NL8201231A - MAGNETIC HEAD. - Google Patents

Description

C / tJ / eh / 1393 J

Magnetic head.

The invention generally relates to a magnetic head and is more particularly directed to a magnetic head which is intended to be used in the so-called recording with a perpendicular or vertical magnetization state.

It is known that for recording a high frequency (small wavelength) signal on a magnetic recording tape, a so-called recording mode with a perpendicular or vertical magnetization state is more favorable than a so-called recording mode with a longitudinal magnetization state, in which first case magnetization applied in a direction perpendicular to a side surface of the magnetic recording tape, while in the latter case magnetization is used in the direction of the side surface of a magnetic tape. This is so because in a magnetic layer of the magnetic recording tape, a self-demagnetizing field is smaller in the perpendicular magnetization recording mode when a wavelength of a recording signal becomes smaller while it. self-demagnetizing field in the recording mode with the longitudinal magnetization state increases.

Several magnetic heads have been proposed for use in this vertical magnetization state recording mode. In order to ideally or perfectly perform the recording (or magnetization of the magnetic recording layer of the magnetic tape) in the recording mode with vertical magnetization state, a major component of the magnetic field generated by the magnetic head should be as perpendicular as possible to a magnetic recording medium, such as a tape , stand.

An example of the magnetic head is shown as h in Fig. 1, where a main magnetic pole 2 made of a thin film of high permeability magnetic material such as permalloy and an auxiliary magnetic pole 3 are arranged on either side of a magnetic recording medium 1, such that they face each other. A coil 4 is wound around the magnetic auxiliary pole 3.

In this case, however, the magnetic auxiliary pole must be 8201231 - 2 -,? . r 'are positioned on the other side of the main magnetic pole 2 relative to the magnetic recording medium 1 eh near the magnetic recording medium, which during mounting and use, such as loading the magnetic recording medium 1 between the magnetic main pole 2 and the auxiliary magnetic pole 3 causes difficulties.

In order to overcome these drawbacks, it is proposed to use a magnetic recording medium 1, which, as shown in Fig. 2, is made of a non-magnetic base 5 and a layer of high permeability material 6, which is applied to the non-magnetic magnetic base 5 is provided and a magnetic recording layer 7 is applied to the layer of material 6 with high permeability. In this case, when a single-pole type magnetic head h made of a thin film of soft magnetic material is disposed opposite the magnetic recording layer 7, and a signal is applied to the winding 4 wound around the pole 2, in order to to record the signal, a satisfactory recording sensitivity and excellent recording characteristic can be achieved.

The main magnetic pole 2 of the magnetic head h of this kind is made of a thin foil of ferromagnetic material such as permalloy, Fe-Af.-Si alloy, a so-called Sendust alloy of about 0.5-3 µm thickness. The coil 4 for magnetically exciting the magnetic main pole 2 of thin foil, ie the recording winding, may be formed of a coil in thin film technique which is provided by means of an insulating foil such as SiO 2, Al 2 O 2, Si 2 N ^ or the like is arranged near the top of the magnetic pole 2. In order to effectively excite the main magnetic pole 2 by means of the coil 4, it is desirable in this case that the front end of the coil 4 is positioned so that it coincides with the top of the main magnetic pole 2, which faces the longitudinally moving surface. of the magnetic recording medium 1 is turned. However, when the coil 4 is at the front end thereof which is opposite the longitudinally moving surface of the magnetic recording medium 1, 8201231? The coil 4 will be short-circuited by the magnetic recording medium 1 when the magnetic recording layer 7 is conductive. Even when the surface of the magnetic recording layer is formed of an insulating material, there is a considerable chance that the coil 4 will be short-circuited, since the coil is usually formed from a relatively soft material, such as copper, aluminum, silver, gold, etc. , so that the coil can form bridges between the coils of the coil, due to the friction of the magnetic recording medium. Also, when the coil 4 is close to the magnetic recording medium 1, as described above, a magnetic field formed by the coil 4 is directly delivered to the magnetic recording medium 1 in addition to the magnetic field generated by the main magnetic pole 2. The area of the magnetic field formed by the coil 4 is so widely spread that the magnetic recording field which will be applied to the magnetic recording medium 1 is forced to spread, thus preventing the high density recording.

