JP4199059B2 - Recording / reproducing apparatus and stabilization adjustment method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a recording / reproducing apparatus for performing recording and / or reproducing processing on a flexible recording disk, and a stabilization adjustment method applied to the recording / reproducing apparatus. To the law It is related.
[0002]
[Prior art]
In recent years, there has been a demand for information recording media to record large volumes of digital data, such as the start of digitization of television broadcasting. For example, in the field of optical discs, one of the basic methods for increasing the density is to reduce the diameter of the light spot collected on the optical disc for recording / reproduction (hereinafter referred to as an optical disc). As a representative example, the recording disk used in the recording / reproducing apparatus targeted by the present invention is intended for all the disk-shaped recording disks such as phase change memory, magneto-optical memory, hologram memory, etc. Not limited to optical discs).
[0003]
For this reason, in increasing the density of the optical disk, it is effective to shorten the wavelength of light used for recording / reproduction and increase the numerical aperture NA of the objective lens. As for the wavelength of light, a wavelength of near infrared light of 780 nm is used for CD (compact disk), and a wavelength of about 650 nm of red light is used for DVD (digital versatile disk). Recently, a blue-violet semiconductor laser has been developed, and it is expected that a laser beam of around 400 nm will be used in the future.
[0004]
As for the objective lens, it was less than NA0.5 for CD, but it is about NA0.6 for DVD. In the future, it is required to further increase the numerical aperture (NA) to NA or more 0.7. However, increasing the NA of the objective lens and shortening the wavelength of light also increase the influence of aberrations when focusing light. Therefore, the margin for the tilt of the optical disk is reduced. Further, since the depth of focus is reduced by increasing the NA, the focus servo accuracy must be increased.
[0005]
Furthermore, since the distance between the objective lens and the recording surface of the optical disk is reduced by using a high NA objective lens, it is necessary to reduce the surface blur of the optical disk before the focus servo at the start is pulled in. The objective lens and the optical disk may collide, causing a pickup failure.
[0006]
As a short-wavelength, high-NA high-capacity optical disk, for example, as described in Non-Patent Document 1, a recording film is formed on a substrate that is as thick as a CD and has high rigidity, and is used for recording / reproducing light. Has been proposed in which recording / reproduction is performed on a recording film through a thin cover layer without passing through the substrate.
[0007]
Further, Patent Documents 1 to 3 and Non-Patent Document 1 have flexibility in opposition to a stabilizing member in order to stabilize surface blurring in an optical disk by utilizing aerodynamic action force according to Bernoulli's law. There is a description of a recording / reproducing apparatus configured to rotate an optical disk or a flexible optical disk.
[0008]
[Patent Document 1]
JP-A-7-105657
[0009]
[Patent Document 2]
Japanese Patent Laid-Open No. 10-308059
[0010]
[Patent Document 3]
JP 2003-115108 A
[0011]
[Non-Patent Document 1]
“Optical Readout of Video Disc”, “EITA TRANSPORTATION ON CONSUMER ELECTRONICS”, November 1976, p. 304-308
[0012]
[Problems to be solved by the invention]
However, in the prior art, when the optical disk substrate is formed of a rigid body, in order to reduce the surface blur and tilt in the rotating optical disk, the recording is performed at a low temperature so as to form a very accurate shape and prevent thermal deformation. A film must be deposited. This prolongs the tact time associated with optical disc manufacture and increases costs.
[0013]
Further, as described in Patent Documents 1 and 2, the method of rotating a flexible optical disk on a stabilizing plate has a high risk of sliding between the optical disk and the stabilizing plate. There is a problem that the surface of the chemical plate is damaged. This sliding causes dust generation, which causes an error.
[0014]
In particular, as described in Patent Document 1, when the recording film is present on the stabilizing plate side, the recording film of the optical disk is damaged by sliding, and an error is directly caused. Moreover, there is a limit to the effect of reducing the disc surface shake by simply using a flat stabilizer, and the risk of collision between the objective lens and the disc is still a problem when using a high NA objective lens. It remains.
[0015]
As one of the methods using the stabilizing plate, there is a method as described in Non-Patent Document 1, but it is the same as the above technique in terms of the configuration of using a planar stabilizing plate, and the same problem Is expected to occur. In this method, it is assumed that an aerodynamic force acts between a stabilizing plate called “smoothing plates” and the disc. For example, the direction in which the disc is separated from the stabilizing plate. If the shape is warped, the aerodynamic force does not act effectively, and the disc surface blur cannot be controlled. In addition, since the aerodynamic force is generated by utilizing the phenomenon that the disk hangs down due to gravity, it cannot cope with the vertical placement of the drive device.
[0016]
As one means for solving these problems, the present inventor uses a columnar stabilization guide member whose surface facing the optical disc forms an arc shape in Patent Document 3 and the like, and a stabilization guide member in the optical disc. A region where no air pressure action is generated (a space without a stabilizing guide member) is provided on the upstream and downstream sides of the disk rotation direction at the part where the surface shake due to the air pressure action is stable. An invention that increases the effect of the stabilizing force by aerodynamic force by reducing the repulsive force in the optical disc at the portion where the surface blurring is stabilized by making the optical disc have a portion that becomes “escape” before and after the portion. Proposed.
[0017]
According to the invention of Patent Document 3, it is possible to surely suppress surface deflection of a flexible optical disc, enable high-density recording, and prevent occurrence of problems such as sliding contact with an objective lens. On the other hand, this realization requires complicated position adjustment control of the stabilizing guide member and the recording / reproducing head, which not only increases the load on the drive control system, but also significantly increases the device cost. Become.
[0018]
Therefore, as one means for solving such a problem, the present inventor proposed a recording / reproducing apparatus having a configuration as shown in FIGS. 14 to 16 in Japanese Patent Application No. 2003-19087.
[0019]
14 is a plan view of the main part of the recording / reproducing apparatus, FIG. 15 is a cross-sectional view taken along the line EE ′ in FIG. 14, FIG. 16 is a front view of the recording / reproducing apparatus in FIG. An optical disk, which is a recording disk, 2 is a hub which is one holding member for rotating the optical disk 1 mounted on the rotation center (center) portion of the optical disk 1, and 3 is a chucking portion which is the other holding member The spindle motor 4 for rotating the optical disc 1 by fitting it to the hub 2 moves in the radial direction of the optical disc 1 to focus the light beam on the optical disc 1 and perform information recording / reproduction processing. This is an optical pickup of recording / reproducing means that performs optical scanning (direction of flow line R) on the optical disc 1.
[0020]
Further, reference numeral 5 moves in the radial direction of the optical disc 1 together with the optical pickup 4 and uses the aerodynamic action force according to Bernoulli's law to cause the optical disc surface blur at least near the recording / reproducing position by the optical pickup 4. The main stabilizing member 6 for suppressing the same is an auxiliary stabilizing member for applying an aerodynamic acting force to the optical disc 1, and the main stabilizing member 5 and the auxiliary stabilizing member 6 are used for recording on the optical disc 1. It is arranged on the disk substrate side opposite to the surface.
[0021]
Further, in this example, the auxiliary stabilizing member 6 is close to the flow line R that moves for the optical pickup 4 to scan in the plane of the optical disk 1 and passes through the vicinity of the center of the optical disk 1 (the flow line R in the figure). Although described above, including those in the vicinity of the flow line R), each of the two regions S1 and S2 separated by A is independently disposed at a symmetrical position with respect to the main stabilizing member 5. ing.
