DE4001225C2 - Magnetic head - Google Patents

Description

The invention relates to a magnetic head with a Steuerab cut to create a vacuum, which in one piece the surface of the magnetic head is formed to a Magnetic plate indicates what makes a good head touch is aimed.  

In particular, the invention relates to a magnetic head according to the preamble of the An saying 1.

Such a magnetic head is known from JP 61-5413 (A), differing from the inventions magnetic head according to JP 61-5413 (A) of the control section in the form of groove portions provided in the magnetic head is formed.

JP 63-96704 (A) describes a magnetic head arrangement in which in addition to and space Lich a control section is provided separately from the magnetic head, which a pull-in hen causes the magnetic plate to the magnetic gap.

DE 27 09 290 C2 also shows a magnetic head arrangement in which a control section also in addition to the completely symmetrical magnetic head is seen.  

If in a recording and reproducing device, wel a thin, flexible magnetic disk as the recording medium used, the magnetic head is simply caused with the Ma magnetic plate tends to come into contact, to be deformed and out by the pressure of the magnetic head the magnetic head come out, and a stable contact will be not achieved.

An attempt has already been made in which one Stabilizing plate in the vicinity of the magnetic head seen which creates a vacuum in the area in which the magnetic head is located to the magnetic disk to the Magnet head side to attract, creating a stable contact is achieved.

Fig. 17 is a schematic view showing the construction of the prior art magnetic disk recording and reproducing device, and Fig. 18 is a schematic perspective view showing part of the device. In these figures, a center core attached to the center of the magnetic plate 13 is detachably attached to a drive shaft 12 of a drive motor 11 to rotate the magnetic plate 13 , and the magnetic plate 13 is rotated by the rotation of the drive motor 11 at a predetermined rotation speed turned.

Under the magnetic disk 13 shown in the figures, a magnetic head 15 is arranged, which is capable of contacting the recording surface of the magnetic disk during the recording and reproducing process. The magnetic head 15 is fixed to a carriage 17 which is engaged with a threaded shaft 16 arranged along the radial direction of the magnetic plate 13 , and by rotating the threaded shaft 16 by a drive unit (not shown), the magnetic head becomes in the radial direction of the magnetic plate 13 moved to scan the recording area.

As shown in Fig. 19, which is a schematic enlarged view of the magnetic head 15 , the magnetic head 15 has a head holder 21 attached to the carriage 17 and a head chip 22 which is located at the end (located at the top in the figure) of the Head bracket 21 is fixed and has a magnetic gap 24 on a counter surface 23 which is opposite to the magnetic plate 13 , and the magnetic plate 13 comes into sliding contact with the magnetic gap 24 of the head chip 22 to perform recording and playback.

So far, the counter surface 23 with the magnetic gap 24 is formed in a smoothly curved surface which protrudes toward the side of the magnetic disk 13 along the direction of rotation (arrow R) and the radial direction of the magnetic disk 13 in order to prevent damage to the recording surface of the magnetic disk 13 and to get good head contact.

Furthermore, as shown in Fig. 20, below the magnetic plate 13, a pair of stabilizing plates 19 are provided with inclined surfaces 18 , one end of which is located in the vicinity of a free rotating surface N on the upstream side with respect to the direction of rotation (arrow R) of the magnetic plate 13 and is inclined so that the distance of the inclined surfaces from the free rotating surface N gradually increases in the direction of rotation in the direction of rotation, with a gap 20 as a displacement of the magnetic head 15th

In this way, the stabilizing plates 19 create a negative pressure in the area between the magnetic plate 13 and the inclined surfaces 18 of the stabilizing plates 19, when the magnetic disk 13 rotates, whereby the negative pressure, the magnetic plate 13 to the side of the magnetic head 15 toward attracts, to cause, that the magnetic plate 13 contacts the magnetic gap 24 of the head chip 22 of the magnetic head 15 . As a result, the magnetic disk 13 always maintains a stable contact state with the magnetic head 15 in the recording and reproducing operation.

Such stabilizing plates for generating negative pressure are described in detail, for example, in Japanese Japanese Patent Laid-Open No. 61-9868 / 1986 Patent Laid-Open No. 60-219671 / 1985 and japani Patent Laid-Open No. 62-33380 / 1987.