Of such. disadvantages can be avoided by arranging the excitation coil 4 © $ ► a distance from the end of the main pole 2 facing the magnetic recording medium, that is to say by providing a gap between the top of the excitation coil and the end of the main magnetic pole. By providing this gap, direct contact of the excitation coil with the magnetic recording medium can be avoided. In addition, the magnetic field generated by the excitation coil rapidly decreases on the magnetic recording medium as the spacing increases.

On the other hand, when the excitation coil 4 is arranged to provide the gap with respect to the magnetic recording medium, the magnetization level at the end of the main magnetic pole 2 goes out

The CV of the portion around which the coil 4 coil is mounted is rapidly decreasing, although the portion of the main magnetic pole 2 around which the coil 4 is mounted is strongly magnetized. This is mainly the case because the excitation coil 4 is wound almost tightly around the main magnetic pole 2, and the diameter of the coil 4 wound around it is chosen relatively J '- 4 - so that the magnetic field generated by the coil rapidly decreases at the portion which is removed from the end of the coil, and the main magnetic pole 2 is made of the thin film with magnetic resistance, etc.

FIG. 3 shows the relationship between a plate in the main magnetic pole 2 and the density of the magnetic flux By along an axis of the main magnetic pole, the abscissa representing the position in the y direction, that is, the axis of the magnetic pole main pole 2, and shows the ordinate / density By 10 in the y direction of the magnetic flux. The solid line 8 shows a distribution of By of the magnetic head in case the excitation coil is wrapped so tightly around the main magnetic pole that the main magnetic pole protrudes 50 μ beyond the top of the excitation coil. The broken line 9 shows the density By of the magnetic flux when the main magnetic pole is excited in a parallel magnetic field instead of the case where the excitation coil 4 is wound around the pole.

As can be seen from curve 8, the magnetization at the top of the main magnetic pole 2 protruding outside the coil 4 abruptly decreases. On the other hand, as shown with curve 9 in Fig. 3, the main magnetic pole 2 is fully excited to its end by the parallel magnetic field. Accordingly, it is desirable that the main magnetic pole 2 be excited based on the parallel magnetic field. In order to achieve such a parallel magnetic field, the diameter of the windings of the coil 4 must be increased. However, when the winding diameter of the coil 4 is increased as described above, the recording efficiency is adversely affected and a large recording current is required.

In order to overcome this drawback, as shown in Fig. 4, it is contemplated that an auxiliary core 10 of high permeability material may be positioned to be attached to one surface or both surfaces of the main thin film magnetic pole 2 , and such that the main magnetic pole protrudes, in other words, the auxiliary cores are disposed at a distance from the longitudinally moving surface of the magnetic recording medium 1.

In this case, it is clear that the recording efficiency will be more improved when the excitation coil 4 is disposed near the top of the auxiliary core 10, as close as possible to the top.

Accordingly, it is an object of the present invention to provide a magnetic head which is intended to be used with a vertical magnetization state recording mode.

Another object of the present invention is to provide a magnetic head for use with a vertical magnetization state recording mode having a high recording efficiency.

Another object of the present invention is to provide a magnetic head construction for the purpose of moderately magnetizing a single-pole magnetic core.

In accordance with an aspect of the present invention, there is provided a magnetic head having a magnetic main pole 20 made of a thin film type magnetic material, having a side surface and at one end thereof facing a magnetic recording medium, while a magnetic auxiliary core is disposed near the side surface of the thin film of magnetic material of thickness a in a direction perpendicular to the side surface, an end of the auxiliary magnetic core being spaced from the end of the main magnetic pole, a coil about the main magnetic pole and the magnetic auxiliary core is wound and at the end of the magnetic auxiliary core, this coil having a thickness b 30, and a, b and i- are chosen such that the condition is met that a value (a + b / 2)> £ not less than 0.55 but not greater than 2.4.

