JP2009199697A - Optical disk driving device and optical pickup device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the clogging of a filter, with respect to a technology for introducing air into an optical pickup device via the filter to release it from near an objective lens. <P>SOLUTION: In the optical pickup device, a part 63a of a lens holder 63 is allocated to a filter 75 a plurality of times by controlling a focus coil or a tracking coil. Then, an abutting part 63a is pressed to the filter 75 for a predetermined period of time. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an optical disk drive device and an optical pickup device.

  Conventionally, in the field of optical disc drive devices that perform read or write access to optical discs, dust is prevented from adhering to internal optical components by actively introducing a clean air flow into the optical pickup device. A plurality of techniques for improving reliability in long-term use are known.

For example, Patent Documents 1 and 2 describe a technique in which an air flow from a blower is introduced into an optical pickup device through a filter, and the introduced air flow is released upward from the vicinity of an objective lens in the optical pickup device. .
JP-A-5-298734 Japanese Patent Application Laid-Open No. 6-294917

  However, when the methods as described in Patent Documents 1 and 2 are used, the clogging of the filter gradually increases, and eventually the air flow cannot be introduced. In view of the above points, the first object of the present invention is to reduce clogging of a filter in a technique for introducing air into an optical pickup device through a filter to escape from the vicinity of an objective lens.

  In Patent Document 2, an air flow generated by the rotation of the disk is introduced into the optical pickup device. The momentum of such an air flow is used for cleaning the optical pickup device. It may be insufficient. On the other hand, in Patent Document 1, a dedicated fan is provided to generate an air flow to be introduced. However, since a separate power source is required for the fan, the configuration of the optical disc drive apparatus is complicated accordingly. turn into.

  In view of the above points, the present invention is a technique for introducing air into an optical pickup device through a filter and releasing it from the vicinity of the objective lens, while ensuring a sufficient momentum of the air flow to be introduced and simplifying the configuration of the optical disc drive device. This is the second purpose.

  The present invention also provides a technique for efficiently letting air that has flowed into the optical pickup device escape from the vicinity of the objective lens in a technique for introducing air into the optical pickup device through the filter and letting it escape from the vicinity of the objective lens. This is the third purpose.

  In Patent Documents 1 and 2, the optical pickup device moves in the radial direction of the optical disc, but the portion that generates the air flow (that is, the disc and the fan) does not move. Therefore, depending on the arrangement of the optical pickup device, the generated air flow may be attenuated before reaching the optical pickup device.

  In view of the above points, the present invention introduces air into the optical pickup device through a filter and releases it from the vicinity of the objective lens. Even when the optical pickup device is moved, the air flow is not moved. A fourth object is to ensure that the flow reaches the optical pickup device.

  The present invention has been made in view of the above points.

  In order to achieve the first object, an invention according to claim 1 relates to an optical disk drive apparatus for performing read or write access to an optical disk (4). This optical disk drive device includes an optical pickup device (6) that accesses the recording surface of the optical disk (4), and a control device (12) that controls the optical pickup device.

  This optical pickup device (6) has an objective lens (64), and also accommodates the objective lens (64) and has a casing (61, 68,) having an opening (62) at the position of the objective lens (64). 69).

  Further, the optical pickup device (6) has a filter (75) for introducing air from the outside to the inside of the casing (61, 68, 69) and catching dust in the introduced air, and the casing (61, 68, 69) and a lens holder (63) for supporting the objective lens (64).

  Furthermore, the optical pickup device (6) has drive mechanisms (72, 73, 81, 82). The drive mechanism (72, 73, 81, 82) moves the lens holder (63) relative to the casing (61, 68, 69) based on the control of the control device (12), whereby the optical disc (4). By changing the position of the objective lens (64) with respect to the optical disk (4), disk access position adjustment driving (for example, tracking driving or focus driving) of the objective lens (64) with respect to the optical disk (4) is realized.

