JPH07225901A - Vertical magnetic disk device - Google Patents

Abstract

PURPOSE:To prevent malfunction by detecting spike noise in a medium area where recording information is not written before the vertical magnetic disk device is started to operate and recognizing intensity of an external magnetic field from intensity of this spike noise. CONSTITUTION:The vertical magnetic disk device is provided with a 1st comparator circuit 27 and a 2nd comparator circuit 28 as an external magnetic field intensity detecting means. Then, spike noise detected by a voltage detecting circuit 26 is inputted to these circuits respectively. In the 1st comparator circuit 27, a voltage value of the spike noise is compared with a 2nd reference voltage value V2 that is larger than a voltage value of a 1st reference voltage V1. Then, when it is decided by an external magnetic field intensity deciding circuit 29 that the vertical magnetic disk device 20 is impressed with a magnetic field by a particular environment to cause malfunction, an error evading measure is taken in accordance with detected intensity of this external magnetic field.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a perpendicular magnetic disk device, and more particularly to a perpendicular recording type magnetic disk device capable of improving the reliability of recording and reproduction when an external magnetic field is applied. Regarding
2. Description of the Related Art In recent years, due to an increase in the amount of information processing in a computer system, the amount of information recorded on a magnetic disk device has also increased, which has led to a reduction in size and capacity, and a demand for higher recording density. Therefore, various densifications have been made, and a vertical recording method, which enables even higher density recording than the conventional horizontal recording method, has been actively developed as a recording method. However, in the perpendicular recording method for performing high density recording, there is a demand for a higher performance perpendicular magnetic disk device that is easily affected by external noise and is resistant to the effect of external noise.

[0002]

2. Description of the Related Art In a conventional perpendicular magnetic disk device, for example, as shown in FIG. 5, a soft magnetic backing layer 2 made of a NiFe film having a high magnetic permeability is provided on a disk-shaped disk substrate 1 made of a non-magnetic material. And a perpendicular magnetic recording medium (perpendicular magnetic disk) 4 having a two-layer film structure in which a perpendicular magnetic recording layer 3 made of a CoCr film or the like is laminated in this order, and a perpendicular magnetic head 5. In the perpendicular magnetic head 5,
The magnetic flux return yoke 12, the non-magnetic insulating material 13, the interlayer insulating layer 14, the thin film coil 15 which is a recording / reproducing coil, the main magnetic pole 16, and the protective film 17 are provided, and the magnetic pole is a single magnetic pole type.

The magnetic flux return yoke 12 is formed as a main magnetic pole forming region on a fillite substrate made of NiZn ferrite. A groove is provided in the main magnetic pole formation region as needed, and a nonmagnetic insulating material 13 such as glass is embedded in the groove. A thin film coil 15 covered with an interlayer insulating layer 14 is provided adjacent to the main magnetic pole formation region, and a main magnetic pole 16 made of a NiFe alloy is provided so as to penetrate the thin film coil 15. The front end of the main pole 16 is exposed on the facing surface of the perpendicular magnetic disk 4, and the rear end is magnetically connected to a ferrite substrate that serves as the magnetic flux return yoke 12. The protective film 17 is made of an Al ₂ O ₃ film or the like and covers the main magnetic pole 16.

The thin-film coil 1 of the perpendicular magnetic head 5
When a recording signal current is passed through the main magnetic pole 5, the main magnetic pole 16 is magnetized so that a magnetic flux sharper than the tip of the main magnetic pole is perpendicular to the perpendicular magnetic recording layer 3 of the perpendicular magnetic disk 4 as shown by a broken line with an arrow. After being magnetized by passing through the magnetic recording medium, it passes through the soft magnetic backing layer 2 in the horizontal direction and again passes through the perpendicular magnetic recording layer 3.
Information is recorded on the perpendicular magnetic recording layer 3 by returning to the magnetic flux return yoke 12 after passing through the perpendicular magnetic recording layer 3 of the perpendicular magnetic recording disk 4 on which information has already been recorded.
Magnetic flux leaking from the magnetic flux flows into the main magnetic pole of the perpendicular magnetic head 5 and is magnetized, whereby the voltage generated in the thin-film coil 15 is detected as a reproduction signal to perform reproduction.

