JP2009158002A - Disk drive - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disk drive which suppresses disk flatter and improve the precision in head positioning. <P>SOLUTION: With a structure of the disk drive 1, disk flatter is suppressed in order to improve the precision in head positioning. Regulators 100 are formed in the carriage arm 5 via a second suspensions 110 to hold the disk surfaces of the disk 3 when inserting the carriage arm 5. Thus, the disk flatter can be suppressed by pressing the surfaces of the disk 3 via air layers. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a disk drive device.

  With the development of information processing technology in recent years, in disk drive devices, for example, hard disk drive devices, improvement in recording density of recording media and improvement in operating speed are increasingly required. Therefore, the positioning accuracy of the magnetic head for reading / writing information on the recording medium with respect to the disk surface is a very important problem. However, since the disk rotates at a high speed in a narrow space in the disk drive device, fluttering called a disk flutter in which the disk vibrates in the direction of the rotation axis is a problem. In order to realize further higher speed and higher storage density in the future, technology for suppressing disk flutter is necessary.

  In Patent Document 1, a fan-shaped squeeze plate is provided at a position opposite to the magnetic head with respect to the rotation axis of the disk, and the compressed air between the disk and the squeeze plate is taken out through a pipe of the squeeze plate to obtain a hydrostatic bearing. A technique is described in which the disk flutter is suppressed by supplying to the head and at the same time, the influence of the friction of the arm is not generated.

However, such a conventional disk flutter suppression technology is contrary to the demand for downsizing the apparatus because the apparatus becomes large. Moreover, since the number of members required is large, there is a possibility that the manufacturing process becomes complicated because the assembly method needs to be changed.
JP 2004-152428 A (FIG. 6)

  The present invention has been made in view of the above points, and an object of the present invention is to provide a disk drive device capable of suppressing disk flutter with a compact configuration.

In order to solve the above problem, a disk drive device according to claim 1 is a disk having a disk surface on which information can be recorded, a motor for rotating the disk,
An arm capable of swinging on the disk surface, an elastically deformable first support portion having one end fixed to the tip portion so as to extend from the tip portion of the arm, and the first support portion A head for recording information on the disk surface or reproducing the recorded information, and a positioning mechanism for positioning the head with respect to the disk surface by driving the arm to swing. One end is fixed to the arm and has a second support part extending to the disk surface side and a surface fixed to the other end of the second support part and facing the disk surface. And a suppressing member that suppresses fluttering of the generated disk.

  According to a seventh aspect of the present invention, there is provided a disk drive apparatus comprising: a disk having a disk surface capable of recording information; a motor for rotating the disk; and recording information on the disk surface or reproducing the recorded information. A head, a first support portion for supporting the head, a first arm for supporting the first support portion at a distal end portion, and the first arm in conjunction with the first arm on the disk side. A second arm disposed on the disk, a drive mechanism for moving and positioning the first arm and the second arm with respect to the disk surface, and a second support portion extending from the second arm. The head is positioned on the disk surface when recording or reproducing information, and has a surface facing the disk surface fixed to the tip of the second support portion so as to face the disk surface. Characterized by comprising a suppressor for suppressing member fluttering of the disk with generated with the rotation of the disk.

  According to the present invention, by disposing a slider on the arm, when the head records / reproduces information on the disk surface, the slider faces the disk surface as the arm moves, thereby suppressing disk flutter. It is possible to provide a disk drive device that can be used.

  Hereinafter, a hard disk drive device (hereinafter referred to as HDD) will be described in detail as a disk drive device according to an embodiment of the present invention with reference to the drawings. Parts that are the same or similar to each other are denoted by common reference numerals, and redundant description is omitted.

(First embodiment)
A first embodiment of the present invention will be described with reference to FIGS. 1 and 2.

  FIG. 1 is a perspective view showing an internal appearance of the HDD 1 according to the first embodiment.

  FIG. 2 is a diagram showing (a) an overall plan view of the HDD 1 (b) a cross-sectional structure taken along AB.

  As shown in FIG. 1 and FIG. 2A, the HDD 1 according to the present embodiment has a housing 2 and two disks 3 that are a plurality of magnetic recording media, 3a and 3b, respectively. And a magnetic head 6 (hereinafter simply referred to as a head) for reading / writing data. Two disks 3 are arranged, and are provided in the housing 2 and rotated while being attached to the spindle motor 4 at a predetermined interval.

  Two carriage arms 5 are arranged on both sides of one disk 3. A head 6 is disposed at the front end of each carriage arm 5 via a first suspension 10 so as to face the disk 3, and reads / writes data from the disk surfaces on both sides of the disk 3.

  The first suspension 10 is an elongated plate-like plate spring that can be elastically deformed. One end of the first suspension 10 is fixed to the tip of the carriage arm 5 and extends from the carriage arm 5. A head 6 is mounted on the other end of the first suspension 10.

  The voice coil motor (VCM) 7 is a mechanism for positioning the head 6 at a target position by rotating the carriage arm 5 in a substantially radial direction on the disk 3 with the bearing portion 8 as a rotation axis. In addition, it has a head IC (not shown) that is connected to the head 6 to control input / output of read / write signals, and a printed circuit board (not shown) provided on the back surface of the housing 1.

  In general, the head 6 includes a substantially rectangular slider and a magnetoresistive head for recording / reproduction formed on the slider (none of which is shown), and is formed at the tip of the first suspension 10. It is fixed to the gimbal part (not shown). The carriage arm 5 is positioned in parallel to the disk surface of the magnetic disk 3 and at a predetermined interval from each other.

  As shown in FIG. 3B, in this embodiment, each carriage arm 5 has a second suspension 110 between the bearing portion 8 and the fixing point of the first suspension 10 (the tip of the carriage arm 5). One end is fixed. That is, the second suspension 110 is provided so as to extend from the middle of the carriage arm 5 to the disk surface side. A restraining member 100 for restraining fluttering of the disk 3 is disposed at the front end (the other end) of the second suspension 110 so as to face the disk surface. Note that the first suspension 10 and the second suspension 110 may be formed integrally with the corresponding carriage arm 5.

  The suppressing member 100 has a planar structure on one surface, and the planar portion is arranged substantially parallel to the disk 3. Since the second suspension 110 and the suppression member 100 are attached to the carriage arm 5, the suppression member 100 faces the surface of the disk 3 at least when data is read / written by the head 6. The restraining member 100 is configured to be positioned on the disk surfaces of the disks 3a and 3b when reading / writing is performed as the carriage arm 5 swings. For this reason, it is possible to suppress the disk flutter by suppressing the disk 3 through the air layer by utilizing the floating effect by the rotation of the disks 3a and 3b.

  The material of the restraining member 100 is required not to be deformed in the long term even when it is on the disk 3 that rotates at high speed, like the slider of the head 6. Therefore, a material having excellent mechanical strength and rigidity, wear resistance, and thermally and chemically stable material is desirable. However, since the general head 6 is brought close to the disk surface of the disk 3 on the order of nanometers in order to improve data reading / writing accuracy, the slider of the head 6 is required to have a very smooth processed surface. For this reason, alumina, titanium, carbide and the like are mainly used. On the other hand, the suppressing member 100 does not need to be as close to the magnetic disk 3 as the slider of the head 6, and a ceramic material other than alumina, titanium, or carbide, or other metal materials may be used.

  A shorter distance between the disk 3 and the restraining member 100 is effective in restraining disk flutter. However, if the restraining member 100 and the disk 3 come into contact with each other, a failure may occur. Even if it is not as close as the distance, the suppression effect can be obtained. Therefore, the distance between the disk 3 and the suppressing member 100 may be such that the floating effect by the rotation of the disk 3 can be obtained, and the floating effect can be obtained at a distance of about 10 nm to 1 μm. The second suspension 110 is arranged in such a length that the distance becomes such a distance.

  Similar to the first suspension 10, the second suspension 110 is a leaf spring that elastically changes, and the disc 3 is sandwiched by the restraining member 100 using the effect that the restraining member 100 floats due to the rotation of the disc 3. The elastic value required for the second suspension 110 varies depending on the size of the disk 3, the number of rotations, the size of the slider, etc., but the second suspension is the same or larger than the spring constant of the first suspension. Is preferred. This is because as the spring constant of the second suspension is larger, the effect of suppressing the disk 3 is obtained. When the restraining member 100 is positioned closer to the outer periphery of the disk 3 than the head 6, the flying effect due to the rotation of the disk 3 can be obtained more by the squeeze effect. Further, even if the spring constant of the second suspension 110 is made slightly larger than that of the first suspension 10 by making the length of the second suspension 110 shorter than that of the first suspension 10, the disk 3 and the restraining member 100. It is possible to keep the distance.