[0022]
In this manner, in addition to the main stabilizing member 5 disposed in the vicinity of the optical pickup 4, the auxiliary stabilizing member 6 is disposed at the specific position as described above, whereby the optical disk 1 on which the main stabilizing member 5 is located. An action force that opposes the main stabilizing member 5 is generated, and the effect of stabilizing the disc surface blurring by the aerodynamic force can be obtained without greatly pushing the main stabilizing member 5 into the optical disc 1.
[0023]
In the invention of the configuration shown in FIGS. 14 to 16, compared to the case where only one main stabilization member 5 is used, a sufficient surface blur reduction effect is obtained at a position where the pushing amount of the main stabilization member 5 is shallow, As a result, the flow line in the radial direction of the disk in the main stabilizing member 5 and the optical pickup 4 can be limited to a range close to the disk reference plane, so that the operation mechanism can be simplified.
[0024]
14 to 16, 21 is a proximity point (action point) between the auxiliary stabilization member 6 and the optical disc 1, 22 is a proximity region between the auxiliary stabilization member 6 and the optical disc 1, and 23 is an operation of the auxiliary stabilization member 6. The center of the surface is shown.
[0025]
However, in the present invention, for example, when the columnar auxiliary stabilizing member 6 having an arcuate surface facing the optical disk 1 is used, strictly as shown in FIG. There is a case in which the acting point 23 is shifted from the auxiliary stabilizing member 6 and the proximity point 21 of the optical disc 1 and the aerodynamic force by the auxiliary stabilizing member 6 does not sufficiently act. In some cases, this phenomenon causes the sliding contact between the optical disc 1 and the auxiliary stabilizing member 6, which becomes a problem in the reliability of recording / reproducing in this apparatus.
[0026]
The object of the present invention is to solve the above-mentioned problems and to optimize the aerodynamic acting force by the auxiliary stabilizing member in the configuration of the main stabilizing member and the auxiliary stabilizing member that causes the Bernoulli effect to act. Recording / playback device and stabilization adjustment method to reduce disc wobbling The law It is to provide.
[0027]
[Means for Solving the Problems]
In order to achieve the above-mentioned object, the invention according to claim 1 is characterized in that a flexible recording disk is rotated and the surface fluctuation of the recording disk at least near the recording / reproducing position is suppressed by utilizing the Bernoulli effect. A stabilizing member and recording / reproducing means for performing recording and / or reproduction on a surface opposite to a main working surface of the Bernoulli effect of the recording disk, and the recording / reproducing means is disposed within the surface of the recording disk. The main stabilizing member is divided into two areas by a straight line A that is close to the scanning flow line and passes through the vicinity of the center of the recording disk, and an aerodynamic force is generated in each of the two areas. A recording / reproducing apparatus in which an auxiliary stabilizing member is disposed so as to generate an acting force that opposes the main stabilizing member on the surface of the recording disk on which the recording medium is positioned. Both the tilt adjusting means for tilting the aerodynamic force acting surface of the adjusting member at the same tilt angle in the disc radial direction and both the auxiliary stabilizing members are pushed into the recording disc surface with the same pushing amount. And a position control means for setting the position of the auxiliary stabilizing member. With this configuration, each auxiliary stabilizing member can be adjusted by adjusting / setting the tilt angle and the pushing amount by the inclination adjusting means and the position controlling means for each auxiliary stabilizing member. The surface of the recording disk on which the main stabilizing member is located can be surely applied to the aerodynamic force of each auxiliary stabilizing member against the recording disk while avoiding sliding between the stabilizing member and the recording disk Thus, it is possible to efficiently generate the acting force that opposes the main stabilizing member. Thereby, the flow line in the disk radial direction in the main stabilizing member and the recording / reproducing means can be limited to a range close to the disk reference plane, and the operation mechanism can be simplified.
[0028]
According to a second aspect of the present invention, there is provided a main stabilizing member that rotates a flexible recording disk and uses a Bernoulli effect to suppress at least a recording / reproducing position near the recording / reproducing position, and a main stabilization member. Recording / reproducing means for recording and / or reproducing on the surface opposite to the main Bernoulli effect surface of the disk, and in the plane of the recording disk close to the flow line scanned by the recording / reproducing means. And the recording disk surface on which the main stabilizing member is located by dividing the two areas by a straight line A passing through the vicinity of the center of the recording disk and generating an aerodynamic force in each of the two areas. Recording / reproducing apparatus provided with an auxiliary stabilizing member so as to generate an acting force that opposes the main stabilizing member, wherein aerodynamics in each auxiliary stabilizing member Both the tilt adjusting means for tilting the acting surfaces of the various forces at the same tilt angle in the disc circumferential direction and the auxiliary stabilizing members are set so that the recording disc surface is pushed in with the same pushing amount. Each of the auxiliary stabilizing members and the recording disk by adjusting / setting the tilt angle and the pushing amount by the inclination adjusting means and the position controlling means for each auxiliary stabilizing member. In this way, the aerodynamic force of each auxiliary stabilizing member against the recording disk can be surely applied to the recording disk surface where the main stabilizing member is located. It is possible to efficiently generate the acting force facing the member. Thereby, the flow line in the disk radial direction in the main stabilizing member and the recording / reproducing means can be limited to a range close to the disk reference plane, and the operation mechanism can be simplified.
[0029]
According to a third aspect of the present invention, in the recording / reproducing apparatus according to the first or second aspect, the center of rotation when the auxiliary stabilizing member is tilted is set near the point of action on the working surface of the auxiliary stabilizing member. With this configuration, even when the tilt angle of the auxiliary stabilizing member is adjusted, it is possible to fix the action point position that is the final target. That is, if the action point is set to be the disk rotation center position according to the tilt angle of the auxiliary stabilizing member, the rotation center and the action point can always be matched. Thereby, even when the position of the auxiliary stabilizing member is adjusted based on the rotation center, the operation point position can be managed by the rotation center position by this operation.
[0030]
According to a fourth aspect of the present invention, in the recording / reproducing apparatus according to the first or second aspect, storage means for storing in advance information on an appropriate inclination angle set in the auxiliary stabilizing member for each disk specification of the recording disk. And the tilt adjustment means can adjust the tilt according to the disk specifications. With this configuration, the operation of the auxiliary stabilizing member can be optimized for various disk specifications.
[0031]
According to the fifth aspect of the present invention, in the recording / reproducing apparatus according to the first or second aspect, the disc specification range that can be used in the device is limited, and the auxiliary stabilizing member set in the disc specification range is appropriate. Based on the center value of the tilt angle, the tilt of the auxiliary stabilizing member is fixed. With this configuration, the fixed auxiliary stabilizing member placement condition can be applied to discs of arbitrary specification range, thereby stabilizing the auxiliary. The mechanism of the member can be simplified. Further, the auxiliary stabilizing member can be fixed to the disk cartridge.
