JP2794790B2 - Evaluation method for durability of disk media - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Summary] The present invention relates to a method for evaluating the durability of a disk medium, which evaluates the degree of resistance to damage caused by the edge of a head coming into contact with a rotating disk medium. Rotating the edge of the head by inclining the head at a specified angle with the aim of obtaining the same evaluation result as that occurring in the disk drive and enabling easy evaluation tests Compression means for compressing the surface of a disk medium to be pressed with a predetermined pressure; conversion means for converting an elastic wave generated by vibration generated by the head being rubbed against a rotating disk medium into an electric signal; A drive unit for rotating the medium, when the disk medium is rotated from a stopped state and reaches a predetermined rotation speed, the drive to the disk medium is stopped, When the disk medium is in the stop state, the disk drive is rotated again and the drive operation of stopping the drive when the rotation speed reaches a predetermined rotation speed is repeated until the peak value of the electric signal converted by the conversion means becomes equal to or more than a predetermined threshold value. The durability of the disk medium is evaluated by measuring the number of repetitions of the driving operation for each specified tilt angle of the head.

[Industrial applications]

The present invention relates to a disk medium used in a disk drive, and in particular, to a method for evaluating the durability of a disk medium for evaluating how much the head edge can withstand damage caused by contact with a rotating disk medium. About.

In recent years, magnetic disk drives have been required to have higher recording densities, and as the rotational speed of the disk medium has increased, the flying height of the head has decreased. In addition to the demand for shortening the access time, the moving speed of the head when performing a seek for positioning the head on the target track has been improved.

For this reason, the acceleration and deceleration of the head during the movement become sharp, the head vibrates, and the edge of the head often comes into contact with the surface of the disk medium, and the edge of the head damages the surface of the disk medium. Sometimes. When the edge of the head comes into contact in this way, the smaller the flying height of the head, the faster the rotation speed of the disk medium, and the faster the moving speed of the head, the greater the damage to the disk medium, the greater the durability of the disk medium. It is necessary to further improve the performance.

For this purpose, it is important to establish a method for evaluating the durability of the disk medium when the edge of the head comes into contact.

[Conventional technology]

As a method for evaluating the durability of a disk medium, an alumina slider or a thin film slider of a head conventionally used in a magnetic disk device is pressed against the surface of the disk medium,
There is a high-speed sliding method in which a disk medium is rotated at a predetermined speed and the slider is rubbed with the disk medium to measure and evaluate the time until the surface of the disk medium is damaged.

In addition, the pencil core is inclined at a predetermined angle and pressed against the surface of the disk medium, and the disk medium is rotated at a predetermined speed. There is a pencil hardness stylus method in which the depth of a scratch is measured and evaluated.

[Problems to be solved by the invention]

The high-speed sliding method is a sliding by the contact between the surface of the slider and the disk medium, and the condition is different from the case where the edge of the head, that is, the edge of the slider is in contact. There is a problem that evaluation cannot be performed.

In addition, the pencil hardness stylus method is similar in condition to the case where the edge of the head is in contact, but requires skill in machining the lead of the pencil and the like. However, there is a problem that the same evaluation is not always obtained as in the case of contact and damage.

The present invention has been made in view of the above problems, and provides a durability evaluation method that can obtain the same evaluation result as that generated in an actual magnetic disk drive and can easily perform an evaluation test. The purpose is.

[Means for solving the problem]

 FIG. 1 is a diagram for explaining the principle of the present invention.

The disk medium 1 starts rotating by the driving of the driving means 2, and when the rotation speed reaches a predetermined rotation speed, the driving means 2 stops driving the disk medium 1, so that the rotation speed gradually decreases and finally stops. When the rotation of the disk medium 1 is stopped, the drive means 2 starts to rotate again to drive the disk medium 1 and reaches a predetermined rotation speed.

Here, since the drive unit 2 stops driving the disk medium 1 again, the rotation speed of the disk medium 1 sequentially decreases and stops. The driving means 2 repeatedly executes the above operation.