In the perpendicular magnetic disk device having such a structure, in order to increase the recording / reproducing efficiency, it is necessary to make it easier for the magnetic flux to pass through the soft magnetic backing layer 2 of the perpendicular magnetic disk 5. Therefore, conventionally, the magnetic permeability of the soft magnetic backing layer 2 has been increased.

[0006]

However, in the conventional perpendicular magnetic disk device using the perpendicular double-layer film medium,
Since the backing layer is a soft magnetic film, there is a problem that it is weak against an external magnetic field (external noise) as compared with a horizontal recording type magnetic disk device. When a strong external magnetic field is applied, the data may be distorted and an error may occur, or the magnetic permeability of the head may decrease.

The problem caused by the external magnetic field in the perpendicular magnetic disk device will be described in more detail. When the magnetic permeability of the soft magnetic backing layer in the perpendicular two-layer film medium is increased, and the thickness of the soft magnetic backing layer is about several μm, the domain wall of the soft magnetic backing layer has a 180 ° domain wall (Bloch domain wall). ). Then, when the magnetic flux generated from the domain wall is picked up when the perpendicular magnetic head passes above, it becomes noise.
As shown in FIG. 6, this noise occurs when the domain wall MW is submillimeter to 1 mm in the soft magnetic backing layer in the circumferential direction of the perpendicular magnetic disk.
Since they exist at intervals of ˜2 mm, the power obtained by integrating the noise over one round is small, but the noise voltage generated from one domain wall is large, and is about 1/10 of the signal waveform.
Note that FIG. 6 is an observation of the Bloch domain wall MW of the backing layer made of NiFe alloy and having a high relative magnetic permeability on the disk of the 3.5-inch perpendicular magnetic disk by the Bitter method.

Further, as shown in FIG. 7, this magnetic flux is emphasized by an external magnetic field, and when a strong external magnetic field is applied, the intensity of spike noise generated becomes strong and causes an error in data. For example, the magnetic permeability of the backing layer is 2000
In this case, spike noise occurs even when there is no external magnetic field, as shown in FIG. 7 (a). Also, 5 on the surface of the same medium
When a vertical magnetic field of about Oe is applied, spike noise is emphasized as shown in FIG. 7 (b). Further, the intensity of one spike noise becomes maximum around 10 to 15 Oe, as shown in FIG. 7 (c). On the other hand, when the applied magnetic field is increased to about 50 Oe, the spike noise is reduced as shown in Fig. 7 (d).
It decreases to the same strength as the non-magnetic field shown in (a).

Since the number of spike noises in the medium is increased by the external magnetic field, the integrated intensity of all spike noises in the medium tends to be different from one spike noise intensity with respect to the external magnetic field. FIG. 8 shows the dependence of the integrated value of one spike noise and the total spike noise in the medium on the external magnetic field. In the characteristics of such a conventional perpendicular magnetic disk device, the inventors of the present invention measure both noise amounts of one spike noise and an integrated value of all spike noise in the medium, and at that time, the perpendicular magnetic disk device is measured. It has been found that it is possible to estimate the vertical external magnetic field applied to.

Therefore, the present invention detects the strength of the external magnetic field applied to the perpendicular magnetic disk device, and can perform an appropriate avoidance operation that does not cause a data error according to the strength of the external magnetic field. The purpose is to provide a device.

[0011]

FIG. 1 shows the structure of a perpendicular magnetic disk drive according to the present invention which achieves the above object. As shown in FIG. 1, the perpendicular magnetic disk device of the present invention includes a perpendicular magnetic recording medium 4 in which a soft magnetic backing layer 2 and a perpendicular magnetic recording layer 3 are laminated on a non-magnetic disk substrate 1, and this perpendicular magnetic recording medium. In the magnetic disk device including at least a single magnetic pole type perpendicular magnetic head 5 for recording / reproducing on / from the magnetic recording medium 4, the perpendicular magnetic head 5 is provided before or during recording / reproducing on / from the perpendicular magnetic recording medium 4. Spike noise detecting means 6 for detecting spike noise included in the detected signal, external magnetic field strength detecting means 7 for detecting the magnitude of the external magnetic field from the level of the spike noise, and the external magnetic field strength of a predetermined value or more. At times, an error avoiding means 8 for causing the perpendicular magnetic head 5 to perform a protection operation so that an error does not occur in the perpendicular magnetic recording medium 4 due to the external magnetic field. It is characterized in that it comprises.