[0032]
According to a sixth aspect of the present invention, there is provided a main stabilizing member that rotates a flexible recording disk and suppresses the surface deviation of the recording disk at least near the recording / reproducing position by utilizing the Bernoulli effect, and the recording Recording / reproducing means for recording and / or reproducing on the surface opposite to the main Bernoulli effect surface of the disk, and in the plane of the recording disk close to the flow line scanned by the recording / reproducing means. And the recording disk surface on which the main stabilizing member is located by dividing the two areas by a straight line A passing through the vicinity of the center of the recording disk and generating an aerodynamic force in each of the two areas. In the recording / reproducing apparatus provided with an auxiliary stabilizing member so as to generate an acting force that opposes the main stabilizing member. By inclining the working surface of the aerodynamic force of the stabilizing member at the same tilt angle in the disk radial direction, and pushing the recording disk surface with the same pushing amount together with the auxiliary stabilizing members, The acting force that opposes the main stabilizing member is optimized, and with this configuration, the tilt angle and the pushing amount with respect to each auxiliary stabilizing member are adjusted / set, thereby recording each auxiliary stabilizing member and recording. While avoiding sliding with the disc, the aerodynamic force of each auxiliary stabilizing member against the recording disc can be surely applied, and the main stability on the recording disc surface where the main stabilizing member is located. It is possible to efficiently generate the acting force that opposes the forming member. Thereby, the flow line in the disk radial direction in the main stabilizing member and the recording / reproducing means can be limited to a range close to the disk reference plane, and the operation mechanism can be simplified.
[0033]
According to a seventh aspect of the present invention, there is provided a main stabilizing member that rotates a flexible recording disk and uses the Bernoulli effect to suppress at least the recording / reproducing position near the recording / reproducing position, and the recording stabilization Recording / reproducing means for recording and / or reproducing on the surface opposite to the main Bernoulli effect surface of the disk, and in the plane of the recording disk close to the flow line scanned by the recording / reproducing means. And the recording disk surface on which the main stabilizing member is located by dividing the two areas by a straight line A passing through the vicinity of the center of the recording disk and generating an aerodynamic force in each of the two areas. In the recording / reproducing apparatus provided with an auxiliary stabilizing member so as to generate an acting force that opposes the main stabilizing member. By inclining the working surface of the aerodynamic force of the stabilizing member at the same tilt angle in the circumferential direction of the disc, and by pushing the recording disc surface with the same pushing amount together with the auxiliary stabilizing members. The operation force facing the main stabilization member is optimized, and by this configuration, the tilt angle and the pushing amount with respect to each auxiliary stabilization member are adjusted / set, The aerodynamic force of each auxiliary stabilizing member against the recording disk can be surely applied while avoiding sliding with the recording disk, and the main stabilizing member is located on the surface of the recording disk. It is possible to efficiently generate the acting force that opposes the stabilizing member. Thereby, the flow line in the disk radial direction in the main stabilizing member and the recording / reproducing means can be limited to a range close to the disk reference plane, and the operation mechanism can be simplified.
[0034]
According to an eighth aspect of the present invention, in the stabilization adjustment method of the recording / reproducing apparatus according to the sixth or seventh aspect, information on an appropriate inclination angle of the auxiliary stabilizing member is stored in advance for each arbitrary disk specification of the recording disk. In addition, the inclination of the auxiliary stabilizing member is adjusted according to the disk specifications. With this configuration, it is possible to optimize the operation of the auxiliary stabilizing member for various disk specifications. .
[0035]
According to a ninth aspect of the present invention, in the stabilization adjustment method for a recording / reproducing apparatus according to the sixth or seventh aspect, the disk specification range used in the apparatus is limited, and the inclination of the auxiliary stabilizing member is set to the disk specification. This is characterized in that it is fixedly set to the center value of the appropriate inclination angle of the auxiliary stabilizing member determined by the range, and by this configuration, the arrangement condition of the fixed auxiliary stabilizing member can be applied to a disc of an arbitrary specification range. In addition, the mechanism of the auxiliary stabilizing member can be simplified. Further, the auxiliary stabilizing member can be fixed to the disk cartridge.
[0036]
According to a tenth aspect of the present invention, in the stabilization adjustment method for a recording / reproducing apparatus according to the sixth or seventh aspect, the effect of the aerodynamic force of the auxiliary stabilizing member is adjusted by adjusting the inclination of the auxiliary stabilizing member. The point is set at the substantial rotation center of the auxiliary stabilizing member, and this configuration makes it possible to optimize the operation of the auxiliary stabilizing member for various disk specifications.
[0038]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0039]
1 is a plan view of a main part for explaining a reference example of the recording / reproducing apparatus of the present invention, FIG. 2 (a) is a cross-sectional view taken along the line EE 'in FIG. 1, and FIG. 2 (b) is in FIG. FIG. 3 is a front view of the recording / reproducing apparatus in FIG. 1, 1 is an optical disc that is a flexible recording disc, and 2 is attached to the rotation center (center) portion of the optical disc 1. A hub 3 as a holding member for holding the optical disc 1 rotated to rotate it, a spindle motor 4 for rotating the optical disc 1 by fitting a chucking portion as the other holding member into the hub 2, Recording / reproducing means that moves in the radial direction of the optical disc 1 to focus the light beam on the optical disc 1 and performs optical scanning (direction of flow line R) on the optical disc 1 to perform information recording / reproduction processing. There is an optical pickup.
[0040]
Further, 5 is a main stabilization in which the optical disk 1 side protrudes in an arc shape when viewed from the front, and moves in the optical pickup scanning flow line R direction in the disk radial direction in synchronization with the movement of the optical pickup 4 as shown in FIG. The main stabilization member 5 uses aerodynamic action force according to Bernoulli's law to suppress surface blurring at least near the recording / reproducing position of the optical pickup 4 in the optical disc 1.
[0041]
Further, reference numeral 6 denotes an auxiliary stabilizing member that acts together with the main stabilizing member 5 to apply an aerodynamic acting force to the optical disc 1. The main stabilizing member 5 and the auxiliary stabilizing member 6 are optical discs. 1 is disposed on the side of the disk substrate opposite to the recording surface.
[0042]
In the reference example, a straight line that is close to the flow line R that moves for the optical pickup 4 to scan in the plane of the optical disk 1 and passes near the center of the optical disk 1 (shown on the flow line R in the figure, Of the two regions S1 and S2 divided by A) (including those in the vicinity of the flow line R), the region S2 located downstream of the optical pickup 4 in the optical disc rotation direction is independent of the main stabilization member 5. At least one auxiliary stabilizing member 6 (only one is shown in the reference example) is provided.
[0043]
The main stabilizing member 5 is provided with a movement control mechanism 11 in the disk radial direction and a position control mechanism 12 in the disk rotation axis direction, and each auxiliary stabilization member 6 has a position control mechanism in the disk rotation axis direction. 13 and a tilt control mechanism 14 which is a tilt adjustment means in the disk radial direction and the disk circumferential direction. The movement control mechanism 11, the position control mechanisms 12 and 13, and the tilt control mechanism 14 are each set of various setting data, etc. Is controlled by a drive unit 16 that receives control data from a memory 15 that stores.
[0044]
The rotation center in the tilt angle control of the tilt angle control mechanism 14 of the auxiliary stabilizing member 6 is the position of the action surface center (action point) 23 of the auxiliary stabilizing member 6. 1 to 3, reference numeral 21 denotes a proximity point between the auxiliary stabilization member 6 and the optical disc 1, and 22 denotes a proximity region between the auxiliary stabilization member 6 and the optical disc 1.
[0045]
4 is a plan view of an essential part for explaining the first embodiment of the recording / reproducing apparatus of the present invention, FIG. 5 (a) is a sectional view taken along the line EE ′ in FIG. 4, and FIG. 5 (b) is FIG. FIG. In the following description, members corresponding to those already described are denoted by the same reference numerals, and detailed description thereof is omitted.
[0046]
The first embodiment is different from the reference example in that at least the auxiliary stabilizing member 6 is provided independently of the main stabilizing member 5 in each of the two regions S1 and S2 divided in the same manner as described in the reference example. One by one (one in each region in the first embodiment) is arranged at a symmetrical position.
[0047]
6 is a plan view of an essential part for explaining the second embodiment of the recording / reproducing apparatus of the present invention, FIG. 7A is a sectional view taken along the line EE ′ in FIG. 6, and FIG. FIG. 7 (a), (b) is a cross-sectional view taken along line FF ′ in FIG. 5 and shows that the second embodiment is different from the first embodiment in comparison with FIGS. 5 (a), 5 (b). The adjustment direction of the disc circumferential direction inclination of the auxiliary stabilizing member 6 as shown in FIG.
[0048]
The operation of the reference example and the embodiment will be described.
[0049]
In order to suppress disc surface blurring by generating an aerodynamic force according to Bernoulli's law between the stabilizing member which is the basic configuration in the reference example and the embodiment and the flexible disc, The balance condition between the adjusting member and the disk is important, and in particular, the reaction force toward the stabilizing member of the disk is an important parameter. Since this reaction force is determined by the rigidity of the disk and the levitation force generated by the disk rotating and flattening, in principle, the balance condition is the radial position of the stabilizing member, the disk rotation speed, In addition, the disk specification depends on the parameters, and a complicated adjustment drive mechanism is required.
[0050]
As a result of various experiments and considerations regarding this point, when an aerodynamic force is applied to the disk surface by an arbitrary stabilizing member, approximately ± 90 upstream and downstream of the disk rotating direction in the stabilizing member. This shows the phenomenon that the disk surface near the angle approaches the disk reference surface when the disk is considered as an ideal plane.
[0051]
Therefore, the phenomenon that the disk surface at a position shifted by ± 90 degrees from any stabilizing member approaches the disk reference surface is used as the reaction force described above to adjust the balance condition between the stabilizing member and the disk. As a result, the effect of stabilizing the disk surface efficiently was obtained.
[0052]
However, at the position of the stabilizing member (auxiliary stabilizing member) used for adjustment, as shown in FIGS. 14 to 16, the point of action of the aerodynamic force deviates from the center point of the auxiliary stabilizing member. As a result, it has been clarified that the effect of the auxiliary stabilizing member described above may be hindered due to this deviation. In this regard, various further experiments were conducted and considerations were made. As a result, by adjusting the tilt angle of the auxiliary stabilizing member, the center point of the auxiliary stabilizing member 6 and the action of the aerodynamic force of the auxiliary stabilizing member. We found that the points can be matched.
[0053]
In the present embodiment, the point of action of the aerodynamic force of the auxiliary stabilizing member 6 is adjusted to an appropriate position by the tilt angle of the auxiliary stabilizing member 6, and the aerodynamic force of the auxiliary stabilizing member 6 on the optical disc 1 is adjusted. Is made to work reliably.
[0054]
In the reference example, by appropriately applying the aerodynamic force of the auxiliary stabilizing member 6 to the optical disc 1, it is possible to efficiently generate a force in which the optical disc 1 faces the main stabilizing member 5, A sufficient surface blur reduction effect was obtained at the moving position of the main stabilizing member 5. As a result, the flow line R in the disk radial direction of the main stabilizing member 5 and the optical pickup 4 is positioned in a range (a relatively wide region illustrated by hatching) H close to the disk reference surface in which the surface shake is suppressed. Therefore, the adjustment mechanism for this purpose can be given a margin, and the adjustment mechanism can be simplified.
[0055]
Note that the configuration of the reference example is that the optical disk 1 in which the disk surface on the downstream side of the main stabilization member 5 is displaced to the side close to the main stabilization member 5 when the apparatus is configured by only the main stabilization member 5. For example, the optical disc 1 in which the static warp shape of the optical disc 1 is convex toward the optical pickup 4 corresponds to this. In this case, the tilt angle of the auxiliary stabilizing member is adjusted in the direction in which the outer peripheral side is brought closer to the optical pickup with respect to the radial direction of the disc, and in the clockwise direction toward the disc center with respect to the disc circumferential direction (auxiliary stabilizing member). The direction in which the upstream side of the disk rotates closer to the disk was appropriate.
[0056]
Further, for example, when the apparatus is configured only by the main stabilization member 5, the optical disc 1 (the optical disc 1 of the optical disc 1) in which the upstream disc surface of the main stabilization member 5 is displaced toward the side close to the main stabilization member 5. In the optical disk 1 in which the static warp shape is concave on the optical pickup 4 side), a configuration in which the disk rotation direction is reversed by modifying the reference example can be applied. By appropriately applying the aerodynamic force of the stabilizing member 6 to the optical disc 1, it is possible to efficiently generate a force in which the optical disc 1 faces the main stabilizing member 5, and the main stabilizing member 5. A sufficient surface blur reduction effect was obtained at the moving position. At this time, the tilt angle of the auxiliary stabilizing member 6 is adjusted in a direction in which the outer peripheral side is brought closer to the optical pickup 4 with respect to the radial direction of the disc and in a clockwise direction toward the disc center with respect to the disc circumferential direction ( The direction in which the disk rotation downstream side of the auxiliary stabilizing member approaches the disk was appropriate.
[0057]
Also in the configuration of the first embodiment, by causing the aerodynamic force of both auxiliary stabilizing members 6 to act appropriately on the optical disc 1, a force for causing the optical disc 1 to oppose the main stabilizing member 5 is efficiently generated. A sufficient surface blurring reduction effect was obtained at the movement position of the main stabilizing member 5.
[0058]
Thereby, the flow line R in the disc radial direction in the main stabilizing member 5 and the optical pickup 4 is positioned in a range (a relatively wide region illustrated by oblique lines) H close to the disc reference plane in which surface deflection is suppressed. Therefore, the adjustment mechanism for this purpose can be given a margin, and the adjustment mechanism can be simplified.
[0059]
The configuration of the first embodiment is such that when the apparatus is composed of only the main stabilizing member 5, the disc surface on the downstream side of the main stabilizing member 5 is displaced toward the side close to the main stabilizing member 5. For example, the optical disc 1 in which the static warp shape of the optical disc 1 is convex toward the optical pickup 4 corresponds to this. At this time, the tilt angles of the auxiliary stabilizing members 6 are adjusted in such a direction that the outer peripheral side is brought closer to the optical pickup 4 with respect to the radial direction of the disc, and a clockwise direction toward the disc center with respect to the disc circumferential direction. (The direction in which the disk rotation upstream side of the auxiliary stabilizing member 6 approaches the optical disk 1) was appropriate.
[0060]
Also in the configuration of the second embodiment, by causing the aerodynamic force of both auxiliary stabilizing members 6 to act appropriately on the optical disc 1, the force that causes the optical disc 1 to oppose the main stabilizing member 5 is efficiently generated. A sufficient surface blurring reduction effect was obtained at the movement position of the main stabilizing member 5.
[0061]
Thereby, the flow line R in the disc radial direction in the main stabilizing member 5 and the optical pickup 4 is positioned in a range (a relatively wide region illustrated by oblique lines) H close to the disc reference plane in which surface deflection is suppressed. Therefore, the adjustment mechanism for this purpose can be given a margin, and the adjustment mechanism can be simplified.
[0062]
Note that the configuration of the second embodiment is an optical disc in which the upstream side disc surface of the main stabilization member 5 is displaced toward the side close to the main stabilization member 5 when the apparatus is configured by only the main stabilization member 5. For example, the optical disc 1 in which the static warp shape of the optical disc 1 is concave on the optical pickup 4 side corresponds to this. In this case, the tilt angles of the auxiliary stabilizing members 6 are adjusted in a direction in which the outer peripheral side is brought closer to the optical pickup with respect to the disc radial direction and in a counterclockwise direction toward the disc center with respect to the disc circumferential direction ( The direction in which the disk rotation downstream side of the auxiliary stabilizing member 6 approaches the disk was appropriate.