The crimping means 6 crimps the head 3 attached to the tip of the spring 4 to the surface of the disk medium 1 with a predetermined pressure.
The spring 4 is rotated in a direction indicated by an arrow A, and is moved in a direction indicated by an arrow C or D in order to incline the head 3 at a specified inclination angle.

Since the head 3 is pressed against the surface of the disk medium 1, the vibration increases as the rotational speed of the disk medium 1 increases. This vibration is transmitted to the conversion means 5 via the spring 4, and the conversion means 5 converts an elastic wave accompanying the vibration of the spring 4 into an electric signal and sends it to the comparison means 7.

The comparing means 7 compares the peak value of the electric signal sent from the converting means 5 with a threshold value, and sends a signal to the terminal E when the peak value is exceeded. The peak value of the electric signal indicates a higher value as the damage of the recording layer of the disk medium 1 of the head 3 increases, so that an accurate damage state can always be detected by comparing the peak value with a certain threshold value.

Therefore, by checking how many times the drive means 2 has driven the disk medium 1 by the time the signal is transmitted, and by measuring the number of times at each specified tilt angle of the head 3, the durability of the disk medium 1 can be accurately determined. Can be evaluated.

[Action]

With the above-described configuration, the pressure bonding means 6 moves in the direction of arrow CD and rotates the spring 4 in the direction of arrow A, so that the head 3 moves the disk medium 1 at a set pressure.
Since the head 3 can be brought into contact with the disk medium 1 while changing its inclination angle, the same state as the contact state of the head 3 in an actual magnetic disk device can be reproduced.

When the edge of the head 3 cuts the surface of the disk medium 1 and penetrates deeper, the vibration increases, and the peak value of the electric signal corresponding to the magnitude of the vibration exceeds a predetermined threshold value. One certain damage condition can be detected.

Therefore, the same evaluation result as that generated in an actual magnetic disk drive can be obtained, and an evaluation test can be easily performed.

〔Example〕

FIG. 2 is a block diagram illustrating an embodiment of the present invention.
FIG. 3 is a diagram for explaining the operation of FIG.

A platen 8 having an extremely small runout (surface sway) when rotated by a motor 9 is attached, and the disk medium 1 is fixed to the platen 8. Therefore, the surface when the disk medium 1 rotates does not swing up and down, and the head 3 is pressed against the surface of the disk medium 1 with a stable pressure.

The drive circuit 14 supplies a current to the motor 9 to rotate it, monitors the rotation speed of the motor 9 detected by, for example, a Hall element, and cuts off the current supplied to the motor 9 when the motor 9 reaches a predetermined rotation speed. I do.

Then, when the motor 9 stops, the current is again supplied to the motor 9 to rotate it, and when the motor 9 reaches a predetermined rotation speed, the current supplied to the motor 9 is cut off. The drive circuit 14 repeats this operation, and the counter 16 records the number of times of this repetition operation.

The slider of the head 3 is fixedly attached to the disk 11 by the spring 4. When the disk 11 rotates in the direction of arrow A, the slider is pressed against the surface of the disk medium 1 by the pressure transmitted through the spring 4.

The disk 11 is given a rotational force by a motor 13,
The rotation of the disk 11 is stopped in a state where the driving force transmitted by the spring 4 and the repulsive force of the spring 4 are balanced. Then, the drive circuit 14 supplies the motor 13 with a current for generating a drive force desired by the operator.

Therefore, the operator measures the pressing force of the head 3 against the disk medium 1 with the strain gauge 17 and operates, for example, a variable resistor provided in the drive circuit 14 to control the motor.
13 sends a current to generate the desired driving force.

The strain gauge 17 measures, for example, a resistance value between the head 3 and the disk medium 1 and displays the measured value as a pressing force.

Also, the disk 11 and the motor 13 are mounted on the support 12,
By adjusting the mounting mechanism, the head 3 moves in the direction of arrow CD, and the mounting position determines the inclination angle of the head 3 with respect to the disk medium 1.

