JPS63293703A - Magnetic recording and reproducing device using superconductive quantum interferometer - Google Patents

Abstract

PURPOSE:To detect a fine reproduced signal with high sensitivity and to attain magnetic recording with high density by using a superconductive quantum interferometer for a part for detecting a signal outputted from a magnetic head. CONSTITUTION:A superconductive ring 12 is constituted of a superconductive material 12 and two Josephson joints 11, a magnetic ring 13 such as ferrite is set up so as to be penetrated into the ring 12, a differential line 14 for transmitting a signal outputted from a magnetic head is wound around the ring 12 and signal detecting lines are formed in the ring 12. Thereby, a fine signal obtained from the magnetic head is converted into magnetic flux flowing into the ring 13 and current flowing through the signal detecting lines 15 is modulated by the quantity of magnetic flux flowing into the ring 13. Since the current flowing into the ring 12 is sensitively modulated also by extremely fine magnetic flux penetrated into the ring 12, a fine signal obtained from the head can be extremely sensitively detected by using the superconductive quantum interferometer.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a magnetic recording and reproducing device using a superconducting quantum interferometer, and particularly to a magnetic recording and reproducing device that can detect weak signals and signals from a magnetic head with high sensitivity. Regarding.

[Conventional technology]

High-density magnetic recording has made remarkable progress, and research into perpendicular magnetic recording, which is suitable for high-density magnetic recording, has progressed in recent years, and even in conventional longitudinal magnetic recording, improvements in magnetic heads and recording media have led to higher recording densities. There is.

When increasing linear recording density and track density, °
Since the area of the recording medium involved per bit or per wavelength decreases, the reproduction output decreases. It has been revealed that when recording is performed by perpendicular magnetic recording, signals with a maximum linear recording density of 500 KBPI can be recorded.

(Summary of the 10th Academic Lectures of the Japanese Society of Applied Magnetics (1986)
) P, 335) [Problem to be solved by the invention] When this recorded signal is reproduced, the magnetic flux generated from the signal magnetization of the medium is weak, so the output is significantly lower than that at a low recording density. There was a problem with the decline.

The present invention aims to solve this problem and provide a magnetic recording/reproducing apparatus having an extremely sensitive detection means so as to be able to reproduce recorded signals with extremely high linear recording density and track density.

[Means for solving problems]

In order to solve the above problems, the magnetic recording and reproducing apparatus of the present invention uses a superconducting quantum interferometer (S u
per conducting quantity
Terference Device, abbreviated as SQU
ID) is used. A superconducting quantum interferometer is a superconducting quantum interferometer that uses the phenomenon that the superconducting current flowing through a superconducting ring containing one or two Josephson junctions changes according to the amount of magnetic flux that passes through the ring, and can be used to measure the amount of magnetic flux with high sensitivity. This is the element to be measured.

Since this superconducting quantum interferometer utilizes a superconducting state, it was necessary to construct the device with a superconducting material and to cool the entire device to an extremely low temperature to achieve the superconducting state.

However, recent advances in research and development of superconducting materials have been remarkable, and materials that become superconducting at an angle of about 95 degrees have been developed.

By using such high-temperature superconducting materials, it becomes possible to reproduce signals with ultrahigh sensitivity using a superconducting quantum interferometer.

[Effect]

The magnetic recording device of the present invention includes at least a coil for converting a reproduction signal into magnetic flux, and a superconducting ring that constitutes a superconducting quantum interferometer that interlinks with the coil. Further, in order to efficiently transmit the magnetic flux from the coil to the superconducting ring, it is effective to interpose a magnetic path made of a magnetic material. Furthermore, by providing a configuration that includes a cooling element that utilizes the Peltier effect, it is effective to efficiently cool the necessary portions and maintain a superconducting state.

The superconducting quantum interferometer used in the present invention includes a DC type including two Josephson junctions and an AC type including - Josephson junctions. Since the DC type requires the formation of two Josephson junctions, it is disadvantageous in terms of process compared to the AC type including - Josephson junctions, but it has the advantage of a simpler circuit configuration. On the other hand, the AC type requires only one Josephson junction to be formed, which is advantageous in terms of process, but the circuit configuration is complicated.1 Either type can be used in the magnetic recording/reproducing device of the present invention, and each You can choose and use the advantages.

The superconducting quantum interferometer used in the magnetic recording/reproducing device of the present invention is extremely sensitive to external magnetic flux, so it has the problem of being vulnerable to leakage magnetic flux other than external signals and noise such as electromagnetic waves. have. In order to solve this problem, in the magnetic recording/reproducing apparatus of the present invention, it is desirable to provide a shield around the superconducting quantum interferometer. As this shield material, a high magnetic permeability material such as a conventional Ni-Fe alloy (permalloy) or an amorphous alloy can be used. Furthermore, since magnetic flux does not penetrate into superconducting materials, it is most preferable to use superconducting materials as the shielding material.

Furthermore, in the magnetic recording device of the present invention, by providing a bias coil arranged so that the magnetic flux interlinks with the ultra-low 4 quantum interferometer element and passing an alternating current bias current through it,
It is also possible to make the detection of the signal easier.

Examples of superconducting materials used in the magnetic recording device of the present invention include 1, for example (SrzLal-x)+Cu○4 (x=0.05~
0.1) or (Bat-xYx)3cuz07 (X~0.3). In particular, the latter is a preferable material because it becomes superconductive at a high temperature of 95°.

In the magnetic recording/reproducing device of the present invention, by inserting the superconducting quantum magnetic flux interferometer between the magnetic head and the signal detection circuit, it becomes possible to detect weak signals and signals from the magnetic head with extremely high sensitivity.

Among magnetic recording and reproducing devices, VTR devices and the like use a head mounted on a high-speed rotating ring to perform recording and reproducing, so a signal transmission component such as a rotary transformer is inserted between the head and the recording/detection circuit. There is. In the magnetic recording and reproducing apparatus of the present invention, by configuring the rotary transformer portion with the superconducting quantum magnetic flux interferometer described above, the reproducing sensitivity can be greatly improved.

Note that the magnetic recording/reproducing device of the present invention is applicable not only to VTRs but also to
audio tape recorder, rigid disk device,
It can be applied to magnetic recording and reproducing devices consisting of a recording medium and a magnetic head, such as floppy disk devices and magnetic tape storage devices for computers.

〔Example〕

Next, the magnetic recording/reproducing apparatus of the present invention will be explained in detail by way of examples.

FIG. 1 shows an example of a direct current type superconducting quantum interferometer used in the magnetic recording device of the present invention.

A superconducting ring 12 is composed of a superconducting material 10 and two Josephson junctions 11, and a magnetic ring 13 made of ferrite or the like is installed so as to penetrate the superconducting ring. A parallel wire 14 for transmitting signals is wound. A signal detection line 15 is provided in the superconducting ring. With this configuration, a weak signal from the magnetic head is converted into magnetic flux flowing through the magnetic ring 13,
The current flowing through the signal detection line 15 is modulated by the amount of magnetic flux flowing through the magnetic ring 13.

The current flowing through the superconducting ring is sensitively modulated even by an extremely weak amount of magnetic flux penetrating the superconducting ring.1 By using a superconducting quantum interferometer as in the present invention, the weak magnetic flux from the head can be modulated. It is possible to detect signals with extremely high sensitivity.

FIG. 2 shows another example of a direct current type superconducting quantum interferometer used in the magnetic recording/reproducing apparatus of the present invention.
(a) shows a plan view, and (b) shows a cross-sectional view of A and A' in (a). A superconducting ring 1 made of superconducting material as in Fig. 1.
2. Josephson junction 11, magnetic ring 13. difference mark 1
4. 16 constituted by the signal detection line 15 is an insulating material. In this embodiment, the superconducting quantum interferometer is configured on the substrate 17, and by incorporating a cooling element using the Peltier effect etc. into the substrate part, the part using the superconducting material can be efficiently cooled. becomes possible.

FIG. 3 shows another example of a direct current type superconducting quantum interferometer used in the magnetic recording/reproducing apparatus of the present invention.

