JPH0536659U - 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 holding plate 9 provided on the head arm 3 is attracted by a holding magnet 8 when the power is turned off, and the head arm is held so that the magnetic head 2 is located above the head retreat position 1b of the disk 1. Therefore, the temperature coefficient of the magnetic field strength of the material of the holding magnet 8 is substantially equal to the temperature coefficient of the magnetic field strength of the material of the VCM magnet 7 that constitutes the VCM.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a head arm lock mechanism for a hard disk device that holds a magnetic head on a head retracted position of the disk when the power supply of the hard disk device is cut off.

[0002]

[Prior Art]

 As a head arm lock mechanism of a conventional hard disk device, for example, there have already been proposed by the applicant in Japanese Patent Application Nos. 3-40021 and 3-60486. In a hard disk device to which this head arm lock mechanism is applied, a head arm rotatably held in the main body of the hard disk device with respect to a recording medium disk (hereinafter simply referred to as “disk”) that is rotated at high speed by a spindle motor. A magnetic head fixed to the tip of the disk is driven by the head arm drive mechanism in the radial direction of the disk to access an arbitrary data area of the disk, thereby recording / reproducing data to / from the disk. The head arm drive mechanism is provided on the opposite side of the upper yoke with the drive coil fixed to the head arm, the drive magnet fixed to the upper yoke, the upper yoke fixed to the main body of the hard disk drive and the drive coil sandwiched. It is composed of a lower yoke fixed to the main body of the hard disk drive.

In this hard disk device, at the time of recording / reproducing data to / from the disk, a predetermined current is applied to the drive coil fixed to the head arm, and this current and a drive magnet substantially fixed to the main body of the hard disk device are formed. The head arm is rotationally driven by the driving force (hereinafter simply referred to as the “driving force of the driving magnet”) due to the interaction with the magnetic field. When the recording / reproducing of data to / from the disk is completed, the head arm drive mechanism moves the head arm so that the magnetic head is located on the head retreat position formed on the inner circumference side of the disk. Then, the holding member provided on the base end side of the head arm is attracted to the holding magnet fixed to the main body of the hard disk device, and the head arm is held in the above state. This mechanism is called a head arm lock mechanism.

The head arm lock mechanism prevents the magnetic head from falling onto the data area of the disk even when the hard disk apparatus receives an impact due to movement of the apparatus or the like. It does not destroy the data recorded on the disc or damage the magnetic layer formed on the disc.

FIG. 2 shows the magnetic flux density formed by each of the drive magnet (made of Nd-Fe-B) and the holding magnet (made of 2-17 series Sm-Co) applied to the hard disk device having the above-mentioned configuration. The graph of a temperature characteristic is shown. In the figure, the straight line C ₁ shows the temperature characteristic of the magnetic flux density formed by the driving magnet (hereinafter, the magnetic flux density is proportional to the strength of the magnetic field, so it will be simply referred to as “the magnetic field strength of the driving magnet” hereinafter). ₂ shows the temperature characteristic of the magnetic flux density formed by the holding magnet (hereinafter, simply referred to as the "magnetic field strength of the holding magnet" as in the driving magnet).

As shown in the figure, at low temperature, that is, at temperature T ₁ , the magnetic field strength of the driving magnet is stronger than that of the holding magnet, but at room temperature, that is, at temperature T ₀ , both are strong. When they become equal, and when the temperature is higher, that is, at the temperature T ₂ , their relationship is reversed. That is, the magnetic field strength of the holding magnet is stronger than the magnetic field strength of the driving magnet.

[0007]

[Problems to be solved by the device]

In the conventional head arm lock mechanism of the hard disk drive having the above-mentioned structure, the driving force of the driving magnet generated by passing a current through the driving coil is relatively strong at low temperature, that is, at the temperature T ₁ , and conversely for holding. The magnet's attractive force is relatively weak. Therefore, when the power is turned on to move the magnetic head over the data area of the disk in order to record / reproduce data to / from the disk at a low temperature (this operation is simply referred to as “startup” below), the drive magnet The holding force of the head arm can be relatively easily separated from the holding magnet by the driving force. However, when the temperature is high, that is, at the temperature T ₂ , the driving force of the driving magnet is relatively weak and the attraction force of the holding magnet is relatively strong. Therefore, the holding member of the head arm cannot be easily separated from the holding magnet even by the driving force of the driving magnet.