[0063]
In the configuration of the first and second embodiments, a position control mechanism or a tilt control system in the direction of the disk rotation axis is added to the main stabilizing member 5 to perform fine adjustment with higher accuracy, so that the recording / reproducing position can be adjusted. It was also possible to optimize the surface blur.
[0064]
FIG. 8 is a plan view of an essential part for explaining a modification of Embodiment 2 of the recording / reproducing apparatus of the present invention, FIG. 9A is a cross-sectional view taken along the line EE ′ in FIG. 8, and FIG. FIG. 8 is a cross-sectional view taken along line FF ′ in FIG. 8. In the second embodiment, the hub 2 of the optical disc 1 is connected to the chuck of the spindle motor 3 shown in FIG. 3 as in the modified examples shown in FIGS. A peripheral portion (circular region in FIG. 8) connecting the fulcrum positions (the outer periphery of the hub 2 in FIG. 8) where the optical disc 1 starts to bend when the stabilizing members 5 and 6 are pushed and bent on the king portion. ) And a straight line A passing through two points intersecting and perpendicular to the straight line A, that is, on a disc surface sandwiched between a straight line B1 closer to the main stabilizing member 5 and a straight line B2 farther from the main stabilizing member 5. In the region C, the auxiliary stabilizing member 6 is located near the straight line B1 on the side close to the main stabilizing member 5. With the structure disposing the use point 23, to further reduce the disk surface vibration at the movement position of the main stabilizing member 5, was obtained exerts sufficient effect described above.
[0065]
In addition, as the inclination adjustment of the auxiliary stabilizing member 6 in the embodiment, for each disk specification of the optical disk used in the apparatus, an optimum of the auxiliary stabilizing member 6 set in accordance with the disk specification by performing a test or the like in advance. The tilt angle information is stored in the memory 15 shown in FIG. 3, and when the optical disc is loaded into the apparatus, the proper tilt angle information corresponding to the disc specification of the optical disc is automatically read from the memory 15 to thereby provide a tilt control mechanism. It is conceivable to adjust the inclination by driving 14.
[0066]
Furthermore, the disc specification range that can be used in the apparatus is limited, the inclination is fixed based on the center value of the appropriate inclination angle of the auxiliary stabilization member 6 set in the disc specification range, and the auxiliary stabilization member 6 is placed in place. You may make it install in. By doing in this way, the arrangement | positioning conditions of the fixed auxiliary stabilization member 6 can be applied to the disk of arbitrary specification ranges, and the mechanism of the auxiliary stabilization member 6 can be simplified.
[0067]
In each of the above embodiments, the auxiliary stabilizing member 6 is provided in the housing 30 of the apparatus main body as illustrated in FIG. 10, so that a disk cartridge for storing the optical disk is not used or the optical disk is removed from the disk cartridge. The present invention can be implemented in a recording / reproducing apparatus that is taken out and driven.
[0068]
Further, as shown in FIG. 11, the auxiliary stabilizing member 6 in each of the above embodiments can be provided on the inner wall of the disc cartridge 31. With this configuration, the configuration on the recording / reproducing apparatus side is configured. It can be simplified. Further, in this configuration, since the auxiliary stabilizing member 6 can be individually set in the disk cartridge 31, the auxiliary stabilizing member 6 can be individually designed for each of various disk specifications, and stabilization due to variations in disk specifications. It is also possible to correct the deviation of conditions.
[0069]
Examples of the disk cartridge 31 include those shown in FIGS. 12 and 13, 32 is a first through-hole portion for allowing the main stabilizing member 5 to be inserted and moving in the radial direction of the disk, 33 is a portion of the optical pickup 4 and the spindle motor 3. This is a second through hole that is inserted and allows the optical pickup 4 to move in the radial direction of the disk. A shutter for opening and closing the through holes 32 and 33, a mechanism for fixing the optical disc 1 in the cartridge, and other mechanisms necessary for installing the cartridge in the spindle motor 3 are illustrated. Not.
[0070]
In the above embodiment, the configuration example in which the auxiliary stabilizing member is disposed on the same side as the main stabilizing member has been described. However, the auxiliary stabilizing member may be disposed on the opposite side of the main stabilizing member and the disk. The disc surface shake reduction effect can be obtained.
[0071]
Next, the present invention will be described more specifically based on reference examples, examples, and comparative examples.
[0072]
(Reference Example 1)
In Reference Example 1, the configuration shown in FIG. 1 and FIG. 2 is adopted, and the auxiliary stabilizing member 6 has a cylindrical shape with a diameter of 15 mm and a surface facing the optical disc (diameter 120 mm) 1 having a curvature radius of 100 mm. The main stabilizing member 5 has a cylindrical shape with a diameter of 10 mm and a surface facing the optical disc 1 with a radius of curvature of 100 mm. Further, the auxiliary stabilizing member 6 is disposed at a position of 90 degrees downstream of the main stabilizing member 5 in the disk rotation direction, and the center of the disk facing surface is positioned at a radius of 45 mm of the optical disk 1. Although not shown, the main stabilization member 5 is provided with a moving mechanism in the disk radial direction and a position control mechanism in the disk rotation axis direction, and the auxiliary stabilization member 6 is provided with a position control mechanism in the disk rotation axis direction. And a tilt control mechanism in the disc radial direction and the disc circumferential direction. The rotation center in the tilt angle control of the tilt control mechanism of the auxiliary stabilizing member 6 is the center position of the working surface of the auxiliary stabilizing member.
[0073]
Reference Example 1 describes a case where a polycarbonate sheet having a thickness of 120 mm and a thickness of 75 μm is used as a disk substrate. In preparing the disk, first, a groove having a stamper pitch of 0.6 μm and a width of 0.3 μm is transferred to the sheet by thermal transfer, and then the sheet / Ag reflection layer 120 nm / (ZrO) by sputtering. ₂ -Y ₂ O ₃ ) -SiO ₂ 7nm / AgInSbTeGe 10nm / ZnS-SiO ₂ 25nm / Si ₃ N ₄ Films were formed in the order of 10 nm. The information recording area was set in a range from an inner diameter of 40 mm to an outer diameter of 118 mm (radius 20 mm to 58 mm). Thereafter, a UV resin was spin-coated and cured by ultraviolet irradiation to form a transparent protective film having a thickness of 5 μm. Further, a hard coat having a thickness of 10 μm was applied to the opposite surface. A hub 2 having an outer diameter of 30 mm, an inner diameter of 15 mm, and a thickness of 0.3 mm was attached to the center of the disk. The finished state of the disk was slightly warped to the hard coat side.
[0074]
The optical disk 1 is rotated at a disk rotational speed of 15 m / sec, the auxiliary stabilizing member and the main stabilizing member are arranged at predetermined positions to stabilize the disk surface vibration, and a laser displacement meter is arranged at the position of the optical pickup 4. The disc surface blur was evaluated. Further, contact between the auxiliary stabilizing member and the recording disk was detected by an AE sensor (not shown) arranged on the auxiliary stabilizing member, and the contact sliding state was evaluated. Here, the auxiliary stabilizing member is tilted by 1 degree in the direction in which the outer peripheral portion is brought close to the optical pickup with respect to the disk radial direction, and 0.7 degrees in the clockwise direction toward the disk center with respect to the disk circumferential direction, Further, it was arranged at a position where the disk reference surface was pushed in by 0.5 mm. The disk reference surface here is a disk surface on the side of the main stabilizing member 5 when the disk is assumed to be ideally flat, and the auxiliary stabilizing member 6 that determines the pushing amount. The reference position was the center position for tilt angle control.
