JPH05325463A - Floating type magnetic head device - Google Patents

Abstract

PURPOSE:To reduce wear caused by sliding of a disk of a slider, and to improve a contact start/stop characteristic by forming a shape of the slider so that an area of the air bearing surface of an air inflow side of an air inflow groove becomes larger than that of air outflow side. CONSTITUTION:A slider 1 is supported by a suspension 2, and attached to an actuator 3. The slider 1 comes into contact with a magnetic disk 3 at the time of actuation, but floats up by receiving an air flow caused by a rotation of the disk 4, and records and reproduced information at a minute gap from the surface of the disk 4. On the principal surface of the slider 1, rail working is performed and a grooved part 5 being an air inflow groove is formed, and on both sides of the grooved part 5, slider rails 6, 7 are protruded and formed. On air bearing surfaces 6a, 7a of the rails 6, 7, a groove part 9 is provided. Length of the surfaces 6a, 7a, width of the grooved part 9, and a distance extending from an end part of an air outflow end side to the center of the grooved part 9 of the surfaces 6a, 7a are denoted as (a), (b) and (c), respectively, so as to become 0.05a<=b<=2.5a, and 0.1a<=c<=0.35a.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floating magnetic head device used for a hard disk drive device,
In particular, the present invention relates to a contact start / stop type flying magnetic head device that records or reproduces information with a minute gap on the surface of a magnetic disk and contacts the surface of the magnetic disk when starting or stopping.

[0002]

2. Description of the Related Art In a hard disk drive device for recording or reproducing information on a hard disk or the like, in order to avoid wear and damage due to contact between the magnetic head and the surface of the magnetic disk, the magnetic head contacts the magnetic disk at the time of starting and stopping, A so-called contact start / stop type flying magnetic head device is used, which is constructed such that the air flow generated on the surface of a magnetic disk that rotates at a high speed during recording / reproducing of information causes the magnetic head to fly above the magnetic disk with a minute gap. ing.

In the above contact start / stop type flying magnetic head device, an air inflow groove is formed on the surface facing the magnetic disk, and slider rails are formed on both sides of the air inflow groove to form an air bearing surface. The slider part and the magnetic head part for recording / reproducing information are integrally formed, and a support is attached to the slider part. Therefore, when the rotation of the magnetic disk is stopped, the magnetic head formed integrally with the slider contacts the surface of the magnetic disk, and when the magnetic disk rotates,
The air bearing generated by the rotation of the air bearing
The magnetic head, which is received on the surface and integrally formed with the slider, floats and moves on the surface of the magnetic disk by the support to record / reproduce information on / from a predetermined recording track.

[0004]

As described above, in the contact start / stop type flying magnetic head device, the slider is in contact with the surface of the magnetic disk at the time of starting and stopping, and immediately after the starting operation or the stopping operation. Immediately after that, the slider slides on the surface of the magnetic disk. At this time, since the slider surface and the magnetic disk surface are very smooth surfaces, adhesion easily occurs between the both surfaces, the slider surface and the magnetic disk surface are worn, the product life is shortened, and it is caused by sliding. The amount of wear adheres to the surface of the slider, which lowers the flying performance of the slider.

Therefore, the surface of the magnetic disk is textured to provide a certain degree of roughness (usually, the height of the protrusion is about several tens of nm) to suppress the contact area between the slider and the magnetic disk, thereby preventing the above phenomenon. However, in recent years, along with the demand for high-density recording, there is an increasing demand for improvement in contact start / stop characteristics and product life. In order to achieve high-density recording, it is desirable to minimize the distance between the magnetic head and the magnetic disk, that is, the flying distance, and it is less desirable to provide a texture on the surface of the magnetic disk more than at present. Therefore, it has become difficult to rely only on the texture of the magnetic disk surface as a method of preventing abrasion between the slider surface and the magnetic disk surface in order to meet the demands for improvement in contact start / stop characteristics and product life.

Therefore, the present invention has been proposed in view of such a conventional situation, and reduces wear due to sliding of a slider on a magnetic disk to reduce contact start / start.
It is an object of the present invention to provide a floating magnetic head device which improves the stop characteristics and improves the product life of the magnetic head, slider and magnetic disk.

[0007]

In order to achieve the above-mentioned object, the inventors of the present invention have made extensive studies, and as a result, in the slider of the flying type magnetic head device, in the slider of the air inflow groove, the slider By making the area of the bearing surface larger than that on the air outflow end side,
We have found that it is possible to shorten the sliding time of the slider on the magnetic disk when the system is stopped.