Therefore, in order to drive the hard disk device at a high temperature, the holding member cannot be separated from the holding magnet unless a relatively large driving current is supplied to the driving coil. Therefore, power consumption at startup increases. Furthermore, since a large amount of current is applied to the drive coil in this way, the drive coil heats up and the life of the drive coil is shortened, and the life of the drive IC that supplies current to the drive coil is overcurrent. Contracted for. Furthermore, if the holding member cannot be separated from the holding magnet due to insufficient driving force of the driving magnet, the hard disk drive cannot be started.

Further, when a holding magnet having a relatively weak magnetic field strength is applied so that such a problem does not occur, when the power supply of the hard disk device is cut off, the magnetic head is placed on the head retracted position of the disk. The ability to hold the head arm in place is reduced. Therefore, the holding member of the head arm may be separated to a position where the attraction force of the holding magnet does not reach due to the impact of the movement of the hard disk drive or the like. In this case, the magnetic head fixed to the head arm may fall into the data area of the disk, destroy the data recorded in the data area, or damage the magnetic layer formed on the disk. There was a problem that

Alternatively, a so-called sticking phenomenon in which the magnetic head adheres to the disk and sticks to it may occur. When this phenomenon occurs, the magnetic head cannot be easily separated from the disk, so that the hard disk drive cannot be started. In addition, when the above-mentioned adhesion phenomenon occurs when the magnetic head is on the data area of the disk, there is a problem that the data recorded in the data area is destroyed.

The present invention has been made in view of the above problems, and prevents the increase of power consumption and shortens the life of the drive coil by ensuring the movement of the head arm when the hard disk device is activated. It is an object of the present invention to provide a head arm lock mechanism for a hard disk drive that can prevent the above and further improve the holding ability of the head arm when not in use.

[0012]

[Means for Solving the Problems]

 According to the present invention, when a power supply of a hard disk device is cut off, a magnetic head is fixed and a holding member provided on a head arm movably held in the hard disk device body is attracted by a holding magnet fixed to the hard disk device body. In a head arm lock mechanism of a hard disk device that holds the head arm so that the magnetic head is located on a head retracted position of a disk of a recording medium, the holding magnet is substantially fixed to the main body of the hard disk device. The head arm is driven so as to move the magnetic head above the data area of the disk by the interaction between the magnetic field formed by the driven magnet and the current flowing in the drive coil fixed to the head arm. Approximately the same as the drive magnet of the head arm drive mechanism It is configured to have a temperature characteristic of the field strength.

[0013]

[Action]

 In the present invention, since the relative relationship of the magnetic field strengths of the driving magnet and the holding magnet hardly changes even when the temperature changes, the holding magnet is supplied by supplying a substantially constant current to the driving coil regardless of the ambient temperature. The head arm held by the suction force can be driven to rotate by the head arm drive mechanism.

[0014]

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 (driving coil) 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 (the head arm drive mechanism; hereinafter simply referred to as “VCM”) has a VCM magnet 7 (the drive magnet) fixed to the back surface and fixed to the hard disk device body 10 by an upper yoke 6. The VCM, which is located behind the upper yoke 6 and is not shown in the figure, and the magnetic circuit space between the VCM magnet 7 and the lower yoke, both of which are provided with a predetermined magnetic gap therebetween. It is composed of a coil 4. Further, the holding magnet 8 fixed to the apparatus main body 10 and the holding plate further fixed to the right rear end (downward in FIG. 1) to which the VCM coil 4 on the base end side of the head arm 3 is fixed. The head arm lock mechanism is constituted by 9 (the holding member).

In the head arm lock mechanism described above, the magnetic holding head 2 fixed to the tip of the head arm 3 is held on the head retreat position 1b where the data of the innermost peripheral portion of the disk 1 is not recorded and the holding magnet. The holding member 9 is attracted by the holding magnet 8 and the holding magnet 9 holds the holding plate 9 in this state. The holding plate 9 may be directly attracted to the holding magnet 8, or the head arm 3 may be rotated in order to prevent the holding magnet 8 from being damaged by the contact of the holding plate 9. By restricting the holding plate 9, the holding plate 9 may be attracted in a state of being close to the holding magnet 8 and may not come into contact with the holding magnet 8.

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 off, the holding plate 9 fixed to the right rear end of the head arm 3 is held by the holding magnet 8 while being attracted by the head arm lock mechanism. This attracting force acts on the holding plate 9 so as to draw the magnetic head 2 toward the inner peripheral side of the disk 1, that is, 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 head retreat position 1b where the data of the disk 1 is not recorded.