  The casing (61, 68, 69) has a structure in which the air that has flowed into the casing (61, 68, 69) through the filter (75) is discharged from the opening (62). As described above, the airflow is introduced into the optical pickup device (6) through the filter (75) and the airflow is released from the vicinity of the objective lens (64), so that the optical component inside the optical pickup device (6) is obtained. In addition to preventing dust from adhering to the objective lens (64), by generating an air flow in the vicinity of the objective lens (64) to peel off the deposit on the objective lens (64), there is a possibility that dust will accumulate on the objective lens. Can be reduced.

  Further, the filter (75) is disposed on an extension line in the direction in which the lens holder (63) moves by the disk access position adjustment drive as viewed from the lens holder (63). Then, the control device (12) causes the drive mechanism (72, 73, 81, 82) to perform the tapping drive as a drive other than the disk access position adjustment drive. In the tapping drive, the drive mechanism (72, 73, 81, 82) moves the lens holder (63) in the direction of the disk access position adjustment drive by a distance longer than the distance of the disk access position adjustment drive, Part (63a, 63b) of the lens holder (63) is repeatedly applied to the filter (75).

  As described above, when a part of the lens holder (63) repeatedly hits the filter (75), dust, foreign matters, and the like attached to the filter (75) are removed. As a result, the possibility of clogging the filter (75) is reduced.

  According to a second aspect of the present invention, the control device (12) causes the drive mechanism (72, 73, 81, 82) to execute the pressing drive after the hit driving, and the driving mechanism ( 72, 73, 81, and 82) keep pressing the part of the lens holder (63) (that is, the part that is applied to the filter (75) during driving operation) against the filter (75) for a reference time. May be.

  By doing so, the air flow toward the casing (61, 68, 69) is blocked, and the dust and foreign matters removed by the driving force are pushed by the air flow and adhere to the filter (75) again. Can be avoided.

  Further, in this case, as described in claim 3, the optical disc drive device includes a blower (9) that generates an air flow, a duct (10) for passing an air flow generated by the blower (9), An air flow intake section (11) that forms a passage for flowing an air flow through the duct (10) to the filter (75) of the optical pickup device (6).

  In this case, the bottom surface of the air flow intake part (11) may have a slope shape that descends from the filter (75) toward the duct (10). In this way, the shape of the air flow intake portion (11) is such that it does not become a sand tray, so that the dust and foreign matter that have been wiped off by the striking drive can be found along the slope. Since it falls outside (11), the effect that the dust struck down does not adhere to the filter (75) increases.

  Further, in this case, as described in claim 4, the duct (10) has a groove shape opened upward, and a portion of the air flow intake portion (11) connected to the duct (10) is: It fits in the groove | channel of a duct (10), and the clearance gap may be provided between the bottom face of a duct (10), and the slope-shaped lower end part of an airflow intake part (11).

  In this way, the air flow from the air flow intake portion (11) into the casing (61, 68, 69) is blocked, and the air flow is connected to the air flow intake portion (11) and the duct (10 ) Escapes from the gap, and dust that has been knocked down and falls down the slope also escapes from the gap. Therefore, the effect that the dust struck down from the filter (75) does not adhere to the filter (75) again increases.

  Alternatively, as described in claim 5, in the optical disc drive device, a portion of the air flow intake portion (11) in the vicinity of the filter (75) may be opened downward. . In this way, the shape of the air flow intake part (11) is such that it does not become a sand tray, so that dust and foreign matters that have been wiped off by the tapping drive can be taken in through the opening. Since it falls under the part (11), the effect that the struck dust does not adhere to the filter (75) increases.

  The invention according to claim 6 for achieving the second object also relates to an optical disk drive apparatus for performing read or write access to the optical disk (4). This optical disk drive device includes a turntable (2) that rotates with an optical disk (4), a motor (3) that rotates the turntable (2), and an optical pickup device that accesses the recording surface of the optical disk (4). 6), a blower (9) that generates an air flow, and a passage forming member (10, 11) that forms a passage for sending the air flow generated by the blower (9) to the optical pickup device (6), It is equipped with.

  Further, the optical pickup device (6) has an objective lens (64), and also accommodates the objective lens (64) and has a casing (61, 61) having an opening (62) at the position of the objective lens (64). 68, 69), and further introduces air sent from the passage forming members (10, 11) into the casing (61, 68, 69), and filters the dust (75) in the introduced air. )have. The casing (61, 68, 69) has a structure in which the air that has flowed into the casing (61, 68, 69) through the filter (75) is discharged from the opening (62).

