JPH0536660U - Head arm lock mechanism of hard disk device - Google Patents

Abstract

(57) [Summary] [Object] The present invention relates to a head arm lock mechanism for a hard disk drive, and an object thereof is to realize a head arm lock mechanism for a hard disk drive that can improve the reliability of the hard disk drive. A member to be attracted 9 provided at the base end of a head arm 3 to which a magnetic head 2 is fixed at the tip is attracted by an attracting magnet 8, whereby the magnetic head 2 retreats position 1b of a disk 1 of a recording medium. The head arm 3 is held so as to be positioned above, and the holding arm 14a contacts the buffer member 13 fixed inside the yoke before the attracted member 9 contacts the attraction magnet 8. This is a configuration for restricting the rotation of the.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a head arm lock mechanism for a hard disk device.

[0002]

[Prior Art]

 As a head arm lock mechanism of a conventional hard disk device, for example, there has already been proposed by the applicant in Japanese Patent Application No. 3-60486. FIG. 7 is an internal plan view of a hard disk device to which the head arm lock mechanism of the hard disk device is applied. The hard disk device of FIG. 1 has a head arm 3 rotatably held by a hard disk device main body 10 with respect to a disk 1 (hereinafter simply referred to as “disk”) of a recording medium that is rotated at a high speed by a spindle motor 11. The magnetic head 2 fixed to the tip is rotationally driven in the radial direction of the disk 1 by a voice coil motor (hereinafter simply referred to as "VCM") to access an arbitrary data area 1a of the disk 1 so as to access the disk 1. It records and reproduces data to and from. The VCM is the VCM coil 4 fixed to the head arm 3, the VCM magnet 7 fixed to the back surface of the upper yoke 6, and the VCM magnet 7 opposite to the VCM magnet 7 with the upper yoke 6 and VCM coil 4 fixed to the main body 10 of the hard disk device sandwiched therebetween. And a lower yoke fixed to the main body 10 of the hard disk device.

When recording / reproducing data to / from the disk 1 in the hard disk device, a predetermined current is applied to the VCM coil 4 fixed to the head arm 3, and this current and the VCM magnet 7 fixed to the upper yoke 6 are formed. The head arm 3 is rotationally driven by the driving force due to the interaction with the magnetic field. When the recording / reproducing of the data to / from the disk 1 is completed, the head arm 3 is rotationally driven by the action of the VCM so that the magnetic head 2 is located at the retracted position 1b formed on the inner peripheral side of the disk 1. Then, the attracted member 9'provided on the base end side of the head arm 3 is attracted to the attracting magnet 8'substantially fixed to the main body 10 of the hard disk device. This mechanism is called a head arm lock mechanism.

By this head arm lock mechanism, the head arm 3 is held so that the magnetic head 2 is located above the retracted position 1 b of the disk 1. Therefore, even if an impact is applied to the hard disk device due to movement of the device, the magnetic head 2 does not come into contact with the data area 1a of the disk 1, and thus the magnetic head 2 causes the data area 1a of the disk 1 to reach the data area 1a. The recorded data will not be destroyed and the magnetic layer formed on the disc 1 will not be damaged.

[0005]

[Problems to be solved by the device]

 However, in the head arm lock mechanism of the conventional hard disk device having the above-described configuration, the impact when the attracted member 9'is attracted by the attracting magnet 8'and abuts them, the magnetic force which is fixed to the tip of the magnetic member via the head arm 3. The magnetic head 2 which is propagated to the head 2 and which is floating on the disk 1 due to the shock generated by the rotation of the disk 1 may come into contact with the disk 1 which is rotating at a high speed. Thus, the magnetic head 2 may be damaged due to the contact of the magnetic head 2 with the retracted position 1b of the disk 1 which is rotating at a high speed.

Further, when the attracted member 9 ′ and the attracting magnet 8 ′ come into contact with each other, the surface layer portion of the attracting magnet 8 ′, which has a relatively weak strength due to the impact, is slightly broken, and is generated by this. Dust and magnetic particles may adversely affect the gap between the magnetic head 2 and the disk 1, the surface of the disk 1, the magnetic head 2, and other circuits and mechanisms in the hard disk drive body. There was a task to give.

The present invention has been made in view of the above problems, and damages the magnetic head 2 when moving the magnetic head 2 of the hard disk device to the retracted position 1b of the disk 1 and breaks the surface layer of the attraction magnet. It is an object of the present invention to provide a head arm lock mechanism for a hard disk drive, which can prevent the above and improve the reliability of the hard disk drive.

