JP2546727B2 - Magnetic head assembly - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Outline] A magnetic head assembly, particularly a gimbal, in a magnetic disk device that records / reproduces information while a core slider is levitated by wind force generated by rotation of a magnetic disk. In a magnetic head assembly extending in a direction perpendicular to the seek direction of the magnetic head, the core slider is less likely to roll during seek operation, and a magnetic head assembly capable of stable flying is provided. In a magnetic head assembly in which a core slider of a magnetic head is attached to a spring arm in a direction perpendicular to the seek direction of the head via a gimbal, the gimbal is long in the seek direction of the magnetic head,
And a plurality of leaf springs formed by joining both ends of each of the plurality of leaf springs are formed, and a central position of one leaf spring of the plurality of leaf springs is fixed to the spring arm, and the other leaf spring is fixed. The central position of the spring portion is fixed to the back surface of the core slider.

[Industrial applications]

A magnetic head for a magnetic disk device used as an external storage device in an information processing system is supported by a thin leaf spring called a gimbal, and is floated by wind force when the magnetic disk rotates at high speed. The present invention
The present invention relates to a magnetic head assembly, particularly a gimbal, in a magnetic disk device that records / reproduces information while the core slider is suspended by the wind force generated by the rotation of the magnetic disk.

[Conventional technology]

6 to 8 are plan views showing a seek method of a magnetic head in a conventional magnetic disk device. In these figures, D is a magnetic disk, H is this magnetic disk D
Is a core slider of a magnetic head for recording / reproducing information, and has a core 1 around which a coil is wound at the rear end.

In FIG. 6, the core slider H is attached via a gimbal 3 to a spring arm 2 extending in the seek direction (arrow a ₁ direction). The carriage 4 that seeks the magnetic head also moves straight in the seek direction. Therefore, a seek is performed by moving the spring arm 2 and the core slider H straight in the longitudinal direction of the spring arm 2.

On the other hand, in the apparatus shown in FIG. 7, the spring arm 2 extending in the seek direction of the magnetic head is attached to the tip of the swing arm 5 which rotates about the rotation axis A. In this case, the rotation axis A is reciprocally rotated, so that the swing arm 5
Is rotated, the spring arm 2 and the core slider H are moved in the radial direction of the magnetic disk D, and a seek operation is performed.

FIG. 8 shows that the spring arm 2 supporting the core slider H, the drive arm 6 and the rotation axis A are positioned on a straight line,
Moreover, since it is perpendicular to the seek direction (a ₁ ) of the core slider H, it is called an in-line system. Also in this case,
Although the seek operation is performed by the reciprocating rotation of the rotation axis A, the spring arm 2 does not move back and forth in the longitudinal direction as shown in FIGS. 6 and 7, but moves in the direction perpendicular to the longitudinal direction. It will shake and swing.

In the conventional magnetic disk device, in order to shorten the access (seek) time of the device and to make the device lightweight and compact,
The magnetic head access system has been improved from the linear carriage system of FIG. 6 to the rotary carriage system of FIG. 7 and further to the in-line system of FIG.

By the way, as shown in FIGS. 6 and 7, when the seek operation is performed in the longitudinal direction of the spring arm 2, the seek operation is performed in the direction in which the gimbal 3 has high rigidity, so that the core slider H can move stably. However, when the spring arm 2 is swung at a right angle as shown in FIG. 8, the stability of the core slider H is poor because the rigidity of the gimbal is weak.

FIG. 9 shows the in-line type magnetic head assembly of FIG. 8, (b) is a right side view, (c) is a bottom view, and (a).
FIG. 6 is a perspective view of a gimbal. FIG. 10 is an exploded perspective view of the magnetic head assembly. 1 is the core of the magnetic head,
The coil C is wound and adhered to the rear end of the core slider H. The gimbal 3 has a U-shaped slit 9 formed by etching a thin plate material as shown in FIGS. 9 (c) and 10.
By providing the center tongue piece (folded piece) 10 and the leaf spring sides 11 and 11 on both sides, the structure is such that it is folded back in a U shape from the folded portion 12 at the tip.

