FR2633428A1 - Magnetic recording/reading head with superconducting pad. - Google Patents

Abstract

The invention relates to a magnetic recording/reading head using a superconducting material. A magnetic pad 35 is placed between the magnetic poles 31, 32 and behind the air gap 30 in order to enhance the read and write effectiveness of the head. Application to all types of magnetic heads.

Description

MAGNETIC RECORDING HEAD /
READING WITH SUPERCONDUCTING PLOT
The invention relates to a magnetic recording / reading head using a superconductive material.

 The magnetic recording / reading heads consist of a magnetic circuit l with high permeability comprising a non-magnetic gap 2 of thickness ~ e and of an electrical circuit 3 which surrounds the magnetic circuit 1 (FIG. 1).

 When the circuit 3 is traversed by a current, it emits a magnetic field H which is picked up by the circuit 1 and concentrated at the level of the gap 2. Conversely, a local variation in flux at the level of the gap 2 induces a voltage V aux circuit terminals 3.

Current heads can be divided into two families
- massive heads produced by machining and assembling two half-heads made of magnetic material (examples: audio heads made of ferrite or magnetic metal, family video heads (VHS) made of ferrite single crystal). Circuit 3 is wound after assembly,
- Thin film heads, produced by successive deposition of thin layers of magnetic materials, dielectric materials, and conductive tracks etched so as to produce the magnetic circuit, the air gap and the electrical circuit.

Each of these families can be used
either for longitudinal recording, that is to say with a recording medium in which the magnetization is parallel to the support and to the running of the tape,
- Either for perpendicular or vertical recording, that is to say with a recording medium in which the magnetization is perpendicular to the support and to the running of the tape.

 These types of heads have a certain number of drawbacks related to the fact that the permeability of the non-magnetic materials used is very close to 1. Most of the flux crosses the air gap directly and is not used during the operations of reading and recording.

 The usable magnetic flux consists of magnetic leaks at the air gap which can influence or be influenced by a magnetic recording medium. The face of the air gap which occurs on this occasion can be called the front face. However, unusable magnetic leaks also occur on the rear face of the air gap.

 To avoid magnetic leaks occurring at the rear of the air gap, the invention provides for the installation at the rear of this air gap of a pad made of superconductive material.

This arrangement has the advantage of being able to be applied to all types of magnetic heads, in particular to that already using a superconductive material in the air gap (see the applicant's patent application registered under number 87 14825).

 The subject of the invention is therefore a magnetic recording / reading head comprising a magnetic circuit terminated by two magnetic poles separated by an air gap, characterized in that a pad made of superconductive material is placed between the two magnetic poles and at the rear of the air gap.

The invention will be better understood and other advantages will appear on reading the description which follows, given without limitation, and thanks to the appended figures among which
FIGS. 1 and 2 represent magnetic recording / reading heads according to the prior art,
- Figures 3, 4 and 5 are explanatory figures of the principle of the invention,
- Figure 6 is a massive recording / reading head according to the invention.

 FIG. 1 represents a massive magnetic recording / closing head according to the known art. The head comprises a magnetic circuit 1, an air gap 2 made of non-magnetic material and a coil 3. The section S of the magnetic circuit at the level of the air gap 2 is a large quantity due to the magnetic flux which passes through this air gap consisting of a material whose permeability is typically equal to 1.

The section S is determined by the width L of the head (which determines the width of the recorded track) and the depth of the air gap l which is fixed by machining conditions and wear of the head
S = Lxl
For example, a VHS video head will have the following characteristics:
- e = 0.3 micrometer (thickness of the air gap)
- L = 40 micrometers
- 1 = 20 micrometers
- S = 800 square micrometers.

 The use of a non-magnetic pad at the rear of the air gap has already been provided for other reasons than that of remedying the magnetic leaks. This use was the subject of a patent application by the applicant registered under the number 87 14820. According to this document, the air gap and the rear non-magnetic stud were designated respectively by the terms microscopic air gap and macroscopic air gap.

 Figure 2 shows such a configuration for a completed magnetic head. We recognize the magnetic poles 11 and 12, the microscopic air gap 14, the macroscopic air gap 16 and the magnetic substrate 15. The magnetic part 17 in the shape of a U allows to close the magnetic field while supporting two electric coils 18 and 19 The windings can be fixed by an adhesive or by a glass welding.