[0008]

[Means for Solving the Problems]

 According to the present invention, when the power supply of the hard disk device is cut off, the magnetic head is fixed to the head arm and the attracted member is attracted by the suction magnet fixed to the main body of the hard disk device to retract the magnetic head from the disk. In a head arm lock mechanism of a hard disk device that holds the head arm so that it is positioned above the magnetic head, the magnetic head is positioned above the retracted position of the disk with the attracted member and the attracting magnet being separated from each other. In this way, an elastic cushioning member that restricts the rotation of the head arm is held so that the head arm is held.

[0009]

[Action]

 In the present invention, since the rotation of the head arm is restricted by the cushioning member made of an elastic body when the magnetic head is moved to the retracted position of the disk, the movement energy of the head arm is absorbed by the cushioning member, No shock is applied to the arm.

[0010]

【Example】

 FIG. 1 is an internal plan view of a hard disk device to which a head arm lock mechanism according to an embodiment of the present invention is applied. In the figure, a magnetic disk (hereinafter simply referred to as "disk") 1 as a recording medium is fixed on a spindle motor 11 which rotates at a high speed. A magnetic head 2 for recording / reproducing data on / from the disk 1 is fixed to the tip of a head arm 3. A VCM (voice coil motor) coil 4 is fixed to the base end side of the head arm 3. The head arm 3 is rotatably held by a rotary shaft 5 fixed to the apparatus body 10. The voice coil motor (hereinafter simply referred to as “VCM”) has an upper yoke 6 having a VCM magnet 7 fixed to the back surface thereof, and a lower yoke (below the upper yoke 6 fixed to the hard disk device body 10). (Not shown), and the VCM coil 4 disposed in a magnetic circuit space between the VCM magnet 7 and the lower yoke via a predetermined magnetic gap therebetween.

Further, the attraction magnet 8, the attracted member 9, and the cushioning member 13 constitute the head arm lock mechanism. With the magnetic head 2 positioned at the retracted position 1b of the disk 1, the VCM coil 4 is fixed to the base end side of the head arm 3 so as to be sandwiched from the left and right sides in FIG. The attraction magnet 8 is fixed to the main body 10 of the hard disk device in the vicinity of the portion where the end of the holding arm 14a of the device faces. The position where the attracting magnet 8 is disposed is located outside the fixing screw 16 on one end side of the portion where the upper yoke 6 is fixed to the hard disk device body 10 and which is far from the disk 1 (lower side in FIG. 1). ) Is near.

Further, a plate-shaped attracted member 9 made of a magnetic material extends toward the attracting magnet 8 at the end of the holding arm 14a at a position close to the attracting magnet 8 in the state of the head arm 3. Are arranged and fixed so that A cushioning member 13 made of an elastic body (rubber in the case of this embodiment) is sandwiched between the lower yoke and a portion where the upper yoke 6 near the attraction magnet 8 is fixed to the main body 10 of the hard disk device. It is firmly fixed.

Next, the operation of the hard disk device configured as described above will be described. First, when the power supply of the hard disk device is cut off, the attracted member 9 fixed to the right rear side of the head arm 3 in FIG. 1 by the head arm lock mechanism is held in a state of being attracted by the attraction magnet 8. This attractive force acts on the attracted member 9 so as to draw the magnetic head 2 toward the inner peripheral side of the disk 1, that is, in the direction D ₁ in FIG. In this state, as described above, the magnetic head 2 fixed to the tip of the head arm 3 is placed on the retracted position 1b of the disk 1 where no data is recorded. With the magnetic head 2 placed on the retracted position 1b of the disk 1, the spindle motor 11 is activated to rotate the disk 1 at a high speed and generate an air flow on the disk 1. Due to this air flow, the magnetic head 2 is levitated from the disk 1 by a very small amount (0.2 to 0.3 μm).

Next, an electric current is supplied to the VCM coil 4 inserted in the above-mentioned magnetic circuit void portion of the VCM. As a result, a driving force proportional to the magnetic flux density formed in the void and the current value flowing in the VCM coil 4 acts on the VCM coil 4 according to Fleming's left-hand rule. This driving force acts so that the magnetic head 2 rotates the head arm 3 in the outer peripheral direction of the disk 1, that is, in the D ₂ direction in FIG. When this driving force becomes stronger than the attraction force exerted by the attraction magnet 8 on the attracted member 9, the head arm 3 is driven clockwise in FIG. 1, that is, in the direction D ₂ .