The leaf spring sides 11, 11 are welded and fixed to the spring arm 2 at the base end 13 side, and the vicinity of the center dowel 7 of the folded side 10 is fixed to the back surface 8 of the core slider H.
The tip of the spring arm 2 contacts the top end P of the dowel 7, and the spring force of the spring arm 2 presses the floating core slider H toward the magnetic disk D side.

The core slider H is thus supported by the gimbal 3, and is pressed toward the magnetic disk surface side by the spring pressure of the spring arm 2. When the magnetic disk D rotates at a high speed, the air flow in the direction of the arrow a ₂ generated between the core slider H and the magnetic disk D causes the core slider H to fly up in a minute gap of 1 μm or less, and in the floating state, the gap G causes the information Is recorded / reproduced.

[Problems to be Solved by the Invention]

FIG. 11 is a front view of the core slider H of FIG. 9 (core 1 side).
It is a view seen from above, and the central tongue piece 10 of the gimbal and the leaf spring sides 11, 11 on both sides are shown in cross section. In this figure,
The state (b) is a state in which the surface is normally floated, the surface is stably floated, and information recording / reproduction is possible. When the magnetic head seeks to another track in this stable state, as shown in (a) or (c), the core slider H
Causes a rotting movement. That is, since the central tongue piece 10 of the gimbal 3 and the leaf spring sides 11, 11 have a small cross-sectional area and are elongated in the direction perpendicular to the paper surface, when the core slider H is moved left and right in the figure for seek, The tongue piece 10 and the leaf spring sides 11, 11 are easily twisted, so that the core slider H easily rolls as shown in FIGS. As the seek speed increases with the increase in the speed of the magnetic disk device, the rolling becomes easier.

As a result, in the case of tilting to the right as shown in (a), the gap between the left floating rail R1 and the magnetic disk D is small, so the left floating rail R1 contacts the magnetic disk D, causing a head crash. May cause (C) When tilted to the left as shown in the figure, the levitation rail R2 on the right side
Since the gap between the magnetic disk D and the magnetic disk D is small, the right floating rail R2 may come into contact with the magnetic disk D and cause a head crash.

Moreover, in the states of (a) to (c), recording / recording of the core 1 is performed.
The gap between the reproducing gap and the magnetic disk D is different,
The efficiency of recording / reproducing information may be reduced, or the output may fluctuate. This problem is particularly noticeable in a magnetic head having a recording / reproducing gap on the left or right flying rails R1 and R2.

Further, in recent years, the gap between the magnetic head and the surface of the magnetic disk has become smaller as the performance and speed of the magnetic disk device have increased, and the above problem becomes more serious.

The technical problem of the present invention is to pay attention to such a problem, and in a magnetic head assembly in which the spring arm extends in the direction perpendicular to the seek direction of the magnetic head, the core slider does not easily roll during seek operation and is stable. It is to realize a magnetic head assembly that can fly.

[Means for solving the problem]

1A and 1B are views for explaining the basic principle of a magnetic head assembly according to the present invention. FIG. 1A is a front view and FIG. 1B is a right side view. H is a core slider of the magnetic head, and 2 is a spring arm. The arrow a ₁ is the seek direction of the magnetic head, and in the figure (b), it is the direction perpendicular to the paper surface. Arrow a ₂
This is the inflow direction of the airflow generated by the rotation of the magnetic disk D.

The spring arm 2 faces the direction perpendicular to the seek direction of the magnetic head, and the core slider H and the spring arm 2 are connected via the gimbal 3 of the present invention.

This gimbal 3 is also made of a thin plate material, and has at least one slit in the seek direction of the magnetic head, that is, in the direction orthogonal to the spring arm 2 in a cross shape, and by the slit, two or more leaf spring portions S1, S2 and S3 are formed separately. The leaf spring parts S1, S2, S3 are integrally connected at both ends of the slit.

