JP2003189676A - Disk apparatus and spindle motor control circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce power consumption when starting the spindle motor of a disk apparatus, and to extend the life when setting a battery to be a power supply. <P>SOLUTION: After a switch means 121 is connected for charging a capacitor 11 by the back electromotive force of a motor 131 immediately after current to a spindle motor 131 from a spindle motor speed control circuit 14 is interrupted by a motor stop instruction, the switch means 121 is broken. The current is supplied to the motor 131 from the speed control circuit 14 by the motor start instruction, and at the same time a switch means 122 is broken after the switch means 122 is connected for supplying energy accumulated in the capacitor 11 to the speed control circuit 14. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disk device for recording and reproducing information on a disk rotated by a spindle motor and a spindle motor control circuit.

[0002]

2. Description of the Related Art With the improvement of recording density, it has become easy to realize a compact and large-capacity portable information storage device in a disk device such as a magnetic disk device. Generally, in the case of such a portable disk device, a battery or a rechargeable battery having a limited power capacity is used as a power source,
It is essential to reduce power consumption.

In a magnetic disk device, information is converted into a magnetic field by a magnetic head and recorded as magnetization on a disk medium rotated by a spindle motor, and the magnetic field generated from this magnetization is converted into an electric signal by the magnetic head. The recorded information is read.

The operation of stopping the rotation of the spindle motor is generally widely adopted for the purpose of reducing the power consumption of the magnetic disk device. For example, ANSI X3
In the ATA interface standard defined in 9.2, a function called an automatic power down sequence is adopted as a standard. This is to wait for the next data transfer request in a state where the spindle motor is automatically stopped and the power consumption is reduced when the data transfer request does not occur within the time set by the user in advance in the standby timer. It is a function.

[0005]

When the spindle motor in the stopped state is started to record and reproduce information, it is necessary to supply a current several times as much as that in the steady rotation in order to supply the rotational energy of the disk. is there. At this time, when a dry battery, a rechargeable battery or the like is used as a power source, a voltage drop and power consumption occur due to the internal resistance of the battery. Generally, as the amount of electric power stored in the battery decreases, the internal resistance increases, the voltage drop at the time of starting the motor becomes noticeable, and it becomes impossible to start the motor before the amount of electric power in the battery reaches 0. It cannot operate.

In the conventional magnetic disk apparatus, as disclosed in, for example, Japanese Patent Laid-Open No. 2000-251429, when the spindle motor is stopped, the counter electromotive force obtained from the rotational energy accumulated in the motor and the disk is cut off when the emergency power is cut off. Although an example is shown in which the head is used as electric power for retracting from the disk recording area, the rotational energy was discarded during normal operation.

In Japanese Patent Laid-Open No. 9-147470, a small battery is charged with counter electromotive force when the spindle motor is stopped,
Techniques have been proposed for supplying the electric power when the spindle motor is restarted. However, since the voltage due to the back electromotive force has a characteristic that it decreases as the rotation speed decreases when the spindle motor is stopped, the means for charging the battery becomes complicated, and it is difficult to efficiently use the back electromotive force when the spindle motor is stopped. there were.

An object of the present invention is that a part of the back electromotive force due to inertial rotation when the spindle motor is stopped can be efficiently used for starting the spindle motor, and the current supplied from the battery to the spindle motor can be suppressed to reduce the battery power. It is to realize a long life.

[0009]

DISCLOSURE OF THE INVENTION A disk device according to the present invention comprises a capacitor for charging a counter electromotive force of a spindle motor, a switch means for connecting and disconnecting one end of the capacitor and a power input terminal of the spindle motor, and a capacitor and a spindle motor speed. A switch means for connecting to a power supply terminal of the control circuit is provided.

Immediately after power supply to the motor is cut off by the spindle motor stop command, the capacitor is connected to the spindle motor, the capacitor is charged by the counter electromotive force generated during inertial rotation of the motor, and the spindle motor is restarted. At times, a capacitor is connected to the power supply to discharge the accumulated charge instantly and play a part of power supply to the motor, thereby suppressing the current from the external power supply and reducing the loss due to the internal resistance of the battery. Battery life can be extended.