By the above driving, the magnetic head 2 reaches the data area 1a of the disk 1, and the attraction force of the attraction magnet 8 to the attracted member 9 is not exerted. In this way, the holding state of the head arm 3 is released, and the hard disk device is activated.

After the start-up is completed, the magnetic head 2 is located at a predetermined track position on the data area 1a of the disk 1 in which required data is recorded according to a command from the host computer to which the hard disk device is applied. Will be moved. In this state, the magnetic head 2 records / reproduces data on / from the disk 1. At this time, the information about the position on the disk recorded on the disk 1 is read by the magnetic head 2, the difference from the desired position is formed as an error signal by an external circuit, and is supplied to the VCM coil 4 by the error signal. Controlled current is controlled. As a result, the position of the head arm 3 on the disk 1 is controlled in detail.

Since the magnetic head 2 is on the data area 1a of the disk 1 during the above operation, the attracting force of the attracting magnet 8 does not reach the attracted member 9 of the head arm 2.

When the recording / reproducing of the data for the disk 1 is completed by the above operation, the supply of the current to the VCM coil is stopped. Next, an elastic restoring force of a flexible printed circuit board (not shown) for transmitting an electric signal between the hard disk drive main body 10 and the head arm 3 or a spindle motor 11 generated by idling when power supply is cut off. The counter electromotive force drives the head arm 3 in the counterclockwise direction in FIG. ₁ , that is, in the direction D ₁ . Further, when the magnetic head 2 reaches the retracted position 1b of the disk 1 by this driving, the attraction force of the attraction magnet 8 is applied to the attracted member 9 of the head arm 3 as described above, and the magnetic head 2 is moved to the head arm 3. The disc 1 is held so as to be located above the retracted position 1b.

Next, the head arm lock mechanism of the hard disk drive according to the present invention will be described in detail. FIG. 2 is an enlarged view of the vicinity of the head arm lock mechanism of FIG. 3 and 4 are perspective views of FIG. 2 seen from the direction III and the direction IV, respectively. In the figure, the hatched rectangular portion is the attraction magnet 8, and the hatched circular portion is the cushioning member 13.

FIG. 5 is a perspective view showing the vicinity of the attraction magnet 8, the attracted member 9 and the cushioning member 13 of FIG. 6 is a perspective view in which the yokes 6 and 8a and the holding arm 14a are cut off so that the cushioning member 13 of FIG. 5 can be seen. As shown in the figure, the attraction magnet 8 is fixed to the yoke 8a fixed to the hard disk device body 10 together with the upper yoke 6 by the outer fixing screw 16 of the fixing screws 15 and 16 fixing the upper yoke 6. ..

As shown in the figure, the yoke 8a is bent in a hook shape at two places, one end of which is fixed to the main body 10 of the hard disk device by a fixing screw 16 and the other end of which the suction magnet 8 is outside (see FIG. The lower part of 2) is fixed so that it is exposed. The attracted member 9 is plate-shaped, one end of which is fitted and fixed to the tip of the holding arm 14a, and the other end faces the exposed outer surface (lower side of FIG. 2) of the attraction magnet 8. Have been extended to do so. Since the area of the attracted member 9 facing the attracting magnet 9 is large as described above, the attracting force of the attracting magnet 9 to the attracted member 9 becomes strong, and therefore the head arm 3 is not affected by vibration or impact. The ability to continue being held in the state of FIGS. 1 and 2, that is, the holding ability of the head arm lock mechanism can be improved.

The buffer member 13 has a columnar shape, and is fitted into the circular recesses formed in the upper yoke 6 and the lower yoke so that the upper and lower ends thereof are fitted, and further adhered to the upper yoke 6. And is sandwiched and fixed between the lower yoke and the lower yoke. As described above, since the buffer member 13 is fixed to the inner surface of the portion where the upper yoke 6 is fixed to the hard disk device body 10, the head arm 3 rotates counterclockwise in FIGS. 1 and 2. When this happens, the side surface of the holding arm 14a comes into contact with the cushioning member 13 and its rotation is locked.

In the head arm lock mechanism configured as described above, the attracted member 9 is attracted while the magnetic head 2 at the tip of the head arm 3 is located on the retracted position 1b where data of the innermost peripheral portion of the disk 1 is not recorded. It is close to the magnet 8. As a result, the attractive force of the attractive magnet 8 is applied to the attracted member 9. Here, the side surface of the holding arm 14a comes into contact with the buffer member 13 before the attracted member 9 comes into contact with the attracting magnet 8, whereby the rotation of the head arm 3 is restricted. Therefore, the attracted member 9 is close to the attraction magnet 8 and does not abut each other when attracted by the attraction magnet 8 (states of FIGS. 1 and 2). In this way, the holding state of the head arm 3 is formed.