[0075]
(Reference Example 2)
In Reference Example 2, based on the configuration of Reference Example 1, the position of the auxiliary stabilizing member 6 is 90 degrees upstream of the main stabilizing member 5 in the disk rotation direction, and the center of the disk facing surface is the disk. The arrangement was changed to a position with a radius of 45 mm.
[0076]
Further, the optical disk 1 was configured such that the hard coat was omitted from the specification of the reference example 1. As a result, the finished state of the optical disc 1 was slightly warped toward the transparent protective film side.
[0077]
The optical disk 1 is rotated at a disk rotational speed of 15 m / sec, the auxiliary stabilizing member and the main stabilizing member are arranged at predetermined positions to stabilize the disk surface vibration, and a laser displacement meter is arranged at the position of the optical pickup 4. The disc surface blur was evaluated. Further, contact between the auxiliary stabilizing member and the recording disk was detected by an AE sensor (not shown) arranged on the auxiliary stabilizing member, and the contact sliding state was evaluated. Here, the auxiliary stabilizing member is tilted 2 degrees in the direction in which the outer peripheral portion is brought closer to the optical pickup with respect to the disk radial direction, and 1 degree in the counterclockwise direction toward the disk center with respect to the disk circumferential direction. The disk was placed at a position where it was pushed in by 1 mm with reference to the disk reference surface. The disk reference surface here is a disk surface on the side of the main stabilizing member 5 when the disk is assumed to be ideally flat, and the auxiliary stabilizing member 6 that determines the pushing amount. The reference position was the center position for tilt angle control.
[0078]
(Example 1)
In the first embodiment, the configuration shown in FIGS. 4 and 5 is adopted, and both auxiliary stabilizing members 6 have a cylindrical shape with a diameter of 15 mm with a curvature radius of 100 mm on the surface facing the optical disc (diameter 120 mm) 1. The main stabilizing member 5 has a cylindrical shape with a diameter of 10 mm and a surface facing the optical disc 1 with a radius of curvature of 100 mm. Both auxiliary stabilizing members 6 are arranged so that the center of the disk facing surface is at a position of a radius of 45 mm of the optical disk 1 at both positions of 90 degrees upstream and downstream in the disk rotation direction of the main stabilizing member 5. Although not shown, the main stabilizing member 5 is provided with a moving mechanism in the disk radial direction and a position control mechanism in the disk rotating shaft direction, and both auxiliary stabilizing members 6 have position control in the disk rotating shaft direction. And a tilt control mechanism in the disk radial direction and the disk circumferential direction. Note that the rotation center in the tilt angle control of the tilt angle control mechanism of the auxiliary stabilizing member 6 is the center position of the working surface of the auxiliary stabilizing member.
[0079]
The same optical disk 1 as in Reference Example 1 was used.
[0080]
The optical disk 1 is rotated at a disk rotational speed of 15 m / sec, both auxiliary stabilizing members and the main stabilizing member are arranged at predetermined positions to stabilize the disk surface shake, and a laser displacement meter is arranged at the position of the optical pickup 4 Then, the disc surface shake was evaluated. Further, contact between the auxiliary stabilizing member and the recording disk was detected by an AE sensor (not shown) arranged on the auxiliary stabilizing member, and the contact sliding state was evaluated. Here, both auxiliary stabilizing members are 0.7 degrees in the direction in which the outer peripheral portion is brought closer to the optical pickup with respect to the disk radial direction, and 0.4 in the clockwise direction toward the disk center with respect to the disk circumferential direction. It was arranged at a position where it was tilted by 0.3 mm and the disk reference surface was pushed in by 0.3 mm. Here, the disk reference surface is a disk surface on the side of the main stabilizing member 5 when the disk is assumed to be ideally flat, and both auxiliary stabilizing members that determine the pushing amount. The reference position 6 was the center position for tilt angle control.
[0081]
(Example 2)
In Example 2, the configuration shown in FIG. 6 and FIG. 7 is adopted, and both auxiliary stabilizing members 6 have a cylindrical shape with a diameter of 15 mm with a curvature radius of 100 mm on the surface facing the optical disc (diameter 120 mm) 1. The main stabilizing member 5 has a cylindrical shape with a diameter of 10 mm and a surface facing the optical disc 1 with a radius of curvature of 100 mm. Both auxiliary stabilizing members 6 are arranged so that the center of the disk facing surface is at a position of a radius of 45 mm of the optical disk 1 at both positions of 90 degrees upstream and downstream in the disk rotation direction of the main stabilizing member 5. Although not shown, the main stabilizing member 5 is provided with a moving mechanism in the disk radial direction and a position control mechanism in the disk rotating shaft direction, and both auxiliary stabilizing members 6 have position control in the disk rotating shaft direction. And a tilt control mechanism in the disk radial direction and the disk circumferential direction. The rotation center in the tilt angle control of the tilt control mechanism of the auxiliary stabilizing member 6 is the center position of the working surface of the auxiliary stabilizing member.
[0082]
Further, the optical disk 1 was configured such that the hard coat was omitted from the specification of the reference example 1. As a result, the finished state of the optical disc 1 was slightly warped toward the transparent protective film side.
[0083]
The optical disk 1 is rotated at a disk rotational speed of 15 m / sec, both auxiliary stabilizing members and the main stabilizing member are arranged at predetermined positions to stabilize the disk surface shake, and a laser displacement meter is arranged at the position of the optical pickup 4 Then, the disc surface shake was evaluated. Further, contact between the auxiliary stabilizing member and the recording disk was detected by an AE sensor (not shown) arranged on the auxiliary stabilizing member, and the contact sliding state was evaluated. Here, both auxiliary stabilizing members are tilted by 1 degree in the direction in which the outer peripheral portion is brought closer to the optical pickup with respect to the disk radial direction, and 0.7 degrees in the counterclockwise direction toward the disk center with respect to the disk circumferential direction. In addition, it was arranged at a position where the disc reference surface was pushed in by 0.5 mm. Here, the disk reference surface is a disk surface on the side of the main stabilizing member 5 when the disk is assumed to be ideally flat, and both auxiliary stabilizing members that determine the pushing amount. The reference position 6 was the center position for tilt angle control.
[0084]
(Example 3)
In Example 3, the configuration shown in FIGS. 8 and 9 is adopted, and both auxiliary stabilizing members 6 have a columnar shape with a diameter of 15 mm with a radius of curvature of 100 mm on the surface facing the optical disc (diameter 120 mm) 1. The main stabilizing member 5 has a cylindrical shape with a diameter of 10 mm and a surface facing the optical disc 1 with a radius of curvature of 100 mm. Both auxiliary stabilizing members 6 are arranged so that the center of the disk facing surface is at a position of a radius of 45 mm of the optical disk 1 at both positions at 75 degrees upstream and downstream in the disk rotation direction of the main stabilizing member 5. Although not shown, the main stabilizing member 5 is provided with a moving mechanism in the disk radial direction and a position control mechanism in the disk rotating shaft direction, and both auxiliary stabilizing members 6 have position control in the disk rotating shaft direction. And a tilt control mechanism in the disk radial direction and the disk circumferential direction. The rotation center in the tilt angle control of the tilt control mechanism of the auxiliary stabilizing member 6 is the center position of the working surface of the auxiliary stabilizing member.
