JP2006236494A - Disk drive device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To support intervals between a case and a main frame, and between the main frame and a sub-frame inexpensively and elastically. <P>SOLUTION: The disk drive apparatus 10A is provided with a case 11, a spindle motor 15 provided in the case 11 and rotary-driving a disk D, a main frame 12 to which an optical pickup 17 and/or a magnetic head being freely movable in the direction of a diameter of the disk D, a sub-frame 18 arranged at an upper side or a lower side of the main frame to absorb vibration generated in the main frame 12, and an elastic member 13 supporting at least three points of intervals between the case 11 and the main frame 12, and between the main frame 12 and the sub-frame 18 elastically at the same position respectively. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a disk drive device configured to suppress vibration caused by rotation of a spindle motor that rotationally drives a disk when an information signal is recorded and / or reproduced on a disk such as an optical disk, a magneto-optical disk, or a magnetic disk. It is about.

Generally, a disk such as an optical disk, a magneto-optical disk, or a magnetic disk can record and / or reproduce music information, video information, or other data in a large capacity and can access desired information at high speed. A disk drive device configured to suppress vibration caused by rotation of a spindle motor that rotationally drives the disk when recording and / or reproducing information signals on the disk is widely used (for example, disclosed) , See Patent Document 1).
Japanese Unexamined Patent Publication No. 2004-6014 (page 4-5, FIGS. 1 to 3).

7 (a) and 7 (b) are a top view, a longitudinal sectional view, and a sectional view showing a conventional disk drive device,
FIG. 8 is a diagram for explaining a vibration model in a conventional disk drive device.

  As shown in FIGS. 7A and 7B, a conventional disk drive device 100 is disclosed in the above-mentioned Patent Document 1 (Japanese Patent Laid-Open No. 2004-6014). A brief description will be given with reference to FIG.

  As shown in FIGS. 7A and 7B, in the conventional disk drive device 100, the first elastic member in which the main frame 102 is formed on the bottom plate 101a in the casing 101 using a rubber material or a resin material. 103 is elastically supported at least at three locations along the outer periphery.

  In this main frame 102, a turntable 104 for mounting the optical disk D is fixed to the motor shaft to rotate the optical disk D, and a radius of the optical disk D is guided by a pair of guide rails 106, 106. An optical pickup 107 that is movable in the direction is attached.

  Further, a sub-frame 108 that functions as a vibration absorber is disposed substantially parallel to the main frame 102 above the main frame 102 and to the right of the spindle motor 105. At least three locations are elastically supported along the outer periphery by the second elastic member 109 formed using a rubber material or a resin material.

  At this time, the main frame 102 maintains a structure that is not easily affected by external vibration due to the action of the first elastic member 103, and the main frame 102 is caused by unbalance of the optical disk D when the spindle motor 105 rotates. The vibration generated in the optical disk D is suppressed by the vibration absorbing action of the subframe 108 and the second elastic member 109, so that the recording and / or reproduction of the optical disc D can be performed satisfactorily.

  Here, FIG. 8 shows a vibration model in the conventional disk drive device 100. In this vibration model, the optical disk D having the eccentric center of gravity is placed on the turntable 104 as described above with reference to FIG. When the main frame 102 vibrates due to the eccentric gravity center of the optical disk D when it is mounted and rotated at a high speed by the spindle motor 105, the subframe 108 elastically supported on the main frame 102 by the second elastic member 109 is the main frame. Since it vibrates in an opposite phase with respect to 102, vibration of the main frame 102 can be effectively suppressed. Further, it is disclosed that since the housing 101 and the main frame 102 are elastically supported by the first elastic member 103, a sufficient damping effect can be obtained even with respect to external vibration. Yes.

  By the way, according to the conventional disk drive device 100, the first elastic member 103 elastically supports the space between the housing 101 and the main frame 102, and the space between the main frame 102 and the sub frame 108. The first elastic member 103 and the second elastic member can be made to act as a vibration absorber for the vibration of the main frame 102 by elastically supporting the second elastic member 109. Two types of elastic members 109 are required, and there are many types and numbers of elastic members, resulting in an increase in the cost of the disk drive device 100.

  Therefore, a disk drive device that can elastically support the space between the housing and the main frame and between the main frame and the sub frame at low cost is desired.