Figure 3 (a) shows the angle of inclination of the head 3, as the disc 11 is moved in the direction of the arrow C, as shown in FIG. 3 (a), the inclination angle theta ₁ of the head 3 is increased, 3 (a), θ ₂ , θ ₃ , θ in FIG.
_As shown in FIG. ₄ , the inclination angle decreases sequentially.

An AE (Acoustic Emission) element 10 is attached to the spring 4, and when the head 3 rubs against the disk medium 1 and oscillates by a known circuit as shown in, for example, JP-A-61-227220, this oscillation AE element 10 via spring 4
The output of a waveform as shown in FIG. 3B is sent to the comparison circuit 15 in accordance with the rotation speed of the disk medium 1.

That is, when the disk medium 1 starts rotating and the rotation speed increases, an output waveform whose level increases in proportion to the rotation speed is sent from the AE element 10 to the comparison circuit 15 as shown in FIG. The peak is reached when the disk medium 1 reaches a predetermined opening distance, and when the current supplied to the motor 9 is cut off, the level becomes lower as the rotation speed of the disk medium 1 decreases, and the level gradually decreases. descend.

When the rotation of the disk medium 1 is stopped, current is supplied to the motor 9 again, and the disk medium 1 starts rotating again, an output waveform as shown in FIG. 3B is obtained in the same manner as described above.

As the surface of the disk medium 1 is damaged and the vibration of the head 3 increases, as shown in FIG.
The level of the waveform transmitted from the AE element 10 increases,
When the peak value exceeds a threshold value as shown in FIG.
15 sends the signal to terminal E.

Therefore, the value of the counter 16 when the comparison circuit 15 sends a signal to the terminal E indicates the durability of the disk medium 1.

In this embodiment, the output waveform of the AE element 10 is monitored by the comparison circuit 15, but an oscilloscope or the like may be used as a matter of course.

〔The invention's effect〕

As described above, the present invention uses a head used in a magnetic disk drive, changes the inclination angle of the head to contact the surface of the disk medium, and damages the recording layer of the disk medium by the edge of the head. AE that provides a wide range of evaluations, obtains the same evaluation results as those that occur in actual magnetic disk drives, and sends out an output waveform that has a peak value corresponding to the damage state of the recording layer.
Since a certain damage state is always detected by the element, accurate evaluation can be performed and an evaluation test can be easily performed.

[Brief description of the drawings]

 FIG. 1 is a diagram for explaining the principle of the present invention, FIG. 2 is a block diagram for explaining an embodiment of the present invention, and FIG. 3 is a diagram for explaining the operation of FIG. In the figure, 1 is a disk medium, 2 is a driving means, 3 is a head, 4 is a spring, 5 is a converting means, 6 is a crimping means, 7 is a comparing means, 8 is a surface plate, 9, 13 is a motor, and 10 is AE. Element, 11 is a disk, 12 is a column, 14 is a drive circuit, 15 is a comparison circuit, 16 is a counter, and 17 is a strain gauge.

Claims (1)

(57) [Claims] 1. A disk medium (1) in which a head (3) is inclined at a specified angle and the edge of the head (3) is rotated.
A pressure bonding means (6) for pressing the surface of the head with a predetermined pressure, and an elastic wave generated by vibration generated when the head (3) rubs against the rotating disk medium (1) is converted into an electric signal. Converting means (5); and driving means (2) for rotating the disk medium (1). When the disk medium (1) is rotated from a stopped state and reaches a predetermined rotational speed, the disk medium (1) is rotated. When the drive for (1) is stopped and the disk medium (1) is stopped, the drive operation is repeated to stop the drive when the disk medium (1) is rotated again and reaches a predetermined rotation speed. The number of repetitions of the driving operation until the peak value of the converted electric signal becomes equal to or greater than a predetermined threshold value is measured for each of the specified tilt angles of the head (3). Evaluation of durability A method for evaluating the durability of a disk medium, comprising: