JP2007273009A - Disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To increase a processing speed for recording/reproducing data, and to reduce power consumption. <P>SOLUTION: This device is provided with a drive shaft 2 supported to rotate and rotary-driven by a driving source, a magnetic disk 10 fixed to the drive shaft 2, and a magnetic head 13 for recording/reproducing data in the magnetic disk 10. Follower disks 4A, 14B, 16A, and 16B having outer shapes similar to that of the magnetic disk 10 are supported coaxially to the magnetic disk 10 to rotate so as to face the magnetic disk 10. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a disk device employed in a hard disk drive or the like of a personal computer that rotates a disk at a high speed and records / reproduces data on the disk with a magnetic head or the like.

A conventional disk device includes a magnetic disk mounted on a spindle, an arm attached to an actuator, and a magnetic head provided at the tip of the arm, and the magnetic disk is rotated at a high speed (3600 rpm) by the spindle, for example. In some cases, the magnetic head is moved / positioned to a target track of the magnetic disk by an actuator, and data is recorded / reproduced on / from the magnetic disk by this magnetic head (for example, see Patent Document 1).
JP-A-6-236670 (paragraphs “0038” and “0045”, FIGS. 2 and 3)

  In the conventional disk device described above, since the magnetic disk is rotated at a high speed, the magnetic disk receives a large air resistance, and the rotation speed does not increase due to a loss due to the resistance, so-called windage loss. Therefore, there is a problem that the processing speed is difficult to improve. In addition, if the supply of power to the spindle motor is increased in order to increase the rotation speed, there is a problem that power consumption increases.

  The present invention has been made in view of the above-described conventional problems, and an object thereof is to increase the processing speed for recording / reproducing data and reduce the power consumption.

  In order to achieve this object, the invention according to claim 1 is a disc device comprising a rotating disc and information processing means for performing processing for reproducing and recording data on the disc, and the outer shape of the disc is substantially the same. A follower disk having the same shape is rotatably supported on the same axis as the disk so as to face the disk.

  The invention according to claim 2 is the invention according to claim 1, wherein a plurality of the disks are provided between a pair of driven disks.

  The invention according to claim 3 is the invention according to claim 1 or 2, wherein a seal member is interposed between the driven disk and the rotating shaft of the disk.

  According to the first aspect of the invention, since the rotational speed of the disk can be increased by reducing the air resistance to the rotating disk, the processing speed for recording / reproducing by the processing means is improved, and the disk is Power consumption for rotation can be reduced.

  According to the invention of claim 2, the rotational speed of the disk can be further increased.

  According to the third aspect of the invention, the fluid between the disk and the driven disk and the fluid between the driven disk are discharged to the outside by centrifugal force due to the high-speed rotation of the disk, while the device is disposed at the center of the disk. The flow of fluid from the outside can be restricted by the seal member. For this reason, fluid does not flow between the disk and the follower disk, so that the fluid resistance to the rotating disk decreases and the rotation speed of the disk increases.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1A is a partially cutaway perspective view showing a disk device according to the present invention, and FIG. The disk device generally indicated by reference numeral 1 in FIG. 1 includes a container 2 that covers a disk 10 and first and second driven disks 14A, 14B, 16A, and 16B, which will be described later, and this container 2 is not shown. Installed in the case of the device. The container 2 is formed in a disc shape and is formed into a substantially sealed cylindrical shape by an upper casing 3 and a lower casing 4 that are opposed to each other and a cylindrical portion 5 that connects between the peripheral ends of the casings 3 and 4. Is formed. A part of the cylindrical part 5 is provided with a window 5a for moving an arm 12, which will be described later, and large-diameter cylindrical parts 6A and 6B and small-diameter cylindrical parts 7A and 7B at the center of the upper casing 3 and the lower casing 4. Are connected to each other.

  Reference numeral 8 denotes a drive shaft that rotates using a motor (not shown) as a drive source, and is rotatably supported by bearings 9 and 9 on the small-diameter cylindrical portions 7A and 7B of the container 2, respectively. A magnetic disk 10 is pivotally attached to the center of the disk. Reference numerals 12 and 12 denote a pair of arms provided with the magnetic disk 10 interposed therebetween, and magnetic heads 13 and 13 as information processing means are attached to the swinging end portions of the arms 12 and 12, respectively. . The base end portion of the arm 12 is connected to the actuator 12a. By driving the actuator 12a, the magnetic head 13 moves in the radial direction of the magnetic disk 10, and is moved and positioned to the target track on the magnetic disk 10. In addition, a process for recording / reproducing data on the magnetic disk 10 in a non-contact state is performed.

