JPS60136976A - Magnetic head controller - Google Patents

Abstract

PURPOSE:To move a magnetic head surely to a prescribed CSS area by detecting a level of a main power supply voltage and applying a current of a fixed direction to a voice coil with a residual power supply voltage when the main power supply voltage is lowered at a fixed level or below from the result of detection. CONSTITUTION:When the main power supply voltage VC is decreased to a fixed level or below and the operation of a magnetic disc device comes to a stop, a Zener diode 31 of a main power supply detection circuit 30 is turned off and a transistor (TR)32 is turned off. If the power supply voltage VC is decreased to a fixed level or below, residual power supply voltages VB+, VB- are generated from a generating circuit. When the level of the main power supply voltage VC is lowered and the operation of the magnetic disc device comes to a stop, a retract current IR in response to the residual power supply voltage is fed to the voice coil 20. In adjusting the direction of the retract current IR and its current value V to the voice coil 20 in advance, the magnetic head is moved to the CSS area on a disc face.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a magnetic head control device used in a contact start/stop type magnetic disk drive.

[Technical background of the invention and its problems]

In recent years, contact start-stop (CSS) type magnetic heads have been used in fixed magnetic disk drives and the like. This C8S type magnetic head, for example,
It is configured as shown in the figure (plan view). That is, a gimbal 11 is attached to the tip of the Herad arm 10, and a head slider 12 is provided on this gimbal 11. The head arm 10 is configured to rotate around a predetermined support 14 when a drive current is supplied to a voice coil 13 of a voice coil motor that is a drive source for the magnetic head.

Incidentally, in a C8S type magnetic disk drive, scratches may occur on the disk surface due to wear during starting and stopping when the magnetic head is brought into contact with the disk surface. For this reason, conventional methods have been developed to prevent scratches, particularly in the data writing area (data area) on the disk surface. That is, for example, when a magnetic disk drive stops operating, the magnetic head is moved to the C8S area of the disk surface (usually the inner area of the disk surface other than the data area), and then the rotation of the disk surface is stopped and the magnetic head is moved. This method involves landing the ball on the disc surface. Further, at the start of operation of the magnetic disk device, a means is used to levitate the magnetic head in the C8S area of the disk surface.

Among the above methods, the means for moving the magnetic head onto the C8S area when stopping the rotation of the disk surface has conventionally been a method using the force of a spring 15 as shown in FIG. ing. That is, in this method, when the supply of drive current to the voice coil 13 is stopped, the helad arm 10 is moved to the stopper 1 by the spring 15.
Pressed to 6. If the position of this stop angle <16 is adjusted in advance, when the supply of drive current to the voice coil 13 is stopped (that is, the power of the magnetic disk device is cut off), the head slider 12 is moved to the C8 on the disk surface set in advance.
It can be located in the S area.

However, in the conventional method as described above, the force of the spring 15 is always applied to the helad arm IO, so in order to set the head slider 12 at a predetermined position, the drive required to cancel the force of the spring 15 is necessary. It is necessary to apply force to the head arm 1O. For this reason, a driving current necessary for the above-mentioned driving force is supplied to the voice coil 13, resulting in a disadvantage that the power consumption of the magnetic disk device becomes relatively large. Also.

Voice coil 1 depending on the power capacity of the magnetic disk device.
If the maximum value of the drive current that can be supplied to 3 is MAX, then the electric current that can be used when moving the magnetic head is rIMA%-
Is J. This Is is the drive current for the voice coil 13 necessary to cancel the force of the spring 15. Here, the driving force of the voice coil motor is proportional to the value of the current flowing through the voice coil 13. Further, the acceleration α during the movement of magnetism to rad is proportional to [F]. Therefore, when I3 becomes large, the drive current I required to move the magnetic head becomes small, and if the power supply capacity is constant, the speed of movement of the magnetic head is limited.

[Purpose of the invention]

The present invention has been made in view of the above circumstances, and its purpose is to solve the problem when a magnetic disk device stops operating.

To provide a magnetic head control device which can reliably move a magnetic head to a predetermined C8S area and can reduce the power supply capacity necessary for driving the magnetic head to one ton.

[Summary of the invention]

In the present invention, a C8S type magnetic head is provided with a detection means for detecting the level of the main power supply voltage supplied to the voice coil of the voice coil motor. When the main power supply voltage drops below a certain level as a result of detection by the detection means, a current in a certain direction is supplied to the voice coil of the voice coil motor using the residual power supply voltage. This residual power supply voltage is generated by the residual power supply voltage generating means based on the main power supply voltage when the level of the main power supply voltage decreases.