  The blower (9) includes a fin (92) that is rotated by the motor (3), and an air flow is generated by the rotation of the fin (92). In this way, the momentum of the air flow to be introduced can be sufficiently ensured by generating the air flow by the rotational force of the fin (92), which is a member dedicated to blowing. Moreover, since the fin (92) is rotated by using the motor (3) for rotating the turntable (2) as a power source, a motor dedicated to the fin (92) is not required, and the configuration of the optical disc drive apparatus is simplified correspondingly. Can be.

  The turntable (2) is rotated when dust is likely to accumulate in the optical pickup device (6). According to the above configuration, a clean air flow flows into the optical pickup device (6) while the turntable (2) is rotating, and the inflow of air is stopped while the turntable (2) is stopped. Therefore, an efficient operation of blowing air only when dust prevention is necessary is realized, and there is no need to separately provide an operation mode for cleaning the inside of the optical pickup device 6.

  In order to achieve the third object, an invention according to claim 7 relates to an optical pickup device. The optical pickup device includes an objective lens (64), a casing (61, 68, 69) that houses the objective lens (64) and has an opening (62) at the position of the objective lens (64), and a casing ( 61, 68, 69) air is introduced into the interior from the outside, the filter (75) that captures dust in the air to be introduced, the casing (61, 68, 69), and the objective lens (64). And a lens holder (63) for supporting air), and the air introduced into the casing (61, 68, 69) through the filter (75) is discharged from the opening (62). It is like that. In the casing (61, 68, 69) of the optical pickup device, only the opening (62) and the filter (75) communicate with the outside of the casing (61, 68, 69).

  Thus, since the casing (61, 68, 69) has a sealed structure except for the opening (62) and the filter (75), when air flows from the filter (75), the casing (61, 68). 69), the air pressure increases, and air flows out only from the opening (62). Therefore, the air that has flowed into the optical pickup device can be efficiently released from the vicinity of the objective lens (64), so that dust does not easily accumulate in the objective lens (64).

  In order to achieve the fourth object, an invention according to claim 8 relates to an optical disk drive apparatus for performing read or write access to the optical disk (4). This optical disk drive device includes an optical pickup device (6) that accesses the recording surface of the optical disk (4), moving means (7, 8) that moves the optical pickup device (6) in the radial direction of the optical disk (4), A blower (9) for generating an air flow, a duct (10) for passing the air flow generated by the blower (9), and a filter ( 75), and an air flow intake part (11) that forms a passage for flowing to (75).

  The duct (10) extends along the moving direction of the optical pickup device (6) and has a groove shape. Moreover, an air flow intake part (11) moves with an optical pick-up apparatus (6), and the part connected to a duct (10) among air flow intake parts (11) is in the groove | channel of a duct (10). It moves in the groove of the duct (10) with the movement of the optical pickup device (6).

  Thus, the duct (10) and the air flow intake section (11) are interposed between the air blower (9) and the optical pickup device (6), so that the air flow is reliably transmitted to the optical pickup device (6). To reach. And even if an optical pick-up apparatus (6) moves, since an air flow intake part (11) moves along the groove | channel of a duct (10), an air flow intake part (11), a duct (10), Are maintained, and the effect that the airflow reaches the optical pickup device (6) is also maintained.

  Further, as described in claim 9, the invention described in claim 1 can also be grasped as an optical pickup device. In this case, the optical pickup device includes an objective lens (64), a casing (61, 68, 69) that houses the objective lens (64) and has an opening (62) at the position of the objective lens (64), and a casing. (61, 68, 69) introduces air from the outside to the inside, and filters (75) for catching dust in the introduced air; and the objective lens while being accommodated in the casing (61, 68, 69). The position of the objective lens (64) relative to the optical disk (4) is changed by moving the lens holder (63) supporting the (64) and the lens holder (63) relative to the casing (61, 68, 69). The drive mechanism (72, 73, 72) for realizing the disk access position adjustment drive of the objective lens (64) with respect to the optical disk (4) by the position change. And 1,82), provided with, also, to discharge the air introduced into the filter (75) through said casing (61,68,69) through the opening (62).