(A) is a plan view, and (B) is a cross-sectional view taken along line A-A' in (A). This embodiment is an example without the magnetic ring 13, which transmits signals from the magnetic head. The difference mark 14 and the superconducting ring 12 are directly coupled to each other. Since the superconducting quantum interferometer has extremely high sensitivity to magnetic flux, it is possible to configure it as in this embodiment. In addition, as shown in (mouth), the magnetic shield 18 is
By providing the superconducting ring as a cover,
Noise generated by external magnetic flux and radio waves can be prevented. Although conventional high magnetic permeability materials can be used as the magnetic shielding material, it is desirable to use superconducting materials in order to enhance the shielding effect. An insulating material 16° 19 is provided to insulate these shielding materials from the superconducting ring and the parallel wires. In addition, in Figure 3 (a), (
Magnetic shield 18 shown in b). The insulating material 16 is omitted from illustration.

FIG. 4 is an example of an AC superconducting quantum magnetic flux interferometer used in the magnetic recording device of the present invention. (a) is a plan view, (b) is a plan view.
shows a sectional view taken along line AA' in (a).

In this embodiment, a superconducting ring 12 including one Josephson junction 11 and a magnetic ring 13 . It consists of a differential mark 14 and a high frequency coil 20 for detecting signals. Further, in the same manner as shown in FIG. 3, the magnetic shield 18 is configured to cover the superconducting ring. In addition, in Figure 4 (a),
The magnetic shield 18 and insulating material 19 shown in (b) are omitted from the illustration.

In addition, the difference mark 14 and the high frequency coil 2 in FIGS. 2 to 4
0 indicates the case of one turn, but it is of course possible to have multiple turns.

Figure 5 shows an example of using a superconducting quantum interferometer in a rotary transformer used for signal transmission in a device such as a VTR that records and reproduces signals on a tape with a head mounted on a cylinder that rotates once. It is. (A) shows a cross-sectional view on the center of the rotation axis of the cylinder.
' shows a plan view on the plane. In this embodiment, the part that rotates together with the cylinder rotation shaft 21 is replaced by a rotating magnetic ring 1.
3' and a winding 14 for transmitting signals from the magnetic head, and the part fixed to the stator 22 is a rotating magnetic ring 13'' and a superconducting ring 12 including one or two Josephson junctions 11. A superconducting quantum interferometer is constructed by combining a one-rotation part and a rotating part.In the embodiment, a plurality of superconducting quantum interferometers are installed in the direction of the rotation axis to transmit and detect a plurality of signals. I can do it.

In order to magnetically separate each superconducting quantum interferometer, a magnetic shield 18 may be provided between the superconducting quantum interferometers. In addition, a difference mark 23 is applied to the stator side, and the Josephson junction is 2
When configuring DC superconducting quantum flux interferometers,
When the bias coil is used as an alternating current superconducting quantum flux interferometer with one Josephson junction, it can be used as a high-frequency coil for signal detection. During signal reproduction, the signal current flowing through the differential mark 14 causes the rotating magnetic ring 13'
A magnetic flux is induced, and this magnetic flux is transmitted to the fixed magnetic ring 13' through the minute air gap 24. Since this magnetic flux penetrates the superconducting ring 12, a signal is detected by the signal detection line 15 connected to the superconducting ring in the case of a DC type, and by the high frequency coil 23 in the case of an AC type.

Furthermore, when recording a signal, by passing a recording current through the difference mark 23, the recording signal can be transmitted to the difference mark 14 on the magnetic head side, similar to a normal rotary transformer.

FIG. 5 shows another example in which a superconducting quantum magnetic flux interferometer is used instead of a rotary transformer. As shown in FIG. 5, the difference fit on the head side that rotates together with the cylinder rotating shaft 21 4. The magnetic shield 18, which is composed of the rotating magnetic ring 13', the superconducting ring 12 fixed to the stator 22, the fixed magnetic ring 13', and the difference mark 23, is fixed to either the rotating side or the stationary side. Install.

In the example shown in FIG. 5, the length of the shaft increases as the number of channels increases, and in the example shown in FIG. 6, it is necessary to increase the diameter in order to increase the number of channels. Either example can be used depending on the device used. Also,
In the examples shown in FIGS. 5 and 6, by incorporating a cooling element using the Peltier effect or the like into the stator 22, it is possible to efficiently cool the superconducting material portion.