[0085]
The same optical disk 1 as in Reference Example 1 was used.
[0086]
The optical disk 1 is rotated at a disk rotational speed of 15 m / sec, both auxiliary stabilizing members and the main stabilizing member are arranged at predetermined positions to stabilize the disk surface shake, and a laser displacement meter is arranged at the position of the optical pickup 4 Then, the disc surface shake was evaluated. Further, contact between the auxiliary stabilizing member and the recording disk was detected by an AE sensor (not shown) arranged on the auxiliary stabilizing member, and the contact sliding state was evaluated. Here, both auxiliary stabilizing members are 0.7 degrees in the direction in which the outer peripheral portion is brought closer to the optical pickup with respect to the disk radial direction, and 0.4 in the clockwise direction toward the disk center with respect to the disk circumferential direction. It was arranged at a position where it was tilted by 0.3 mm and the disk reference surface was pushed in by 0.3 mm. Here, the disk reference surface is a disk surface on the side of the main stabilizing member 5 when the disk is assumed to be ideally flat, and both auxiliary stabilizing members that determine the pushing amount. The reference position 6 was the center position for tilt angle control.
[0087]
(Comparative example)
In this comparative example, the configuration shown in FIG. 14 to FIG. 16 is adopted, and both auxiliary stabilizing members 6 have a columnar shape with a diameter of 15 mm with a curvature radius of 100 mm on the surface facing the optical disc (diameter 120 mm) 1. The main stabilizing member 5 has a cylindrical shape with a diameter of 10 mm and a surface facing the optical disc 1 with a radius of curvature of 100 mm. Both auxiliary stabilizing members 6 are arranged so that the center of the disk facing surface is at a position of a radius of 45 mm of the optical disk 1 at both positions of 90 degrees upstream and downstream in the disk rotation direction of the main stabilizing member 5. Although not shown, the main stabilizing member 5 is provided with a moving mechanism in the disk radial direction and a position control mechanism in the disk rotating shaft direction, and both auxiliary stabilizing members 6 have position control in the disk rotating shaft direction. A mechanism was provided.
[0088]
The same optical disk 1 as in Reference Example 1 was used.
[0089]
The optical disk 1 is rotated at a disk rotational speed of 15 m / sec, both auxiliary stabilizing members and the main stabilizing member are arranged at predetermined positions to stabilize the disk surface shake, and a laser displacement meter is arranged at the position of the optical pickup 4 Then, the disc surface shake was evaluated. Further, contact between the auxiliary stabilizing member and the recording disk was detected by an AE sensor (not shown) arranged on the auxiliary stabilizing member, and the contact sliding state was evaluated. Both auxiliary stabilizing members were arranged at a position where the disk reference surface was pushed in by 0.5 mm. Here, the disk reference surface is a disk surface on the side of the main stabilizing member 5 when the disk is assumed to be ideally flat, and both auxiliary stabilizing members that determine the pushing amount. The reference position of 6 is the center of the working surface of the auxiliary stabilizing member.
[0090]
In the reference example, the example, and the comparative example, the results of testing the disk surface shake at a radius of 55 mm and the sliding state of the disk and the auxiliary stabilizing member when stabilizing the same surface shake are shown in FIG. Came to show.
[0091]
In each embodiment, by adjusting the tilt angle of the auxiliary stabilizing member, as shown in FIGS. 1 to 4, the auxiliary stabilizing member 6 and the optical disc 1 are adjacent to each other, that is, an aerodynamic force acting point, The working surface center 23 of the auxiliary stabilizing member 6, that is, the appropriate point for applying the aerodynamic force of the auxiliary stabilizing member 6 can be adjusted to substantially the same position. An aerodynamic force on the optical disc 1 can be applied reliably.
[0092]
As a first effect by the above action, a good surface blur reduction effect at the movement position of the main stabilizing member 5 was obtained. This is related to the fact that the acting force opposed to the main stabilizing member 5 can be efficiently generated on the optical disk surface on which the main stabilizing member 5 is located by the action of the auxiliary stabilizing member 6.
[0093]
In particular, in the first to third embodiments, the effect of the arrangement form of the auxiliary stabilizing member 6 was added to this effect, and a smaller disc surface fluctuation could be realized.
[0094]
Further, as a second effect by the above action, a floating state between the optical disc 1 and the auxiliary stabilizing member 6 can be realized, and contact sliding between the optical disc / auxiliary stabilizing member can be surely avoided. This is because the point of application of the aerodynamic force by the auxiliary stabilizing member 6 can be adjusted to an appropriate point by adjusting the tilt angle.
[0095]
On the other hand, in the comparative example, as illustrated in FIGS. 14 to 16, the proximity stabilizing point 6 between the auxiliary stabilizing member 6 and the optical disk 1, that is, the point of action of the aerodynamic force is that of the auxiliary stabilizing member 6. The auxiliary stabilizing member 6 is located on the side close to the operating surface boundary region of the auxiliary stabilizing member 6, deviating from the working surface center 23, that is, the appropriate point where the aerodynamic force of the auxiliary stabilizing member is applied. The generation of aerodynamic force due to has become unstable.
[0096]
For this reason, improper vibration is superimposed on the disc surface shake at the position of the main stabilizing member 5, and a sufficient disc surface shake reduction effect cannot be obtained. In addition, since the generation of aerodynamic force by the auxiliary stabilizing member 6 becomes unstable, the flying condition between the auxiliary stabilizing member 6 and the optical disk 1 cannot be established, causing contact sliding, The optical disk 1 has been damaged.
[0097]
As described above, in the present embodiment and the present example, in the configuration of the main stabilizing member and the auxiliary stabilizing member that cause the Bernoulli effect, the aerodynamic acting force by the auxiliary stabilizing member is optimized and recorded. It is possible to provide a recording / reproducing apparatus capable of realizing good disk surface fluctuation reduction at the reproducing position.
[0098]
【The invention's effect】
As described above, the recording / reproducing apparatus and the stabilization adjustment method according to the present invention To the law According to the structure of the main stabilizing member and each auxiliary stabilizing member that causes the Bernoulli effect to act, both the aerodynamic force acting surfaces in each auxiliary stabilizing member are tilt-adjusted at the same tilt angle, and By setting each of the auxiliary stabilizing members to be pushed into the recording disk surface with the same pushing amount, air between each auxiliary stabilizing member and the recording disk is avoided while avoiding sliding between each auxiliary stabilizing member and the recording disk. It is possible to reliably apply a mechanical force, and it is possible to efficiently generate an acting force that opposes the main stabilizing member on the recording disk surface on which the main stabilizing member is located. It can be reduced satisfactorily. Thereby, the flow line in the disk radial direction in the main stabilizing member and the recording / reproducing means can be limited to a range close to the disk reference plane, and the operation mechanism can be simplified.
[Brief description of the drawings]
FIG. 1 is a plan view of a main part for explaining a reference example of a recording / reproducing apparatus of the present invention.
2A is a cross-sectional view taken along line EE ′ in FIG. 1, and FIG. 2B is a cross-sectional view taken along line FF in FIG.
FIG. 3 is a front view of the reference example of FIG.
FIG. 4 is a plan view of a main part for explaining Embodiment 1 of the recording / reproducing apparatus of the present invention.
5A is a cross-sectional view taken along line EE ′ in FIG. 4, and FIG. 5B is a cross-sectional view taken along line FF in FIG.
