JPH0430378A - Supporting device for magnetic head slider - Google Patents

Abstract

PURPOSE:To highly secure the stability of the floating position of a magnetic head slider by forming a pivot or a pivot bearing on a vertical line to pass through the centroid of the magnetic head slider precisely without an error. CONSTITUTION:When a magnetic head slider 7 is pushed up against gimbals 13 by floating force F1 upward by an air flow generated by the high speed rotation of a hard disk 1, a pivot 11 is engaged in a pivot bearing 12 and a center P1 of the pivot 11 and the pivot bearing 12 is positioned surely on a vertical line P2 to pass through centroid G of the magnetic head slider 7. As a result, distance l3 between one end 3a which is the fixed end of a loading beam 3 and the centroid G of the magnetic head slider 7 is set precisely as a design value. Then, a spring load F2 precise as the design value set by the above mentioned distance l3 of the loading beam 3 can be added to the centroid G of the magnetic head slider 7 through the pivot bearing 12 and the pivot 11 precisely without an error.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a magnetic head slider support device that is most suitable for application to hard disk drives.

[Summary of the invention]

The invention is based on a magnetic head slider support device in which one end of the magnetic head slider is fixed to the head moving member and a gimbal is attached to the other end of the TFC load beam. By integrally forming the pivot.

The 5GC is applied so that the bouncing load of the load beam can be applied correctly to the center of gravity of the magnetic head slider, thereby ensuring the stability of the flying posture of the magnetic head slider.

[Prior Art] As a conventional example of a support device for a magnetic head slider in a hard disk drive, there is an invention described in, for example, Japanese Unexamined Patent Publication No. 55-22296.

As shown in the sixth factor, this conventional example
It has a head moving member 2 configured to be movable in the direction,
At one end 3a of the load beam 3, which is configured by a plate spring and has nth-order elasticity, the head moving member 2 is attached to a screw 4 with a full reparation rate.
The upper piece 5a of the gimbal 5, which has a substantially U-shaped cross section, is fixed to the lower surface of the other end 6b of the load beam 6 by spot welding 6. 5b, a magnetic helide slider 7 is adhered to the gimbal 5 with an adhesive 8, and a pivot 9 integrally formed on the lower piece 5b of the gimbal 5 is brought into contact with the lower surface of the upper piece 5a of the gimbal 5. It is. The gimbal 5 is composed of a leaf spring that is thinner than the load dome 6.
The load beam has a 6L higher elastic modulus.

In this conventional example, by rotating the hard disk 1 at high speed, an air flow generated on the surface of the hard disk 10 generates an upward floating blade F on the magnetic head slider 7, and the magnetic head slider 7 is moved to the load beam 3.
The pivot 9 of the lower piece 5b of the gimbal 5 is brought into contact with the lower surface of the upper piece 5a by pushing up against the gimbal 5. On the other hand, the downward spring load F2 of the load beam 6 is transmitted to the magnetic head slider 7 through the entire pivot 9.

The magnetic head slider 7 is levitated from the disk 1 with a flying height H on the order of submicrons by the balancing action of the flying blade Fl and the spring load F2.

Then, while maintaining this floating state, the magnetic head slider 7 is moved approximately in the radial direction of the hard disk 1 (in the direction a) by the head moving member 2, thereby recording and/or reproducing the hard disk 1. In row 5, the magnetic head slider 7 is caused to roll and pinch around the pivot 9, following changes in the surface of the hard disk 1.

[Problems to be solved by Development 8A] However, in the conventional example, since the pivot 9 was entirely formed on the gimbal 5 interposed between the load beam 3 and the magnetic head slider 7, there were the following problems. this.

That is, in order to improve the recording and reproducing performance of the hard disk 1 and to enable high-density recording, it is important to stabilize the flying posture of the rad slider 7 and to reduce the flying height H. And for that.

The center Pl of the pivot 9 is the center of gravity G of the magnetic head slider 7.
It is necessary to position it strictly on the vertical line P2 passing through.

However, in the conventional example, the lower part 5bK of the gimbal 5 is completely formed with the pivot 9, and the magnetic head slider 7 is adhered to the lower surface of the lower part 5bD with the adhesive 8. The center P of the magnetic head slider 7 was likely to be misaligned by 1□ with respect to the vertical line P2 passing through the center of gravity G of the magnetic head slider 7. As a result, the spring load F2 of the load beam 3 transmitted to the magnetic head slider 7 via the pivot 9 is applied to a position shifted from the center of gravity G of the magnetic head slider 7. Tilt in the roll direction and pitch direction was likely to occur. Also,
An error occurs between the value of the spring load (2) actually applied to the magnetic head slider 7 and the designed value, and variations in the float of the S-air head slider 7 are likely to occur.

Further, in the conventional example, since the upper piece 5a of the gimbal 5 having the pivot 9 is spot welded 6 to the other end 6b of the load beam 5, the load beam 5 One end 6a which is the fixed end of
9 and 11F-#zlC variations are likely to occur,
The spring load F2 itself applied to the magnetic head slider 7 also varies.

Variations in the flying height of the magnetic head slider 7 were likely to occur.

The present invention allows the bouncing load of the load beam to be accurately directed to the center of gravity of the magnetic head slider.') KL71B
The object of the present invention is to provide a support device for an air head slider.

[Means for Solving the Problems] In order to achieve the above objects, claim 1 of the magnetic head slider support device of the present invention provides gimbal mounting of the magnetic head slider on a vertical line passing through the center of gravity of the magnetic head slider. A pivot is integrally formed on the surface, and the pivot is configured to abut against a load beam.

According to a second aspect of the present invention, the pivot is configured to fit into a pivot receiver integrally formed with the load beam.

According to a third aspect of the present invention, a pivot receiver is integrally provided on the gimbal mounting surface of the magnetic head slider on a vertical line passing through the center of gravity of the magnetic head slider, and the pivot receiver is mounted on a vertical line passing through the center of gravity of the magnetic head slider.
It is configured to fit into a pivot formed integrally with the frame.

[For production]

Claims 1 and 6 of the magnetic head slider support device configured as described above are characterized in that the pivot or the pivot receiver is integrally formed on the gimbal mounting surface of the magnetic head slider.
This allows the pivot or pivot holder to be accurately formed on a vertical line passing through the center of gravity of the magnetic slider without any error. Therefore.

The spring load of the load beam can be properly aligned to the center of gravity of the magnetic head slider via the pivot.

According to claims 2 and 6, since the magnetic head slider is fitted into a pivot or a pivot integrally formed on the magnetic head slider and a pivot receiver or a pivot formed integrally on the load beam, the identified end of the load beam and the magnetic head slider are fitted. The distance between the center of gravity can be set accurately.

[Embodiment] Hereinafter, an embodiment in which the present invention is applied to a support device for a magnetic head slider in a hard disk drive will be described with reference to FIGS. 1 and 29. Note that the same structural parts as in the conventional example shown in FIG. 3 are designated by the same reference numerals, and repeated explanation will be omitted.

FIG. 1 shows the first embodiment, in which a vertical line F2 passing through the center of gravity G of the magnetic head slider 7 has a small convex shaped upward pivot on the gimbal mounting 67a of the magnetic head slider 7. 11 are integrally formed. Note that this pivot 17 can be easily formed by a normal powder beam etching method. 1fc, an upwardly directed pivot receiver 12 in the shape of a small recess is integrally formed on the lower surface 6c of the other end 6b of the load beam 6. Note that the gimbal 16 used here has a substantially Z-shaped cross section in which the upper piece 13a and the lower piece 16b are diagonally connected by the intermediate piece 13c, and the upper piece i3a and the lower piece 13b are connected diagonally by an intermediate piece 13c. are fixed to the lower surface 3c of the load beam 6 and the gimbal mounting surface 7a of the magnetic slider 7 by adhesive or the like. At this time, the pivot 11 is fitted and positioned in the non-positioning hole 14 provided in the upper piece 13a%, and with the pivot 11 fitted in the pivot receiver 12, the upper piece 13a and the lower piece 13b are connected. is fixed to the load beam 6 and the magnetic head slider 7 by adhesive or the like. Note that 7b is a magnetic head of the magnetic head slider 7.

According to this first embodiment, when the magnetic head slider 7 is pushed up against the gimbal 16 by the upward floating blade F caused by the entire airflow generated by the high-speed rotation of the hard disk 1, the pivot 11 is moved into the pivot receiver 12. Fitting=n
Therefore, the upper middle PI of the pivot 11 and the pivot receiver 12 are not accurately positioned on the vertical line F2 tracing back the weight L and G of the magnetic head slider 7.

As a result, the distance [i] between the fixed end 3a of the load beam 5 and the center of gravity G of the magnetic head slider 7 is set accurately as the designed value. and.

An accurate spring load F2 according to the design value set by the distance stone 3 of the load beam 3 is applied to the center of gravity G\C of the magnetic head slider 7 via the pivot receiver 12 and the pivot 11.
It can be added accurately without any errors.