The spike noise detecting means may detect the spike noise outside the data zone of the perpendicular magnetic recording medium 4 before the recording / reproducing operation of the perpendicular magnetic head is started, and the spike noise detecting means 6 may detect the spike noise. It is also possible to include a low-pass filter and detect the spike noise by removing the reproduction signal by this low-pass filter during reproduction of the perpendicular magnetic head.

The error avoiding means stops the operation of the perpendicular magnetic head when the external magnetic field strength is equal to or higher than a first predetermined value, and is equal to or higher than a second predetermined value which is larger than the first predetermined value. At times, the perpendicular magnetic head may be retracted from the data zone of the perpendicular magnetic recording medium. Further, the error avoiding means separates from the recording / reproducing coil attached to the perpendicular magnetic head, and is an exciting coil for applying a DC magnetic field to the perpendicular magnetic recording medium so as to cancel spike noise emphasized by the external magnetic field. And the external magnetic field strength is equal to or lower than a specific strength, the exciting coil can be operated. The recording / reproducing coil and the exciting coil can be formed of double thin film coils.

[0014]

According to the perpendicular magnetic disk apparatus of the present invention, only spike noise is detected in the medium area where no recording information is written before the operation of the perpendicular magnetic disk apparatus is started.
The external magnetic field strength is recognized from the strength. Then, in a special environment where a magnetic field that causes a malfunction to the perpendicular magnetic disk device is applied, the error avoiding means operates, and the perpendicular magnetic head does not start operating depending on the applied external magnetic field strength. If it is medium, either the operation is stopped or the perpendicular magnetic head is retracted from the data zone of the magnetic disk, and the malfunction in an environment where a strong external magnetic field exists can be significantly improved.

Further, the intensity of spike noise is measured even when the perpendicular magnetic head is reproducing, and a direct current is passed through the exciting coil so that the magnetic flux flowing in the head magnetic pole is canceled by the external magnetic field, whereby the disturbance resistance is improved and the operation is improved. The stop magnetic field can be set high, and the magnetic permeability of the head can be prevented from lowering.

[0016]

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. FIG. 2 is a block circuit diagram showing a configuration of a main part of a perpendicular magnetic disk device 20 according to an embodiment of the present invention.
2, 4 is a vertical magnetic disk, 5 is a vertical magnetic head, 9 is a voice coil motor (VCM) for moving the vertical magnetic head 5 on the magnetic disk 4, 18 is a changeover switch, 19 is a VCM drive circuit, and 21 is Preamplifier, 22
Is a high pass filter, 23 is a signal demodulation circuit, 24 is a signal write circuit, 25 is a low pass filter, 26 is a voltage detection circuit, 27 is a first comparison circuit, 28 is a second comparison circuit, 2
Reference numeral 9 denotes an external magnetic field strength determination circuit.

When writing data to the perpendicular magnetic disk 4, the changeover switch 18 is connected to the contact a by a control circuit (not shown), and a signal from the signal writing circuit 24 flows to the perpendicular magnetic head 5 for writing. On the other hand, when reading data from the perpendicular magnetic disk 4, the changeover switch 18 is connected to the contact b by a control circuit (not shown),
The data read from the perpendicular magnetic head 5 is amplified by the preamplifier 21, the noise component is removed by the high pass filter 22, and the data is demodulated by the signal demodulation circuit 23.

In the perpendicular magnetic disk device 20 which operates as described above, the low pass filter 25 and the voltage detection circuit 26 are used as spike noise detection means in this embodiment.
And. The low-pass filter 25 has a preamplifier 21.
The output of the signal is branched and input, the reproduction signal is removed by the low-pass filter 25, the spike noise component is extracted, and the magnitude (intensity) thereof is detected by the voltage detection circuit 26.

