JP3035136U - Magnetic head slider - Google Patents

Abstract

(57) [Summary] [PROBLEMS] The present invention can secure a stable flying height regardless of where the magnetic head moves to the inner circumference side or the outer circumference side of a magnetic disk, and is installed in a place with a large altitude difference. It is an object of the present invention to provide a magnetic head slider that can sufficiently stabilize the flying traveling stability even in the case of being present and can secure an appropriate flying height. A magnetic head slider according to the present invention comprises a magnetic head core in a plate-shaped slider body, and a plurality of positive pressure generating portions 11b and 11d are formed on a medium facing surface of the slider body on a magnetic disk side. Of the positive pressure generating portions 11b and 11d, which are provided on both side edge portions on the front side of the slider body 10.
The first positive pressure generating portion 11b of the pair is connected by the first connecting portion 12 to form the first negative pressure generating portion 16 on the rear side of the first connecting portion 12, and It is characterized in that the longitudinal direction of the positive pressure generating portion 11b and the direction parallel to the side surface of the slider body 10 form an angle θ.

Description

[Detailed description of the invention]

[0001]

[Technical field to which the invention belongs]

 The present invention relates to a magnetic head slider that floats on a magnetic recording medium at minute intervals to record and reproduce magnetic information, and more particularly to a magnetic head slider capable of stabilizing the flying characteristics.

[0002]

[Prior art]

 Conventionally, as a magnetic recording device for a computer, a magnetic disk device as shown in FIG. 7 is known. This magnetic disk device has a structure in which a magnetic head 2 is arranged oppositely on a disk-shaped magnetic disk 1 that is rotatably provided. The magnetic head 2 is supported by a support arm 4 via a triangular spring plate 3. The magnetic head 2 is supported and is configured so that the magnetic head 2 can be moved to a desired position in the diametrical direction of the magnetic disk 1 by a pivoting operation around the pivot center portion 4a of the support arm 4.

In the magnetic disk device having the configuration shown in FIG. 7, when the magnetic disk 1 is stopped, the bottom surface of the magnetic head 2 is lightly pressed against the magnetic disk 1 by the urging force of the spring plate 3 supporting the magnetic head 2. Therefore, when the magnetic disk 1 is rotated, the magnetic head 2 is configured to levitate on the magnetic disk 1 at a predetermined height by utilizing the air flow generated by the rotation. When the rotation of the disk 1 is stopped, the magnetic head 2 that has levitated and travels again contacts the magnetic disk 1 and is stopped. The magnetic information is read from and written to the magnetic recording layer of the magnetic disk 1 during the floating operation, and this series of operating conditions is usually called CSS (contact start stop).

FIG. 8 and FIG. 9 show a flying state of a two-rail type magnetic head 2 which is widely used at present. The bottom surface of the magnetic head 2 has a groove 5 at the center. The side rails 6, 6 are formed on both sides thereof, and an inclined surface 6a is formed on the lower end surface side of each side rail 6 (upstream side in the rotational direction of the magnetic disk 1). As shown by an arrow A in FIG. 8 through the air, the bottom surface of the side rail 6 of the magnetic head 2 serves as a positive pressure generating portion so that the magnetic head 2 floats. Further, as shown by the chain double-dashed line in FIG. 8, a negative pressure groove 6b is formed on the bottom surface of the side rail 2, and the negative pressure generated in the negative pressure groove 6b and the positive pressure generated in the side rails 6, 6 are formed. Also known is a configuration of a magnetic head that stabilizes the flying performance by balancing the spring pressure.