In this description, the free rotating surface N refers to a rotating surface of the magnetic disk 13 which is attached to the drive motor 11 of the magnetic disk recording and reproducing device and rotates without the effect of external forces other than the rotating driving force.

With the stabilizing plates 19 of a type as shown in FIG. 20, a gap 20 is formed for the magnetic head 15 and the carriage 17 for displacing the magnetic head 15 between the two stabilizing plates 19 . However, since the negative pressure is generated by the stabilizing plates 19 mainly in the area between the inclined surfaces 18 formed on the stabilizing plates 19 and the magnetic plate 13 , the gap 20 is not involved in generating negative pressure, but tends to reduce the negative pressure generated .

Therefore, the above structure is defective in that the magnetic plate 13 is attracted to the inclined surfaces of the two stabilizing plates 19 , which are located on both sides of the magnetic head 15 , but tends to float up at the gap 20 where the magnet 15 is arranged , which leads to insufficient contact of the magnetic plate 13 on the magnetic head 15 .

In addition, since the magnetic head 15 and the stabilizing plates 19 are provided separately, it requires a very complicated effort to position the magnetic head 15 and the stabilizing plates 19 precisely, which can lead to an increase in costs.

With a view to eliminating problems with magnetic heads according to the prior art is the main object of the invention the creation of a magnetic head,  which has a simpler structure and can therefore be manufactured more cost-effectively can, but at the same time the advantageous pulling of the magnetic plate to the magnetic gap guaranteed.

This object is achieved by the magnetic head according to the invention with the features of Claim 1 solved. Advantageous developments of the invention result from the dependent claims related to claim 1.  

The one on the opposite surface of the magnet head-formed control section against the magnetic disk creates a negative pressure between the magnetic plate and the Control section when the magnetic disk rotates, and the Un The pressure pulls the magnetic plate to the side of the magnetic head to cause the magnetic disk to be attached to the the magnetic gap formed comes into sliding contact, which gives good head contact.

The control section may be an inclined surface, so ge tends to be in the direction of rotation of the magnetic disk to the downstream side from the free rotating surface of the magnet plate further away, and the inclination of the inclined surface right relative to the free rotating surface of the magnetic disk can be longitudinal the direction of rotation of the magnetic plate can be changed. Further can the control section with a groove along the direction of rotation tion of the magnetic disk to be provided to the generation of Un to increase the pressure and align the air flow.

For a better understanding of the invention, an example shows a magnetic head with a head neck and a head chip attached to the head holder, which has a head chip that is capable of is to come in contact with the magnetic disk one with the headgear formed control section for generating a negative pressure between the control section and the magnetic disk to the Pull the magnetic plate towards the side of the head chip.

In this way, when the magnetic disk rotates, the on control section formed a negative pressure between the control section and the magnetic disk to the Magnetic plate towards the side of the head chip, and causes the magnetic disk with the head chip in sliding con tact comes, which makes good head contact.

In the following the invention with reference to one in the drawing shown embodiment described in more detail. In the Show drawing:

Figure 1 is a schematic perspective view of an embodiment of the magnetic head according to the inven tion.

Fig. 2 is a schematic sectional view taken along line 2-2 in Fig. 1;

Fig. 3 is a schematic perspective view of an embodiment of the magnetic head of the invention;

Fig. 4 is a schematic sectional view taken along 4-4 in Fig. 3;

Fig. 5 is a schematic plan view of an at the other embodiment of the magnetic head according to the invention;

Fig. 6 is a schematic perspective view of an embodiment of the magnetic head of the invention;

Fig. 7 is a schematic sectional view taken along line 7-7 in Fig. 6;

Fig. 8 is a schematic side sectional view of another embodiment of the magnetic head according to the invention;

Fig. 9 is a schematic perspective view of an embodiment of the magnetic head of the invention;

. Fig. 10 and 11 schematic sectional views taken along line 10- 10 and 11-11;

... Figure 12, Figures 13 and 14 are schematic sectional views showing examples of control members;

. Fig. 15 and 16 are schematic perspective views of a better understanding serving Examples of other magnetic heads;

Fig. 17 is a schematic side view of a recording and reproducing device according to the prior art;

Fig. 18 is a schematic perspective view of part of the recording and reproducing apparatus shown in Fig. 17;

Fig. 19 is a schematic side view of a magnetic head according to the prior art; and

Fig. 20 is a schematic sectional view of a recording and reproducing device according to the prior art.