This invention is made | formed in view of the said subject, The invention of Claim 1 is a housing | casing,
A main frame provided in the housing and mounted with a spindle motor for rotating the disk, and an optical pickup and / or a magnetic head movable in the radial direction of the disk;
A sub-frame disposed above or below the main frame to absorb vibrations generated in the main frame;
A disk drive comprising: an elastic member that elastically supports at least three positions between the casing and the main frame and between the main frame and the subframe at the same position. Device.

According to a second aspect of the present invention, there is provided the disk drive device according to the first aspect,
The elastic member is formed in a substantially cylindrical shape using a rubber material or a resin material having a damping characteristic with respect to vibration, a central hole is formed through an inner central portion of the substantially cylindrical shape, and substantially The disk drive device is characterized in that first and second annular groove portions are formed in a cylindrical outer peripheral portion with an interval in the axial direction.

  According to the disk drive device of claim 1, when absorbing external vibration and absorbing vibration of the main frame by the sub frame, in particular, between the housing and the main frame and between the main frame and the sub frame. Since the same elastic member elastically supports at least three locations at the same position, only one type of elastic member needs to be prepared and the number of elastic members can be reduced. As described above, the cost of the disk drive device can be reduced as compared with the case where two types of elastic members are used.

Further, according to the disk drive device of claim 2, since the elastic member can be attached between the housing and the main frame and between the main frame and the sub frame,
A sufficient damping effect against external vibration can be obtained between the housing and the main frame by the elastic member, and vibration of the main frame can be obtained between the main frame and the sub frame by the sub frame and the elastic member. It can be effectively attenuated.

  Hereinafter, an embodiment of a disk drive device according to the present invention will be described in detail with reference to FIGS.

1 (a) and 1 (b) are a top view, a longitudinal sectional view, and a sectional view showing a disk drive device according to the present invention,
2A and 2B show a disk drive device according to the present invention, in which FIG. 2A is an enlarged view of the elastic member shown in FIG. 1 and FIG. A longitudinal sectional view showing, in an enlarged manner, a state in which the elastic member is elastically supported by an elastic member integrally formed between them,
FIG. 3 is a diagram for explaining a vibration model in the disk drive device according to the present invention.

  As shown in FIGS. 1A and 1B, in the disk drive device 10A according to the present invention, the housing 11 is formed in a box shape.

  In this case 11, left elastic member support pieces 11b1 and 11b1 are formed so as to protrude from the inside of the left side plate 11b suspended from the left end of the bottom plate 11a to the right in parallel with the bottom plate 11a with a space in the front and rear. In addition, the right elastic member support pieces 11a1 and 11a1 are bent to the left after the right elastic member support pieces 11a1 and 11a1 are directed upward to the right on the bottom plate 11a, and are spaced at the same height as the left elastic member support pieces 11b1 and 11b1. Protrusions are formed.

  And the upper surface of the main frame 12 formed in a substantially rectangular shape is formed in each hole of the left side elastic member support pieces 11b1, 11b1 and the right side elastic member support pieces 11a1, 11a1 formed at intervals in the front, rear, left, and right inside the housing 11. A total of four lower portions of the elastic members 13 fitted into the four corners of 12a via shafts 20 described later are fitted.

  Thereby, the main frame 12 is elastically supported by the four elastic members 13 in substantially parallel to the bottom plate 11a of the housing 11.

  The main frame 12 is guided by a pair of guide rails 16 and 16 and a spindle motor 15 that rotates the optical disk D by fixing a turntable 14 for mounting the optical disk D on the motor shaft. An optical pickup 17 that is movable in the radial direction is attached. At this time, since the spindle motor 15 is mounted on the right side of the main frame 12, the center of gravity of the main frame 12 is biased to the right of the center. If a balance weight (weight) (not shown) is provided as necessary, and the center of gravity of the main frame 12 is set to be substantially in the center, the effect of suppressing vibrations generated in the main frame 12 will be further improved as will be described later. is there.

  Further, in the main frame 12, an escape hole 12c through which the optical pickup 17 disposed on the lower surface side of the optical disc D faces downward is formed, and the optical pickup 17 is disposed along the front and rear of the escape hole 12c. A pair of guide rails 16 are provided in parallel to guide left and right.