With the magnetic head 2 placed on the disk 1, the spindle motor 11 is activated to rotate the disk 1 at high speed. Due to the air flow generated on the disk 1 by this rotation, the magnetic head 2 is levitated from the surface of 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 arranged in the magnetic circuit void of the VCM. As a result, a driving force proportional to the magnetic flux density formed in the void and the value of the current flowing through the VCM coil 4 (hereinafter simply referred to as "the driving force of the VCM magnet 7") is generated by Fleming's left-hand rule. It acts on the VCM coil 4. This action works so that the head arm 3 is rotationally driven so that the magnetic head 2 moves 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 holding magnet 8 on the holding plate 9, the head arm 3 is driven clockwise in FIG. 1 (that is, the direction D ₂ ). When the magnetic head 2 reaches the data area 1a of the disk 1 by the above driving, the holding plate 9 is sufficiently separated from the holding magnet 8 and the attraction force of the holding magnet 8 to the holding plate 9 is not exerted. The above operation is referred to as the activation of the hard disk device.

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 and reproduces data on and from the disk 1. At this time, the information about the position on the disk recorded on the disk 1 is simultaneously read by the magnetic head, and the difference from the desired position is formed as an error signal by an external circuit, and the error signal causes the VCM coil 4 to move. The current supplied 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 holding plate 9 of the head arm 2 is not attracted by the holding magnet 8.

When the recording / reproducing of the predetermined data to / from the disk 1 is completed by the above operation, the supply of the current to the VCM coil is stopped first. Next, the elastic restoring force of the flexible printed circuit board 12 that transmits electrical signals between the hard disk drive body 10 and the head arm 3, and the counter electromotive force of the spindle motor 11 that is generated by the power supply being cut off and idling. , And an action such as friction of the head slider is exerted on the head arm 3. Due to this action, the head arm 3 is driven counterclockwise in FIG. 1 and immediately in the direction D ₁ . By driving the head arm 3, the magnetic head 2 reaches the head retreat position 1b of the disk 1. Here, as described above, the attraction force of the holding magnet 8 to the holding plate 9 of the head arm 3 is applied, and the head arm 3 holds the magnetic head 2 at a position for holding the magnetic head 2 at the innermost portion of the head retract position 1b of the disk 1. To be done.

Next, the materials of the VCM magnet 7 and the holding magnet 8 having the features of the present invention will be described. In the case of this embodiment, Nd-Fe-B is applied to both the VCM magnet 7 and the holding magnet 8. This material is an alloy of neodymium, iron, boron and a small amount of other metallic elements, and the magnetic hysteresis curve shown in FIG. 3 (the magnetic flux of the material shown on the vertical axis by sequentially increasing and decreasing the external magnetic field shown on the horizontal axis). The temperature coefficient of the magnetic flux density (residual magnetism) at the Br point and the value of the magnetic field strength (coercive force) at the Hc point in the graph showing the change in density are approximately −0.13% / ° C. in this embodiment, respectively. It is approximately -0.6% / ° C.

Further, the driving force of the VCM magnet 7 with respect to the head arm 3 exceeds the attraction force of the holding magnet 8 at room temperature. As described above, since the temperature coefficients of both magnetic field strengths have the same negative value, the magnetic field strength of both the VCM magnet 7 and the holding magnet 8 is strengthened at the same rate at low temperature, and similarly at the high temperature, both of them are at the same rate. Strength is weakened. Therefore, the magnetic field strength of the holding magnet 8 does not become stronger than the magnetic field strength of the VCM magnet 7 at a low temperature, and the driving force of the VCM magnet 7 is always attracted by the holding magnet 8 when the hard disk device is started. Then, the holding state of the head arm 3 is released, and the magnetic head 2 is moved to the data area 1a of the disk 1. Although Nd-Fe-B is applied to both the VCM magnet 7 and the holding magnet 8 in the above embodiment, the present invention is not limited to this, and Sm-Co (alloy of samarium and cobalt, temperature coefficient of magnetic field strength is composition). 2-17 series and 1-5 series may be -0.035% / ° C and -0.04% / ° C respectively, and it is not always necessary to use the same material. , Such as Nd-Fe-B and Sr (strontium) ferrite (the temperature coefficient of the magnetic field strength is -0.2% / ° C), a combination of materials having relatively close temperature coefficient of the magnetic field strength is used. You may apply. As described above, by applying materials having the same or similar temperature coefficient of magnetic field strength to each other, that is, having substantially the same temperature characteristics, for the VCM magnet 7 and the holding magnet 8, even if the ambient temperature changes. The holding state of the head arm 3 can be reliably released when the hard disk device is activated. That is, the head arm 3 can be driven so that the magnetic head 2 is surely moved onto the data area 1a of the disk 1 by the driving force of the VCM magnet.