Since in the preferred Aus described with reference to the figures the mounting position and the mounting structure of the magnetic head according to the invention in the recording and Playback device are the same as in the prior art Technology, are the corresponding terms with the same loading marks, and their description becomes transitional gene.

In Fig. 1, which shows this embodiment, is an end surface 31 of a head holder 21 with projecting stop Eglie countries 32 provided to clamp and a head chip 22 to fix it integral with the head holder 21, and the head chip 22 is integrally formed on the retaining members 22 attached. A counter surface 33 , which comes into sliding contact with the recording surface of a magnetic disk 13 , is formed at the front end of the head chip 22 , which is opposite to the recording surface of the magnetic disk 13 .

Near the center of the counter surface 33 , a plurality (two in this embodiment) of magnetic gaps 34 are formed, which come almost along the radial direction of the magnetic disc 13 in sliding contact with the recording surface of the magnetic disc 13 for mediation (transmission and recording) To make information. As shown in Fig. 2, which is a schematic sectional view taken along the line 2-2 in Fig. 1, the counter surface 33 is formed as an inclined surface 35 which is inclined so that it extends further from the free rotating surface N of the magnetic disk 13 removed in the direction of the downstream side in the direction of rotation (arrow R) of the magnetic plate 13 .

When the magnetic disk 13 rotates, is thus 13 generates a negative pressure between the inclined surface 35 of the head chip 22 and the magnetic disk, said magnetic disk attracts 22 through 13 to the side of the head chip, and causes the magnetic disk 13 with the magnetic gap 34 comes into sliding contact which is provided at the end of the head chip 22 , whereby a good head contact is achieved.

Furthermore, an end portion 36 of the head chip 22 , which is located on the upstream side of the magnetic plate 13 with respect to its direction of rotation, is made of a harder material than the head chip 22 , for example of sapphire, in order to ver abrasion due to sliding on the magnetic plate 13 avoid.

In Fig. 3, which shows another embodiment, a plurality of magnetic gaps 34 (two in this embodiment) are provided on the counter surface of the head chip 22 , which are opposite to the magnetic plate 13 approximately along the radial direction thereof. At the mating surfaces, the side at the upstream side or the downstream of the magnetic gaps 34 are located with respect to the direction of rotation of the magnetic disk 13, an inclined surface 41 and an oblique surface 42 are provided. As shown in Fig. 4, which is a sectional view taken along line 4-4 in Fig. 3, these inclined surfaces 41 and 42 are formed so that their distance from the free rotating surface N of the magnetic disk 13 in the direction of rotation of the magnetic disk to it Downstream (arrow R) increases, and the angle of inclination θ _{2 of} the inclined surface 42 to the free rotation surface N is greater than the inclination angle θ _{1 of} the inclined surface 41 to the free rotation surface N.

Preferably, the inclination angles θ ₁ and θ _{2 are,} for example, θ ₁ = 1 ° to 3 °, while θ ₂ = 2 ° to 6 °, a value which is approximately twice the value of θ ₁ . In FIG. 5, which is a schematic plan view of the head chip 22 shown in FIG. 3, the size of the counter surface of the head chip 22 , which is opposite to the magnetic plate 13 , is preferably at least l ₁ = 1.2 mm and l ₂ = 2 mm, where l _{1 is} the length of a side which is approximately perpendicular to the direction of rotation (arrow R) of the magnetic plate 13 , and l _{2 is} the length of a side along the direction of rotation.

