JPH05242580A - Disk driving device - Google Patents

Abstract

PURPOSE:To easily and surely fix a disk body to a disk supporting body uniformly over the whole periphery even if the thickness of a disk driving device in its rotational axis direction is furthermore mad thinner. CONSTITUTION:The 1st hard disk 48 is externally engaged with a 1st disk engaging peripheral part 46 almost not to form a gap and the lower face of its inner peripheral edge part is supported by a 1st disk supporting face 44. The 1st gap part 52 whose cross section is an approximate wedge shape is formed by the 1st contracted diameter face 50 formed on the upper part of the peripheral part 46 and the upper face of the inner peripheral edge part of the disk 48. The 1st elastic ring member is engaged with the 1st gap part 52 in a peripheral direction tension remaining stress state. Shrinkage force obtained by said status allows both the faces of the inner peripheral edge part of the disk 48 to be pressed and held between the 1st disk supporting face 44 and the 1st elastic ring member 54 uniformly over the whole periphery.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disk drive device in which a disk body is externally fitted and held on a disk support which is rotationally driven.

[0002]

2. Description of the Related Art Conventionally, in a disk drive device for fixedly holding a recording disk such as a hard disk on the outer peripheral portion of a rotor frame in a spindle motor and rotating it,
A hard disk or the like is pinched and held between an outer protruding portion provided on the rotor frame and a clamp member fixed to the rotor frame.

For example, as shown in FIG. 2, the clamp member has a base portion d1 of the rotor frame d at a portion of the clamp member a inside the inner peripheral portions of the hard disks b and c.
It was fixed to the rotor frame d by being screwed to the hard disks b and c. In the example of FIG. 2, two hard disks b and c are held under pressure with an annular spacer e interposed therebetween. However, when fixing the clamp member a in this way, the thickness of the portion of the clamp member a inside the inner peripheral portion in the direction of the rotation axis and the thickness for providing the screw hole f in the base portion d1 of the rotor frame d. Therefore, the thickness of the disk drive device g in the direction of the rotation axis has to be relatively thick. Also, if the tightening of the screw h becomes uneven, the hard disks b, c
There was a risk of warpage.

In order to improve this point, the inner peripheral portion of the clamp member and the outer peripheral portion of the rotor frame may be respectively threaded and screwed together to clamp the hard disk. .. This eliminates the need for a portion of the clamp member inside the hard disk inner peripheral portion for screwing to the rotor frame, and also eliminates the need to provide a screw hole for screwing the clamp member at the base portion of the rotor frame. Therefore, the thickness of the disk drive device in the rotation axis direction can be greatly reduced.

However, if the thickness of the disk drive device in the direction of the rotation axis is further reduced, if such means is adopted, the length of the portion where the rotor frame and the clamp member face each other in the rotation axis direction is extremely small. Since the length is shortened, fine screw cutting is required on the inner peripheral portion of the clamp member and the outer peripheral portion of the rotor frame, which makes machining difficult. For example, when the length in the direction of the rotation axis of the portion where the rotor frame and the clamp member face each other is about 1 mm, the difficulty of processing is extremely remarkable.

The present invention has been made in view of the above problems existing in the prior art, and an object thereof is to further reduce the thickness of the disk drive device in the rotation axis direction. It is an object of the present invention to provide a disk drive device that can easily and surely fix a disk body to a disk support evenly and reliably over the entire circumference.

[0007]

In order to achieve the above-mentioned object, a disk drive device of the present invention is an annular disk body which is fitted onto a disk fitting outer peripheral portion of a disk support which is rotationally driven with substantially no space. One surface of the inner peripheral edge of the disk is supported by a support surface that is perpendicular to the rotation axis of the disk support and is radially outward of the disk fitting outer circumference, and tapers toward the support surface. The reduced diameter surface of the disk support that is reduced in diameter and the other surface of the inner peripheral edge portion of the disk body that faces the reduced diameter surface have a substantially wedge-shaped cross section in which the interval narrows radially inward. It is assumed that a gap is formed and the disk body is held between the support surface and the elastic ring member by a contracting force of the elastic ring member fitted in the gap in the circumferential tensile residual stress state.

[0008]

According to the present invention, one surface of the inner peripheral edge portion of the annular disc body, which is fitted onto the disc fitting outer peripheral portion of the disc support body with substantially no gap and is positioned in the radial direction, is perpendicular to the rotation axis of the disc support body. It is supported by a support surface located radially outward of the fitting outer peripheral portion. Then, the diameter-reduced surface of the disk support that is tapered toward the support surface side and the other surface of the inner peripheral edge of the disk body that faces the diameter-reduced surface are A gap portion having a substantially wedge-shaped cross section is formed so that the gap is narrowed inward.
Therefore, both surfaces of the inner peripheral edge portion of the disk body are supported by the supporting surface mainly by the contracting force of the elastic ring member fitted in the gap in the circumferential tensile residual stress state and the reaction force acting from the contracting surface. And the elastic ring member are evenly clamped and held over the entire circumference.