  14A and 14B are first driven discs rotatably supported on the drive shaft 8 via bearings 17 and 17 provided between the cylindrical portions 14a and 14a and the cylindrical portions 16a and 16a provided upright in the center. The first driven disks 14A and 14B face the magnetic disk 10 so as to be close to the magnetic disk 10 and have an outer shape substantially the same as that of the magnetic disk 10. Reference numerals 16A and 16B denote second driven disks that are rotatably supported.

  The second driven disks 16A and 16B include bearings 18 and 18 provided between the cylindrical portions 16a and 16a, the upper and lower upper casings 3 of the container 2, and the large-diameter cylindrical portions 6A and 6B of the lower casing 4. And is rotatably supported by the container 2. Each of the second driven disks 16A and 16B is opposed to the first driven disks 14A and 14B so as to be close to the top and bottom, and is close to the upper and lower upper casings 3 and 4 of the container 2. The outer shape of the first driven disks 14A and 14B is substantially the same as that of the first driven disks 14A and 14B. That is, the first driven disks 14A and 14B and the second driven disks 16A and 16B are both rotatable coaxially with the magnetic disk 10 around the drive shaft 8 which is the rotating shaft of the magnetic disk 10. It is supported by.

  Here, the first driven disk 14A, 14B adjacent to the magnetic disk 10 is rotatably supported on the drive shaft 8 on which the magnetic disk 10 is rotatably supported via a bearing 17, and the first driven circle is rotated. Second driven disks 16A and 16B adjacent to the plates 14A and 14B are rotatably supported via bearings 18. As described above, since the first driven disks 14A and 14B and the second driven disks 16A and 16B are connected to the drive shaft 8 in series via the bearings 17 and 18, the drive shaft 8, the rotation loss can be reduced more than the structure in which the first driven disks 14A and 14B and the second driven disks 16A and 16B are individually supported and connected in parallel.

  In addition, the first driven disks 14A and 14B having substantially the same outer shape as the magnetic disk 10 are rotatably supported on the same axis as the magnetic disk 10 so as to face the magnetic disk 10, and the first driven circle. The second driven disks 16A and 16B having substantially the same outer shape as the plates 14A and 14B are rotated coaxially with the first driven disks 14A and 14B so as to face the first driven disks 14A and 14B. It is supported freely. With such a configuration, the first driven disk 14A, 14B and the second driven disk adjacent to the first driven disk 14A, 14B adjacent to the magnetic disk 10 and the first driven disk 14A, 14B adjacent to the magnetic disk 10 are configured. Since the relative speed between 16A and 16B decreases, windage loss can be reduced. Hereinafter, the principle of reducing windage loss will be described.

That is, the fluid resistance D per unit area in the rotating body such as the magnetic disk 10 is ρ, the fluid density is ρ, the coefficient determined by the number of ray nozzles and the kinematic viscosity coefficient is A, and the speed of the rotating body is V.
D = (1/2) ρAV ²
It is known that

That is, since A is a coefficient, it can be seen that the resistance D is proportional to the square of the speed. Therefore, it can be seen that the resistance received by the entire rotating body is proportional to the square of the angular velocity of the rotating body. Assuming ω, the torque Q is Q = (1/2) ρBω ²
It is represented by

Here, this method is applied to the present invention. First, a case where only the first driven disks 14A and 14B are provided will be described. A magnetic disk 10 first driven disc 14A, 14B and a surface area substantially the same, the angular velocity omega ₁ of the magnetic disk 10, the first driven disc 14A, rotates in balance and the angular velocity omega ₂ of 14B and that, the magnetic disk 10 first driven disc 14A, the torque due to fluid resistance between the 14B and Q _1, the first driven disc 14A, 14B and the first driven disc 14A, 14B of Assuming that the torque due to the fluid resistance between the outside and the outside is Q ₂ , Q ₁ and Q ₂ are Q ₁ = (1/2) ρB (ω ₁ −ω ₂ ) ²
Q ₂ = (1/2) ρBω ₂ ²

Since both of them rotate in balance and their torques Q ₁ and Q ₂ are equal, the relationship of Q ₁ = Q ₂ is established, and the following relationship is derived from the above formulas of Q ₁ and Q ₂ .
(1/2) ρB (ω ₁ −ω ₂ ) ² = (1/2) ρBω ₂ ²
Rearranging this equation gives ω ₂ = ω _1/2 . This indicates that the angular velocity ω ₂ of the first driven disks 14A and 14B rotates at a speed that is ½ of the angular velocity ω ₁ of the magnetic disk 10.