That is, in the levitation type magnetic head device of the present invention, the levitation type magnetic head device is provided with slider heads formed on both sides of an air inflow groove formed on the surface of the slider facing the hard disk. In the magnetic head device, a groove portion that is orthogonal to the air inflow direction of the air inflow groove and divides the slider rail is provided in the air bearing surface of the slider rail, and the length of the air bearing surface is a, When the width of the groove is b and the distance from the air outflow end of the air bearing surface to the center of the groove is c,
0.05a ≦ b ≦ 0.25a, 0.1a ≦ c ≦ 0.35
It is characterized by being a.

Further, in the flying type magnetic head device of the present invention, the flying type in which the magnetic head elements are provided on the slider rails protrudingly formed on both sides of the air inflow groove formed on the surface of the slider facing the hard disk. In the magnetic head device, the slider rail has a large air bearing surface width portion on the air inflow end side of the air inflow groove, and an air bearing surface on the air outflow end side via the air bearing surface width changing portion. It is a shape having a small surface width portion, the length of the air bearing surface of the slider rail is a, the width of the air bearing surface wide portion is d, the width of the air bearing surface small portion is f, When the length of the air bearing surface small width part is g and the length of the air bearing surface width changing part is e, 0 5d ≦ f ≦ 0.85d, 0.15a
It is characterized in that ≦ e ≦ 0.35a and 0.3a ≦ g ≦ 0.8a.

Further, in the flying type magnetic head device of the present invention, the flying type magnetic head element is provided on slider rails projecting on both sides of the air inflow groove formed on the surface of the slider facing the hard disk. In the magnetic head device, the width of the air bearing surface of the slider rail is gradually narrowed from the air inflow end side of the air inflow groove toward the air outflow end side. Where h is the width and i is the width of the air bearing surface on the air outflow end side, 0.3h ≦ i ≦ 0.7h.

[0011]

In the contact start / stop type flying magnetic head device, air inflow grooves are formed on the surface facing the magnetic disk, and slider rails are formed on both sides of the air inflow grooves to form air bearing surfaces. The slider part and the magnetic head part for recording / reproducing information are integrally formed, and a support is attached to the slider part.

Therefore, in the flying magnetic head device as described above, the slider is in contact with the surface of the magnetic disk when the rotation of the magnetic disk is stopped. After sliding on the disk, the airflow generated by the rotation of the magnetic disk is received by the air bearing surface of the slider, the slider levitates, and it moves on the magnetic disk surface by the support body and is integrated with the slider on a predetermined recording track. Recording and reproduction of information is performed by a magnetic head that is configured as a unit. When the slider slides on the magnetic disk, the relative speed between the magnetic disk and the slider gradually increases as the number of rotations of the magnetic disk increases, and the airflow generated by the rotation of the magnetic disk is sufficiently generated. When the velocity is reached, the slider receives the air flow and levitates. Therefore, the sliding time of the slider on the magnetic disk can be shortened by suppressing the relative speed between the magnetic disk and the slider when the slider is flying.

Further, at the time of stop, the air flow supporting the slider decreases as the rotation speed of the magnetic disk decreases, and the slider descends and contacts the magnetic disk, slides on the magnetic disk for a while, and then stops. Therefore, the sliding time of the slider on the magnetic disk can be shortened by suppressing the relative speed of the slider and the magnetic disk when the slider contacts the magnetic disk.

In the flying type magnetic head device of the present invention, the area of the air bearing surface on the air inflow end side of the slider is larger than that on the air outflow end side, and the air flow due to the rotation of the magnetic disk is moved to the air of the slider. Since it is easy to receive on the inflow end side, it is easy to get on the air flow, and at the time of startup, the slider is levitated and stopped without increasing the relative speed between the magnetic disk and the slider that increases with the increase in the rotation speed of the magnetic disk. Even at times
Since the slider easily rides on the air flow, the airborne time of the slider can be extended even if the air flow supporting the slider decreases as the rotation speed of the magnetic disk decreases, and the relative speed between the magnetic disk and slider can be increased. The slider can be brought into contact with the magnetic disk after being sufficiently reduced, and the sliding time of the slider on the magnetic disk can be shortened.

[0015]

EXAMPLES Specific examples to which the present invention is applied will be described below. First, FIG. 1 shows the configuration of a floating magnetic head device. As shown in FIG. 1, the slider 1 is attached to the suspension 2 and the actuator 3. Although the slider 1 is in contact with the magnetic disk 4 at the time of start-up, it receives the airflow generated by the rotation of the magnetic disk 4 in the direction R ₁ in FIG. Recording and reproduction are performed, and when the recording is stopped, the recording medium is lowered onto the magnetic disk 4. Further, when the magnetic disk 4 rotates in the R ₁ direction in the figure, the actuator 3 rotates in the R ₂ direction in the figure and moves the slider 1 attached to the suspension 2 on the surface of the magnetic disk 4 as indicated by an arrow M. .

