JPH0562447A - Hard disk device - Google Patents

Abstract

PURPOSE:To make a hard disk device and a computer device or the like using it further thin. CONSTITUTION:The inner peripheral parts 51a-59a of the stator gears 51-59 of a stator core 40 are positioned at the outside of the radial direction of a rotor magnet 24. The length of the peripheral directions of the inner peripheral parts 51a-59a are substantially equal, and the inner peripheral parts 51a-59a are symmetrically arranged on a constant circumference. Coil winding parts 51b-55b, and 59b are biased in an almost peripheral direction with the movable range of a magnetic head 64 and a supporting arm 66 which supports it as a center. No stator coil 60 exists between the stator core 40 and a hard disk 30 in the movable range, and a space where the magnetic head 64 and the supporting arm 66 can move is prepared.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thin hard disk device.

2. Description of the Related Art Recently, portable notebook type personal computers and the like having a built-in hard disk device have been commercially available. Needless to say, there is a demand for further thinning of notebook personal computers and the like, and in order to meet the demand, it is necessary to further reduce the thickness of the built-in hard disk device.

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 a hard disk device and a computer device using the same. It is an object of the present invention to provide a hard disk device that can meet the above demands.

[0003]

In order to achieve the above object, a hard disk device of the present invention is provided with a stator core on the outer peripheral side of a rotor to which a hard disk is fixed,
A hard disk device in which a stator coil is wound around a coil winding portion of a stator tooth of the stator core, wherein the coil winding portion of at least a part of the stator teeth is biased in a substantially circumferential direction, It is assumed that a space in which the magnetic head and the magnetic head supporting means can move due to the absence of the stator coil is formed between the stator core and the hard disk.

[0004]

Since the stator core is provided on the outer peripheral side of the rotor to which the hard disk is fixed, the magnetic head and the magnetic head supporting means move between the stator core and the hard disk.

However, when the coil winding portion of at least a part of the stator teeth of the stator core is biased in the substantially circumferential direction, the stator coil does not exist between the stator core and the hard disk over the required range. be able to.

Therefore, by forming a space in which the magnetic head and the magnetic head supporting means can move due to the absence of the stator coil between the stator core and the hard disk, the thickness of the hard disk drive is approximately equivalent to the winding thickness of the stator coil. It becomes possible to make the thickness thinner.

[0007]

Embodiments of the present invention will be described with reference to the drawings. 1 and 2 relate to a hard disk device as one embodiment of the present invention, of which FIG.
-QR-S-T-I line sectional view, FIG.
It is a II-OP-II sectional view taken on the line.

Reference numeral 10 is a base of the hard disk device. A cylindrical bearing housing 14 of a spindle motor 12 for driving a hard disk is provided in a protruding manner at the center of the base 10 on the left side in FIG. 16 is a rotor hub. The rotor hub 16 has a substantially cup shape, and a rotating shaft 20 is provided in a protruding manner at a center portion inside a peripheral wall 18 thereof.
The rotary shaft 20 is rotatably supported inside the bearing housing 14 via two ball bearings 22.

The peripheral wall 18 of the rotor hub 16 is located on the outer peripheral side of the bearing housing 14, and the annular rotor magnet 24 is located on the outer peripheral side of the opening (lower end in FIG. 2) of the peripheral wall 18.
Are arranged. As shown in FIG. 2, the rotor magnet 24 and the lower ends of the peripheral wall 18 are inserted into an annular recess 26 provided on the outer periphery of the base of the bearing housing 14 of the base 10. The rotor 28 is mainly composed of the rotor magnet 24 and the rotor hub 16.

A hard disk 30 is externally fitted to the base portion (upper end portion in FIG. 2) of the peripheral wall 18 of the rotor hub 16. A disc spring-shaped washer 32 is externally fitted to the base portion (upper end portion in FIG. 2) of the rotor hub 16 and is located on the inner peripheral portion of the hard disk 30. Hard disk 30
Is fixed by the fixing annular member 34 via the washer 32. The inner periphery of the fixing annular member 34 is formed in a female screw portion, and is screwed onto the outer periphery of the base portion of the rotor hub 16 formed in the male screw portion.