[0011]

FIG. 1 is a block diagram showing a disk device according to a first embodiment of the present invention. Further, FIG. 2 is a timing chart of the control and current and voltage of each part in this embodiment.

The spindle motor drive unit of the magnetic disk drive 1 of this embodiment is a single-phase DC spindle motor 131.
, Capacitor 11, external power supply 2, capacitor 11
And a switch means 121 for connecting one of the terminals of the spindle motor 131 and the spindle motor rotation speed control circuit 1
4 and switch means 122 connected to the capacitor 11 and the power input terminal of the spindle motor rotation speed control circuit 14. For the switch means 121 and 122, for example, a semiconductor switch such as a relay switch or a power MOS transistor can be used, but it is desirable that the switch drive power, the leakage current when the switch is off and the switch on resistance are small.

During recording, reproduction and idle operation, the spindle motor rotation speed control circuit 14 adjusts the current to the spindle motor 131 so that the rotation speed of the spindle motor 131 reaches a required value. At the same time as or after the current from the spindle motor rotation speed control circuit 14 to the spindle motor 131 is cut off by the stop command of the spindle motor 131, the switch means 121 is connected, and the capacitor 11 is driven by the counter electromotive force due to the inertia rotation of the spindle motor 131. To charge.

Here, as shown in FIG. 2, the spindle motor 131 decreases as the rotation speed of the spindle motor 131 decreases.
The counter electromotive voltage of the capacitor decreases, and at the same time, the voltage across the terminals of the capacitor 11 increases due to charging, and the capacitor 11 is charged until these two voltages become equal. Therefore, the energy stored in the capacitor 11 is maximized by shutting off the switch means 121 when the two coincide.
Spindle motor 1 by measurement or simulation in advance
It is possible to obtain the time from the start of charging until the above-mentioned two voltages are coincident with each other by obtaining the time-dependent change of the back electromotive force of 31 and the time-dependent change of the terminal voltage of the capacitor 11. Control as connection time.

The time required to charge the capacitor 11 depends on the time constant determined by the product of the capacity of the capacitor and the resistance of the circuit composed of the capacitor and the spindle motor.
In order to efficiently charge the counter electromotive force of the spindle motor 131, it is desirable that the time constant be shorter than the inertial rotation time after the current supply to the spindle motor 131 is stopped.
When the capacitor voltage V ₁ after charging is lower than the voltage V ₀ of the external power source 2, if the switch means 122 is connected after the switch means 121 is cut off and before the spindle motor 131 is started by the motor start command, the voltage of the capacitor 11 is changed. Is recharged until is equal to the voltage of the external power supply 2. The energy consumed by additional charging is represented by Formula 1 where C is the capacitance of the capacitor.

[0016]

[Number 1] _{C (V 0} -V ¹⁾ at the same time 2/2 (Equation 1) when the current from the motor speed control circuit 14 to the spindle motor 131 is supplied by the starting instruction of the spindle motor 131, the switch means 122 The capacitor 11 is connected to supply current to the motor rotation speed control circuit 14. Here, the switch means 122 is set to the spindle motor 13
By shutting off the electric charge of the capacitor 11 after the start of No. 1 when the electric charge of the capacitor 11 is sufficiently discharged, the current supplied from the external power source 2 can be suppressed as shown in FIG.
It is possible to suppress the loss due to the internal resistance when a battery is used for the battery and extend the battery life.

The optimum connection-disconnection time of the switch means 122 is determined by measuring or simulating in advance the external power supply 2 when the switch means 122 is not connected when the spindle motor 131 is started and when the switch 122 is connected.
From the above, the change with time of the current supplied to the motor rotation speed control circuit 14 is obtained, and it can be determined as the time until the two match. Further, when the spindle motor 131 is started, the energy supplied from the capacitor 11 is given by the _equation 2, V ₁ is larger than V 0/2, and the difference between the _equation 2 and the _equation 1 stops the spindle motor 131. When it is larger than the sum of the energy consumption of the switch means 121 and 122 during the operation and the loss due to the leakage current of the capacitor 11 or the like, the power consumption at the time of starting the motor can be reduced.