Therefore, it is possible to prevent the magnetic heel slider 7 from tilting in the roll direction or pitch direction, thereby ensuring a high degree of stability in the flying posture of the magnetic head slider 7, and also making it possible to prevent the magnetic head slider 7 from tilting in the roll direction or pitch direction.
1 and the spring load F2 can be balanced as designed.
The flying height H' (17) can be reduced to the submicron order and the stability of the flying height can be ensured.In addition, since the pivot 11 can be accurately set on the vertical a P 2 passing through the center of gravity G, the magnetic The head slider 7 can perform roll motion and pinch motion in the smoothest manner, and is useful during transient responses due to external forces and the like.

Next, FIG. 2 shows a second embodiment.

Vertical a )' 2 passing through the center of gravity G of the magnetic head slider 7
Above, a downward pivot receiver 12Th having a small concave shape is integrally formed on the gimbal mounting surface 7a of the magnetic head slider 7,
A downward pivot 12 in the shape of a small convex portion is integrally formed on the lower surface 6c of the other end 6b of the load beam 6.

The structure is such that the pivot receiver 12 is fitted into the pivot 11 when the magnetic head slider 7 is pushed up against the gimbal 13 by the square floating blade FIK generated by the high-speed rotation of the hard disk 1. This is what I did.

Therefore, this second embodiment provides the same functions and effects as those of the first embodiment described above.

Although the non-inventive implementation VIJ has been described above, the present invention is not limited to the above-mentioned embodiments (and various effective changes can be made based on the technical considerations of the present invention).

Furthermore, the present invention is not limited to a support device for a magnetic head slider of a disk device, but is also applicable to a support device for a magnetic head slider of various disk devices that record and/or reproduce various disk-shaped recording media. It is applicable to

〔Effect of the invention〕

Since the present invention is configured as described above, it produces the effects described below.

MX items 1 and 3 are to form the pivot or the pivot holder integrally with the gimbal mounting surface of the magnetic head slider so that the pivot or the pivot holder can be formed accurately without error on a vertical line passing through the center of gravity of the magnetic head slider. Since the spring RN of the load beam can be properly bent to the center of gravity of the τ magnetic head slider via the pivot, the magnetic head slider in the flying state is tilted in the roll direction and the pitch direction. This can be prevented and the stability of the flying posture of the magnetic head slider can be highly ensured. Since there is almost no error between the load beam bounce load actually applied to the magnetic head slider and the design value, there is no variation in the flying height of the magnetic head slider, and the flying height can be reduced. Quantification becomes possible.

Since the pivot can be accurately set on a vertical line passing through the center of gravity of the magnetic head slider, the magnetic head slider can perform roll and pinch movements in the smoothest manner, which is advantageous when responding to transients caused by external forces or the like.

Claims 2 and 6 provide a connection between the fixed end of the load beam and the magnetic head slider by fitting the pivot or pivot receiver integrally formed on the magnetic head slider into the pivot receiver or pivot integrally formed on the load beam. Since the distance between the center of gravity and the center of gravity can be set accurately, the load beam spring 8 added to the magnetic head slider
It is possible to realize N at the design value. Therefore, the flying height of the magnetic head slider can be reduced to the submicron order, and the stability of the flying height can be ensured.

[Brief explanation of drawings]

FIG. 1 and FIG. 2 show an embodiment of the present invention, and FIG. 1 shows the l! of the first embodiment. FIG. 2 is a cross-sectional side view of the second embodiment. FIG. 6 shows a cross-sectional side layer of a conventional example. Also, in the symbols used in the drawings. 2...Head moving member 5...
...Load beam 3a...One end of load beam 6b...
......Other end of load beam 7...Magnetic head slider 7a...Jimpal mounting surface 11...Pivot 12... ...Pivot receiver 16...Gimbal Fl...Floating blade F2...Spring load H...Floating Quantity G... Center P of the magnetic head slider... Center P2 of the pivot... Vertical edge.

Claims (3)

[Claims] (1) In a magnetic head slider support device in which one end of a load beam is fixed to a head moving member and a magnetic head slider is attached to the other end of the load beam via a gimbal, a vertical line passing through the center of gravity of the magnetic head slider is provided. 1. A support device for a magnetic head slider, characterized in that a pivot is integrally formed on a gimbal mounting surface of the magnetic head slider on a line, and the pivot is brought into contact with the load beam. (2) A support device for a magnetic head slider, characterized in that the pivot is configured to fit into a pivot receiver integrally formed with the load beam. (3) In a magnetic head slider support device in which one end of a load beam is fixed to the head moving member and a magnetic head slider is attached to the other end of the load beam with a gimbal, the center of gravity of the magnetic head slider passes through the support device. A magnetic head slider characterized in that a pivot holder is integrally provided on a gimbal mounting surface of the magnetic head slider on a vertical line, and the pivot holder is configured to fit into a pivot formed integrally with the load beam. Support device.