  When a magneto-optical disk (not shown) is mounted on the turntable 14 instead of the optical disk D, an optical pickup 17 and a magnetic head (not shown) are provided so as to be movable in the radial direction of the magneto-optical disk. Just do it. When a magnetic disk (not shown) is mounted on the turntable 14 instead of the optical disk D, a magnetic head (not shown) is provided to be movable in the radial direction of the magnetic disk instead of the optical pickup 17. Just do it.

  Further, a sub-frame 18 that functions as a vibration absorber with respect to the main frame 12 is disposed substantially parallel to the main frame 12 above the main frame 12. The sub-frame 18 is formed in a substantially rectangular shape with substantially the same outer size as the main frame 12, and a relief hole 18 a where the spindle motor 15 and the optical pickup 17 face is opened inside. And the upper part of the above-mentioned four elastic members 13 is inserted in each hole formed in the four corners of the sub-frame 18 formed in a substantially rectangular shape, and the sub-frame 18 elastically supports the main frame 12. Has been.

  At this time, the attachment intervals for attaching the four elastic members 13 to the four corners of the main frame 12 and the sub-frame 18 are the same for both the frames 12 and 18.

  Accordingly, the space between the housing 11 and the main frame 12 and the space between the main frame 12 and the subframe 18 are elastically supported by the same elastic member 13 at the same position along the outer periphery at four locations. However, the present invention is not limited to this, and it is only necessary to elastically support at least three locations at the same position along the outer periphery.

  Therefore, only one type of elastic member 13 needs to be prepared, and the number of elastic members 13 can be further reduced. Therefore, compared to the case of using two types of elastic members 103 and 109 (FIG. 7) as described in the conventional example. Thus, the cost of the disk drive device 10A can be reduced.

  Here, as shown in an enlarged view in FIG. 2A, the elastic member 13 described above is integrally formed into a substantially cylindrical shape by molding using a rubber material or a resin material having a damping characteristic against vibration. The first and second annular groove portions 13c and 13e are formed so that a central hole 13a is formed through an inner central portion of the substantially cylindrical shape and the outer peripheral portion of the substantially cylindrical shape is spaced in two axial directions. Is formed. Accordingly, the first flange portion 13b, the first annular groove portion 13c, the second flange portion 13d, the second annular groove portion 13e, and the third flange portion 13f are formed in order from the bottom to the top on the outer peripheral portion of the elastic member 13. ing.

  At this time, in FIG. 2A, the outer diameter of the outer peripheral portion of the elastic member 13 is illustrated with substantially the same dimensions, and the heights of the first and second flange portions 13b, 13d are illustrated with approximately the same dimensions. However, the outer diameter and height of the first and second flange portions 13b and 13d may be set as appropriate in accordance with the vibration design of the main frame 12 and the sub frame 18.

  For example, only the left side in the housing 11 will be described with reference to FIG. 2B. A shaft 20 is planted upward in the left corner of the upper surface 12a of the main frame 12, and the shaft 20 is elastic. The center hole 13a of the member 13 is fitted to support the elastic member 13 on the main frame 12, and the elastic member 13 is inserted into the hole of the left elastic member support piece 11b1 formed to protrude inside the left side plate 11b of the housing 11. The first annular groove 13c is fitted, and the second annular groove 13e of the elastic member 13 is fitted into a hole formed in the left corner of the subframe 18, and the shaft is screwed from the upper part of the elastic member 13 with a screw 22 via the washer 21. 20, the integrally formed elastic member 13 is attached between the housing 11 and the main frame 12 and between the main frame 12 and the subframe 18. It is attached. At this time, the elastic member 13 is supported by the left elastic member support piece 11b1 and the right elastic member support piece 11a1 formed in the housing 11 at a height between the main frame 12 and the sub frame 18.

  In this embodiment, the elastic member 13 is supported via the shaft 20 planted on the main frame 12. However, the present invention is not limited to this, but the illustration is omitted here, but on the bottom plate 11 a of the housing 11. Alternatively, the elastic member 13 may be supported by implanting a shaft and fitting the central hole 13a of the elastic member 13 into the shaft. In this case, the mounting interval of the elastic member 13 is made to coincide with both the frames 12 and 18, and the first and second annular groove portions 13c of the elastic member 13 are inserted into the holes formed at the corners of the main frame 12 and the sub frame 18, respectively. , 13e may be inserted.