The central portion of one leaf spring S1 is the core slider H.
The spring arm 2 is attached to the mounting portions 14 and 15 which are fixed to the back of the vehicle and integrally extend from the center of the local leaf springs S2 and S3.
Is fixed.

The slits are not only those formed by etching a thin plate material for the gimbal, but also the gaps formed between the leaf springs by integrating both ends of the leaf springs with spacers in between. Etc. are also included.

[Action]

In the magnetic head assembly of the present invention, the spring arm 2
The core slider H and the core slider H are connected to each other by a plurality of leaf spring portions S1, S2, S3 in the seek direction. Then, of the leaf spring portions S1, S2, S3 that form the gimbal, a part of the leaf spring portions S1
Is fixed to the core slider H side, and the other leaf springs S2, S3 are
Mounting parts 14 and 15 that are integrally extended from each of
It is fixed to the spring arm 2.

In the present invention, these leaf spring portions S1, S2, S3 are formed by the slits to be long in the seek direction of the magnetic head (direction of arrow a ₁ ) and have high rigidity in the seek direction. Moreover, since the mounting portions 14 and 15 extending from the central portions of the leaf spring portions S2 and S3 on the upper side of the drawing are fixed to the spring arm 2, the core slider H exerts an external force in the rolling direction during the seek operation. Even if received, the leaf spring portions S1, S2, S3 are difficult to deform in the direction in which the rolling of the core slider H is allowed. Therefore, the core slider H includes the leaf springs S1, S2,
It is difficult to deform and roll S3, and the rolling of the core slider H is suppressed.

As a result, the left and right floating rails R1 and R2 of the core slider H are
Since the floating clearances are the same and the robot floats stably, there is little risk of head crash due to contact with the magnetic disk surface, and the gap between the recording / playback gap and the disk surface is always constant, and efficient and Stable recording / playback is possible.

〔Example〕

Next, practical examples of how the magnetic head assembly according to the present invention is embodied will be described. 2 to 5 are views showing various embodiments of the present invention.

FIG. 2 is an exploded perspective view showing the first embodiment of the present invention. Reference numeral 2 is a spring arm, 3 is a gimbal, and H is a core slider. The gimbal 3 has three leaf spring portions S1, S2, S3 long in the seek direction by forming slits l1, l2 in the seek direction in one thin plate material. Both end portions of each leaf spring portion S1, S2, S3 are integrally connected, and a step h is provided at the positions of the slits l1, l2 so that only the leaf spring portion S1 at the center has leaf spring portions S2, S3 on both sides. Slightly lower.

Attachment parts 14 and 15 to the spring arm 2 are integrally provided at the centers of the leaf spring parts S2 and S3 on both sides, and are fixed to the spring arm 2 by spot welding the X mark part to the spring arm 2. To be done. Then, the central portion of the middle leaf spring portion S1 is adhesively fixed to the rear surface central portion 8 of the core slider H. In the assembled state, the lower end of the dowel 7 abuts on the central portion 16 of the leaf spring S1 in the middle, and during the seek operation and the CSS operation, the core slider H flies stably with this abutting portion as a fulcrum.

FIG. 3 is a second embodiment of the gimbal and is a front view. This embodiment has three leaf spring parts S1, S2, S3 which are divided by two slits l1, l2 as shown in FIG. 2, in which steps are provided at both ends of the leaf spring parts S1, S2, S3. It is an example provided in. That is, in (a), the leaf spring part in the middle is
Both ends of S1 are bent downward to form a step h. Further, in (b), the step h is provided by bending both ends of the leaf spring portions S2, S3 on both sides to the upper side.

When the leaf springs S2, S3 on both sides are attached to the spring arm 2, the dowel 7 of the spring arm abuts the central portion of the leaf spring S1 in the middle, as shown by the broken line.

FIG. 4 is a third embodiment, (a) is a side view, (b).
Is a perspective view. The gimbal 3 is formed by bending a single thin plate material into a U-shape to provide a step h, and by providing a slit 1 in the seek direction at the bent portion, the leaf spring portion S1 is vertically provided.
S2 is formed. When viewed from the side, the lower leaf spring portion S1 and the upper leaf spring portion S2 are displaced to the left and right, the upper leaf spring portion S2 is attached to the spring arm 2, and the lower leaf spring portion S1 is When attached to the core slider H, the dowel 7 of the spring arm 2 comes into contact with the central portion 16 of the lower leaf spring portion S1.