〔Effect of the invention〕

As mentioned above, by using a superconducting quantum flux interferometer in the part that detects the signal from the magnetic head in a magnetic recording device, it is possible to detect a weak reproduced signal with extremely high sensitivity, and a high-density Magnetic recording becomes possible. Furthermore, particularly in devices such as VTRs in which a head is mounted on a rotating cylinder, highly sensitive signal reproduction is possible by using a superconducting quantum magnetic flux interferometer instead of a rotary transformer.

[Brief explanation of the drawing]

FIG. 1 is a perspective view of an embodiment of a superconducting quantum flux interferometer used in the magnetic recording device of the present invention, and FIGS. 2 to 4 are implementations of the superconducting quantum flux interferometer used in the magnetic recording device of the present invention. FIGS. 5 and 6 are diagrams showing an example of a superconducting quantum flux interferometer used in place of a rotary transformer. 10...Superconducting material 11...Josephson junction 12...Superconducting ring 13...Magnetic ring I4...Differential mark 15...Signal detection line 17...Substrate 18... Magnetic shield 20...High frequency coil 21...Cylinder rotating shaft 22...Stator extrusion 1m

Claims (1)

[Claims] 1. Fine conducting quantum A magnetic recording/reproducing device comprising an interferometer and detecting a reproduced signal using a superconducting quantum interferometer. 2. In the magnetic recording/reproducing device according to claim 1, a ring of magnetic material is provided so as to penetrate the ring of superconducting material, and a winding for passing a reproduction signal from the magnetic head is provided in the ring of magnetic material. A magnetic recording and reproducing device characterized by being wrapped. 3. In the magnetic recording and reproducing device according to claim 1 or 2, the ring of superconducting material includes two Josephson couplings, and constitutes a direct current type superconducting quantum interferometer. A magnetic recording/reproducing device characterized by detecting signals. 4. In the magnetic recording and reproducing device as claimed in claim 1 or 2, the ring of superconducting material includes one Josephson junction, and the ring of superconducting material includes a single Josephson junction, and a signal detection junction magnetically coupled with the upper and front rings. A magnetic recording/reproducing device comprising a high-frequency coil and configured as an AC-type superconducting quantum interferometer to detect signals. 5. A magnetic recording and reproducing device according to any one of claims 1 to 4, characterized in that a magnetic shield is applied to cover the ring of superconducting material. 6. A magnetic recording and reproducing device according to any one of claims 1 to 5, characterized in that the magnetic shielding material is a superconducting material. 7. A magnetic recording and reproducing device according to any one of claims 1 to 6, characterized in that a portion using a superconducting material is cooled by a cooling element using a Peltier effect or the like. Device. 8. A magnetic recording and reproducing device according to any one of claims 1 to 7, characterized in that the superconducting quantum interferometer is used in place of the rotary transformer. 9. In the magnetic recording/reproducing device according to claim 8, the superconducting quantum interferometer is fixed to at least a rotating magnetic ring that rotates together with a cylinder rotation axis, a winding that transmits signals from a magnetic head, and a stator. The rotating magnetic ring is composed of a superconducting ring and a fixed magnetic ring, and the magnetic flux induced in the rotating magnetic ring by the winding is transmitted to the fixed magnetic ring through a minute air gap. magnetic recording and reproducing device. 10. The magnetic recording and reproducing device according to claim 8 or 9, characterized in that one cylinder is provided with a plurality of the superconducting quantum interferometers so as to transmit and detect one or more signals. magnetic recording and reproducing device. 11. A magnetic recording and reproducing apparatus according to claim 10, characterized in that a magnetic shield is provided between each superconducting quantum interferometer. 12. A magnetic recording and reproducing device according to any one of claims 9 to 11, characterized in that the stator side is provided with a difference line that magnetically couples with a ring of superconducting material. Device. 13. The magnetic recording and reproducing apparatus according to claim 12, wherein a recording current is passed through the difference line during a recording operation so that the magnetic recording and reproducing apparatus operates as a normal rotary transformer. 14. A magnetic recording and reproducing device according to any one of claims 9 to 13, characterized in that the superconducting material is cooled by incorporating a cooling element based on the Peltier effect into the stator. Device.