  The filter (75) is arranged on an extension line in the direction in which the lens holder (63) moves by the disk access position adjustment drive as viewed from the lens holder (63). The drive mechanism (72, 73, 81, 82) is a lens holder (drive other than the disk access position adjustment drive) in a direction longer than the disk access position adjustment drive in the direction of the disk access position adjustment drive. 63) is moved to perform a tapping drive in which a part (63a, 63b) of the lens holder (63) is repeatedly applied to the filter (75). Also with such a configuration, the first object can be achieved.

  In addition, the code | symbol in the bracket | parenthesis in the said and the claim shows the correspondence of the term described in the claim, and the concrete thing etc. which illustrate the said term described in embodiment mentioned later. .

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described. FIG. 1 schematically shows a partial cross-sectional view of the internal configuration of an optical disc drive apparatus 100 according to the present embodiment. The optical disc drive device 100 is a device for performing only one or both of reading data recorded in the inserted optical disc 4 and writing data into the optical disc 4.

  The optical disk drive device 100 includes a drive housing (not shown), and inside the casing, as shown in FIG. 1, a chassis 1, a turntable 2, a spindle motor 3, a clamper 5, an optical pickup device 6, a motor 7, and a lead. It has a screw 8, a blower 9, a duct 10, an air flow intake fin 11, a control device 12, and the like.

  The chassis 1 is a member for holding each component in the drive housing. An optical disk 4 inserted into the drive housing is placed on the turntable 2, and when the turntable 2 spins about the axis 20 indicated by a one-dot chain line, the optical disk 4 also has the axis 20. Rotate around.

  The spindle motor 3 is an electric motor for rotating the turntable 2 and the clamper 5. The clamper 5 is a member for pressing the optical disc 4 against the turntable 2 when the optical disc 4 is inserted.

  The optical pickup device 6 is an optical device for accessing the recording surface of the inserted optical disk 4 (that is, either or both of data reading and data writing).

  The motor 7 is disposed further outside the outer edge of the inserted optical disk 4 and rotates a lead screw 8 extending from the motor 7 in the radial direction of the optical disk 4 as necessary. The lead screw 8 supports the optical pickup device 6. When the lead screw 8 is rotated by the motor 7, the lead screw 8 transports the optical pickup device 6 in the radial direction of the optical disk 4.

  The blower 9 is a device that is provided below the spindle motor 3, is driven by the spindle motor 3, generates an air flow, and sends the generated air flow to the duct 10 as indicated by an arrow 21. In the present embodiment, the direction from the turntable 2 to the optical disk 4 is upward, and the direction from the turntable 2 to the spindle motor 3 is downward.

  The duct 10 is fixed directly or indirectly to the chassis 1 and extends from the blower 9 to the position of the motor 7 in parallel with the lead screw 8 (that is, along the moving direction of the optical pickup device 6). In addition, it passes directly under the optical pickup device 6. The duct 10 has a groove shape with a U-shaped cross section. As will be described in detail later, the duct 10 has a structure that allows an air flow from the blower 9 to pass therethrough.

  The air flow intake fin 11 is fixed to the bottom of the optical pickup device 6, moves with the optical pickup device 6, and further connects and communicates with the duct 10. Therefore, a part of the air flow passing through the duct 10 flows from the duct 10 to the air flow intake fin 11 as shown by the arrow 22 regardless of the position of the optical pickup device 6, and the bottom of the optical pickup device 6. The optical pickup device 6 enters the optical pickup device 6.

  The control device 12 is an electronic circuit such as a microcomputer that controls various operations described later of the blower device 9, the motor 7, and the optical pickup device 6 by executing a program recorded in advance in a ROM or the like.

  Next, the internal configuration of the optical pickup device 6 will be described. FIG. 2 is a plan view of the optical pickup device 6 as viewed from the upper side (that is, the side facing the optical disc 4). As shown in this figure, the optical pickup device 6 includes a pickup housing 61 for accommodating other components of the optical pickup device 6 therein. The pickup housing 61 has a rectangular opening 62 on its upper surface, an objective lens 64 is disposed in the opening 62, and a lens holder 63 that supports the objective lens 64 immediately below the opening 62. A part of is arranged. With such a configuration, the pickup housing 61 can optically access the optical disc 4 through the objective lens 64.