Next, a case where there are an arbitrary number of driven disks will be described. When n pairs of driven disks are provided and the torque of each driven disk is Q ₁ , Q ₂ , Q ₃ ,..., Q _n−1 , Q _n , they all have the same value, and their relative angular velocities Is equal to ω ₁ / (n + 1). Further, since the number of fluids in contact with the magnetic disk 10 and the driven disk is (n + 1) layers, when the torque due to the fluid resistance when rotating the magnetic disk 10 without the driven disk is Q ₀ , The torque Q _n due to fluid resistance when n driven disks are provided is
Qn = Q ₀ / (n + 1) ²
It becomes. Therefore, the fluid resistance received by the magnetic disk 10 decreases to 1/4, 1/9, 1/16,... As the follower disks increase in pairs, two pairs, three pairs,.

  Thus, it can be seen that by providing a large number of driven disks in the magnetic disk 10, the fluid resistance received by the magnetic disk 10 is reduced, and so-called windage loss can be reduced. Accordingly, since the drive source for rotating the drive shaft 8 can increase the rotation speed of the magnetic disk 10 with the same drive force, the recording / reproduction processing speed by the magnetic head 13 is improved. Moreover, since the load of the drive source for rotationally driving the magnetic disk 10 is reduced by reducing the fluid resistance, the power consumption of the drive source can be reduced.

  2A and 2B show a second embodiment of the present invention, in which FIG. 2A is a partially cutaway perspective view and FIG. 2B is a cross-sectional view showing the main part. In the second embodiment, first seal members 23, 23 are interposed between the upper casing 3, the lower casing 4, and the drive shaft 8, and the cylinders of the second driven discs 16A, 16B. Between each of the parts 16a and 16a and the drive shaft 8, annular second seal members 21 and 21 are interposed, and the cylindrical parts 14a of the first driven disks 14A and 14B. , 14a and the drive shaft 8 are interposed third seal members 22, 22 formed in an annular shape.

  With this configuration, when the magnetic disk 10 rotates at high speed, the air between the magnetic disk 10 and the first driven disks 14A and 14B moves outward by centrifugal force, and the container 2 From the window 5a. On the other hand, since the first, second and third seal members 23, 21, 22 are provided, the center of the magnetic disk 10 from the outside of the apparatus passes through the upper and lower openings of the small diameter cylindrical portions 7A, 7B of the container 2. Inflow of air into the part is restricted. Therefore, no fluid flows between the magnetic disk 10 and the first driven disks 14A and 14B, so that the rotation speed of the magnetic disk 10 can be increased without increasing the output of the drive source that rotates the drive shaft 8. .

  FIG. 3 is a cross-sectional view of an essential part showing a third embodiment of the present invention. In the third embodiment, two magnetic disks 10 and 10 are axially attached to the drive shaft 8 so as to face each other at an interval, and each of the magnetic disks 10 and 10 is sandwiched. Two pairs of arms 12 to which a magnetic head 13 is attached are provided at the tips.

  Between each of the two magnetic disks 10, 10 and the upper and lower upper casings 3, 4 of the container 2, two driven disks 33, 33 are located at the center of the driven disks 33, 33. It is rotatably supported by the container 2 via bearings 35, 35 provided between the cylindrical parts 33a, 33a erected on the part and the large-diameter cylindrical parts 6A, 6B of the container 2. The drive shaft 8 is rotatably supported by bearings 9 and 9 provided between the upper casing 3 and the lower casing 4 of the container 2. Accordingly, the driven disks 33 and 33 are rotatably supported coaxially with the magnetic disk 10 of the drive shaft 8. As described above, the driven disks 33 and 33 having substantially the same outer shape as the magnetic disk 10 are rotatably supported coaxially with the magnetic disk 10 so as to face the magnetic disk 10. The same effects as those of the embodiment can be obtained.