[0018]

In Equation 2] _CV ⁰ 2/2 ... (Equation 2) Figure 4 shows the configuration of a second embodiment. The spindle motor drive unit of the magnetic disk device 1 of this embodiment includes a three-phase spindle motor 132, a capacitor 11, an external power supply 2,
Spindle motor speed control circuit 14, spindle motor back electromotive force rectification circuit 15, switch means 12 for connecting the output terminals of capacitor 11 and back electromotive force rectification circuit 15.
1 and a switch means 122 for connecting the capacitor 11 and the power supply terminal of the spindle motor rotation speed control circuit 14. The operation procedure of the switch means 121, 122 for charging and discharging the capacitors is the same as that of the first embodiment. When a multi-phase motor such as a three-phase brushless motor is used as the spindle motor as in this embodiment, the counter electromotive force rectifier circuit 15 is added to charge the capacitor 11 with the rectified counter electromotive force output. By the first
The same effect as that of the embodiment can be obtained.

FIG. 5 shows the configuration of the third embodiment of the present invention. A timing chart is shown in FIG. In this embodiment, the switch means 123 and the voltage adjusting circuit 16 are added to the first embodiment, and after charging the capacitor 11, the switch means 123 connects the terminal of the voltage adjusting circuit 16 and the capacitor 11. The voltage adjusting circuit 16 has a structure capable of generating a preset DC voltage or an arbitrary DC voltage.
When the voltage of the voltage adjusting circuit 16 is set to V ₂ , additional charging is not necessary when the sum of V ₁ and V ₂ is V ₀ or more. V ₁ and V ₂
Is less than V _{0, the} energy consumed by the additional charge is Equation 3 and the energy supplied from the capacitor 11 when the spindle motor 131 is started is Equation 4.

[0020]

[Number 3] ^{_{C (V 0 -V 1 -V 2}} ) 2/2 ... ( number 3)

[0021]

Equation 4] _CV ¹ 2/2 ... (Equation 4) Therefore the difference between _{V 0} and _{V 2} is less than _V 1/2, more number 4 and difference in the number 3, while the spindle motor 131 is stopped When the energy consumption of the switch means 121, 122, 123 and the voltage adjusting circuit 16 and the energy loss of the capacitor 11 are larger than the sum, the power consumption at the time of starting the motor can be reduced.

FIG. 7 shows the configuration of the fourth embodiment of the present invention. This embodiment is similar to the second embodiment except that the switch means 1 is used.
23 and the voltage adjusting circuit 16 are added, the same effect as the third embodiment can be obtained.

In the above, the case where the present invention is applied to a magnetic disk device has been described. However, the present invention is not limited to the magnetic disk device, and any disk device that records and reproduces information by rotating a recording medium by a spindle motor. It is applicable as well. The present invention is also applied to a spindle motor control circuit mounted on a disk device.

[0024]

According to the present invention, the total power consumption for driving a spindle motor of a disk device can be reduced, and when a battery is used as an external power source, power consumption and voltage drop due to internal resistance at the time of starting the spindle motor can be suppressed. It is possible to extend the life of the battery.

[Brief description of drawings]

FIG. 1 is a block diagram showing a first embodiment of the present invention.

FIG. 2 is a timing chart for explaining the first embodiment of the present invention.

FIG. 3 is a diagram showing a current from an external power source at the time of starting the spindle motor according to the first embodiment of the present invention.

FIG. 4 is a block diagram showing a second embodiment of the present invention.

FIG. 5 is a block diagram showing a third embodiment of the present invention.

FIG. 6 is a timing chart for explaining a third embodiment of the present invention.

FIG. 7 is a block diagram showing a fourth embodiment of the present invention.

[Explanation of symbols]

1 ... Disk device, 2 ... External power supply, 11 ... Capacitor,
14 ... Spindle motor rotation speed control circuit, 15 ... Spindle motor counter electromotive rectification circuit, 16 ... Voltage adjustment circuit, 121
... 123 ... switch means, 131 ... single-phase spindle motor, 132 ... 3-phase spindle motor.