Other objects, features and advantages of the present invention will become apparent from the following description with reference to the accompanying drawings, in which like reference numerals designate like elements and parts.

8201231! _ ί - 6 -

Fig. 1, 2 and 4 are diagrams, respectively, each of which has a known magnetic head which is intended to be used in a recording mode with vertical magnetization state; Fig. 3 shows a relationship between a magnetic flux density in a main magnetic pole and the position in the pole; Figures 5,6 and 10 are diagrams, respectively, each showing examples of a magnetic head according to the present invention; Figures 7, 8 and 9 are graphs for explaining the present invention, and Figures 11-17 are schematic views showing the fabrication of the magnetic head of the present invention in 15 steps.

With the magnetic head with such an auxiliary core, the size of the magnetic field for the recording in the upper part of the main magnetic pole depends on the size of the magnetic excitation field at the top of the main magnetic pole, in other words, the size of a magnetic field top of the main magnetic pole when the main magnetic pole is removed but instead the auxiliary core around which the coil is wound is only present.

In order to most efficiently record the signal or the magnetic recording medium, the strongest magnetic field must be generated at the top of the main magnetic pole when a certain current is applied to the excitation coil. As the diameter of the wound coil becomes large, the attenuation of the magnetic field at a distance from the coil on the central axis of the coil generally becomes small. On the other hand, the magnetic field on the central axis of the coil decreases as the diameter of the coils of the coil increases. It is therefore necessary to consider the construction of the coil, the position of the coil wound on the core, the diameter of the coil, etc., in order to maximize the exciting magnetic field.

8201231 - 7 - * -1 *

On the basis of the considerations and clarifications given above and further on the basis of various experiments and discussions, a magnetic head is produced. which is intended to be used with a high recording efficiency in a vertical magnetization recording mode.

Hereinafter, embodiments of the magnetic head of the present invention will be described with reference to Fig. 5 and following Fig., With reference numerals corresponding to those used in Figs. 1, 2, and 10 indicating the same elements and parts.

In the Figure, the letter H refers to the entire construction of a magnetic head according to the present invention.

In the embodiment of the invention, as shown, for example, in Figs. 5 or 6, the main magnetic pole 2 is formed of a magnetic material in the form of a thin film, for example, of permalloy, Sendust alloy, etc. of about 0 5-3 thick, the thickness of which is indicated in the figure by the letter t. A magnetic core or auxiliary cores 10 of high permeability material such as Mn-Zn ferrite, Ni-Zn ferrite or the like are magnetically closed on both surfaces 20 or on one surface of the main magnetic pole 2. This auxiliary core 10 is positioned in such a way that the top thereof faces a distance / below the top of the main magnetic pole 2 which faces the longitudinally moving surface of the magnetic recording medium (not shown) and along which the main magnetic pole 2 moves. .

The coil 4 is arranged on this auxiliary magnetic core 10 such that both the auxiliary magnetic core 10 and the main pole 2 are described thereby. More precisely, the coil 4 is arranged as close as possible to the end of the auxiliary core 10 thereon, so that the top surface thereof can coincide with the top surface of the magnetic auxiliary core 10 around which, for example, a conductive wire is wound.