Next, FIG. 2 shows an enlarged view of the slider 1. As shown in FIG. 2, rail processing is performed on one main surface of the slider 1 to form a groove portion 5 which is an air inflow groove,
Slider rails 6 and 7 are formed as ridges on both sides of the groove 5. Further, the magnetic head 8 has an air bearing surface 6a whose magnetic gap is a surface of one slider rail 6 facing the magnetic disk 4.
It is provided to face. Therefore, immediately after the start operation or the stop operation, the surface of the magnetic disk 4 and the air bearing surfaces 6a, 7a of the slider rails 6, 7 of the slider 1 are in a state of sliding.

At this time, in the flying type magnetic head device of this embodiment, as shown in FIG. 2, the air bearing surface 6 of the slider rails 6, 7 of the slider 1 is as shown in FIG.
Grooves 9 that divide the slider rails 6 and 7 are provided in a and 7a at right angles to the air inflow direction of the groove 5.
As shown in FIG. 3, the groove 9 has a length a of the air bearing surfaces 6a and 7a, a width b of the groove 9 and an end of the air bearing surfaces 6a and 7a on the air outflow end side. When the distance from the center of the groove 9 to c is
0.05a ≦ b ≦ 0.25a, 0.1a ≦ c ≦ 0.35
It is provided so that it becomes a.

Further, in the flying type magnetic head device of the present embodiment, the slider rail has the large air bearing surface width portion on the air inflow end side of the air inflow groove, and the air bearing surface width changing portion. It may be a shape having an air bearing surface narrow portion on the air outflow end side through. For example, as shown in FIG.
4, the length of the air bearing surfaces 10a, 11a of the slider rails 10, 11 is a, the width of the air bearing surfaces 10a, 11a on the air inflow end side is d, and the air on the air outflow end side is d. When the width of the narrow portion of the bearing surface 10a, 11a is f, the length of the narrow portion of the air bearing surface 10a, 11a is g, and the length of the varying width portion of the air bearing surface 10a, 11a is e. , 0.5d ≦ f ≦ 0.85d, 0.15
It is provided so that a ≦ e ≦ 0.35a and 0.3a ≦ g ≦ 0.8a. At this time, when a mini slider is used as the slider, a is 3.66 m
m and d are about 0.5 mm, and when a micro slider is used, a is 2.29 mm and d is 0.32.
The value is about mm.

Further, in the floating magnetic head device of this embodiment, the width of the slider rail may be gradually narrowed from the air inflow end side of the air inflow groove toward the air outflow end side. For example, as shown in FIG. 5, in the slider 15, the lengths of the air bearing surfaces 12a and 13a of the slider rails 12 and 13 are a,
The width of the air bearing surfaces 12a, 13a on the air inflow end side of the slider rails 12, 13 is h, and the air bearing surfaces 12a, 13a on the air outflow end side.
When the width of i is i, 0.3h ≦ i ≦ 0.7h. At this time, when a mini slider is used as the slider, a is 3.
66 mm and h have a value of about 0.5 mm, and when a micro slider is used, a has a value of 2.29 mm and h has a value of about 0.32 mm.

In the levitation type magnetic head device of this embodiment, since the area of the air bearing surface on the air inflow end side of the slider is larger than that on the air outflow end side, the air flow due to the rotation of the magnetic disk is reduced by the slider. It is easy to catch the air flow at the air inflow end side of the slider, and at the time of startup, the slider is levitated without increasing the relative speed between the magnetic disk and the slider that increases with the increase in the rotational speed of the magnetic disk. Since the slider easily rides on the airflow even when stopped, the airborne time of the slider can be extended even if the airflow supporting the slider is reduced as the rotational speed of the magnetic disk is reduced. It is possible to bring the sliders into contact with the magnetic disk after sufficiently reducing the relative speed between the sliders. It is possible to shorten the sliding time of the slider of the magnetic disk.