  FIG. 4 is a cross-sectional view of a main part showing a fourth embodiment of the present invention. The fourth embodiment is different from the above-described third embodiment in that it is formed in an annular shape between the cylindrical portions 33a, 33a of the two driven disks 33, 33 and the drive shaft 8. The seal members 41 and 41 are interposed, and the seal members 42 and 42 formed in an annular shape between the upper casing 3 and the lower casing 4 and the drive shaft 8 are interposed. With this configuration, the seal members 41 and 41 restrict air from flowing from the outside of the apparatus to the center of the magnetic disk 10 through the upper and lower openings of the small-diameter cylindrical portions 7A and 7B of the container 2. Thus, as in the second embodiment described above, no fluid flows between the magnetic disks 10 and 10 and the driven disks 33 and 33, so that the output of the drive source that rotates the drive shaft 8 is not increased. The rotational speed of the magnetic disk 10 is increased.

  FIG. 5 is a model diagram showing another embodiment of a bearing support structure for rotatably supporting a magnetic disk and a driven disk in the disk apparatus according to the present invention. In the disk apparatus shown in FIG. 2A, the entire apparatus is horizontally arranged, and the first driven disk 14B is interposed between the first driven disk 14B and the drive shaft 8 of the magnetic disk 10. The second driven disks 16A and 16B are rotatably supported by a provided bearing 15, and the second driven disks 16A and 16B are located between the first driven disks 14A and 14B adjacent to the second driven disks 16A and 16B. It is rotatably supported by bearings 17 and 17 provided on the surface. In the disk apparatus shown in FIGS. 7B to 7D, the drive shaft 8 is disposed horizontally. In the structure shown in FIG. 5B, the bearing 9 of the drive shaft 8 of the magnetic disk 10 is the container 2. The first driven disks 14A and 14B are rotated by a bearing 17 provided between the second driven disks 16A and 16B adjacent to the first driven disks 14A and 14B. It is supported freely. The second driven disks 16 </ b> A and 16 </ b> B are rotatably supported by bearings 18 supported by the container 2.

  In the disk apparatus shown in FIG. 2C, the first driven disk 14A is rotatable by a bearing 15 provided between the first driven disk 14A and the drive shaft 8 of the magnetic disk 10. It is supported. In the disk apparatus shown in FIG. 4D, the first driven disks 14A and 14B are both provided between the first driven disks 14A and 14B and the drive shaft 8 of the magnetic disk 10. The bearings 15 and 15 are rotatably supported.

  In this embodiment, an example in which two pairs of driven disks are provided has been described. However, three or more pairs may be provided if necessary, and either one is not provided as a pair above and below the magnetic disk 10. At least one may be provided on one side. Further, although the recording medium is the magnetic disk 10, it may be an optical disk or the non-contact type magnetic head 13, but may be a contact type magnetic head.

FIG. 1A is a perspective view showing a disk device according to the present invention in a partially broken view, and FIG. The 2nd Embodiment of this invention is shown, The figure (A) is a partially broken perspective view, The figure (B) is sectional drawing of the principal part. It is sectional drawing of the principal part which shows the 3rd Embodiment of this invention. It is sectional drawing of the principal part which shows the 4th Embodiment of this invention. FIG. 5 is a model diagram showing another embodiment of a bearing support structure for rotatably supporting a magnetic disk and a driven disk in the disk device according to the present invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Disk apparatus, 2 ... Container, 8 ... Drive shaft, 10 ... Magnetic disk, 13 ... Magnetic head, 14A, 14B ... 1st driven disk, 17, 18 ... Bearing, 16A, 16B ... 2nd driven circle Plates 21, 22, 23 ... sealing members, 33 ... driven disks, 41, 42 ... sealing members.

Claims (3)

  In a disk device comprising a rotating disk and information processing means for performing processing for reproducing / recording data on the disk, a driven disk having substantially the same outer shape as the disk is arranged so as to face the disk. A disk device characterized by being rotatably supported on the same axis as the disk.   2. The disk device according to claim 1, wherein a plurality of the disks are provided between a pair of driven disks.   3. The disk apparatus according to claim 1, wherein a seal member is interposed between the driven disk and the rotating shaft of the disk.

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