KR100211111B1 - Manufacturing method of magnetic head - Google Patents

Abstract

The manufacturing method of a magnetic head which does not shift a head track. According to the method, a plurality of tracks are machined in pairs with each other to have a winding groove and a plurality of welded glasses so that the welded glass is engaged vertically with the bonded ferrite plate, and the low melting glass is fused to the tracks and the upper surface is processed. After grinding, ferrite is cut to form a reinforcement track at one head core edge.

Description

Magnetic Head Manufacturing Method

1 is a basic self-head structure diagram.

2 (a) (b) is an external perspective view of a conventional magnetic head.

3 is a cross-sectional view of a conventional magnetic head process.

4 is a plan view and a front view of a magnetic head according to the present invention.

Figure 5 (a) (b) (c) is a perspective view and a cross-sectional view showing a manufacturing process of the magnetic head according to the present invention.

6 (a) (b) are plan views of the magnetic head according to the present invention.

* Explanation of symbols for main parts of the drawings

11: head track width 12: head gap

14: welding glass 15: C core

16: I core 17: Upper track groove processing part

18: reinforcing track 19: soft metal magnetic material

20: metal laminated film

The present invention relates to a method of manufacturing a magnetic head, and more particularly, to a method of manufacturing a magnetic head without track misalignment.

A magnetic head records or reads or erases information in magnetic drums, magnetic disks, magnetic tapes, and the like used as storage devices for electronic devices, and also records, records, plays back, and erases data on tapes, recorders, and VTRs. Says the device.

1 is a basic structural diagram of such a magnetic head, in which the magnetic flux density (B (Wb / ) And the magnetic permeability ratio (H / AT / m) of the magnetic field, the coil core is wound around the cone core 1 and the like and the gap 3 is in contact with the magnetic surface of the tape.

Here, the core 1 is mainly composed of permalloy, which is an alloy of nickel (40-90%) and iron, or ferrite sintered at high temperature after appropriately mixing and molding oxides or carbonates such as iron, zinc, and manganese. have.

FIG. 2 (a) is a perspective view showing the appearance of a conventional MIG (Metal In Gap) head. The magnetic film 5 and the welding glass 6 are formed on the upper side of the ferrite plate 4 with the gap 3 as a boundary. As such, this conventional magnetic head manufacturing method will be described with reference to FIG.

3 is a first step of processing the winding groove 12 for winding the coil in the center of one ferrite plate (11a) as shown in (a) and (b), and the first step as shown in FIG. The second step of processing a plurality of tracks 13 for forming a gap on one side of the ferrite plate (11a) after the processing, and the winding groove 2 and the plurality of tracks 13 as shown in FIG. The second step of depositing the insulator 14 on the entire surface of the formed ferrite plate 11a, and the same method as the ferrite plate 11b and the first to third steps as shown in FIG. After joining the same ferrite plate 11a of the same shape so as to face each other, the fourth step of heating the welding glass rod 16 into the winding groove 12 and the welding glass as shown in FIG. A fifth step of sequentially cutting the center of each of the plurality of tracks 13 inserted while melting the rods 16 and separating them into a plurality of magnetic heads is carried out.

Here, instead of the ferrite plate 11B in the fourth step, the ferrite plates in the second and third steps may be joined. Usually, the ferrite plate which passed through 1, 2 and 3 steps is called a C type ferrite plate, and the ferrite plate which has passed only 2 and 3 steps is called an I type ferrite plate.

Since the track 13 faces downward when the welding glass rod 16 is inserted into the winding groove 12 in the fourth step, the welding glass rod 16 is melted so that the respective tracks 13 are joined. Spliced to fill the space created.

However, in the conventional technique, as shown in FIG. 2 (b), the track width W and the head gap 3 are fixed by the joining of two ferrite plates 11a and 11b when viewed from the sliding surface of the head. In this case, the track deviation of the two ferrite plates 11a and 11b causes the track shift due to the joining error. This track deviation provides a cause of noise in recording and reproducing operations of the magnetic head.

An object of the present invention is to solve the above problems and to provide a method of manufacturing a magnetic head without track misalignment.