When the magnetic plate 13 rotates, therefore, a negative pressure is generated in the area which is surrounded by the magnetic plate 13 and the inclined surfaces 41 and 42 , which attracts the magnetic plate 13 to the head chip 22 in order to come into contact with it in Gleitkon. However, since the angle of inclination of the inclined surface 42 , which is located on the downstream side with respect to the direction of rotation of the magnetic plate 13 , is greater than the inclination angle of the inclined surface 41 , which is located on the upstream side, the magnetic plate 13 is on the downstream side of the magnetic gap 34 by one greater negative pressure attracted. Consequently, the magnetic plate 13 is attracted while being deformed on both sides of the magnetic gap 34 , whereby the contact of the magnetic plate 13 with the magnetic gap 34 is improved ver.

In this embodiment, a plurality of grooves 43 (three in this embodiment), which are formed approximately along the direction of rotation of the magnetic plate 13 over both inclined surfaces 41 and 42 , are arranged approximately along the radial direction of the magnetic plate 13 . The grooves 43 are formed continuously from the upstream end of the inclined surface 41 to the downstream end of the inclined surface 42 and have an almost arcuate cross section, so that the depth at the upstream end and at the downstream end is zero.

The grooves 43 absorb air flow in a nearly radial direction other than that in the direction of rotation (circumferential direction), which is mainly generated by the rotation of the magnetic disk 13 , and cause the air flow to flow along the direction of rotation, thereby controlling the air flow in an almost radial direction , which hinders the generation of negative pressure. Since the grooves 43 can expand in the area between the magnetic plate 13 and the head chip 22 , they can additionally increase the negative pressure generated in the area. Furthermore, the grooves 43 also have an effect of stabilizing the air flow (formation of a laminar flow) in the rotational direction of the magnetic plate 13 , whereby the head contact of the magnetic plate 13 is further improved.

In FIG. 6, which is a schematic perspective view of another embodiment, and Fig. 7, which is a schematic sectional view taken along line 7-7 in FIG. 6, the magnetic disk 13 opposite mating surface of the head chip 22 on the downstream side of the magnetic gap 34 with respect to the direction of rotation (arrow R) of the magnetic plate 13 is a flat surface 44 with a tilt angle of zero, that is, it is parallel to the free rotating surface N of the magnetic plate 13 . At the downstream of the magnetic gap with respect to the direction of rotation of the magnetic plate 13 front end of the head chip 22 , a gently inclined curved surface 45 is provided, which is designed so that it gradually in the direction of rotation of the magnetic plate 13 to its downstream side further from the free rotary surface N of the magnetic plate 13 removed.

The inclined curved surface 45 has a plurality of grooves 46 (two in this embodiment) which are formed approximately along the direction of rotation of the magnetic plate 13 and are arranged on both sides of the magnetic gap 34 approximately along the direction of rotation of the magnetic plate 13 . The grooves 46 , which have zero depths at the upstream end of the inclined curved surface 45 and predetermined depths at the downstream end of the inclined curved surface 45 , communicate with the downstream region of the head chip 22 . The grooves 46 preferably have a maximum depth of 50 μm. In this embodiment, the free surface of revolution N is the magnetic disk 13 parallel planar surface 44 formed on the opposite surface of the head chip 22 which is opposite to the magnetic disk. 13 Alternatively, however, an inclined curved surface 47 may be formed, for example, as shown in FIG. 8, over the entire counter surface, which is gradually inclined so as to face the downstream side with respect to the direction of rotation of the magnetic disk 13 from the free Rotation surface N further away.

In this case, in which the distance between the magnet gap 34 , which is located near the center of the inclined curved surface 47 , and the free rotating surface is N h ₁ and the distance between the downstream end of the inclined curved surface 47 and the free Rotational area N h ₂ is preferably set, for example, h ₁ = 0 to 100 microns and h ₂ = 200 microns, or, as shown by the chain line in the figure, the position of the inclined ge curved surface 47 is parallel to 100 to Moved 200 microns to the side of the free rotating surface N to position part of the surface 47 or the entire surface 47 above (in the Fi gur) of the free rotating surface N.

In this way, when the magnetic disk 13 rotates, a negative pressure is generated in the area between the magnetic disk 13 and the inclined curved surface 45 or 47 , which attracts the magnetic disk 13 toward the front end of the head chip 22 to cause the magnetic disk 13 comes in sliding contact with the magnetic gap 34 , and the groove 46 receives the air flow in the almost radial direction of the magnetic plate 13 in order to increase the negative pressure, and regulates the total air flow which arises in connection with the rotation of the magnetic plate 13 , such that it is a laminar flow, thereby achieving a stable head contact.

