 134 to support the shaft 132.

The support plate 144 may be fixed to the support plate 144 by inserting the support plate 144 into the lower portion of the sleeve 136 and then applying an external force to bend the fastening protrusion 146. .

Next, FIGS. 2 to 5 show a thin disk chucking device 1 according to the present invention mounted on the motor mechanism 100 shown in FIG. 1.

That is, as shown in Figs. 2 and 3, the disk chucking apparatus 1 of the present invention is basically supported on the inner peripheral surface of the disk D while being mounted on the rotor case 120 of the motor mechanism 100. , A device housing 10 including a chucking member inserting portion 12, and a disk chucking member 30 elastically received to enable disk chucking to an insertion portion of the device housing 10. have.

In particular, the apparatus of the present invention may further include a thin forming surface 50 provided on the device housing 10 to enable a thinning of the device, and the thin forming surface 50 on the disk chucking member 30. It may be configured to further include a corresponding surface 70 corresponding to).

Therefore, since the thin disk chucking device 1 of the present invention has the thin forming surface 50, the height 'H' of the device housing 10 is the chucking of the existing chucking device 200 shown in FIG. It may be lower than the height 'h' of the device housing 210 in which the member 230 is accommodated.

For example, such a height reduction by the thin forming surface 50 of the device housing 10 of the present invention, that is, thinning, allows the miniaturization of the product as a whole in parallel with the recent trend of thinning of the (spindle) motor.

In addition, as will be described in detail below, since the present invention includes a corresponding surface 70 provided on the driving support part 34 of the chucking member 30, the device housing ( 10 is to be accommodated in the thinner device housing without reducing the height of the driving support portion 34 of the chucking member 30 accommodated in the chucking member insertion portion 12 of the 10.

Meanwhile, as shown in FIGS. 3 to 5, the device housing 10 includes a horizontal surface 14 and a disk support surface 16, and the thin forming surface 50 is disposed between the horizontal surface and the disk support surface. It is provided as a gradient surface, for example, an inclined surface integrally formed in the.

That is, since the diameter of the device housing 10 of the chucking device 1 of the present invention on which the optical disk D is seated and supported is determined corresponding to the size of the inner peripheral surface (hole) of the standardized disk, the diameter of the device housing is maintained. In order to realize the thinning of the device housing 10, a thinly formed surface having a gradient surface between the horizontal surface 14 of the device housing 10 and the disk support surface 16 on which the inner circumferential surface (hole) of the chucked disk is contacted and supported. 50 is formed to be inclined.

Meanwhile, as shown in FIGS. 3 to 5, a boss hole 24 into which the rotor hub 124 of the center of the rotor case of the motor mechanism 100 of FIG. 1 is inserted is formed in the center of the apparatus housing 10 of the present invention. Such a boss hole 24 is formed inside the boss frame 28 formed in the center of the inner surface 18 of the device housing 10, as shown in FIG.

In addition, the chucking member inserting portion 12 provided in the device housing 10 includes a narrow first cutout 12a and a disk contact portion in which the driving support portion 34 of the chucking member 30 is supported from the inside. A wide second cutout 12b into which 32 is inserted is provided in a stepped form.

At this time, as shown in Figure 3, the chucking member insertion portion 12 of the device housing 10 is disposed at three points at intervals of approximately 120 degrees, and the disk guide for guiding the chucking of the disk to three points in between. A portion 22 is formed, such a disk guide portion 22 is cut in part to be elastically in close contact with the inner peripheral surface (hole) of the disk to pass chucking tightly.

On the other hand, preferably the thin formed surface 50 provided in the device housing of the present invention, as shown in Figures 3 and 4, the upper portion of the first cutout (12a) of the chucking member insertion portion 12 The gradient is started with the lower portion of the cut portion of the disc guide portion 22 as a line.

Therefore, the end portion of the first cutout 12a of the chucking member insertion part 12 is also partially gradient, and as a result, the gradient end 12 ′ of the chucking member insertion part is driven by the driving support part of the chucking member 30 ( 34) affects the thin formed surface corresponding surface 70 provided.

For example, the first cutout 12a described above in the chucking member insertion part 12 supports the upper surface of the driving support part 34 to block the departure of the driving support part, thus forming a thin shape for thinning the device housing 10. The corresponding surface 70 corresponding to the gradient surface, which is the surface 50, eventually solves the problem caused by the interference with the device housing 10 without reducing the thickness of the driving support 34, and only a part of the driving support is removed. Since it is formed with the mating surface 70, there is little influence on the strength of the driving support, and thus stable chucking of the disk is also maintained.