  Unlike the head 6, the restraining member 100 does not need to be positioned and the distance from the disk 3 need to be determined strictly. Therefore, the suppressing member 100 may be larger than the head 6. A larger area is more effective, but if it is too large, the carriage arm 5 may vibrate during the swinging motion, and the positioning accuracy of the head 6 may be lowered. It is desirable that the size is large enough to allow the disk 3 to float by rotation.

  When the head 6 reads / writes information from an area close to the outer periphery of the disk surface, a read error due to fluttering of the disk 3 is more likely to occur. Therefore, when the head 6 is positioned in the vicinity of the outer periphery of the disk 3, the shape of the suppressing member 100 that can obtain a floating effect by the rotation of the disk 3 is preferable.

  In this embodiment, two heads 6 and restraining members 100 attached to each carriage arm 5 with respect to one disk 3 are positioned facing each other, and are arranged so as to sandwich each magnetic disk 3 from both sides. Has been. In addition, since the structure is such that a plurality of carriage arms 5 and heads 6 can be pressed at both ends when reading / writing data on one disk surface, the effect of further suppressing disk flutter can be expected and the disk flutter can be further reduced. it is conceivable that.

  Each of the first suspension 10 and the second suspension 110 may be formed integrally with the corresponding second carriage arm 120.

  In order to improve the recording density of the disk 3, a structure is known in which carriage arms 5 are provided on both sides of the disk 3, and a head 6 is provided at the tip of each carriage arm 5. In that case, since the upper and lower carriage arms 5 normally move in conjunction with each other, they can be restrained by the restraining members 100 from both sides at the same position on the disk surface of the disk 3. It is considered that the disk flutter can be further suppressed by suppressing the disk 3 with the suppressing member 100 from both sides.

  Further, in the configuration of the existing disk drive device, one carriage arm 5 is substantially in contact with the disk 3 only by the head 6, whereas in the present invention, the disk 3 is separated from the disk 3 at two points separated from the restraining member 100. It is the structure which substantially contacts. This can also be said to be an effective configuration for suppressing disk flutter.

  In the present embodiment, since the second suspension 110 is elastically deformed, it is possible to obtain an effect that the suppressing member 100 floats due to the squeeze effect caused by the rotation of the disk 3. Therefore, the suppressing member 100 can be provided at a distance close to the disk 3 without contacting the disk 3. Therefore, even if the structure is close to the disk 3, the disk flutter can be suppressed without contacting the disk 3.

When the HDD 1 senses an external shock such as an impact, the carriage arm 5 is generally controlled so that the head 6 is retracted from the disk surface of the disk 3. In this embodiment, since the restraining member 100 and the second suspension 110 are arranged on the carriage arm 5, the restraining member 100 is retracted from the disk surface of the disk 3 simultaneously with the head 6 even when an external shock is applied to the HDD 1. Is possible. Therefore, even if the suppressing member 100 is disposed at a position close to the disk surface of the disk 3, the possibility of damaging the disk surface of the disk 3 is low.
Since the restraining member 100 and the second suspension 110 are attached to the conventional carriage arm 5, it is not necessary to secure a new space.

  In addition to the disk flutter, vibration of the head 6 due to wind turbulence is also regarded as a problem in improving reading accuracy. By providing the restraining member 100 on the disk surface of the disk 3, the air flow velocity in the rotational direction on the disk surface of the disk 3 is reduced and the flow becomes turbulent, thereby suppressing vibration due to wind turbulence of the head 6. The effect can also be expected.

  In the present embodiment, the configuration including the two magnetic disks 3a and 3b has been described. However, the number of disks can be increased or decreased as necessary. Also, the number of heads 6 for one disk can be increased or decreased as necessary.

  It is also possible to add the restraining member 100 and the second suspension 110 only at necessary positions. When three or more disks 3 are mounted in the same housing 2, the disk 3 at the intermediate position sandwiched between the disks 3 and 3 is most likely to cause disk flutter. Therefore, the second suspension 110 and the restraining member 100 may be disposed only on the carriage arm 5 on which the head 6 that retrieves data from the disk 3 at the intermediate position is disposed. For example, when a plurality of three or more disks 3 are arranged, it is also conceivable that the suppressing member 100 and the second suspension 110 are arranged only for those arranged between the disks having a particularly high air flow rate.

  Further, the effect of the present embodiment can be obtained even in a structure in which the disk 3 is held by the suppressing member 100 only on one side of one disk. However, it can be said that the structure in which the restraining member 100 is pressed from both sides of the disk 3 is preferable because the effect of suppressing the disk flutter can be further improved.