In the above-described embodiments, the inclined surfaces 41 and 42 or the flat surface 44 and the inclined curved surface 45 are individually formed on the upstream and downstream sides of the magnetic gap 34 . The position of the magnetic gap 34 can, however, be pushed ver from the boundary of the inclined surface 41 and the inclined surface 42 or from the boundary of the flat surface 44 and the inclined curved surface 45 . Or it can be a larger number (three or more) of inclined surfaces with different angles of inclination to the free rotating surface N of the magnetic plate 13 may be formed on the opposite surface of the head chip 22 , which the magnetic plate 13 along the direction of rotation opposite. In this manner, the angle of inclination of the inclined surface to the free surface of revolution N 13 can be varied 13 the direction of rotation of the magnetic disk of the magnetic disk along.

Furthermore, the shapes and positions and numbers of the grooves 43 and 46 are not limited to those of the embodiments, but it is only necessary that these grooves are formed on the counter surface of the head chip 22 which is opposite to the magnetic plate 13 along its direction of rotation.

An example of the magnetic head 15 manufactured for use in a recording and reproducing apparatus for a two-inch video floppy disk uses a head chip which is almost the same as the head chip 22 shown in FIG. 6. The head chip 22 has a cross section of about 2 mm ² , the inclined curved surface 45 is formed on the part of about 3/4 of the area on the downstream side of the head chip 22 , the two magnetic gaps 34 are ge with a distance of about 100 µm and are arranged near the center of the front end of the head chip 22 . In search, it has been confirmed that this magnetic head achieves very good head contact.

Fig. 9 is a schematic perspective view of another embodiment of the inventive magnetic head, and FIG. 10 is a schematic sectional view of the head chip 22 along the line 10-10 in Fig. 9, that is, along the direction of rotation (arrow R) of the magnetic plate 13. In FIGS. 9 and 10 is a counter surface 48 of the head chip 22 which is opposite to the magnetic plate 13 is inclined, for example with a radius of curvature r _1, to extend from the free surface of revolution N of the magnetic disk 13 along its direction of rotation gradually descend further remove. On the other hand, as shown in FIG. 11, which is a schematic sectional view of the head chip 22 along the line 11-11, that is, along the radial direction of the magnetic disk 13 , the counter surface 48 of the head chip 22 is inclined with a radius of curvature r ₂ , for example that the magnetic gap 34 is at the upper end.

Therefore, the counter surface 48 of the head chip 22 is an almost spherical curved surface with the magnetic gap 34 at the upper end, and if r ₁ and r _{2 are set} almost the same, their radius of curvature can be about 50 to 150 mm, for example. Alternatively, however, r ₁ and r ₂ can be defined differently, so that the cross-sectional edge of the head chip 22 is straight along the radial direction of the magnetic plate 13 , that is to say r ₂ = ∞. In this way, the head chip 22 which is opposite to the magnetic disk 13, a control section on the counter surface 48 is formed which creates a negative pressure between the control section and the magnetic disk 13 during rapid rotation of the magnetic disk 13 in order these to attract. Further, grooves, as previously described with reference to FIG. 3 and FIG. 6, on the opposite surface 48 along the direction of rotation be formed of the magnetic disk 13 to regulate the flow of air and promoting the generation of negative pressure.

The head chip 22 , which is provided with the control section for generating negative pressure, can have such dimensions, as shown in FIG. 9, in which l _{1 is} at least 1.2 mm and l _{2 is} at least approximately 1.2 mm, where l _{2 is} the length of a side along the direction of rotation of the magnetic plate 13 and l _{1 is} the length of a side perpendicular to the direction of rotation.