FIG. 6 is a plan view of a main part for explaining Embodiment 2 of the recording / reproducing apparatus of the present invention.
7A is a cross-sectional view taken along line EE ′ in FIG. 6, and FIG. 7B is a cross-sectional view taken along line FF in FIG.
FIG. 8 is a plan view of a main part for describing a modification of the second embodiment of the recording / reproducing apparatus of the present invention.
9A is a cross-sectional view taken along line EE ′ in FIG. 8, and FIG. 9B is a cross-sectional view taken along line FF in FIG.
FIG. 10 is a cross-sectional view showing an installation example of an auxiliary stabilizing member in the recording / reproducing apparatus of the present embodiment.
FIG. 11 De Sectional view for explaining a disk cartridge
FIG. FIG. Top view of the disc cartridge
13 is a cross-sectional view of the disk cartridge of FIG.
FIG. 14 is a plan view of the main part of a recording / reproducing apparatus as a comparative example of the present invention.
15 is a sectional view taken along line EE ′ in FIG.
FIG. 16 is a front view of the recording / reproducing apparatus in FIG.
FIG. 17 is a diagram showing a list of characteristic evaluations in the reference examples, examples, and comparative examples of the present invention.
[Explanation of symbols]
1 Optical disc
2 Hub
3 Spindle motor
4 Optical pickup
5 Main stabilizer
6 Auxiliary stabilizer
11 Movement control mechanism
12, 13 Position control mechanism
14 Tilt control mechanism
15 memory
16 Drive unit
21 Proximity point between auxiliary stabilizing member and optical disc
22 Proximity region between auxiliary stabilizing member and optical disc
23 Center of action of auxiliary stabilizing member (point of action)
30 Body of the device body
31 disc cartridge
A Extension line of optical pickup flow line
B1, B2 A straight line passing through the circumference of the hub and perpendicular to the straight line A
R flow line
S1, S2, C Areas divided in the plane of the recording disk

Claims (10)

A main stabilizing member that rotates a recording disk having flexibility and uses the Bernoulli effect to suppress surface blurring of the recording disk at least in the vicinity of the recording / reproducing position; and a working surface of the main Bernoulli effect of the recording disk; Comprises recording / reproducing means for recording and / or reproducing on the opposite side,
The surface of the recording disk is divided into two areas by a straight line A that is close to the flow line scanned by the recording / reproducing means and passes near the center of the recording disk, and each of the two areas is provided with aerodynamics. A recording / reproducing apparatus in which an auxiliary stabilizing member is disposed so as to generate an acting force so as to generate an acting force opposite to the main stabilizing member on the surface of the recording disk on which the main stabilizing member is located. There,
A tilt adjusting means for tilting the working surface of the aerodynamic force in each auxiliary stabilizing member at the same tilt angle in the disk radial direction;
A recording / reproducing apparatus comprising: position control means for setting the positions of the auxiliary stabilizing members so that the recording disk surface is pushed in with the same pushing amount. A main stabilizing member that rotates a recording disk having flexibility and uses the Bernoulli effect to suppress surface blurring of the recording disk at least in the vicinity of the recording / reproducing position; and a working surface of the main Bernoulli effect of the recording disk; Comprises recording / reproducing means for recording and / or reproducing on the opposite side,
The surface of the recording disk is divided into two areas by a straight line A that is close to the flow line scanned by the recording / reproducing means and passes near the center of the recording disk, and each of the two areas is provided with aerodynamics. A recording / reproducing apparatus in which an auxiliary stabilizing member is disposed so as to generate an acting force so as to generate an acting force opposite to the main stabilizing member on the surface of the recording disk on which the main stabilizing member is located. There,
A tilt adjusting means for tilting the acting surface of the aerodynamic force in each auxiliary stabilizing member at the same tilt angle in the disk circumferential direction;
A recording / reproducing apparatus comprising: position control means for setting the positions of the auxiliary stabilizing members so that the recording disk surface is pushed in with the same pushing amount.   3. The recording / reproducing apparatus according to claim 1, wherein a rotation center when the auxiliary stabilizing member is tilted is set in the vicinity of an action point on an action surface of the auxiliary stabilizing member.   Storage means for storing in advance information on an appropriate inclination angle set in the auxiliary stabilizing member for each disk specification of the recording disk, and the inclination adjustment means can adjust the inclination according to the disk specification. The recording / reproducing apparatus according to claim 1 or 2.   The disc specification range that can be used in the device is limited, and the inclination of the auxiliary stabilizing member is fixed based on the center value of the appropriate inclination angle of the auxiliary stabilizing member set in the disc specification range. The recording / reproducing apparatus according to claim 1 or 2, characterized in that: A main stabilizing member that rotates a recording disk having flexibility and uses the Bernoulli effect to suppress surface blurring of the recording disk at least in the vicinity of the recording / reproducing position; and a working surface of the main Bernoulli effect of the recording disk; Comprises recording / reproducing means for recording and / or reproducing on the opposite side,
The surface of the recording disk is divided into two areas by a straight line A that is close to the flow line scanned by the recording / reproducing means and passes near the center of the recording disk, and each of the two areas is provided with aerodynamics. A recording / reproducing apparatus provided with an auxiliary stabilizing member so as to generate an acting force to generate an acting force opposite to the main stabilizing member on the surface of the recording disk on which the main stabilizing member is located. A stabilization adjustment method used,
Both the aerodynamic force acting surfaces of the auxiliary stabilizing members are inclined at the same tilt angle in the disk radial direction, and both the auxiliary stabilizing members are pushed into the recording disk surface with the same pushing amount. Thus, the method of adjusting the stabilization of the recording / reproducing apparatus, wherein the acting force facing the main stabilizing member is optimized. A main stabilizing member that rotates a recording disk having flexibility and uses the Bernoulli effect to suppress surface blurring of the recording disk at least in the vicinity of the recording / reproducing position; and a working surface of the main Bernoulli effect of the recording disk; Comprises recording / reproducing means for recording and / or reproducing on the opposite side,
The surface of the recording disk is divided into two areas by a straight line A that is close to the flow line scanned by the recording / reproducing means and passes near the center of the recording disk, and each of the two areas is provided with aerodynamics. A recording / reproducing apparatus provided with an auxiliary stabilizing member so as to generate an acting force to generate an acting force opposite to the main stabilizing member on the surface of the recording disk on which the main stabilizing member is located. A stabilization adjustment method used,
Both the aerodynamic force acting surfaces of the auxiliary stabilizing members are inclined at the same tilt angle in the disk circumferential direction, and both the auxiliary stabilizing members are A method for adjusting the stabilization of a recording / reproducing apparatus, wherein the acting force facing the main stabilizing member is optimized by pushing.   The information on an appropriate inclination angle of the auxiliary stabilizing member is stored in advance for each arbitrary disk specification of the recording disk, and the inclination of the auxiliary stabilizing member is adjusted according to the disk specification. 8. A method for adjusting the stabilization of a recording / reproducing apparatus according to 6 or 7.   Limiting the disk specification range used in the apparatus, and setting the inclination of the auxiliary stabilizing member fixed to the center value of the appropriate inclination angle of the auxiliary stabilizing member determined by the disk specification range. 8. A method for stabilizing and adjusting a recording / reproducing apparatus according to claim 6 or 7.   8. The tilt point of the auxiliary stabilizing member is set to set the point of action of the aerodynamic force of the auxiliary stabilizing member at a substantially rotational center of the auxiliary stabilizing member. Method for stabilizing the recording / reproducing apparatus.

Images