As a result, when the main power supply voltage level drops and the operation of the magnetic disk drive stops, the residual power supply voltage drives the voice coil motor to move the magnetic head to a predetermined position (C8
S area).

[Embodiments of the invention]

An embodiment of the present invention will be described below with reference to the drawings. FIG. 2 is an equivalent circuit of a magnetic head control circuit according to one embodiment. In FIG. 2, 20 is a voice coil that constitutes a voice coil motor that drives a magnetic head. This voice coil 2O consists of a resistance component 21a and an inductance component 21b. 2;'1゜22b is an interlocking switch, which supplies a driving current in ten directions, for example, to the voice coil 2O when turned on. Here, vc is the main power supply voltage in the magnetic disk device, and when the magnetic head is normally
It is supplied at a certain level or higher during operations (data read and write operations). In addition, 24 is a current source and 1
It is controlled by an external circuit (not shown).

Further, the interlocking switches 28a, jl:Ib supply, for example, a unidirectional drive current to the voice coil 20 when turned on. As a result, the interlocking switches 22B, 22b and J8
By controlling the operation of a p J J b, the moving direction of the head arm (10 in FIG. 1) can be controlled.

Further, by adjusting the value of the driving current from the 1% current source 24, the driving force of the voice coil motor can be adjusted.

By the way, the main power voltage ■. When the magnetic disk drive drops below a certain level and the operation of the magnetic disk device stops, the interlocking switches (hereinafter referred to as lid switches) 25a and j5b are turned on. As a result, the reduct current l is supplied to the voice coil 20 in a fixed direction by the residual power supply voltage (VB+ -VB-). Residual power supply voltage (VB+,
VB-) is generated, for example, from a residual power supply voltage generating circuit as shown in FIG. That is, this generation circuit includes a rectifier circuit 40 that rectifies the back electromotive force generated when the supply of power vc to the DC motor 41 is cut off (in response to the operation of the relay switch 42). The DC motor 41 is a motor for rotating a disk in a magnetic disk device. The rectifier circuit 40 includes diodes 4Ja to 4Jd, as shown in FIG.

The back electromotive force causes a current to flow through the coupling diodes 43m and 43c generated on the power terminal A4 side of the coil of the motor 41.

Further, when a back electromotive force is generated on the ground terminal 45 side of the coil of the motor 41, a current is caused to flow through the diodes 4Jb and 43d.

FIG. 3 is a circuit diagram specifically showing the retract switches 25m, 11b and their peripheral circuits in the equivalent circuit of FIG. 2. In FIG. 3, the power supply detection circuit 30 is connected to a resistor R
1. It has a series circuit consisting of a Zener diode J1 and a resistor R, and the main power supply voltage VC is supplied to the Zener diode 31 via the resistor R1. Furthermore, the detection circuit 30 includes a transistor 32 whose emitter is grounded, and the base of this transistor 32 is connected to the Zener diode 31.
and is connected to the connection point of resistor R3. The collector of the transistor 32 is connected to the tract switch 2 shown in FIG.
It is connected to the base of the transistor 33 corresponding to 5a. This transistor 33 has its base connected to the resistor R
, , R, is connected to a voltage dividing circuit 35 . This voltage dividing circuit 35 is supplied with the residual power supply voltage VB0,
A divided voltage of VB+ based on the voltage dividing ratio of the resistor R8°R4 is supplied to the base of the transistor 33.

Further, the transistor 33 has its collector connected to one terminal of the whirlpool coil 20, and its emitter is supplied with the residual power supply voltage vB-. The other terminal of the voice coil 20 is connected to the collector of a transistor 34 corresponding to the tract switch 25b in FIG. 2 above. This transistor 34 is connected to its base to a voltage dividing circuit 36 consisting of resistors R, , R6,
Further, a zero voltage divider circuit 36 whose emitter is supplied with the residual power supply voltage VB+ via a resistor R7 is provided between the power supply vB+ and the collector of the transistor 33, and is connected to the resistor R, .
A divided voltage based on the voltage dividing ratio of R, is supplied to the base of the transistor 340. Incidentally, the series circuit consisting of the resistor R and the Zener diode 37 shown in FIG.

The residual power supply voltage VB+ momentarily becomes a large value.