FIG. 3 is a plan view of the washer 32, and FIG. 4 is an end view taken along line IV-IV in FIG. Inward projections 36 are provided at three locations on the inner circumference of the washer 32. The inward projection 36 is fitted into a recess 38 provided in the outer peripheral portion of the base of the rotor hub 16, and accordingly, the washer 32 is screwed when the fixing annular member 34 is screwed into the base of the rotor hub 16.
Is to prevent the rotation.

As described above, the hard disk 30 is pressed against the rotor hub 16 over the entire inner circumference of the hard disk 30 via the disk spring-shaped washer 32 with the rotation prevention. The clamping force is applied almost evenly over the entire inner peripheral portion to prevent warping of the disk and the hard disk 30 when fixed.
It is possible to prevent the damage to and the generation of dust and the like.

Reference numeral 40 is a stator core fixed to the base 10. The stator core 40 has a yoke portion 42 around the entire outer circumference thereof, and nine stator teeth 51 to 59 project from the inner circumference of the yoke portion 42. Inner peripheral portions 51a to 59a of the stator teeth 51 to 59 are located radially outward of the rotor magnet 24 and face the rotor magnet 24 in the radial direction. As shown in FIG. 2, the inner peripheral portions 51 a to 59 a of the stator teeth 51 to 59 are fixed in contact with the upper surface of the base plate 10 so as to face the rotor magnet 24, and are substantially magnetic from the rotor magnet 24. The centers are matched. The stator teeth 51 to 59 are arranged on the inner peripheral portion 5
A little outside of 1a to 59a, it is bent upward in FIG. 2 and its height is maintained up to the yoke portion 42. This is to accommodate the stator coil 60 wound around the base of the stator teeth 51 to 59, that is, the coil winding portions 51b to 59b. In addition, the lower portion of the stator coil 60 is provided with a coil accommodating recess 62 provided on the base plate 10.
Has been inserted into.

By the way, the inner peripheral portions 51a to 59a of the stator teeth 51 to 59 have substantially the same circumferential length (about 33 degrees at the central angle from the rotational axis of the spindle motor 12) and have a constant circumference. The coil winding portions 51b to 55b and 59b are arranged so as to have a substantially nine-fold rotational symmetry.
Is biased in a substantially circumferential direction around a movable range (upper right part in FIG. 1) of a magnetic head 64 and a support arm 66 supporting the magnetic head 64, which will be described later. Magnetic head 64 and support arm 66
By eliminating the stator coil 60 between the stator core 40 and the hard disk 30 in the movable range of the stator core 40 and the hard disk 30.
This is to form a space in which the magnetic head 64 and the support arm 66 can move. With the above-described configuration of the inner peripheral portions 51a to 59a of the stator teeth 51 to 59, the magnetic relationship with the rotor magnet 24 is as a whole when the coil winding portions 51b to 55b and 59b are not biased. It is almost the same.

Incidentally, the deviation of the coil winding portion in the substantially circumferential direction is
The angle shift of the stator teeth with respect to the inner circumference is as follows. However, the angle mentioned here is an angle formed by the central positions of the coil winding portion and the inner peripheral portion when viewed from the rotation axis of the spindle motor 12.

The inner peripheral portions 56a to 58a and the coil winding portions 56b to 58b of the stator teeth 56 to 58 are located on the same radial direction, and there is substantially no deviation.

The coil winding portion 52b of the stator tooth 52 is
It is offset about 43 degrees clockwise with respect to the inner peripheral portion 52a in FIG. In addition, the coil winding portion 51b of the stator tooth 51
Is offset about 23 degrees counterclockwise with respect to the inner peripheral portion 51a. The coil winding portion 53b of the stator tooth 53 is approximately 33 degrees clockwise with respect to the inner peripheral portion 53a, and the coil winding portion 54b of the stator tooth 54 is approximately 24 degrees clockwise with respect to the inner peripheral portion 54a. The coil winding portion 55b of 55 is approximately 10 degrees clockwise with respect to the inner peripheral portion 55a, and the coil winding portion 59b of the stator tooth 59 is approximately 10 degrees counterclockwise with respect to the inner peripheral portion 59a. It is biased.