  Here, as shown in FIG. 3, in the vibration model in the disk drive device 10 </ b> A according to the present invention configured as described above, between the housing 11 and the main frame 12 and between the main frame 12 and the subframe 18. When elastically supported by the elastic member 13 formed integrally therewith, the optical disk D having an eccentric gravity center is mounted on the turntable 14 and rotated at a high speed by the spindle motor 15 as described above with reference to FIG. Sometimes, when vibration occurs in the main frame 12 due to the eccentric gravity center of the optical disk D, the subframe 18 elastically supported by the elastic member 13 on the main frame 12 vibrates in an opposite phase with respect to the main frame 12. The vibration of the main frame 12 can be effectively damped. At this time, the first flange portion 13b of the elastic member 13 elastically supporting between the housing 11 and the main frame 12 and the second of the elastic member 13 elastically supporting between the main frame 12 and the subframe 18 are provided. As described above, the outer diameter and the height of each shape of the flange portion 13d may be appropriately set according to the vibration design.

  Further, since the housing 11 and the main frame 12 are also elastically supported by the elastic member 13, it is possible to obtain a sufficient damping effect against external vibration.

  Next, modified examples 1 to 3 in which the disk drive device 10A of the embodiment is partially modified will be briefly described with reference to FIGS.

FIG. 4 is a longitudinal sectional view showing a disk drive device according to a first modification in which the disk drive device according to the present invention is partially modified.
FIG. 5 is a longitudinal sectional view showing a disk drive device according to a second modification in which the disk drive device according to the present invention is partially deformed,
FIG. 6 is a longitudinal sectional view showing a disk drive device of Modification 3 in which the disk drive device according to the present invention is partially modified.

  The disk drive devices 10B to 10D of Modifications 1 to 3 shown in FIGS. 4 to 6 have the same configuration except for the configuration of the disk drive device 10A of the above-described embodiment, and will be described here. For the sake of convenience, the above-described constituent members are illustrated with the same reference numerals, and different portions are denoted with new reference numerals, and different points will be mainly described.

  First, in the disk drive device 10B of Modification 1 shown in FIG. 4, the left elastic member support piece 11b2 formed to protrude inside the left plate 11b of the housing 11 and the right elastic member support formed to protrude right of the bottom plate 11a. Each height of the piece 11a2 is set higher than the left elastic member support piece 11b1 and the right elastic member support piece 11a1 previously shown in FIG. Four elastic members 13 are attached to the four corners of the upper surface 12 a of the main frame 12 via shafts 20.

  Then, the first annular groove 13c of the elastic member 13 is fitted in each of the four corner holes of the subframe 18, and the second annular groove of the elastic member 13 is inserted into each of the left elastic member support piece 11b2 and the right elastic member support piece 11a2. By fitting 13e, the subframe 18 is disposed above the main frame 12, and both the frames 12 and 18 are supported by the housing 11 via the same elastic member 13. At this time, the elastic member 13 is supported by the left elastic member support piece 11b2 and the right elastic member support piece 11a2 formed in the housing 11 at a height higher than the subframe 18.

  Therefore, also in the case of this modification 1, the sub-frame 18 functions as a vibration absorber with respect to the main frame 12 like the embodiment.

  Next, in the disk drive device 10C of the modification 2 shown in FIG. 5, the left elastic member support piece 11b3 formed to protrude inside the left plate 11b of the housing 11 and the right elastic member formed to protrude right of the bottom plate 11a. Each height of the support piece 11a3 is set lower than the left elastic member support piece 11b1 and the right elastic member support piece 11a1 shown in FIG. In addition, four elastic members 13 are mounted upside down at four corners of the lower surface 12b of the main frame 12 via shafts 20.

  Then, the first annular groove 13c of the elastic member 13 is fitted into each of the four corner holes of the subframe 18, and the second annular groove of the elastic member 13 is inserted into each of the left elastic member support piece 11b3 and the right elastic member support piece 11a3. By fitting 13e, the subframe 18 is disposed below the main frame 12, and both the frames 12 and 18 are supported by the casing 11 via the same elastic member 13. At this time, the elastic member 13 is supported by the left elastic member support piece 11b3 and the right elastic member support piece 11a3 formed in the housing 11 at a lower level than the subframe 18.

  Therefore, also in the case of this modification 2, the sub-frame 18 functions as a vibration absorber with respect to the main frame 12 similarly to the embodiment.