The external magnetic field strength detecting means is as follows.
A first comparison circuit 27 and a second comparison circuit 28 are provided, and spike noise detected by the voltage detection circuit 26 is input to each of them. The first comparison circuit 27 compares the voltage value of the spike noise with the first reference voltage V1, and the second comparison circuit 28 compares the spike noise voltage value with the second reference voltage value V2 having a voltage value larger than the first reference voltage V1. Compare. The comparison results of the first comparison circuit 27 and the second comparison circuit 28 are input to the external magnetic field strength determination circuit 29, and the strength of the external magnetic field is determined by the strength of spike noise. By using such a circuit system, it is possible to measure the spike noise intensity even during reproduction of the perpendicular magnetic head 5.

When the external magnetic field strength determination circuit 29 determines that a special environment in which a magnetic field causing malfunctions is applied to the perpendicular magnetic disk drive 20, the external magnetic field strength determination circuit 29 determines the following error. Evasion measures are taken. (1) When V1 ≦ external magnetic field strength ≦ V2 It is determined that an error will occur when the perpendicular magnetic head 5 is operated, and the changeover switch 18 is switched to the contact c. As a result, if the perpendicular magnetic head is not in operation, it will not start operating,
If the perpendicular magnetic head is operating, the operation stops. (2) External magnetic field strength> V2 When the vertical magnetic head 5 is on the magnetic disk 4, it is determined that an external magnetic field flows to the main magnetic pole and an error occurs in the magnetic disk, and the VCM drive circuit 19 causes the VCM (voice The coil motor) 9 is operated to retract the perpendicular magnetic head 5 from the data zone of the magnetic disk 4.

By the above operation, the perpendicular magnetic disk device 20 of this embodiment can remarkably improve the malfunction in the environment where a strong external magnetic field exists. The above-mentioned spike noise intensity may be detected outside the data zone of the perpendicular magnetic disk 4 before the perpendicular magnetic head 5 starts the recording / reproducing operation.
During the reproduction operation of, the spike noise intensity may be continuously monitored from the signal from which the reproduction signal has been removed by the low-pass filter 25.

FIG. 3 is a block circuit diagram showing the configuration of a perpendicular magnetic disk device 30 according to another embodiment of the present invention.
The same members as those of the perpendicular magnetic disk device 20 described in FIG. 2 are designated by the same reference numerals. The perpendicular magnetic disk device 30 of this embodiment differs from the perpendicular magnetic disk device 20 shown in FIG. 2 in that a recording / reproducing coil (not shown in FIG. 3) originally provided in the perpendicular magnetic head 5 is used.
In addition to (described later), an exciting coil 11 for canceling an external magnetic field is added, and a DC bias circuit 32 for driving the exciting coil 11 is provided. And
In order to operate the exciting coil 11, a third comparing circuit 31 is provided at the subsequent stage of the voltage detecting circuit 26. The third comparison circuit 31 compares the third reference voltage value V0 having a smaller voltage value than the first reference voltage V1 described above with the spike noise intensity, and the comparison result is the external magnetic field intensity determination circuit. 29 is input.

FIG. 4 shows the structure of the perpendicular magnetic head 5 used in the perpendicular magnetic disk device 30 of the embodiment shown in FIG. As described above, the perpendicular magnetic head 5 has
The magnetic flux return yoke 12, the nonmagnetic insulating material 13, the interlayer insulating layer 14, the recording / reproducing coil 15, the main magnetic pole 16, and the protective film 17 are provided, and the magnetic pole is a single magnetic pole type. In this embodiment, the perpendicular magnetic head 5 is provided with the exciting coil 11 so as to overlap the recording / reproducing coil 15.
The excitation coil 11 can also be formed as a double thin film coil like the recording / reproducing coil 15, and can be operated independently of the recording / reproducing coil 15.