The thickness of the auxiliary core, i.e. the distance of one surface of the main magnetic pole against which a surface of the auxiliary magnetic pole abuts until the inner surface of the coil is further indicated by a, and the thickness of the coil 4 by b. According to the invention, the above-defined dimensions L, a and b are chosen such that the condition that (a + b / 2) / £ is not greater than 2.4 but not less than 0.55 is met, wherein 4 in practice is between 10 and 200 µm. The reason why the distance ü is selected as described above is based on the results as shown in Figs. 7 and 8, where the component of the magnetic field is examined axially at the top of the main magnetic pole 2 when the value of (a + b / 2) / (, in the magnetic head is changed, of which magnetic head the construction is shown in fig. 5 and 6. In fig. 7 15 and 8 the magnetic field is expressed as a relative value starting from 100% if the maximum value In Fig. 7, curves 11, 12 and 13 each describe the case where the positions of the tops of the paired auxiliary magnetic core 10, which are symmetrically located and occupy the main magnetic pole 2 between 20, as shown in Fig. 5 , be chosen so that the distance 4.between the top of the main magnetic pole 2 and the top of the auxiliary magnetic core 10 is 30 µm, 50 µm and 100 µm respectively Curves 14, 15 and 16 of FIG. the case where the position of the top of the auxiliary magnetic core 10 on one side of the main magnetic pole 2, as shown in Fig. 6, is chosen such that the distance JL between the top of the main magnetic pole 2 and the auxiliary core 10 and 30 µm, respectively, 50 and 100 jams can be. In this case, Fig. 8 shows a distribution of the magnetic field at the distance d in which no magnetic auxiliary core is present, which is chosen equal to the distance a.

Returning to Fig. 7, it will be appreciated that the magnetic field is strongest when (a + b / 2) is // 1.3, with the magnetic field decreasing by about -2% (+ 1%) of the maximum value when (a + b / 2) //. is in an area of 0.8 - 2.0 and the field decreases by -4% (± 2%) of the maximum value when (a + b / 2) / 1 is in an area between 0.65 and 2.4 . It can also be seen in Fig. 8 that the magnetic field becomes the strongest. 8201231 - 9 -

1; S

when (a + b / 2) is // 1.22, this field decreases by about -2% (i 1%) of the maximum value when (a + b / 2) / A is in an area between 0.7 and 2.0 decreases by -4% (- 2%) of the maximum value when (a + b / 2) L is in a range of 0.55 - 2.42.

When the proposition line in Fig. 7 is compared to that in Fig. 8, a tendency of how the top of the main magnetic pole 2 affects the magnetic field is virtually the same in both cases when the auxiliary magnetic core 10 on both surfaces of the magnetic main pole 2 is arranged as 10 when it is applied to one surface thereof, as shown in figures 5 and 6. From figures 7 and 8 it is clear that the magnetic field at the top of the magnetic main pole 2 is effectively improved when (a + b / 2) / t is in the range of 0.55 - 2.4, which is why the range of 15 (a + 'b / 2) / L is chosen between 0.55 and 2.4.

As shown in Fig. 6, the auxiliary core 10 is arranged on one side surface of the main magnetic pole 2, the same magnetic field measured at the top of the main magnetic pole 2 while the distance d from the other side surface of the magnetic main pole 2 ', where the auxiliary core 10 is not attached until the inner surface of the coil 4 on its opposite is selectively changed with the results shown in FIG. 9. In this case 50 µm is taken, a 50 µm is taken. and is taken for b 20 pm.

In addition, for the length c of the coil 4 50 µm is taken.

As will be clear, the magnetic field at the top of the main magnetic pole 2 becomes larger when d = b. Thus, when the auxiliary magnetic core 10 is disposed on one side of the main magnetic pole 2, it is desirable to choose the ratio between the lengths d and b such that d-b is satisfied.

The depth of the coil 4, i.e. the dimension indicated by c in Figs. 5 and 6, does not affect the recording efficiency as much. However, if the depth c is too great compared to the thickness b, this is not favorable because it reduces the recording efficiency. For the value c / b, therefore, 5 or less, in particular, for example, less 8201231, i-10 - than about 2-3 should be taken.

Although in the auxiliary core 10, the distance a at the top where the coil 4 is wound is chosen such that (a + b / 2) // is in a range of 0.55 - 2.4, 5 the thickness can the rear side can be enlarged in view of the mechanical strength.

Fig. 10 shows an example of such a case where each non-magnetic material such as Zn ferrite shaped reinforcing member 17 is further connected to the top 10 of the auxiliary magnetic core 10 so that it extends to the top of the main magnetic pole 2. , which reinforces the top of the main magnetic pole 2. ·.