  Further, in the disk drive device 10D of Modification 3 shown in FIG. 6, the left elastic member support piece 11b4 that protrudes inside the left plate 11b of the housing 11 and the right elastic member support that protrudes to the right of the bottom plate 11a. Although the heights of the pieces 11a4 are set to be substantially the same as the left elastic member support pieces 11b1 and the right elastic member support pieces 11a1 shown in FIG. 1B, the four corners of the lower surface 12b of the main frame 12 are set. Four elastic members 13 are attached upside down via a shaft 20.

  Then, the first annular groove portion 13c of the elastic member 13 is fitted into each hole of the left elastic member support piece 11b4 and the right elastic member support piece 11a4, and the second annular groove portion of the elastic member 13 is inserted into each of the four corner holes of the subframe 18. By fitting 13e, the subframe 18 is disposed below the main frame 12, and both the frames 12 and 18 are supported by the casing 11 via the same elastic member 13. At this time, the elastic member 13 is supported by the left elastic member support piece 11b4 and the right elastic member support piece 11a4 formed in the housing 11 at a height between the sub frame 18 and the main frame 12.

  Therefore, also in the case of this modification 3, the sub-frame 18 functions as a vibration absorber with respect to the main frame 12 like the embodiment.

  From the above, in the disk drive devices 10B to 10D of the first to third modifications, similarly to the disk drive device 10A (FIG. 1) of the above-described embodiment, the number of elastic members 13 may be one and the number can be reduced. As described in the conventional example, the cost of the disk drive devices 10B to 10D can be reduced as compared with the case where two types of elastic members 103 and 109 (FIG. 7) are used.

(A), (b) is the top view and longitudinal cross-sectional view which showed the disk drive apparatus based on this invention. In the disk drive device according to the present invention, (a) is an enlarged view of the elastic member shown in FIG. 1, and (b) is an integral part between the housing and the main frame and between the main frame and the subframe. It is the longitudinal cross-sectional view which expanded and showed the state elastically supported by the formed elastic member. It is a figure for demonstrating a vibration model in the disc drive apparatus which concerns on this invention. It is the longitudinal cross-sectional view which showed the disk drive apparatus of the modification 1 which deform | transformed the disk drive apparatus based on this invention partially. It is the longitudinal cross-sectional view which showed the disk drive apparatus of the modification 2 which deform | transformed the disk drive apparatus based on this invention partially. It is the longitudinal cross-sectional view which showed the disk drive apparatus of the modification 3 which deform | transformed the disk drive apparatus based on this invention partially. (A), (b) is the top view and longitudinal cross-sectional view which showed the conventional disc drive device. It is a figure for demonstrating a vibration model in the conventional disc drive device.

Explanation of symbols

10A: disk drive device of embodiment,
10B to 10D: the disk drive device of Modifications 1 to 3 in which the embodiment is partially modified;
DESCRIPTION OF SYMBOLS 11 ... Housing | casing, 11a ... Bottom plate, 11a1-11a4 ... Right side elastic member support piece,
11b ... left side plate, 11b1-11b4 ... left side elastic member support piece,
12 ... Main frame, 12a ... Upper surface, 12b ... Lower surface, 12c ... Escape hole,
13 ... Elastic member, 13a ... Center hole, 13b ... First flange part, 13c ... First annular groove part,
13d ... 2nd flange part, 13e ... 2nd annular groove part, 13f ... 3rd flange part,
14 ... turntable, 15 ... spindle motor, 16, 16 ... a pair of guide rails,
17 ... optical pickup, 18 ... subframe, 18a ... escape hole,
20 ... shaft, 21 ... washer, 22 ... screw,
D: Optical disc.

Claims (2)

A housing,
A main frame provided in the housing and mounted with a spindle motor for rotating the disk, and an optical pickup and / or a magnetic head movable in the radial direction of the disk;
A sub-frame disposed above or below the main frame to absorb vibrations generated in the main frame;
A disk drive comprising: an elastic member that elastically supports at least three positions between the casing and the main frame and between the main frame and the subframe at the same position. apparatus. The disk drive device according to claim 1, wherein
The elastic member is formed in a substantially cylindrical shape using a rubber material or a resin material having a damping characteristic with respect to vibration, a central hole is formed through an inner central portion of the substantially cylindrical shape, and substantially A disk drive device, wherein first and second annular groove portions are formed in a cylindrical outer peripheral portion with an interval in an axial direction.

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