Thus, in the magnetic head 15 according to the invention, the control section, which has the same function as the stabilizing plate, is provided in one piece on the counter surface of the very small head chips 22 opposite the magnetic plate 13 in order to ensure head contact, thereby making very efficient use of the recording surface Magnetic plate 13 is made possible. For example, if the above-described 2 mm ² head chip 22 is applied to a two-inch video floppy disk, the floppy disk has a diameter of approximately 23.5 mm, which is reduced by a central hub diameter of approximately 9 mm , 2 mm for the head chip 22 and a tolerance of 1 mm (a total of 2 mm for the diameter) at the periphery of the floppy disk, the floppy disk has an effective diameter of 10.5 mm, which is the formation of about 105 tracks.

Since the use of the magnetic head 15 according to the invention eliminates the need for the provided for generating negative pressure Sta bilisierplatte 19 separately from the magnetic head, the positioning of the individual magnetic head 15 and the stabilizing plate required in the prior art systems can be eliminated, making it very simplified Operations in manufacturing are made possible.

In order to improve the head contact of the magnetic head 15 even further, it is also possible to combine the magnetic head 15 with an additional control element. In an example of such a construction, as shown in FIG. 12, a control member 49 for generating overpressure is on the opposite side of the head chip 22 of the magnetic head 15 according to the invention with respect to the free rotating surface N of the magnetic plate 13 and on the upstream side of the direction of rotation (arrow R) the magnetic plate 13 is arranged. When the magnetic plate 13 rotates, an overpressure is generated between the control member 49 and the magnetic plate 13 , which pushes the magnetic plate 13 toward the side of the magnetic head 15 , whereby the effect of the above-described various types of control sections for generating negative pressure applied to the Head chip 22 are formed at the end of the magnetic head 15 , is further improved.

In another example, as shown in FIG. 13, a control member 50 is arranged on the same side as the magnetic head 15 with respect to the free rotating surface N of the magnetic disk 13 and on the upstream side of the magnetic head 15 with respect to the direction of rotation of the magnetic disk 13 . In linkage with the rotation of the magnetic disk 13, a negative pressure between the control member 50 and the magnet plate 13 is generated to the magnetic disk 13 hen anzuzie toward the side of the magnetic head 15, whereby the effect of the various above-described types of control members for generating negative pressure, which are formed on the head chip 22 at the end of the magnetic head 15 is further improved.

Alternatively, as shown in FIG. 14, the control member 49 shown in FIG. 12 for generating excess pressure can be designed as a leaf spring 51 . In this case, an overpressure between the magnetic plate 13 and the leaf spring 51 , it generates to press the magnetic plate 13 to the side of the magnetic head 15 , and at the same time the magnetic plate 13 is also pressed to the side of the magnetic head 15 by the pressing force the leaf spring 51 . Therefore, the end of the Blattfe of 51 on the side of the magnetic plate 13 , which can come into contact with this, is provided with a pad 52 to protect the magnetic plate 13 against damage. The previously described control members 49 and 50 and the leaf spring 51 are not absolutely necessary.

In Fig. 15, which is a schematic perspective view of a better understanding example, an annular control member 61 surrounding the head chip 22 is integrally formed with the head holder 21 on a front surface 31 of the head holder 21 . When the magnetic plate 13 rotates, this control member 61 creates a negative pressure in the area between a groove 62 , which is formed by the inner peripheral surface of the annular control member 61 and the front surface 31 of the head holder 21 , and the magnetic plate 13 to the side of the head chip 22 attract and act to be that it comes into sliding contact with the magnetic gap 34 of a sliding surface 33 , whereby a stable head contact is achieved. In addition, an inclined surface may be provided which is shaped so as to be spaced from the standstill magnetic disk 13 toward the inner periphery of a front surface 63 of the control member 61 , thereby varying the magnitude of the negative pressure generated.

The magnetic head 15 , which is provided with the head holder 21 , the head chip 22 and the control member 61 , can be attached to the carriage 17 or the like as in the case of systems according to the prior art and can be displaced on the receiving surface of the magnetic disk 13 by moving the slide 17 . With the control member 61 for generating vacuum, which is arranged in the vicinity of the head chip 22 , the generation of vacuum by other control members with the same effect, which are positioned further away from the head chip 22 , can be improved, thereby improving head contact is achieved, and the head chip 22 and the control member 34 can both be positioned exactly before on the head holder 21 , where the positioning work with improved positioning accuracy compared to the positioning adjustment of the individual members is considerably reduced.