As described above, since the hard disk device can be surely started up, the reliability of the hard disk device can be improved. Further, since it is not necessary to apply an overcurrent to the VCM coil 4 in order to release the holding state of the head arm 3 even at a high temperature, it is possible to drive the VCM coil 4 and the VCM coil 4 with an electric current. The life of the IC is not shortened due to overcurrent, and it can contribute to the improvement of reliability of the hard disk device. Further, since the current supplied to the VCM coil 4 at the time of starting the hard disk device can be minimized to a necessary level, power saving can be achieved.

Further, since the relative relationship between the magnetic field strengths of the VCM magnet 7 and the holding magnet 8 is hardly changed even if the ambient temperature is changed, it is not necessary to consider the margin related to the temperature change. It is possible to optimize the setting of the magnetic field strength of the magnet. That is, the strength of the magnetic field formed by the holding magnet 8 and its magnetic circuit can be increased as necessary. Therefore, the holding ability of the holding arm 8 for holding the head arm 3 when the power supply of the hard disk device is cut off can be enhanced, and the head arm 3 is protected against vibrations, shocks, etc., which are applied to the hard disk device when the hard disk device is moved. The holding plate 9 does not move away from the holding magnet 8 and the attraction force of the holding magnet 8 does not fall. In this way, since the magnetic head 2 can be reliably held on the head retreat position 1b of the disk 1 when the hard disk device is not operating, the magnetic head 2 does not drop into the data area 1a of the disk 1 and the magnetic head The data recorded on the disc 1 is not destroyed by the item 2. Further, as long as the magnetic head 2 is held on the head retreat position 1b, even if an adhesion phenomenon of the magnetic head 2 occurs on the head retreat position 1b, the driving force of the disk 1 with a relatively low torque causes the magnetic head 2 to move. The sticky state can be released. Therefore, the hard disk device can be started without imposing an excessive load on the spindle motor 11, which can contribute to the improvement of the reliability of the hard disk device.

Further, if a combination of Nd-Fe-B and ferrite is applied to the materials of the VCM magnet 7 and the holding magnet 8 described above, ferrite is relatively inexpensive and has high strength and stability. By carrying out production, it is possible to reduce the price of the magnet and improve the reliability of the hard disk drive.

[0028]

[Effect of the device]

 As described above, according to the present invention, even if the ambient temperature changes, the hard disk drive can be reliably started up without causing an excessive current to the drive coil, so that the power consumption of the hard disk drive can be saved. It is possible to improve reliability. Furthermore, the magnetic field strength of the holding magnet can be increased as necessary, and the magnetic head does not move during non-operation, thus eliminating the damage to the data recorded on the disk and the destruction of the magnetic layer of the disk. Therefore, it is possible to realize the head arm lock mechanism of the hard disk drive that can improve the reliability of the hard disk drive.

[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 a diagram showing temperature characteristics of magnetic field strengths of a driving magnet and a holding magnet applied to a conventional hard disk device.

FIG. 3 is a magnetic hysteresis curve of a ferromagnetic material.

[Explanation of symbols]

 1 disk 1a data area 1b head retreat position 2 magnetic head 3 head arm 4 VCM coil (driving coil) 5 rotating shaft 7 VCM magnet (driving magnet) 8 holding magnet 9 holding plate (holding member) 10 hard disk device body 11 Spindle motor 12 Flexible printed circuit board

Claims (1)

[Scope of utility model registration request] 1. A holding magnet fixed to a main body of a hard disk device attracts a holding member provided on a head arm fixed to a magnetic head when the power supply of the hard disk device is cut off and movably held in the main body of the hard disk device. In a head arm lock mechanism of a hard disk device for holding the head arm so that the magnetic head is located on a head retracted position of a disk of a recording medium, the holding magnet is substantially fixed to the main body of the hard disk device. A head for driving the head arm so as to move the magnetic head onto the data area of the disk by the interaction of the magnetic field formed by the driving magnet and the current flowing in the driving coil fixed to the head arm. A temperature characteristic having a magnetic field strength substantially equal to that of the driving magnet of the arm driving mechanism. Head arm locking mechanism of a hard disk device having a.