The perpendicular magnetic head 5 constructed as described above
In addition to the above-described operations (1) and (2) of the perpendicular magnetic disk device 20 described with reference to FIG. 2, the perpendicular magnetic disk device 30 provided with the following operation is performed as follows. (3) When V0 ≦ external magnetic field strength ≦ V1 A direct current is passed from the DC bias circuit 32 to the exciting coil 11 so as to cancel the magnetic flux flowing through the main magnetic pole 16 by the external magnetic field. By the current flowing through this exciting coil 11,
The magnetic flux flowing through the main pole 16 disappears due to the external magnetic field,
The external magnetic field strength reference voltage V1 for improving the disturbance resistance of the vertical magnetic head 5 and stopping the operation of the vertical magnetic head of (2).
It is possible to set a high value of and to prevent a decrease in magnetic permeability of the head.

As described above, in the perpendicular magnetic disk device 30 of the embodiment shown in FIG. 3, when the intensity of the external magnetic field is small, the exciting coil 11 cancels the magnetic flux flowing through the main magnetic pole 16 of the vertical magnetic head 5 by the external magnetic field. When it is determined that an error occurs when a current is applied to the vertical magnetic head 5 to increase the strength of the external magnetic field and the vertical magnetic head 5 is operated, the operation of the vertical magnetic head 5 is stopped and the strength of the external magnetic field is further increased. When it is determined that an error will occur when the vertical magnetic head 5 is on the magnetic disk 4, the vertical magnetic head 5 is evacuated from the data zone of the magnetic disk 4 in three stages. Magnetic field avoidance measures can be taken. As a result, the disturbance resistance can be further improved, and at the same time, the external magnetic field strength for prohibiting the operation start and stopping the operation can be set higher.

As described above, according to the perpendicular magnetic disk device of the present invention, before the operation of the perpendicular magnetic disk device is started, only spike noise can be detected in the medium area in which the recording information is not written, and the intensity of the spike noise can be detected. The external magnetic field strength can be recognized. Then, in a special environment where a magnetic field that causes a malfunction to the perpendicular magnetic disk device is applied, the error avoiding means operates, and the perpendicular magnetic head does not start operating depending on the applied external magnetic field strength. If it is medium, either the operation is stopped or the perpendicular magnetic head is retracted from the data zone of the magnetic disk, and the malfunction in an environment where a strong external magnetic field exists can be significantly improved.

Further, the intensity of spike noise is measured even when the perpendicular magnetic head is reproducing, and a direct current is passed through the exciting coil so that the magnetic flux flowing in the head magnetic pole is canceled by the external magnetic field, whereby the disturbance resistance is improved and the operation is improved. The stop magnetic field can be set high, and the magnetic permeability of the head can be prevented from lowering.

[0028]

As described above, according to the present invention,
In an environment where there is an external magnetic field that causes an error when operated, the operation of the perpendicular magnetic head is prohibited according to the strength of the external magnetic field, the operation is stopped if it is in operation, or the perpendicular magnetic head is Since the data is saved from the data zone of the magnetic disk, the reliability of the perpendicular magnetic disk device can be improved. Moreover, since an exciting coil is added to the perpendicular magnetic head and a DC bias magnetic field is caused to flow through the exciting coil so as to cancel the external magnetic field when an external magnetic field is applied, it is possible to suppress the emphasis of spike noise. It is possible to set a high threshold value of the external magnetic field for prohibiting the operation or evacuating the magnetic disk out of the data zone, and it is also possible to suppress a decrease in head permeability due to the external magnetic field.

[Brief description of drawings]

FIG. 1 is a principle configurational diagram showing a configuration of a perpendicular magnetic disk device of the present invention.

FIG. 2 is a block circuit configuration diagram showing a configuration of a perpendicular magnetic disk device according to an embodiment of the present invention.

FIG. 3 is a block circuit configuration diagram showing a configuration of a perpendicular magnetic disk device according to another embodiment of the present invention.

FIG. 4 is a configuration diagram showing a configuration of a perpendicular magnetic head used in the embodiment of FIG.

FIG. 5 is a cross-sectional view of essential parts for explaining the configurations of a magnetic head and a double-layer film medium of a conventional perpendicular magnetic disk device.

FIG. 6 is a plan view showing a result of observing a domain wall generated in a high-permeability backing layer on a conventional 3.5-inch perpendicular magnetic disk by a bitter method.