When the auxiliary core 10 is formed on one side of the main magnetic pole 2, the reinforcing member 17 mounted on the side where the magnetic auxiliary core 10 is not mounted is extended backward or downward such that it is combined with the magnetic main pole 2, thereby the coil 4 can be wound both around this elongated reinforcing member 17 and the auxiliary magnetic core 10 on the other side of the main magnetic pole 2.

As an example, the dimensions of the respective parts of the magnetic head H, the construction of which is shown in FIG.

10 is shown indicated below. 100 ^ rai, a = 150 µm, 25 b = 50 µm and c = 1.5 mm. In addition, the thickness of the rear portion of the auxiliary magnetic core 10, the thickness of which is large and indicated by e ^ in Fig. 10, is taken 1 mm and the length thereof indicated by f can be taken 4 mm.

In this case, a magnetic recording medium 1 can be used whose layer of high permeability material 6 is formed from a 0.5 µm thick permalloy layer and whose magnetic recording layer 7 is formed from a Co-Cr alloy layer of 0 , 5 p thick.

An example of a method of manufacturing a magnetic head according to the present invention will now be described in detail with reference to Fig. 11 et seq.

8201231 - 11 - I Λ

First, as shown in Fig. 11,. a composite body 30 manufactured by joining together a block of magnetic material 20 of rectangular shape and a plate-shaped block of non-magnetic material 27. The block of magnetic material 20 can be made of Mn-Zn ferrite or Ni-Zn ferrite, and the block of non-magnetic material can be made of glass, ceramic, non-magnetic Zn ferrite, etc. However, it is desirable that both the magnetic and the non-magnetic material have an equal thermal expansion coefficient 10, thus it is preferred that the magnetic and non-magnetic blocks 20, 27 be made of magnetic and non-magnetic ferrite, respectively. The block 20 of. magnetic material and the non-magnetic material block 27 may be joined together by a glass-fiber bond, by water glass, an organic adhesive such as epoxy resin, or an inorganic adhesive.

The composite body 30 made of the magnetic material block 20 and the non-magnetic material block 27 is cut along surfaces 20 indicated by dashed-dotted lines m ^, n ^, m ^, ... in FIG.

11, in order to obtain a number of plate members 31, each of a certain thickness, as shown in FIG. 12.

A side surface 3la that extends over the part 20 of magnetic material and the part 27 of non-magnetic material is polished so that a mirror surface is obtained. An insulating layer 32 of, for example, SiO2, Si ^ N ^, α ^ 2 ° 3 Comparative is applied to this side surface 31a, after which a thin film of magnetic material 22 of, for example, permalloy-Sendust alloy, etc., of 0.5 -30 µm thickness is applied by vacuum evaporation, sputtering or the like.

As shown in FIG. 13, the thin film of magnetic material 22 is locally removed using a photolythographic technique leaving band-like portions 22 ', 22' * ... that run parallel to each other and a given width and spacing. The sections between the tape-shaped thin film 22 ', 22 "....

8201231-12 - are filled with non-magnetic material 34 to obtain a flat surface. In addition, materials such as SiCl 2, Si 3 N 4 and A <2 0 ^ or the like can be applied thereon.

As shown in Fig. 14, another plate member 31 ', which is of the same composite body 30 as described above with reference to Fig. 11, becomes of the part 20 of magnetic material and the part 27 of non-magnetic material is manufactured, cut. A side surface 31a 'is polished in the same manner to obtain a mirror surface and, as shown in Fig. 14, this side surface 31a' is joined to the side of the plate 31 on which the thin film magnetic material 22 and the non-magnetic layer 34 are formed, as shown in FIG.

15 13 is displayed. In this case, first a recess or groove 35 in the side surface 31a "of the plate member 31" is formed, for example, by etching, and an adhesive 36 is applied in this recess 35, whereby the two plate members 31 and 31 'can be firmly joined together.