In order to achieve the above object, the present invention comprises a first step of processing a C core having a winding groove using a first ferrite plate;

A second step of processing the plurality of C cores or I cores using a second ferrite plate paired with the first ferrite plate;

An insulating film is formed on the C and I cores formed in the first and second steps, respectively, and then bonded to face each other to form a gap, and a low melting point glass is inserted into the winding groove to be welded to form a welding glass. Step three,

A fourth step of processing the plurality of tracks in the direction parallel to the slicing cut surface of the welding glass in the third step;

A fifth step of depositing low melting glass or epoxy in the plurality of grooves formed in the fourth step;

A sixth step of grinding the upper surface molded in the fifth step; And a seventh step of cutting the plurality of welding glasses such that a reinforcement track is formed at the head edge portion of the bonded core.

Hereinafter, with reference to the accompanying drawings, the manufacturing method of the magnetic head according to the present invention will be described in detail.

Referring to FIG. 4, the ferrite plate 21 and the ferrite plate 22 which are paired with each other are prepared, and one winding groove 23 for winding the coil in the center of the ferrite plate 21 is provided with the ferrite plate 21. ) In the longitudinal direction. Subsequently, a plurality of tracks are processed on one side of the ferrite plate 21 protruding on both sides of the ferrite plate 21 and the winding groove 23 to form a C core. Subsequently, a plurality of tracks are processed at positions facing the plurality of tracks formed in the second step without processing the winding grooves processed in the first step of the ferrite plate 22, which is paired with the ferrite plate 21, to form I core. Make. Subsequently, an insulator (SiO 2) is deposited on the upper surfaces of the C cores and the I cores 21 and 22 by using a sputtering device to form a gap 12, and then pressure is applied so that the two cores 21 and 22 do not displace. While each formed track is bonded so as to face each other, and the low melting point welding glass is sandwiched in the winding groove 23 to be welded to form the welding glass (24a-24c) as shown in FIG. Subsequently, as shown in FIG. 5B, a plurality of tracks 25a-25d are processed in a direction perpendicular to the gap 12 on the ferrite plate on which the welded glasses 24a-24c are formed.

At this time, the width of the tracks 25a-25d is 100 It should be as follows. Subsequently, a plurality of tracks 25a-25d are subjected to welding of a low-melting glass or epoxy. Subsequently, the upper surface of the core welded in step 6 is polished, and the corner portion of the head core to which the C and I cores 20 and 21 are joined is 5-100. The reinforcement track 18 is cut to form.

FIG. 5C is a plan view of a magnetic head manufactured by the method of manufacturing a magnetic head according to the present invention, where 19 is a soft metal material, and 20 is a metal laminate film.

The C and I cores may be any of MnZn ferrite, NiZn ferrite, MIG type, and metal lamination type, and ceramics may be used instead of ferrite.

According to the present invention as described above, it is possible to fundamentally prevent the occurrence of track shift, which inevitably occurs frequently when the magnetic head is generated. Accordingly, it is possible to provide a noiseless self-head, thereby further improving the reliability of products requiring digitalization and high density.

Claims (5)

A first step of processing the C core having the winding groove by using the first ferrite plate; Insulating the plurality of C cores or I cores using a second ferrite plate paired with the first ferrite plate, and insulating film to the C and I cores formed in the first and second steps After forming each of them to be bonded to face each other in order to form a gap, and the low melting point glass is inserted into the winding groove and welded to form a welding glass, in the third step the welding glass is bonded to the combined core A fourth step of processing a plurality of tracks in a direction parallel to the slicing cut surface; a fifth step of depositing low melting glass or epoxy in the plurality of grooves formed in the fourth step; and an upper surface molded in the fifth step. A sixth step of polishing; And a seventh step of cutting the plurality of welding glasses such that a reinforcement track is formed at a head edge portion of the bonded core. The width of the plurality of tracks formed in the fourth step is 100. Magnetic head manufacturing method characterized by forming below. The method of claim 1, wherein the C or I core is MnZn ferrite, NiZn ferrite plate, MIG type, or metal lamination type, characterized in that the magnetic head manufacturing method. The method of claim 1, wherein the first and second ferrite plates are replaceable with ceramic plates. The method of claim 1, wherein the thickness of the reinforcing track is 5-100 Magnetic head manufacturing method characterized in that.