[0009]

Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a cross-sectional view of a hard disk drive device having a total height of about 9 mm using a spindle motor device according to an embodiment of the present invention. However, the left half shows a state where the hard disk is not fixed.

The substrate 10 has a recess 12 having a circular cross section. The lower end of a cylindrical fixed column 14 is fitted and fixed to the center of the recess 12. A lead-out groove 16 is provided from the upper and lower intermediate portions of the fixed column 14 to the lower end, and the inner surface of the lead-out groove 16 is coated with an insulating coating. Such a fixed column 14 can be obtained by, for example, performing electrodeposition coating or electrostatic coating on the entire surface of the columnar body provided with the lead-out groove 16 and then cutting the outer peripheral surface of the columnar body to a predetermined size.
As a coating means, electrodeposition coating is preferable because a thin coating film can be obtained and workability is good.

Reference numeral 18 is a substantially bowl-shaped rotor hub (disk support), and 20 is an annular member 22 fitted in the upper opening of the rotor hub 18. The rotor hub 18 and the annular member 22 that is integral with the rotor hub 18 are rotatably supported by the fixed column 14 via upper and lower ball bearings 24 and 26.

A portion of the base 10 around the fixed column 14 is formed with an annular protrusion 28.
The lower end of the inner ring of the lower ball bearing 26 is supported on the upper side. The lower portion of the rotor hub 18 is separated from the base 10 by a slight gap.
Of the annular hub 30 fitted in the concave portion 12 of the rotor hub 18 and provided at an intermediate position in the outer peripheral portion of the rotor hub 18.
Is located slightly above the annular upper protrusion 32 provided on the peripheral edge of the recess 12 of the base 10. With such a configuration, a labyrinth seal-like effect is exerted between the base 10 and the rotor hub 18, and the lubricant or the like of the lower ball bearing 26 is scattered outward from the gap between the overhanging portion 30 and the upper protruding portion 32. Is effectively prevented.

An annular bush member 34 is externally fitted and fixed to the upper end of the fixed column 14, and the outer peripheral surface of the bush member 34 faces the inner peripheral surface of the annular member 22 with a slight radial gap. ing. With such a structure, the effect of a labyrinth seal is exhibited, and the lubricant or the like of the upper ball bearing 24 is prevented from scattering outward.

A stator core 36 is externally fitted and fixed between the upper and lower ball bearings 24 and 26 of the fixed column 14, and a stator coil 38 is wound around the stator core 36. On the other hand, a cylindrical rotor magnet 40 is fixed to the inner peripheral portion of the rotor hub 18, and faces the stator core 36 outside with a radial gap.

Reference numeral 42 is a lead-out portion of the stator coil 38. The lead-out portion 42 is led out below the base 10 through the notch groove portion 43 provided on the inner peripheral side of the stator core 36 and the lead-out groove 16 in the fixed support column 14. It is desirable that the portion of the lead-out portion 42 that passes through the lead-out groove 16 be adhesively fixed in the lead-out groove 16 with an adhesive in order to avoid inconvenience such as disconnection. Even if the insulating coating of the lead-out portion 42 is peeled off, since the inner surface of the lead-out groove 16 is coated with insulating coating, sufficient insulation is ensured.

The upper surface of the overhanging portion 30 of the rotor hub 18 is the first disk supporting surface 44, and the portion of the outer peripheral portion of the rotor hub 18 immediately above the first disk supporting surface 44 is the outer peripheral portion 46 for fitting the first disk. Is. A ring-shaped first hard disk 48 is fitted onto the first disk-fitting outer peripheral portion 46 with almost no gap and positioned in the radial direction with respect to the rotor hub 18, and the lower surface of the inner peripheral edge portion is on the first disk supporting surface 44. Supported by.

A notch is provided over the entire circumference in the upper portion of the outer peripheral portion of the rotor hub 18 above the first disc fitting outer peripheral portion 46, and the upper surface of the notch is lower, that is, the first portion. A first diameter-reducing surface 50 is formed so as to taper off toward the disk support surface 44. The first reduced diameter surface 50 and the upper surface of the inner peripheral edge portion of the first hard disk 48 form a first gap portion 52 having a substantially wedge-shaped cross section with a narrower gap inward in the radial direction.

Reference numeral 54 denotes a first elastic ring member having a diameter of about 0.5 mm, which is fitted in the first gap portion 52 in a circumferential tensile residual stress state. As the material of such an elastic ring member, various materials such as synthetic resin, synthetic rubber, metal, etc. can be used, but longitudinal elasticity is required so that fitting in a sufficient circumferential tensile residual stress state is possible. It is desirable to use a material having a sufficiently large coefficient and tensile strength. Further, it is desirable to use at least a surface of the elastic ring member that is in contact with the hard disk with a material that does not damage the hard disk.