If necessary, as shown in Fig. 15, the external surfaces of the two plate members 31 and 31 'are cut away on the side of the non-magnetic member 27, the thickness of the cut away portion being selected such that is smaller than the remaining 25 parts. As shown by the dashed lines n ^, n2, ... in Fig. 15, the interconnected plates 31 and 311 are cut away including the respective tape-like thin film of magnetic material 22 ', 22 ", ... the top surfaces each being ground or polished to provide a sliding surface S which may come in contact with the magnetic recording medium not shown.

Thus, the magnetic head H according to the present invention can be manufactured such that the main magnetic pole 2 of the thin film magnetic material 22 can contact the longitudinal sliding surface S of the magnetic recording medium, the amplifiers 17 of the non-magnetic magnetic member 27 is located on either side of the main magnetic pole 2, the top side of which and the auxiliary cores 10 formed of the magnetic recording member 20 are located behind the amplifying member 17.

In this case, in which the non-magnetic material 34 is located near the main magnetic pole 2, a gap or gap between the two reinforcing members 17 on either side of the main magnetic pole 2 is in contact with the sliding surface S for the magnetic recording 10 medium is almost completely filled with the non-magnetic material 34, so that an amount of the adhesive is contained in it. the aforementioned slit to be applied will be smaller, in other words, the surface contacting the sliding surface S for the magnetic recording medium in which the adhesive is used is smaller than in the case when the non-magnetic material 34 is not applied. Clogging of the head due to the fact that much adhesive adheres to the sliding surface S can thus be avoided.

The coil 4 is wound around the magnetic head H at the locations of the thin sections which lie further back than the sliding surface S. Even in this case, for the magnetic head H thus manufactured, a ratio is maintained for the dimensions and the mutual location of the respective parts, as previously described.

This magnetic head H is also, as shown, for example, in Fig. 17, attached to a head holder 43 in which openings 41 are provided for mounting on a rotating drum of a VTR (video tape recorder) and on which conductive connecting tracks 42 are provided. Each terminal end of the coil 4 at the magnetic head H is electrically connected to each of the conductive terminal tracks 42, for example, by soldering.

As described above, with the magnetic head according to the present invention, the recording efficiency 35 is high, although the coil 4 is further away from the sliding surface S for the recording medium.

It is also clear that the same effect can be achieved when the magnetic head of the present invention is used for a multi-element type magnetic head in which a plurality of main magnetic poles 2 are present.

The above description has been made with reference to the preferred embodiment of the invention; however, it will be appreciated that many modifications and variations can be made by one skilled in the art without departing from the spirit or scope of the invention.

8201231

Claims (5)

1. Magnetic head, characterized by a magnetic main pole, formed of a thin film of magnetic material with a side surface, and turned at one end to a magnetic recording medium, by a magnetic auxiliary core of thickness a near the side surface of the thin film of magnetic material in a direction perpendicular to that side surface, with one end of the auxiliary magnetic core being spaced from the end of the main magnetic pole, about the main magnetic pole and the auxiliary magnetic core wrapped around a coil, and the core at the end of the auxiliary magnetic core has a thickness b, the a, b and Z being selected such that (a + b / 2) / β is not less than 0.55 and not greater than 2.4. 2. Magnetic head according to claim 1, characterized in that the auxiliary magnetic core is arranged on either side of the main magnetic pole. Magnetic head according to claim 1, characterized in that the main magnetic pole is provided on one side with the auxiliary magnetic core and the other side is provided with a non-magnetic spacer, the thickness of which is greater than the b. Magnetic head according to claim 1, characterized in that the magnetic pole in a surface facing the magnetic recording medium is provided with a non-magnetic material on either side thereof. The magnetic head according to claim 1, characterized in that the auxiliary magnetic core is configured such that a portion remote from the surface facing the magnetic recording medium and around which no coil is wound has a thickness greater than that of the other part around which the coil is wound. 8201231