FIG. 7 shows a case where only a spike noise is extracted by passing a reproduction signal from a perpendicular magnetic head through a low pass filter,
The spike noise changes due to the vertical external magnetic field. (A) is a waveform diagram showing the state of spike noise when no external magnetic field is applied, and (b) shows spike noise when an external magnetic field of 5 Oe is applied. Figure 5 (c) shows the state of spike noise when an external magnetic field of 15 Oe is applied. (D) shows the state of spike noise when an external magnetic field of 50 Oe is applied. It is a waveform diagram.

FIG. 8 is a characteristic diagram showing changes in the intensity of one spike noise and the integrated intensity of all spike noise in the medium with respect to the applied intensity of the external magnetic field due to the external magnetic field.

[Explanation of symbols]

 1 ... Non-magnetic disk substrate 2 ... Soft magnetic backing layer 3 ... Perpendicular magnetic recording layer 4 ... Perpendicular magnetic recording medium (perpendicular magnetic disk) 5 ... Perpendicular magnetic head 6 ... Spike noise detection means 7 ... External magnetic field strength detection means 8 ... Error Avoidance means 11 ... Excitation coil 12 ... Magnetic flux return yoke 13 ... Nonmagnetic insulator 14 ... Interlayer insulating layer 15 ... Thin film coil 16 ... Main pole 17 ... Protective film 18 ... Changeover switch 19 ... VCM drive circuit 20 ... One of the present invention Perpendicular magnetic disk device 25 of the embodiment 25 ... Low-pass filter 26 ... Voltage detection circuit 27 ... First comparison circuit 28 ... Second comparison circuit 29 ... External magnetic field strength determination circuit 30 ... Perpendicular magnetic disk of another embodiment of the present invention Device 31 ... Third comparison circuit 32 ... DC bias circuit

Claims (6)

[Claims] 1. A perpendicular magnetic recording medium (4) in which a soft magnetic backing layer (2) and a perpendicular magnetic recording layer (3) are laminated on a non-magnetic disk substrate (1), and the perpendicular magnetic recording medium (4). A magnetic disk device comprising at least a single-pole type perpendicular magnetic head (5) for recording / reproducing with respect to a perpendicular magnetic head before or during recording / reproducing to / from a perpendicular magnetic recording medium (4). Spike noise detection means (6) for detecting spike noise included in the detection signal obtained from (5), and external magnetic field strength detection means (7) for detecting the magnitude of the external magnetic field from the level of this spike noise, An error avoiding means (8) for causing the perpendicular magnetic head (5) to perform a protection operation so that an error does not occur in the perpendicular magnetic recording medium (4) due to the external magnetic field when the external magnetic field strength is a predetermined value or more. , Is provided. The magnetic disk device. 2. The spike noise detection means (6) detects the spike noise outside the data zone of the perpendicular magnetic recording medium (4) before the recording / reproducing operation of the perpendicular magnetic head (5) is started. The perpendicular magnetic disk drive according to claim 1. 3. The spike noise detection means (6) includes a low-pass filter (25), and the reproduction signal is removed by the low-pass filter (25) during reproduction of the perpendicular magnetic head (5) to detect spike noise. The perpendicular magnetic disk drive according to claim 1, wherein 4. The perpendicular magnetic head (5) when the external magnetic field strength is equal to or higher than a first predetermined value by the error avoiding means (8).
Stop the operation of the second and the second value larger than the first predetermined value.
4. The perpendicular magnetic disk device according to claim 1, wherein the perpendicular magnetic head (5) is retracted from the data zone of the perpendicular magnetic recording medium (4) when the value is equal to or more than the predetermined value. . 5. Perpendicular magnetic recording so that the error avoiding means (8), apart from the recording / reproducing coil (15) attached to the perpendicular magnetic head (5), cancels spike noise emphasized by the external magnetic field. The medium (4) includes an exciting coil (11) for applying a DC magnetic field, and when the external magnetic field strength is below a specific strength, the exciting coil (11) is operated. Perpendicular magnetic disk unit. 6. A perpendicular magnetic disk drive, wherein the recording / reproducing coil (15) and the exciting coil (11) are formed of double thin film coils.