As described above, when the magnetic head 2 is moved to the retracted position 1b of the disk 1 when the power supply of the hard disk device is cut off, the holding arm 14a of the head arm 3 abuts on the cushioning member 13 made of an elastic body. Since the rotation of the head arm 3 is restricted, when the rotation of the head arm 3 is locked, the shock of the holding arm 14a colliding with the shock absorbing member 13 is absorbed by the shock absorbing member 13. Therefore, since the shock is not propagated to the magnetic head 2 through the head arm 3, the magnetic head 2 does not come into contact with the retracted position 1b of the disk 1 which continues to rotate at high speed, and the magnetic head 2 is damaged. Never.

Further, since the attracted member 9 is prevented from directly contacting the attracting magnet 8, the surface layer portion of the attracting magnet 8 is not destroyed by the impact of collision, and dust, magnetic particles, etc. It does not adversely affect the gap between the disk 2 and the disk 1, the magnetic head 2, the disk 1, and other circuits and mechanisms of the hard disk device.

Further, since the attracted member 9 is provided so as to extend from the holding arm 14a to the attracting magnet 8, the attracted member 9 is retained even if the holding arm 14a and the attracting magnet 8 are relatively separated from each other. The attraction force of the attraction magnet 8 is sufficiently exerted on the head arm 3 and the holding state of the head arm 3 (states of FIGS. 1 and 2) can be easily maintained even against an impact given to the head arm lock mechanism when the hard disk device is moved. Is never cancelled. Further, by inserting a buffer member 13 of a sufficient size between the holding arm 14a and the attraction magnet 8, it is possible to increase its shock absorbing capacity. As a result, the shock when the holding arm 14a collides with the buffer member 13 is sufficiently absorbed, and the shock is prevented from propagating to the magnetic head 2.

In this embodiment, the cushioning member 13 is fixed to the yoke and is substantially fixed to the hard disk device main body 10. However, the cushioning member 13 is fixed to the holding arm 14 a of the head arm 3. The head arm 3 may be restricted from rotating by contacting the inner wall surface of the upper yoke 6.

[0028]

[Effect of the device]

 As described above, according to the present invention, the head arm lock mechanism holds the head arm and the attraction magnet with a gap therebetween so as not to collide with each other, and the buffer member moves the magnetic head to the retracted position of the disk. Since the shock received by the head arm when stopped is absorbed, the magnetic head does not come into contact with the retracted position of the disk during high-speed rotation, the magnetic head is not damaged, and the attraction magnet is Since it does not come into contact with the attracted member, the attraction magnet is not destroyed, dust and magnetic particles are prevented from being generated, and the gap between the magnetic head and the disk, the magnetic head, the disk, and the hard disk drive Other circuits and mechanisms will not be adversely affected. Therefore, the reliability of the hard disk device can be improved.

[Brief description of drawings]

FIG. 1 is an internal plan view of a hard disk device to which a head arm lock mechanism according to an embodiment of the present invention is applied.

FIG. 2 is an enlarged view of the head arm lock mechanism of FIG.

FIG. 3 is a perspective view seen from the direction of III in FIG.

FIG. 4 is a perspective view seen from the direction of IV in FIG.

5 is an enlarged perspective view of the head arm mechanism of FIG. 2. FIG.

FIG. 6 is an enlarged perspective view of a state where a part of the yoke of FIG. 5 is cut off.

FIG. 7 is an internal plan view of a hard disk device to which a conventional head arm lock mechanism is applied.

[Explanation of symbols]

 1 disk 1a data area 1b retreat position 2 magnetic head 3 head arm 4 VCM coil 5 rotating shaft 6 upper yoke 7 VCM magnet 8 attraction magnet 8a yoke 9 attracted member 10 hard disk drive main body 11 spindle motor 13 cushioning member 14a, 14b holding Arms 15 and 16 fixing screws

Claims (1)

[Scope of utility model registration request] 1. When the power supply of the hard disk device is cut off, a attracting magnet fixed to the main body of the hard disk device attracts a member to be attracted provided to a head arm to which the magnetic head is fixed, so that the magnetic head is retracted to the disk. In a head arm lock mechanism for a hard disk device that holds the head arm so that it is located above, the magnetic head is located above the retreat position of the disk with the attracted member and the attracting magnet being separated from each other. A head arm lock mechanism for a hard disk drive having a cushioning member made of an elastic material that restricts rotation of the head arm so that the head arm is held.