  FIG. 3 shows a plan view of the optical pickup device 6 when the upper surface and side surfaces of the pickup housing 61 are removed. 4 and 5 are cross-sectional views of the pickup housing 61 taken along lines AA and BB in FIG. 3, respectively. 3 corresponds to the moving direction of the optical pickup device 6 by the lead screw 8.

  As shown in this figure, the optical pickup device 6 further includes an LD / PD module 65, a wave plate 66, a collimating lens 67, an ACT base 68, a suspension holder 69, suspension wires 70 and 71, and a focus coil 72 inside a pickup housing 61. Tracking coils 73 and 74, a filter 75, magnets 81 and 82, and the like.

  The LD / PD module 65 emits laser light used for accessing the optical disc 4 in the direction of the wave plate 66 based on the control signal from the control device 12, and the laser light received from the wave plate 66 is an electric signal. And output to the control device 12 or the like.

  Laser light emitted from the LD / PD module 65 reaches the objective lens 64 via known optical components such as the wave plate 66, the collimator lens 67, and the rising mirror 74, and travels from the objective lens 64 toward the optical disk 4. Emitted.

  The laser beam reflected from the surface of the optical disk 4 (that is, the recording surface on which data is recorded) is emitted as an objective lens 64, a rising mirror 74, a collimating lens 67, a wave plate 66, and an LD / PD module 65. The LD / PD module 65 is reached again through a route opposite to the time, and is converted into an electric signal there.

  The ACT base 68 is made of a metal plate that is tightly fixed to the pickup housing 61, and magnets 81 and 82 are fixed to the upper surface thereof. In addition, a suspension holder 69 is fixed in close contact with the pickup housing 61. A casing in which a part of the ACT base 68, the suspension holder 69, and the pickup housing 61 are combined has a sealed structure except for the opening 62 and the filter 75. That is, the inside of the casing including a part of the ACT base 68, the pickup housing 61 and the suspension holder 69 is communicated with the outside only by the opening 62 and the filter 75. The suspension holder 69 constitutes a part of the side wall of the casing, and a part of the ACT base 68 constitutes a part of the upper surface of the casing.

  In addition, one end of each of the metal suspension wires 70 and 71 is fixed to the suspension holder 69. The suspension wires 70 and 71 extend horizontally and perpendicular to the suspension holder 69 and parallel to each other. A lens holder 63 is attached to the other end of each of the suspension wires 70 and 71. The lens holder 63 is supported by the suspension holder 69 through the suspension wires 70 and 71 while being movable with respect to the suspension holder 69.

  The lens holder 63 is made of a resin member having two holes, and an objective lens 64 is embedded in the first hole far from the suspension holder 69 out of the two holes. The second hole closer to the suspension holder 69 is provided at a position where the magnets 81 and 82 can penetrate. A focus coil 72 and a tracking coil 73 are attached to the second hole.

  In addition, a portion of the lens holder 63 closer to the suspension holder 69 than the second hole (hereinafter referred to as a contact portion) 63a is lower (that is, the figure) than the portion around the first hole. 3 in the back direction of the paper surface of FIG. 4 and in the downward direction of the paper surface of FIG. 5 and has a flat bottom surface.

  In addition, a portion of the bottom portion of the pickup housing 61 corresponding to the portion immediately below the contact portion 63a is opened, and a filter 75 is embedded in the opening portion. The filter 75 has a structure that allows air to pass through. However, when the air passes, the filter 75 captures dust in the air.

  In the ACT base 68, a hole is formed in a portion immediately below the objective lens 64, and a rising mirror 74 is provided in the hole. Thereby, the optical path of a laser beam is ensured. Further, the ACT base 68 has a shape in which a portion directly below the contact portion 63a is missing. In this way, the bottom surface of the contact portion 63a faces the filter 75 without any obstacle. As will be described later, when the contact portion 63a moves downward, the bottom surface of the contact portion 63a can contact the filter 75.