By the way, FIG. 8 shows the state in which the magnetic head 2 is viewed from the side surface side, and FIG. 9 shows the state in which the magnetic head 2 is viewed from the rear side side. Since air flows into the bottom surface side of the magnetic head 2 via 6a, the magnetic head 2 is levitating while tilting at a small angle with the air inflow side raised as shown in FIG. The angle is called a pitch angle (α: usually about 100 to 500 μRad). Further, as shown in FIG. 9, when the magnetic head 2 in the floating traveling state is viewed from the rear, the angle at which the magnetic head 2 tilts to the left and right is called a roll angle (β). On the other hand, when the magnetic head 2 is moved to the position shown by reference numeral 2'in FIG. 7 by the rotation of the support arm 4, the center line of the magnetic head 2 (the magnetic head 2 passes through the center of the magnetic head 2). Line a parallel to the side surface of the magnetic head 2 does not coincide with the tangent line b of the magnetic disk 2 passing through the center line portion of the magnetic head 2. However, the angular deviation in this case is called the skew angle (γ). ing. The pitch angle and roll angle are used as one measure of running stability.

In the magnetic head 2 having the above-mentioned configuration, it is more advantageous for the magnetic head 2 to be closer to the magnetic recording layer of the magnetic disk 1 in terms of magnetic recording. It is desirable to make the height of the magnetic head as low as possible, and it is necessary to prevent the magnetic head 2 from colliding with minute foreign matter such as dust on the magnetic disk 1 from the standpoint of stabilizing the flying performance and reliability. Therefore, there are contradictory requirements such that it is desirable to make the height during levitation as high as possible. At present, the levitation height is set by taking a compromise point of these contradictory requirements.

However, in the magnetic disk 1, the peripheral speed on the inner peripheral side is different from that on the outer peripheral side, and the amount of air flowing into the bottom of the magnetic head 2 is also different. The inner circumference side and the outer circumference side of the magnetic disk 1 are different. Moreover, since the skew angle γ of the magnetic head 2 is different between the inner circumference side and the outer circumference side of the magnetic disk 2 due to the rotation of the support arm 4, the positive pressure generated in the two side rails 6 of the magnetic head 2 is reduced. There is a problem in that the gap flying height of the magnetic head 2, the pitch angle α, and the roll angle β become unstable due to the different effects.

From the above background, even when the skew angle γ of the magnetic head 2 is changed, that is, when the magnetic head moves to any part on the inner circumference side or the outer circumference side of the magnetic disk, the pitch angle Although it is desired to develop a magnetic head that has a small effect on the roll angle and the roll angle and that can secure a stable flying height, in the conventional magnetic head 2 having two side rails 6, the skew can be reduced. The flying height, roll angle, and pitch angle are sensitive to changes in the angle.

Therefore, conventionally, in addition to the positive pressure generating portion mainly composed of side rails, a negative pressure generating portion is formed by forming a U-shaped rail portion or groove on the center side of the bottom surface of the magnetic head. A magnetic head is known that has a structure that attempts to stabilize the floating running state by skillfully balancing the negative pressure and the negative pressure. This type of magnetic head can be found in JP-A-6-44719, JP-A-6-124562, JP-A-6-195916, and JP-A-6-215516. However, even with the magnetic heads according to these patents, for example, when the atmospheric pressure at the location where the magnetic head is installed is low, that is, when the vehicle is used at a low pressure due to the effect of the altitude difference at the installation location, running stability is insufficient. Could occur.

[0010]

[Problems to be solved by the device]

 The present invention has been made in view of the above circumstances, and it is possible to secure a stable flying height regardless of where the magnetic head moves on the inner circumference side or the outer circumference side of the magnetic disk, and to install the head at a place with a large altitude difference. It is an object of the present invention to provide a magnetic head slider that can sufficiently stabilize the flying traveling stability even in the case of being exposed, and can secure an appropriate flying height.