 FIG. 3 is an explanatory view of the distribution of the magnetic field in the region of the air gaps when these are made of non-magnetic materials as is the case for FIG. 2. According to FIG. 3, the air gap 20 (air gap microscopic), for example in glass, is between the magnetic poles 21 and 22. The non-magnetic pad 23 (macroscopic air gap) is between the magnetic parts 24 and 25. The magnetic materials used (poles 21 and 22, magnetic parts 24 and 25) are for example made of a magnetic metal alloy: Fe-Ni, Fe-AI-Si, Co-Zr-Nb, etc.

If the magnetic flux is well channeled in the elements made of magnetic material, it is different for the air gap 20 and the pad 23. The non-magnetic parts 20 and 23 allow part of the magnetic flux to pass directly, the rest of the flux passing in front of the air gap 20 and behind the pad 23, as is briefly represented by arrows in FIG. 3. It is the leaks occurring in front of the air gap that are useful for reading and recording.

 Typically, the leaks occurring in front of the air gap (therefore the useful leaks) are of the order of 5% of the flux circulating in the magnetic circuit.

 Superconductive materials have, for a temperature below the critical temperature, zero permeability (-MEISSNER effect). The essential aspect of the invention consists in using this property in order to increase the rate of magnetic leaks in front of the air gap.

 In FIG. 4, the reference 26 relates to a pad made of superconductive material. The pad 26 being in its superconductive state, the magnetic flux flowing in the magnetic circuit no longer passes through the pad 26. Also, by comparison with FIG. 3, the flow leakage in front of the air gap can be of the order of 10 % of total flow.

 In FIG. 5, the reference 27 relates to an air gap made of superconductive material. The stud 26 and the air gap 27 being in their superconductive state, the magnetic flux flowing in the magnetic circuit no longer passes through the stud 26 and the air gap 27. Thus, by comparison with FIG. 3, the flux leakage in front of the 'air gap can be greater than 50% of the total flux.

 A first example of application of the invention consists of the planar head as described in the patent application registered under number 87 14820. The production of the magnetic head is carried out according to the teaching of this patent application to with the exception of the superconducting pad.

This can be obtained by a sputtering method. It is also possible to insert the superconductive pad into its housing by methods known to those skilled in the art, for example by bonding. This type of head being advantageously achievable by a collective manufacturing process, it is also possible to produce, by sintering, a plate comprising alternating strips of superconductive and magnetic materials (for example ferrite) so as to obtain, after
Individualization, a magnetic head as shown in Figure 2. If the air gap must be made of superconductive material, to increase the efficiency of the head, it can be obtained according to the teaching of the patent application of the plaintiff registered under number 87 14825.

 A second example of application of the invention is constituted by the massive head shown in FIG. 6. The configuration of this head is entirely conventional. It comprises two magnetic poles 31 and 32 separated by an air gap 30. A U-shaped part 33 connects the two magnetic poles 31 and 32 to ensure the closing of the magnetic field. Around one of its branches a winding 34 has been arranged. The parts 31, 32 and 33 are made of magnetic material.

The air gap 30 can be a conventional dielectric material such as glass.

 According to the invention, a pad 35 of superconductive material is placed at the rear of the air gap 30. The fixing of the pad 35 on the magnetic head can be carried out for example by gluing or by glass welding, processes well known in the art. skilled in the art.

 As before, the air gap 30 can also be made of superconductive material.

Among the advantages provided by the invention, there may be mentioned:
an increase in flow leaks, and therefore in the magnetic field H in front of the air gap, which results in a significant increase in the efficiency of reading and writing of the head,
- a decrease in the inductance of the head and therefore an increase in the signal to noise ratio,
- the use of massive superconductive materials which are easier to use than thin film materials.

Claims (2)

 1 - Magnetic recording / reading head comprising a magnetic circuit terminated by two magnetic poles (31, 32) separated by an air gap (30), characterized in that a stud (35) made of superconductive material is placed between the two poles magnetic and at the back of the air gap.  2 - Magnetic head according to claim 1, characterized in that the air gap (30) is also made of superconductive material.