In Fig. 16, which is a schematic view of another example for better understanding of the invention, instead of the annular control member 61 used in the above embodiment, a control member 65 is provided projecting on the front surface 31 of the head bracket 21 , which inclined surfaces 64 has, which are individually ausgebil det on the opposite side of the magnetic plate 13 in the current side and the downstream side of the head chip 22 with respect to the direction of rotation (arrow R) of the magnetic plate 13 . These inclined surfaces 64 are shaped so that their stand from the recording surface of the magnetic disk 13 in the direction of rotation of the magnetic disk 13 to the downstream side increases. When the magnetic disk 13 rotates, a negative pressure between the inclined surfaces 64 and the magnetic disk 13 will he attests to attract to the side of the head chip 22 towards them and to cause them to come into sliding contact with the magnetic gap 34 che of Gleitflä 33rd

In the examples shown in FIGS. 15 and 16, the ring-shaped control member and the control member having inclined surfaces 37 are used individually as control members. However, the design of the control member is not limited to these examples, rather any type of control member can alternatively be used, which is formed in one piece with the head holder 21 in order to generate a vacuum between this member and the magnetic plate 13 in connection with their rotation and to attract the magnetic plate to the side of the head chip 22 .

Claims (11)

1. magnetic head with a counter surface ( 33 ) for arrangement in a radial direction opposite to the recording surface of a magnetic disk ( 13 ) which, when rotated in a direction of rotation (R), defines a free plane of rotation (N),
a magnetic gap ( 34 ) formed on the counter surface ( 33 ), and
a control section for generating a vacuum between the control section and the magnetic plate ( 13 ) when it rotates such that the magnetic plate ( 13 ) is attracted to the magnetic gap ( 34 ),
characterized in that
the counter surface ( 33 ) is designed as a control section ( 35 ; 41 , 42 ; 44 , 45 ; 48 ) in such a way that its distance from the free plane of rotation (N) of the magnetic plate ( 13 ) in the direction of rotation (R) of the magnetic plate ( 13 ) gradually increases. 2. Magnetic head according to claim 1, characterized in that the inclination angle of the control surface ( 41 , 42 ; 44 , 45 ; 48 ) formed as the counter surface to the free plane of rotation (N) of the magnetic plate ( 13 ) along the direction of rotation (R) of the magnetic plate ( 13 ) is varied. 3. Magnetic head according to claim 1 or 2, characterized in that the Steuerab section comprises a first and a second inclined surface ( 41 , 42 ) and the magnetic gap ( 34 ) is formed at the cutting line of the first and the second inclined surface ( 41 , 42 ) , wherein the magnetic gap ( 34 ) extends in the radial direction of the magnetic plate ( 13 ). 4. Magnetic head according to one of claims 1 to 3, characterized in that the control section is provided with at least one groove ( 43 ) which is formed along the direction of rotation (R) of the magnetic plate ( 13 ). 5. Magnetic head according to claim 4, characterized in that the groove ( 43 ) is also arranged na along the same radial direction. 6. Magnetic head according to claim 4, characterized in that the groove ( 43 ) is formed continuously from an upstream to a downstream direction. 7. Magnetic head according to claim 4, characterized in that the groove ( 43 ) has a Bo gengestalt along the direction of rotation (R). 8. A magnetic head according to claim 1, characterized in that the designed as a cam counter-surface (48) having a radius of curvature r1 in the direction of rotation of the magnetic disk (13) and with a radius of curvature r2 plate in the radial direction of the magnet (13) is defined. 9. Magnetic head according to claim 8, characterized in that r1 = r2. 10. Magnetic head according to one of the preceding claims, characterized by an additional control member ( 49 ; 50 ; 51 ) arranged upstream of the magnetic head ( 15 ) for generating an overpressure. 11. Magnetic head according to one of the preceding claims, characterized in that the magnetic head ( 22 ) comprises a head end ( 36 ) which is arranged on the upstream portion of the magnetic head ( 22 ) and consists of a wear-resistant mate rial.