3 to 5, in the chucking device 1 of the present invention, the chucking member 30 is integrally connected to both sides of the disc contact portion 32 and the disc contact portion 32. And a drive support part 34 formed through the unsigned).

At this time, the driving support 34 is moved along the guide surface 20 formed adjacent to the chucking member insertion portion 12 to the inner surface 18 of the device housing 10, as shown in FIG. .

Such a guide surface 20, as shown in Figure 5, is formed on the inner surface of the device housing 10 horizontally on the side of the gushing portion 20a which is integrally formed on the gradient portion of the thin forming surface 50 The connection (boundary) wall 20b is formed between the portions of the grate, thereby solidifying the strength of the device housing 10 as a whole.

Then, the projection 32a is formed on the rear surface of the disk contact portion 32 of the chucking member 30, and the receiving portion 26 is formed on the central boss frame 28, the elastic member 36 therebetween. That is, the spring is fastened.

Therefore, when the disk is chucked, the disk contact portion 32 of the chucking member 30 moves backward while compressing the elastic member when the inner circumferential surface (hole) portion of the disk is pressed, and the driving support portion 34 moves backward. Move along the guide surface 20 to remain constant.

On the other hand, the outer surface of the driving support portion 34 is further formed with a projection (unsigned) to guide the movement of the driving support to a constant, the guide surface 20 is correspondingly formed with a groove for receiving such projections Can be.

At this time, preferably as shown in Figures 3 and 6, the corresponding surface 70 provided in the chucking member drive support portion 34 is in a position corresponding to the thin formed surface of the device housing 10 It is provided as a chamfer surface formed in the drive support (34).

That is, as shown in FIG. 6, since the height 'T1' of the driving support part 34 is higher than the height 'T2' of the disk support surface 16 of the device housing 10, the gradient surface that is the thin formed surface 50 is. If the upper end of the disc contact portion side of the driving support part 34 is not provided as a chamfering surface by the inclined structure of, the interference (contact) between the thin-formed surface and the driving support part 34 is generated, and thus the chamfering surface which is the corresponding surface 70 is formed. If not, the height of the driving support should be lowered, in which case the strength of the driving support becomes weak.

Therefore, in the case of the present invention, the chamfered surface, which is the corresponding surface 70, enables the normal disk chucking without reducing the height of the driving support portion 34, so that the strength of the device housing can be maintained as before. .

On the other hand, as shown in Figure 7a and 7b, the inclined angle 'Θ1' of the thin formed surface 50, that is, the inclined gradient surface provided in the device housing 10 of the present invention, the drive support portion 34 It is necessary to form larger than the corresponding surface 70, that is, the chamfered inclination angle 'Θ2' provided in the).

Of course, since the thin forming surface 50 of the device housing 10 must satisfy complex conditions such as the diameter of the device housing and the accommodation of the chucking member 30, it is preferable to meet the conditions for forming the thin forming surface 50. It may be desirable to adjust the corresponding surface 70, ie, the chamfer inclination angle, provided in the drive support 34.

While the invention has been shown and described in connection with specific embodiments so far, it will be appreciated that the invention can be varied and modified without departing from the spirit or scope of the invention as set forth in the claims below. It will be appreciated that those skilled in the art can easily know.

1 .... Thin disc chucking device 10 .... Device housing
12 .... Chucking element insert 16 .... Disk support surface
30 .... disc chucking member 32 .... disc contact
34 .... Drive Support 50 .... Thin Formation Surface on Device Housing
70 .. Corresponding surface of chucking member 100 .... Motor mechanism

Claims (4)

An apparatus housing including a chucking member insert, the disk housing being supported on the motor mechanism; And,
A disk chucking member elastically received to enable disk chucking to the chucking member insertion portion of the device housing;
Consists of including
The device housing further comprises a gradient thin forming surface that forms an outer wall forming the chucking member inserting portion and is provided to enable device thinness, and a gradient inner surface corresponding to the thin forming surface, wherein the disk chucking member includes: The thin disk chucking device further comprising a thin forming surface and a corresponding surface corresponding to the inner surface.
The method of claim 1,
The device housing is installed on the rotor case of the motor mechanism, and includes a horizontal surface and a disk support surface,
The thin disk chucking device, characterized in that the thin surface is formed as a gradient surface integrally formed between the horizontal surface and the disk support surface.
The method according to claim 1 or 2,
The chucking member includes a disk contact portion and a driving support provided at both sides thereof,
And the corresponding surface is provided as a chamfered surface formed in the drive support portion at a position corresponding to the thin formed surface of the device housing.
The method of claim 3,
And the gradient surface angle Θ1 of the thin forming surface provided in the device housing is larger than the chamfering angle Θ2 of the corresponding surface provided in the drive support.

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