This circuit prohibits large current from flowing through the voice coil 20. This circuit can prevent the bed arm from colliding with the stopper 16 shown in FIG. 1 due to impact.

Next, the operation of one embodiment will be explained with reference to FIG. First, the main power supply voltage ■. decreases below a certain level,
Assume that the operation of the magnetic disk device has entered a stopped state. As a result, the Zener diode 3 of the main power detection circuit 3O
1 is turned off, so that transistor 32 is turned off. At this time, when the main power supply voltage vc falls below a certain level, the residual power supply voltage (hereinafter referred to as residual voltage) VB+ e VB- is generated from the generating circuit shown in FIG. 4 as described above.

When the transistor 32 of the detection circuit 30 is turned off, the transistor 33 is turned on by the divided voltage of the voltage dividing circuit 35. Further, in conjunction with the on operation of the transistor 33, the transistor (PNP transistor) 34 is turned on.

This is because when the transistor 93 is turned on, the common connection point 38 between the collector of the transistor 33 and one terminal of the voice coil 20 becomes almost zero voltage, and the divided voltage of the voltage dividing circuit 36 is supplied to the pace of the transistor 34. This is to be done. As a result, a tract current IR is supplied to the voice coil 20 through the resistor R, . This retract current 1. is predetermined (K IC#
When adjusted, the voice coil motor beam tract current IR
It is possible to obtain driving force according to the Note that when the main power supply voltage vc is at a certain level and the magnetic disk drive is operating.

Transistor 8: Because 4 and 34 are in the off state.

A current corresponding to the residual voltage vB0 is not supplied to the voice coil 20.

In this manner, when the main power supply voltage vc is leveled down and the operation of the magnetic disk drive is stopped, a tract current I is supplied to the voice coil 20 in a certain direction in accordance with the residual power supply voltage. As a result, the voice coil motor is driven and the head arm (10 in FIG. 1) can be moved to a predetermined position (stopper 16).

Therefore, by adjusting the current value of the retracting electric current fiIu and the direction in which it flows to the voice coil 20 in advance, the magnetic head (that is, the head slider 12 shown in FIG. 1) can be moved to the C8S area on the disk surface. In this case, the means for moving the magnetic head to the C88 area is electrical means as described above.

The conventional stiff spring (15 in FIG. 1) and the like can be omitted. Therefore, power consumption for canceling the force of the spring can be saved, so that the power capacity for driving the magnetic head can be significantly reduced compared to the conventional technology.

In the above embodiment, the residual power supply voltage generating circuit is the fourth one.
It is constructed of a circuit that utilizes the back electromotive force of a DC motor 41 as shown in the figure.

For example, but not limited to this, main power voltage■. A circuit using a capacitor that constantly accumulates may also be used.

〔Effect of the invention〕

As described above in detail, according to the present invention, the magnetic head can be reliably moved to a predetermined position (C8S area) when the operation of the magnetic disk device is stopped using a simple electric circuit. That is, since mechanical means such as springs can be omitted, unnecessary power consumption unrelated to the original drive of the magnetic head can be saved. Therefore, as a result, the power supply capacity for driving the magnetic head can be significantly reduced.

Further, even if the power supply capacity is the same as that of the conventional one, the power supply capacity for driving the magnetic head can be increased, so that there is an effect that the moving speed of the magnetic head can be improved.

[Brief explanation of drawings]

FIG. 1 is a plan view showing the configuration of a conventional magnetic head, FIG. 2 is an equivalent circuit diagram showing the configuration of a magnetic head control circuit according to an embodiment of the present invention, and FIG. 3 is a portion of the magnetic head control circuit. FIG. 4 is a circuit diagram showing an example of a residual power supply voltage generation circuit related to the magnetic head control circuit. 20...Voice coil, 30...Main power supply voltage detection circuit, 32-34...Transistor. Applicant's agent Patent attorney Takehiko Suzue Figure 1 Figure 2 113'' Figure 4

Claims (1)

[Claims] In a magnetic disk drive in which a contact start/stop type magnetic head is driven by a voice coil motor, there is a voltage detection means that detects when the main power supply voltage drops below a certain level, and a voltage detection means that detects when the main power supply voltage drops below a certain level. residual voltage generating means for generating a residual voltage based on the main power supply voltage when detecting that the voltage of the main power supply has become below a certain voltage; A magnetic head control device comprising: a switch means for supplying current in a fixed direction to the voice coil of the voice coil motor according to the residual voltage.