[0011]

[Means for Solving the Problems]

 In order to solve the above-mentioned problems, a magnetic head slider of the present invention comprises a magnetic head core in a plate-shaped slider body, and a plurality of positive pressure generating parts on a medium facing surface of a slider body on a magnetic disk side, Of the positive pressure generating portions, a pair of first positive pressure generating portions provided on both side edges on the front side of the slider body are connected by a first connecting portion to the rear side of the first connecting portion. The first negative pressure generating section is formed, and the longitudinal direction of the first positive pressure generating section and the direction parallel to the side surface of the slider body have an angle. The plurality of positive pressure generating portions are a pair of first positive pressure generating portions provided on both side edge portions on the front side of the slider body, and a pair of first positive pressure generating portions provided on both side edge portions on the rear side of the slider body. And a second positive pressure generating section of the above. Then, the first positive pressure generating portion and the second positive pressure generating portion that are adjacent to each other along both side edge portions of the slider body may be connected by the second connecting portion. Further, the angle formed by the longitudinal direction of the first positive pressure generating portion and the direction parallel to the side surface of the slider body is preferably 5 to 60 degrees.

[0012]

[Embodiment of the invention]

 Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 and 2 show an embodiment of a magnetic head slider according to the present invention. The magnetic head slider of this example comprises a plate-shaped slider body 10 and a magnetic core 30 having a structure described later. . The parts other than the magnetic core 30 part of the slider body 10 are entirely composed of a substrate made of ceramics or the like, and are used similarly to the conventional magnetic head shown in FIG. The bottom surface (the upper surface in FIGS. 1 and 2 and the medium facing surface facing the magnetic disk) of the slider body 10 is located on both side edge portions thereof and extends from the front side to the rear side of the slider body 10. There are two side rails 11, 11. In this specification, the upper side of the slider body 10 in FIG. 1 is referred to as the front side of the slider body 10, and this front side is generally referred to as the leading side of the slider to which the air flow from the magnetic disk flows. On the contrary, the lower side of the slider body 10 in FIG. 1 is referred to as the rear side of the slider body 10, and this rear side is generally referred to as the trailing side of the slider, and the air flow from the magnetic disk is It is the side that is leaked.

In this embodiment, the two side rails 11 and 11 are formed in the same planar shape and are connected by the first connecting portion 12. The side rails 11, 11 may have different shapes. Each of the side rails 11 and 11 has an inclined surface 11a formed on the front side of the slider body 10 and a first positive pressure generation which extends continuously from the inclined surface 11a to the rear side to almost the center of the slider body 10. The portion 11b, the second positive pressure generating portion 11d located from the substantially central portion of the slider body 10 to the rear side, and the first positive pressure generating portion 11b and the second positive pressure generating portion 11d are connected to each other. It is composed of two connecting portions 11c. The side rails 11 and 11 are formed on the inner side of both side edges of the slider body 10, and a step portion 31 is formed on the lateral outer side of the side rail 11. Further, the rear ends of the side rails 11, 11 are formed inside the rear end edge of the slider body 10, and a step portion 32 is formed on the rear outer side of the side rail 11.

The inclined surface 11a is formed in a rectangular shape. The planar shape of the first positive pressure generating portion 11b is an extended line segment portion 13a formed by extending one side 13 of the two sides 13 and 14 of the inclined surface 11a parallel to the side surface of the slider body 10 to the rear side. Then, an oblique line segment 13b extending obliquely toward the rear side, a parallel line segment 13c extending parallel to the side surface of the slider body 10 to the rear side, and the other side of the inclined surface 11a. 14 extended to the rear side, an extended line segment 14a extending to the rear side in parallel to the diagonal line segment 13b, and a rear line parallel to the end surface of the slider body 10. It has a shape surrounded by the end segment 15.

Further, the second positive pressure generating portion 11d is formed on the rear side of the first positive pressure generating portion 11b via a groove portion 17 of equal width, and its planar shape is the first positive pressure generating portion 11d. An oblique line segment 18 parallel to the slanted line segment 14b of the generating part 11b, a straight line part 19 located on the extension of the parallel line segment 13c of the first positive pressure generating part 11b, and a first positive pressure The front end on the front side of the trapezoid, which is composed of the straight line portion 20 located on the extension of the extended line segment portion 14a of the generating portion 11b and the rear end line segment portion 21 parallel to the end surface of the slider body 10, is formed on the straight line portion 20. In contrast, it has a shape in which a notch 22 is formed by obliquely notching.

The pair of first positive pressure generating portions 11b, 11b formed on both side edges of the slider body 10 are connected to the first connecting portion 12 on the inner extended line segment portions 13a, 14a. The first negative pressure generating part 16 is formed on the rear side of the first connecting part 12. In this way, by making the front side (air inflow side) of the first negative pressure generating section 16 closed by the first connecting section 12, the negative pressure generated in the first negative pressure generating section 16 is generated. The pressure can be increased.

Further, in the present embodiment, the front end of the second positive pressure generating portion 11d and the first positive pressure generating portion 11b are connected by the rectangular second connecting portion 11c. . As described above, the groove portion 17 between the first positive pressure generating portion 11b and the second positive pressure generating portion 11d is closed by the second connecting portion 11c to generate the first negative pressure. The negative pressure generated in the portion 16 can be further increased. Further, between the first positive pressure generating portion 11b and the second positive pressure generating portion 11d which are adjacent to each other along the both side edges of the slider body 10, the second negative pressure generating portion 23 and the third negative pressure generating portion 23 are respectively provided. The pressure generator 24 is formed. Then, the groove portion 17 between the first positive pressure generating portion 11b and the second positive pressure generating portion 11d is closed by the second connecting portion 11c, so that the second connecting portion 11c Also, the negative pressure generated in the negative pressure generating portion on the air outflow side, that is, the second negative pressure generating portion 23 can be increased. It is also possible to adopt a configuration in which the second connecting portion 11c is not provided. In this case, although the floating stability due to the difference in altitude is slightly deteriorated, the degree of freedom in design is increased.

Here, in this specification, an apex A at which the parallel line segment 13c and the rear end line segment 15 of the first positive pressure generating portion 11b intersect with each other in the plan view of the magnetic head slider, and this vertex A Is defined as a longitudinal direction of the first positive pressure generating portion 11b and the second positive pressure generating portion 11d. The magnetic head slider of this embodiment is arranged and used so that the apex A is located closer to the outer peripheral side of the magnetic disk than the apex B. When the angle θ formed by the longitudinal direction of the first and second positive pressure generating portions 11b and 11d and the direction parallel to the side surface of the slider body 10 is changed, the flying height with respect to the skew angle γ is likely to change. As a result, the flying height when the magnetic head is located on the inner circumference side of the magnetic disk and the flying height when the magnetic head is located on the outer circumference side can be accurately adjusted. For example, as shown in FIG. 3, as the angle θ is increased, the flying height on the outer peripheral side is decreased and the flying height on the inner peripheral side is increased, that is, from the state shown by the broken line in FIG. 3 to the solid line. It can be changed to a state. This angle θ is preferably in the range of 5 to 60 degrees, more preferably 5 to 30 degrees. If it is smaller than this, the flying height on the outer peripheral side becomes too high, which is not preferable, and if it is larger than this, it is on the outer peripheral side. It is not preferable because the flying height becomes too low. The angle θ is appropriately set according to the setting or specifications of the skew angle γ in the magnetic disk device.

Further, by changing the length C in the direction parallel to the side surface of the slider body 10 from the front end of the inclined surface 11a to the rear end of the first positive pressure generating portion 11b, the magnetic head is It is possible to change the flying height when the magnetic disk is located at the center in the circumferential direction. For example, as shown in FIG. 4, the shorter the length C, the lower the flying height at the center, that is, the state shown by the broken line in FIG. 4 can be changed to the state shown by the solid line. Also, by changing the length D in the direction parallel to the side surface of the slider body 10 from the front end of the inclined surface 11a to the second connecting portion 11c, the magnetic head is positioned at the central portion in the circumferential direction of the magnetic disk. The flying height can be changed. For example, as shown in FIG. 4, the shorter the length D, the lower the flying height at the center, that is, the state shown by the broken line in FIG. 4 can be changed to the state shown by the solid line. Furthermore, the pitch angle α of the magnetic head can be adjusted by changing the length E of the first connecting portion 12 in the width direction of the slider body 10. For example, the pitch angle α decreases as the length E of the connecting portion 12 increases.

Next, the structure of the magnetic core 30 formed on the outer peripheral side on the rear end side of the slider body 10 will be described. The magnetic core 30 shown in this example is a composite type magnetic head core whose sectional structure is shown in FIG. 5 and FIG. 6, and the MR head (reading head) h1 and , And an inductive head (writing head) h2 are sequentially laminated.

The MR head h1 detects a magnetic flux leaked from a recording medium such as a disk by utilizing a magnetoresistive effect and reads a magnetic signal. As shown in FIGS. 5 and 6, the MR head h1 has a structure in which alumina (Al _{2 is formed} on the lower shield layer 53 made of a magnetic alloy such as sendust (Fe-Al-Si) formed at the rear end of the slider body 10. A lower gap layer 54 made of a non-magnetic material such as O ₃ ) is provided, and a magnetoresistive effect material film 55 is laminated on the lower gap layer 54. On both sides of the giant magnetoresistive material film 55, a hard bias layer for applying a bias magnetic field to the film, an electrode layer for applying a detection current, and the like are formed, and an upper gap layer is formed on the hard bias layer. An upper shield layer is formed on the upper part of the upper shield layer, and the upper shield layer is also used as the lower core layer 45 of the inductive head h2 provided thereon.

In the inductive head h 2, the gap layer 44 is formed on the lower core layer 45, and the coil layer 46 patterned so as to have a planar spiral shape is formed on the gap layer 44. Are surrounded by an insulating material layer 47. The upper core layer 48 formed on the insulating material layer 47 has its tip portion 48a opposed to the lower core layer 45 at the ABS surface 51b with a minute gap, and its base end portion 48b to the lower core layer 45. It is magnetically connected. A protective layer 49 made of alumina or the like is provided on the upper core layer 48.

In the inductive head h2, the recording current is applied to the coil layer 46, and the recording magnetic field is applied from the coil layer 46 to the core layer. Then, a magnetic signal can be recorded on a magnetic recording medium such as a magnetic disk by a leakage magnetic field from the tips of the lower core layer 45 and the upper core layer 48 at the magnetic gap G. Further, in the MR head h1, the electric resistance of the magnetoresistive material film 55 changes depending on the presence or absence of a minute leakage magnetic field from the magnetic disk. Therefore, the recorded contents of the magnetic disk can be read by reading this resistance change. it can.

In the magnetic head slider 10 constructed as described above, the magnetic head slider 10 floats above the magnetic disk 1 by CSS as in the conventional magnetic head 2 shown in FIG. Write and read information. Therefore, when the magnetic disk 1 is stopped, the magnetic head slider is stopped while the bottom surface of the side rail 11 is lightly pressed against the surface of the magnetic disk 1 by the urging force of the spring plate 3.

When the magnetic disk 1 starts to rotate from this state, an air flow is generated on the surface of the magnetic disk, and this air flow flows into the bottom surface side of the slider body 10 via the inclined surfaces 11 a of the slider body 10 and 11 a. Become. Here, since the lift force is generated on the inclined surfaces 11a, 11a due to the generation of this air flow, when the lift force becomes large enough to overcome the urging force of the spring plate 3, the slider body 10 starts to fly. Further, the air that has passed through the inclined surfaces 11 a and 11 a and has flowed into the bottom surface side of the slider body 10 and the air that has passed through the first connecting portion 12 between the inclined surfaces 11 a and 11 a are transferred to the first negative pressure generating portion 16. Inflow, a large negative pressure is generated there, and the slider body 10 tilts at a predetermined pitch angle α with the tilted surface 11a side being lifted up like the magnetic head 2 shown in FIG.

Further, a part of the air that has passed through the inclined surfaces 11a and 11a flows along the side rails 11 to generate positive pressure in the first positive pressure generating section 11b and the second positive pressure generating section 11d. However, the air that has passed through the inclined surfaces 11 a, 11 a and has flowed into the second negative pressure generation unit 23 also generates negative pressure in the second negative pressure generation unit 23. Further, the air that has passed through the inclined surfaces 11a and 11a and has flowed into the third negative pressure generation unit 24 also generates negative pressure in the third negative pressure generation unit 24. Here, when negative pressure is generated at the three places of the first negative pressure generating unit 16 and the second negative pressure generating unit 23 and the third negative pressure generating unit 24 located on both sides of the first negative pressure generating unit 16, the slider main body 10 is negatively affected. Since there are three positions where pressure is applied and a force for attracting the slider body 10 to the magnetic disk 1 side is generated at three locations, the slider body 10 can be attracted to the magnetic disk 1 side with a well-balanced attraction force. Further, in particular, since the air inlet side of the first negative pressure generating portion 16 is closed by the first connecting portion 12, a strong negative pressure is generated in the first negative pressure generating portion 16, so that the slider body is The central portion of 10 can be attracted to the magnetic disk side 1 with a strong attraction force. Therefore, the flying stability of the slider body 10 can be improved.

Next, step portions 31 and 32 are formed on both side edge portions and the rear edge portion of the slider body 10, but these step portions 31 and 32 are formed on the slider body 10 for some reason. When the roll angle β becomes large, the edge of the slider body 10 on the side closer to the magnetic disk 1 is prevented from coming into contact with the magnetic disk 1. Further, when the slider main body 1 completes the levitation traveling, since the flying height is sufficiently secured, the probability that the rear end of the slider main body 10 contacts the magnetic disk 1 by the roll ring is low. At the time when the slider body 10 starts to fly, the flying height is small. Therefore, if a large rolling occurs at this time, the magnetic disk 1 may come into contact with the trailing edges of the slider body 10. By providing it, this problem can be reduced. Further, by providing the step portions 31 and 32, it is possible to prevent the side rail 11 from being cut due to an error in cutting the magnetic head slider.

Further, according to the magnetic head slider of the present embodiment, the angle θ formed by the longitudinal direction of the first and second positive pressure generating portions 11b and 11d and the direction parallel to the side surface of the slider body 10 is adjusted. By doing so, it is possible to control the flying height when the magnetic head is located on the inner peripheral side of the magnetic disk and the flying height when the magnetic head is located on the outer peripheral side. Also, adjust the length C from the front end of the inclined surface 11a to the rear end of the first positive pressure generating portion 11b, or the length D from the front end of the inclined surface 11a to the second connecting portion 11c. This makes it possible to control the flying height when the magnetic head is located at the circumferential center of the magnetic disk. In this way, the profile of the flying characteristics can be controlled by the structural parameters of the head slider, so that the flying amount of the slider can be stabilized according to any running condition. Further, since the air inflow side of the first negative pressure generating section 16 is closed by the first connecting section 12, a strong negative pressure is generated in this first negative pressure generating section 16 and a strong suction force is obtained. . As a result, it is possible to reduce the influence of the altitude difference of the installation location on the flying height, and thus it is possible to prevent the flying height of the head slider from decreasing when the magnetic head is installed at a high altitude location. Further, the pitch angle α of the magnetic head can be controlled by adjusting the length E of the first connecting portion 12 in the width direction of the slider body 10.