[0021]

As is apparent from the above description, in the floating magnetic head device of the present invention, the slider rails formed on both sides of the air inflow groove formed on the surface of the slider facing the hard disk are formed. In a floating magnetic head device provided with a magnetic head element, a groove portion that is orthogonal to the air inflow direction of the air inflow groove and divides the slider rail is provided on the air bearing surface of the slider rail. ·bearing·
When the surface length is a, the width of the groove is b, and the distance from the end of the slider rail on the air outflow end side to the center of the groove is c, 0.05a ≦ b ≦ 0.25a, 0.1a ≦
provided such that c ≦ 0.35a, or
The slider rail has a large air bearing surface width part on the air inflow end side of the air inflow groove and a small air bearing surface width part on the air outflow end side via the air bearing surface width change part. Is a shape that has
The length of the air bearing surface of the slider rail is a, the width of the wide portion of the air bearing surface is d, the width of the narrow portion of the air bearing surface is f, and the length of the narrow portion of the air bearing surface. G, air
When the length of the bearing / surface width change part is e,
0.5d ≦ f ≦ 0.85d, 0.15a ≦ e ≦ 0.35
a, 0.3a ≦ g ≦ 0.8a, and further, the width of the air bearing surface of the slider rail extends from the air inflow end side of the air inflow groove toward the air outflow end side. Where h is the width of the air bearing surface on the air inflow end side and i is the width of the air bearing surface on the air outflow end side, 0.3h ≤ i ≤ 0.7h It is easy to catch the air flow due to the rotation of the magnetic disk on the air inflow end side of the slider because it is installed so that it is easy to catch the air flow, and it increases with the increase in the rotation speed of the magnetic disk at the time of startup. The slider is levitated without increasing the relative speed between the magnetic disk and the slider so much that the slider easily rides on the air flow even when stopped.
Even if the air flow supporting the slider decreases as the number of rotations of the magnetic disk decreases, the airborne time of the slider can be extended, and after the relative speed between the magnetic disk and the slider is sufficiently decreased, the slider is moved to the magnetic disk. Can be brought into contact with the magnetic disk, the sliding time of the slider on the magnetic disk can be shortened, the contact start / stop durability of the magnetic head, slider and magnetic disk can be improved, and the magnetic head, slider and magnetic disk can be improved. The product life of the disc can be improved.

[Brief description of drawings]

FIG. 1 is a schematic perspective view of a main part showing a configuration of a floating magnetic head device.

FIG. 2 is a perspective view showing a slider of a flying magnetic head device according to an embodiment of the present invention.

FIG. 3 is a plan view showing a slider of an embodiment of a flying magnetic head device to which the present invention is applied.

FIG. 4 is a plan view showing a slider of another embodiment of a floating magnetic head device to which the present invention is applied.

FIG. 5 is a plan view showing a slider of still another embodiment of the floating magnetic head device to which the present invention is applied.

[Explanation of symbols]

1 ... Slider 5 ... Groove 6, 7, 10, 11, 12, 13, ... Slider rails 6a, 7a, 10a, 11a, 12a, 13a ... Air bearing surface 8 ... Magnetic head 9 ... Groove

Claims (3)

[Claims] 1. A flying-type magnetic head device comprising magnetic head elements provided on slider rails projecting on both sides of an air inflow groove formed on a surface of a slider facing a hard disk. The bearing surface is provided with a groove portion that is orthogonal to the air inflow direction of the air inflow groove and divides the slider rail. The length of the air bearing surface is a, the width of the groove portion is b, and the air bearing When the distance from the end of the surface on the air outflow end side to the center of the groove is c, 0.05a ≦ b ≦ 0.
25a, 0.1a ≦ c ≦ 0.35a, a floating magnetic head device. 2. A flying-type magnetic head device comprising magnetic head elements provided on slider rails projecting on both sides of an air inflow groove formed on a surface of a slider facing a hard disk, wherein the slider rail is an air A shape having an air bearing surface large width portion on the air inflow end side of the inflow groove and an air bearing surface small width portion on the air outflow end side via the air bearing surface width changing portion, The length of the air bearing surface of the slider rail is a, the width of the wide portion of the air bearing surface is d, the width of the narrow portion of the air bearing surface is f,
When the length of the air bearing surface narrow portion is g and the length of the air bearing surface width changing portion is e, 0.5d ≦ f ≦ 0.85d, 0.15a ≦ e ≦ 0.
35a, 0.3a ≦ g ≦ 0.8a, a floating magnetic head device. 3. A flying-type magnetic head device comprising magnetic head elements provided on slider rails projecting on both sides of an air inflow groove formed on the surface of the slider facing the hard disk, wherein the slider rail air The width of the bearing surface is gradually narrowed from the air inflow end side of the air inflow groove toward the air outflow end side. The width of the air bearing surface on the air inflow end side is h, and the air on the air outflow end side is・
When the width of the bearing surface is i, 0.3h ≤
A flying type magnetic head device characterized in that i ≦ 0.7h.