Reference numeral 68 in FIG. 2 is a magnetic shield member for preventing the magnetic influence of the stator from affecting the hard disk 30 and the magnetic head 64, and extends from the outer peripheral portion to the inner peripheral portion of the stator core 40. It is provided so as to be separated from the hard disk 30.

Next, among the laminated electromagnetic steel plates constituting the stator core 40, the upper half in FIG. 2 is bent and positioned slightly upward, and extends in the lower right direction in FIG. 1 to provide a voice coil for driving the magnetic head. Lower yoke 72 of motor 70
Are configured. As described above, the stator core 40 of the spindle motor 12 for driving the hard disk and the lower yoke 72 of the voice coil motor 70 for driving the magnetic head are integrally configured, so that the voice coil motor 70 is positioned with respect to the spindle motor 12. In addition, the positioning of the magnetic head 64 with respect to the hard disk 30 is further ensured.

Reference numeral 74 denotes a support column which is erected on the base 10, and 76
Is a rotary sleeve member that is rotatably supported on the column 74 via a ball bearing (not shown). The support arm 66 is provided so as to project outward in the radial direction of the rotary sleeve member 76, and the magnetic head 64 is supported at the tip of the support arm 66. A movable coil 78 is fixed to the side of the rotary sleeve member 76 opposite to the support arm 66.

Reference numeral 80 denotes an upper yoke fixed above the column 74, and reference numerals 82 and 84 denote a lower surface of the upper yoke and the lower yoke 7.
It is a substantially fan-shaped permanent magnet plate fixed to each upper surface of the pair 2. The movable coil 78 is located between the upper and lower permanent magnet plates 82 and 84.

When the movable coil 78 is excited and rotates about the rotation axis of the rotary sleeve member 76, the magnetic head 64 is driven in the direction shown by the arrow in FIG. Move along. Since the stator coil 60 does not exist between the hard disk 30 and the stator core 40 in the movable range of the magnetic head 64 and the support arm 66, the total thickness of the hard disk 30 device is thinned by about the winding thickness of the stator coil 60. ing.

Further, since the substrate 10 also serves as the frame of the spindle motor 12, further thinning is realized.

If the coil housing recess can be deepened and the lower part of the stator coil can be housed in the coil housing recess while ensuring sufficient strength and rigidity of the base, the stator teeth of the stator core 40 can be accommodated. It is not necessary to bend the parts 51 to 59 upward slightly outside the inner peripheral parts 51a to 59a, so that the hard disk mounting position can be made lower and the overall thickness can be further reduced. 86 is a lid for sealing the disk chamber.

[0025]

In the hard disk device of the present invention, the thickness thereof can be reduced by an amount substantially equivalent to the winding thickness of the stator coil, and not only the hard disk device but also a thin computer device using the same. It is possible to meet the demands for realization.

[Brief description of drawings]

1 is a sectional view taken along the line IQR-S-T-I in FIG.

FIG. 2 is a sectional view taken along line II-OP-II in FIG.

FIG. 3 is a plan view of a washer 32.

FIG. 4 is an end view taken along line IV-IV in FIG.

[Explanation of sign]

 28 rotor 30 hard disk 40 stator core 51 stator tooth 51b coil winding portion 52 stator tooth 52b coil winding portion 53 stator tooth 53b coil winding portion 54 stator tooth 54b coil winding portion 55 stator tooth 55b coil winding portion 56 stator tooth 56b Coil winding portion 57 Stator tooth 57b Coil winding portion 58 Stator tooth 58b Coil winding portion 59 Stator tooth 60 Stator coil 64 Magnetic head 66 Support arm

Claims (1)

[Claims] 1. A hard disk drive in which a stator core is provided on an outer peripheral side of a rotor to which a hard disk is fixed, and a stator coil is wound around a coil winding portion of a stator tooth of the stator core. By displacing the coil winding portion of at least a part of the coil in the substantially circumferential direction, a space in which the magnetic head and the magnetic head supporting means can move due to the absence of the stator coil is formed between the stator core and the hard disk. A hard disk device characterized by the above.