[0029]

[Effect of the invention]

 As described above, the magnetic head slider of the present invention comprises a magnetic head core in a plate-shaped slider body, and a plurality of positive pressure generating portions on the magnetic disk side medium facing surface of the slider body. A pair of first positive pressure generating parts provided on both side edges of the pressure generating part on the front side of the slider body are connected by a first connecting part, and a pair of first positive pressure generating parts are provided on the rear side of the first connecting part. One negative pressure generating portion is formed, and the longitudinal direction of the first positive pressure generating portion and the direction parallel to the side surface of the slider body form an angle. Therefore, a large negative pressure can be obtained in the first negative pressure generating section, so that even when the magnetic head is installed in a place with a large altitude difference, an appropriate flying height can be secured and a stable traveling state can be obtained. be able to. Further, since the flying characteristic profile of the head slider can be controlled by adjusting the angle formed by the first positive pressure generating portion and the direction parallel to the side surface of the slider body, the flying characteristic profile of the head slider can be controlled on the inner or outer peripheral side of the magnetic disk. Stabilizes the flying height of the slider body by suppressing changes in the flying height due to different peripheral speeds of the magnetic disk, a slight difference in the amount of air flowing into the bottom of the slider body, and changes in the skew angle. Thus, it is possible to provide a magnetic head slider that can be made stable and can stabilize the flying state.

In the above-mentioned structure, the plurality of positive pressure generating portions are provided with a pair of first positive pressure generating portions provided on both side edge portions on the front side of the slider body and both side edge portions on the rear side of the slider body. If it is configured to include a pair of second positive pressure generating portions provided in, the control of the flying height becomes easy. Further, if the first positive pressure generating portion and the second positive pressure generating portion that are adjacent to each other along both side edges of the slider body are connected by the second connecting portion, respectively, the negative pressure becomes large. , The influence of the altitude difference can be reduced. Further, if the angle formed by the longitudinal direction of the first positive pressure generating portion and the direction parallel to the side surface of the slider body is 5 to 60 degrees, the flying height can be made constant from the inner circumference to the outer circumference. it can.

[Brief description of the drawings]

FIG. 1 is a bottom view of an example of a magnetic head slider according to the present invention.

FIG. 2 is a perspective view showing the shape of the bottom side of an example of a magnetic head slider according to the present invention.

FIG. 3 is a graph showing an example of flying height control in a magnetic head slider according to the present invention.

FIG. 4 is a graph showing an example of controlling the flying height of the magnetic head slider according to the present invention.

FIG. 5 is a sectional view showing an example of a magnetic core portion provided in a magnetic head slider according to the present invention.

FIG. 6 is a partial cross-sectional view showing an example of a magnetic core portion provided in a magnetic head slider according to the present invention.

FIG. 7 is a diagram showing an arrangement relationship between a general magnetic head and a magnetic disk.

FIG. 8 is a side view showing an example of a conventional magnetic head in a flying state.

FIG. 9 is a rear view showing an example of a conventional magnetic head in a flying state.

[Explanation of symbols]

 10 Slider body 11 Side rail 11b First positive pressure generating portion 11c Second connecting portion 11d Second positive pressure generating portion 12 First connecting portion 30 Magnetic core

Claims (4)

[Utility model registration claims] 1. A magnetic head core is provided in a plate-shaped slider body, and a plurality of positive pressure generating portions are provided on a medium facing surface of the slider body on the magnetic disk side. A pair of firsts provided on both side edges
The positive pressure generating part of the first connecting part is connected by the first connecting part.
The first negative pressure generating portion is formed on the rear side of the connecting portion of
The magnetic head slider is characterized in that the longitudinal direction of the first positive pressure generating portion and the direction parallel to the side surface of the slider body form an angle. 2. A plurality of positive pressure generating portions are provided on a pair of first positive pressure generating portions provided on both side edge portions on the front side of the slider body and on both side edge portions on the rear side of the slider body. Provided 1
2. The magnetic head slider according to claim 1, comprising a pair of second positive pressure generating portions. 3. The first positive pressure generating portion and the second positive pressure generating portion which are adjacent to each other along both side edge portions of the slider body are connected by a second connecting portion, respectively. Item 2. The magnetic head slider according to Item 2. 4. The angle between the longitudinal direction of the first positive pressure generating portion and the direction parallel to the side surface of the slider body is 5 to 60 degrees. The magnetic head slider described.