(Second Embodiment)
FIG. 3 is a schematic diagram showing (a) a plan view and (b) a cross-section between AB of the HDD 1 showing the second embodiment of the present invention. The same parts as those of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  In the present embodiment, a second carriage arm 120 different from the carriage arm 5 is provided on the disk side. The second carriage arm 120 operates with the bearing portion 8 as an axis in conjunction with the carriage arm 5 by the VCM 7 (shown in FIG. 1). The second suspension 110 is provided so as to extend from the second carriage arm 120. A suppressing member 100 is supported at the tip of the second suspension 110. Similar to the HDD 1 according to the first embodiment, the restraining member 100 and the second suspension 110 are arranged on the carriage arm 5 so that the restraining member 100 is positioned above the disk 3 when the head 6 reads / writes data. Arranged. Even when the head 6 is reading / writing data in the storage area on the outermost periphery of the disk 3, the suppressing member 100 is arranged to face the surface of the disk 3.

  According to the present embodiment, no change is required in the carriage arm 5 of the conventional hard disk drive, and if the assembly is also the current stack system, the disk flutter suppression effect according to the present invention can be achieved simply by placing it between the carriage arms 5. Can be obtained.

  The present invention is not limited to the embodiment described above, and various modifications can be made within the scope of the present invention. For example, in each of the above-described embodiments, the disk drive device is applied to an HDD that drives a magnetic disk. However, the present invention is not limited to this, and the present invention can also be applied to a disk drive device that drives another disk. For example, the present invention is also suitably used for a servo track writer that forms a servo signal that is position information of a recording track on a disk.

1 is a perspective view showing the inside of an HDD according to a first embodiment of the present invention. BRIEF DESCRIPTION OF THE DRAWINGS (a) Whole top view of HDD concerning the 1st Embodiment of this invention (b) The schematic diagram which shows the cross-section between AB. (A) Whole top view of HDD concerning the 2nd Embodiment of this invention (b) The schematic diagram which shows the cross-section between AB.

Explanation of symbols

1 Disk drive device 2 Housing 3, 3a, 3b Magnetic disk 4 Spindle motor (SPM)
5 Carriage arm 6 Magnetic head (head)
7 Voice coil motor (VCM)
8 Bearing 9 Head IC
10 first suspension 100 restraining member 110 second suspension 120 second arm

Claims (8)

A disc having a disc surface on which information can be recorded;
A motor for rotating the disk;
An arm capable of swinging on the disk surface;
An elastically deformable first support part having one end fixed to the tip part so as to extend from the tip part of the arm;
A head arranged on the other end of the first support portion, for recording information on the disk surface, or reproducing the recorded information;
A positioning mechanism that drives the arm to swing to position the head relative to the disk surface;
A second support portion having one end fixed to the arm and extending toward the disk surface;
A disc drive comprising: a restraining member that is fixed to the other end of the second support portion and that faces the disc surface and suppresses fluttering of the disc that occurs as the disc rotates. apparatus.
The arms are arranged as a pair on both sides of the disc,
2. The disk drive according to claim 1, wherein when the head records information on the disk surface or reproduces the recorded information, the suppressing member is disposed so as to sandwich the disk from both sides. apparatus.
3. The disk drive device according to claim 1, wherein the second support part is an elastically deformable member.
2. The disk drive device according to claim 1, wherein a distance between the suppression member and a disk surface of the disk is larger than a distance between the disk surface of the disk and the head.
2. The disk drive device according to claim 1, wherein an area of the restraining member is larger than an area of the head.
2. The disk drive device according to claim 1, wherein the second support portion is less likely to be elastically deformed than the first support portion.
A disc having a disc surface on which information can be recorded;
A motor for rotating the disk;
A head for recording information on the disk surface or reproducing the recorded information;
A first support for supporting the head;
A first arm that supports the first support portion at a tip portion;
A second arm arranged in conjunction with the first arm and located closer to the disk than the first arm;
A drive mechanism for moving and positioning the first arm and the second arm with respect to the disk surface;
A second support portion extending from the second arm;
The head has a surface facing the disk surface fixed to the tip of the second support portion so that the head is positioned on the disk surface and faces the disk surface when recording or reproducing information, and the disk rotates. A disk drive apparatus comprising: a suppressing member that suppresses fluttering of the disk that occurs with the disk drive.
The first arm and the second arm are arranged as a pair with respect to both surfaces of the disk,
8. The disk drive according to claim 7, wherein when the head records information on the disk surface or reproduces the recorded information, the restraining member is disposed so as to sandwich the disk from both sides. apparatus.

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