FIG. 5 shows a fourth embodiment, in which a plurality of leaf spring parts S1, S
This is an example in which both ends of 2 and S3 are integrated by sandwiching spacers 17 and 18 as separate bodies. In this way, a plurality of leaf spring parts S1, S2,
By integrating both ends of S3, a slit 11 is formed between the leaf spring portions S1 and S2, and a slit 12 is formed between the leaf spring portions S1 and S3.

Mounting parts 14, 15 formed on the upper leaf spring parts S2, S3
Is attached to the spring arm 2 and the lower leaf spring portion S1 is attached to the core slider H, the state shown in FIG. 1 is obtained.

If the right side leaf spring portion S3 in this embodiment is omitted, it becomes the same as the embodiment of FIG.

In each of the above embodiments, the dowel 7 serving as the fulcrum of the core slider H is formed on the spring arm 2 side, but it may be formed upward on the leaf spring portion S1 of the gimbal 3.

〔The invention's effect〕

As described above, according to the present invention, the spring arm 2
In the magnetic head assembly perpendicular to the seek direction of the core slider H, a plurality of leaf spring portions S1, S2, S3 which are long in the seek direction of the core slider H are provided, and a portion of the leaf spring portion S2 is included. , S3 integrally attached to the spring arm 2 and attached to the core slider H. Therefore, even if the core slider H receives a force in the rolling direction during a seek operation, the leaf springs S1, S2, S3 of the gimbal have high rigidity in the seek direction, so that the core slider H cannot roll and the flying stability is high. Is improved. As a result, the core slider H
The gaps between the respective parts and the magnetic disk surface are constant, there is no risk of head crash due to contact with the magnetic disk surface, and the reproduction output is also constant, which is particularly effective in an apparatus having a small flying clearance.

The resonance frequency in the conventional magnetic head assembly is
Although it was about 3 kHz, the magnetic head assembly of the present invention is 8
It can be increased up to about 9 kHz, and the deviation from the resonance frequency of the magnetic disk device becomes large, so that the stable operation area of the seek operation is expanded.

[Brief description of drawings]

FIG. 1 is a front view and a right side view for explaining the basic principle of a magnetic head assembly according to the present invention, and FIGS. 2 to 5 are views showing various embodiments of the present invention. 6 to 8 are plan views showing a seek method of a magnetic head in a conventional magnetic disk device, and FIG.
FIG. 7 is a rotary type, and FIG. 8 is an in-line type. 9 and 10 are diagrams showing details of the in-line magnetic head assembly, and FIG. 11 is a diagram showing the rolling operation of the core slider in the in-line type magnetic head assembly. In the figure, D is a magnetic disk, H is a core slider, 1
Core, 2 spring arm, 3 gimbals, A is the rotation shaft, l1, l2 slit, S1, S2, S3 leaf spring portion, a ₁ seek direction of the magnetic head, a ₂ is the rotation of the magnetic disk The air flow generated by

Claims (1)

(57) [Claims] 1. A magnetic head assembly in which a core slider (H) of a magnetic head is attached to a spring arm (2) extending in a direction perpendicular to a seek direction of the magnetic head in a magnetic disk device via a gimbal. In the above, the gimbal is formed to be long in the seek direction of the magnetic head, both ends thereof are coupled to each other, are long in the seek direction, and have a plurality of leaf spring portions formed with steps, and the plurality of leaf spring portions of the plurality of leaf spring portions. And a mounting portion extending in the length direction of the spring arm from a central position of one leaf spring portion located on the spring arm side, the mounting portion being fixed to the spring arm, and the core slider ( A magnetic head assembly characterized in that the center position of the other leaf spring located on the (H) side is fixed to the back surface of the core slider (H).