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Claims (14)

[Claims] 1. In a disk device equipped with a single-phase DC spindle motor for rotating a disk medium on which information is recorded and reproduced, and a spindle motor rotation speed control circuit, a capacitor and a switch for connecting and disconnecting the capacitor and the terminal of the spindle motor. And a switch means for connecting and disconnecting the capacitor and the power supply input terminal of the spindle motor rotation speed control circuit.When the spindle motor is stopped, the motor and the capacitor are connected to charge the counter electromotive force of the motor, and when the spindle motor starts A disk device characterized by connecting a number control circuit to supply electric power for a capacitor. 2. A disk device including a multi-phase spindle motor for rotating a disk medium on which information is recorded and reproduced, and a capacitor, and a circuit for rectifying a counter electromotive force of the spindle motor in a disk device including a spindle motor rotation speed control circuit. A switch means for connecting and disconnecting the capacitor and the output terminal of the counter electromotive force rectifier circuit, and a switch means for connecting and disconnecting the capacitor and the power supply input terminal of the spindle motor speed control circuit. A disk device, which is connected to charge a counter electromotive force of a motor, and when the spindle motor is started, a capacitor and a rotation speed control circuit are connected to supply power of the capacitor. 3. The disk device according to claim 1, wherein a dry battery or a rechargeable battery is used as a power source. 4. The disk device according to claim 1, wherein when the capacitor is charged, the switch means is shut off immediately after the terminal voltage of the capacitor and the back electromotive force of the spindle motor become equal. . 5. The product of the capacitance of the capacitor and the resistance of the circuit when the capacitor and the spindle motor are connected is shorter than the inertial rotation time when the spindle motor is stopped. The disk device described in 1. 6. When the voltage after charging the capacitor is lower than the power supply voltage of the spindle motor rotation speed control circuit, the capacitor is charged and the power supply and the capacitor are connected to each other before the spindle motor is restarted. The disk device according to claim 1, wherein the disk device is additionally charged. 7. The disk device according to claim 6, wherein the voltage after the capacitor is charged by the back electromotive force of the spindle motor is larger than 1/2 of the power supply voltage of the spindle motor speed control circuit. 8. The method according to claim 1, wherein when the spindle motor is started, power is supplied from the capacitor to the motor rotation speed control circuit, and then the switch means for connecting the capacitor and the motor rotation speed control circuit is cut off. Item 2. The disk device according to item 2. 9. A capacitor comprising a voltage adjusting circuit for generating a fixed or arbitrary DC voltage and a switch means for connecting and disconnecting the capacitor and the voltage adjusting circuit, and connecting the capacitor and the voltage adjusting circuit after charging the capacitor, 3. The disk device according to claim 1, wherein the potential of the terminal is changed while holding the electric charge accumulated in the disk. 10. The voltage generated in the voltage adjusting circuit according to claim 6, which is larger than the difference between the power supply voltage of the spindle motor speed control circuit and twice the voltage immediately after the capacitor is charged by the back electromotive force. A disk device characterized by being equal to or less than a difference between a power supply voltage of a spindle motor rotation speed control circuit and a voltage immediately after a capacitor is charged by a back electromotive force. 11. A single-phase spindle motor rotation speed control circuit, a terminal connected to a capacitor, a switch means for connecting and disconnecting the terminal and a motor connection terminal of the motor rotation speed control circuit, a capacitor connection terminal and a motor rotation speed control circuit. 2. A spindle motor control circuit comprising: switch means for connecting and disconnecting the power supply terminal of 1. and a circuit for controlling the switch means. 12. A multi-phase spindle motor rotation speed control circuit, a spindle motor back electromotive force rectification circuit, a terminal connected to a capacitor, a switch means for connecting and disconnecting the terminal and an output terminal of the back electromotive force rectification circuit, and a capacitor. A spindle motor control circuit comprising: switch means for connecting and disconnecting a connection terminal and a power supply terminal of a motor speed control circuit; and a circuit for controlling the switch means. 13. A voltage adjusting circuit for generating a fixed or arbitrary DC voltage, and a switch means for connecting and disconnecting the capacitor terminal and the voltage adjusting circuit.
The spindle motor control circuit according to claim 1 or 12. 14. A back electromotive force of a spindle motor is charged,
14. A capacitor for supplying the electric power stored at the time of starting the motor to the spindle motor rotation speed control circuit.
Spindle motor control circuit according to.