Both surfaces of the inner peripheral edge portion of the first hard disk 48 are caused by the contracting force of the first elastic ring member 54 and the reaction force acting from the first reducing surface 50 to the first disk supporting surface 44. And the first elastic ring member 54
The holding pressure is evenly held over the entire circumference between and, and the occurrence of warpage or the like of the first hard disk 48 due to the uneven holding pressure is avoided.

An annular spacer 56 is fitted onto the first elastic ring member 54 on the outer peripheral portion of the rotor hub 18 and supported on the first elastic ring member 54. The upper surface of the spacer 56 is the second disk support surface 58,
A portion of the outer peripheral portion of the rotor hub 18 immediately above the second disc supporting surface 58 is a second disc fitting outer peripheral portion 60. An annular second hard disk 62 is fitted onto the second disk fitting outer peripheral portion 60 with almost no gap and positioned in the radial direction with respect to the rotor hub 18, and the lower surface of the inner peripheral edge portion is on the second disk supporting surface 58. Supported by.

A notch is provided over the entire circumference in a portion above the second disk fitting outer peripheral portion 60 in the outer peripheral portion of the rotor hub 18, and the upper surface of the notch is downward, that is, the second portion. A second diameter-reducing surface 64 is formed so as to taper off toward the disk support surface 58. The second diameter-reduced surface 64 and the upper surface of the inner peripheral edge portion of the second hard disk 62 form a second gap portion 66 having a substantially wedge-shaped cross section with a narrower gap inward in the radial direction.

Mainly, the contraction force of the second elastic ring member 68 having a diameter of about 0.5 mm fitted in the second gap 66 in the circumferential tensile residual stress state and the second contracted surface 64
The reaction force applied from the second hard disk 62
Both surfaces of the inner peripheral edge portion of the disk are uniformly clamped and held over the entire circumference between the second disk support surface 58 and the second elastic ring member 68, and the second hard disk 62 is pressed by the uneven pressure. It is possible to avoid warpage and the like.

Since the thickness in the direction of the rotation axis required to hold the hard disk under pressure is extremely small, the two hard disks 48 and 62 are connected to the first elastic ring even if the total height of the apparatus is about 9 mm. Member 54 and second
The elastic ring members 68 can be easily and surely fixed.

In the above embodiment, two hard disks are supported and driven by the rotor hub 18, but the number of hard disks may be one or three or more. Also, as the hard disk to be used,
A substrate having a magnetic film formed on the surface of a substrate made of an aluminum-based material or a glass material is preferable, but the substrate is not limited to this. The present invention can also be applied to various recording disks other than hard disks and other disks. Further, the vertical positional relationship in the description of the above embodiments is merely for convenience of description based on the drawings, and does not limit the actual use state or the like.

[0025]

In the disk drive device of the present invention, the disk body is externally fitted to the disk fitting outer peripheral portion of the disk support body and has a substantially wedge-shaped cross section formed by the reduced diameter surface and the inner peripheral edge portion of the disk body. By fitting the elastic ring member in the gap portion in the circumferential tensile residual stress state, both surfaces of the inner peripheral edge portion of the disk body can be easily and surely provided between the support surface and the elastic ring member, and also on the entire circumference. The holding pressure is evenly held, and the occurrence of warpage or the like of the disk body due to the uneven holding pressure is avoided. Therefore, it is extremely suitable for thinning, as compared with the case where the clamp member is tightened with a screw and the case where the inner peripheral portion of the clamp member and the outer peripheral portion of the disk support are respectively screwed to screw them together.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of a hard disk drive device.

FIG. 2 is a cross-sectional view of a conventional hard disk drive device.

[Explanation of sign]

 18 rotor hub 44 first disk supporting surface 46 first disk fitting outer peripheral portion 48 first hard disk 50 first reduced diameter surface 52 first gap 54 first elastic ring member 58 second disk supporting surface 60 second disk fitting outer periphery Part 62 second hard disk 64 second diameter-reducing surface 66 second gap part 68 second elastic ring member

Claims (1)

[Claims] 1. An inner peripheral edge portion of an annular disc body fitted around a disc fitting outer peripheral portion of a disc drive body which is rotationally driven with substantially no gap, and one surface of which is perpendicular to a rotation axis of the disc support body. A diameter-reduced surface of the disk support, which is supported by a support surface located radially outward of the fitting outer peripheral portion and taper-reduces toward the support surface side, and a portion facing the diameter-reduced surface. With the other surface of the inner peripheral edge of the disk body, a gap having a substantially wedge-shaped cross section is formed which is narrowed inward in the radial direction, and the gap is fitted in a circumferential tensile residual stress state. A disk drive device characterized in that the disk body is clamped and held between a support surface and the elastic ring member by a contracting force of the elastic ring member.