  Next, the structure of the air blower 9 and the duct 10 is demonstrated. In FIG. 6, the top view of the air blower 9 and the duct 10 is shown. The blower device 9 is fixed to a rotating portion 90 that rotates in synchronization with the rotation of the spindle motor 3, an outer shell portion 91 that surrounds the rotating portion 90 apart from the rotating portion 90, and a plurality of positions on the outer periphery of the rotating portion 90. The plurality of fins 92 are provided. The outer shell portion 91 has two cuts, one of the cuts communicates with the outside, and the other is connected to the duct 10.

  The duct 10 extends from the blower 9 to the position of the motor 7 in parallel with the lead screw 8 (that is, along the moving direction of the optical pickup device 6), and passes directly under the optical pickup device 6. It has become. As will be described in detail later, the duct 10 has a structure that allows an air flow from the blower 9 to pass therethrough.

  When the rotating unit 90 rotates using the spindle motor 3 as a power source, the fin 92 rotates (specifically, circulates) in the gap between the rotating unit 90 and the outer shell 91, so that the outer shell 91 breaks off. An air flow 94 is introduced from a certain inlet, and is further sent to the duct 10 as an air flow 96. Then, the air flow proceeds along a groove having a U-shaped cross section opened on the duct 10.

  Next, the air flow intake fin 11 will be described. FIG. 7 is a cross-sectional view for schematically showing the attachment structure of the airflow intake fin 11 to the pickup housing 61 (the cross section is the same as the CC cross section of FIG. 3). However, in FIG. 7, only the pickup housing 61, the contact portion 63a of the lens holder 63, the objective lens 64, and the filter 75 are shown in the optical pickup device 6, and the display of other components is omitted. ing.

  FIG. 8 is a diagram schematically showing a connection structure between the duct 10 and the air flow intake fins 11, and only the optical pickup device 6, the duct 10, and the air flow intake fins 11 are connected to the air blower 9 side. It is the figure seen from.

  As shown in FIGS. 7 and 8, the airflow intake fin 11 has a shape obtained by cutting a hollow cylinder into a 90 ° fan shape, and one end thereof is fixed around the filter 75. Therefore, the inside of the optical pickup device 6 and the inside of the airflow intake fin 11 communicate with each other through the filter 75.

  Further, as shown in FIGS. 8 and 1, the air flow intake fin 11 is loosely fitted in a U-shaped groove of the duct 10. In this way, even if the optical pickup device 6 moves in the radial direction of the optical disk 4 by the rotation of the lead screw 8, the loose fitting of the air flow intake fin 11 to the duct 10 is maintained, The air flow intake fin 11 moves together with the optical pickup device 6. That is, when the pickup housing 61 moves in the seek operation along the lead screw 9, the airflow can be taken in from the duct 10 by the airflow intake fin 11 at any position without hindering the movement. It has become.

  Further, the bottom portion of the air flow intake fin 11 (that is, the portion corresponding to the outer peripheral portion of the above-described cylinder) has a slope shape that descends from the filter 75 toward the duct 10. Furthermore, as shown in FIG. 8, a gap is provided between the bottom surface of the duct 10 and the slope-shaped lower end portion of the air flow intake fin 11.

  Next, the operation of the optical disc drive apparatus 100 configured as described above will be described. As described above, during the normal operation of the optical disc drive apparatus 100, the control device 12 controls the LD / PD module 65 so that the LD / PD module 65 has the wave plate 66, collimating lenses 67 and 84, and the objective lens 64. The optical disk 4 is accessed by exchanging the laser light with the optical disk 4 via.

  However, since the position of the pits on the surface of the optical disk 4 is always shaken by the rotation of the optical disk 4, the control device 12 applies servo control to move the objective lens 64 up, down, left, and right in order to follow the laser beam.

  Specifically, the control device 12 passes a current from the suspension holder 69 via the suspension wires 70 and 71 to the focus coil 72 or the tracking coil 73 and further adjusts the amount of the current. Due to the interaction between the current flowing through the coils 72 and 73 and the magnetic field of the magnets 81 and 82, a driving force is applied to the lens holder 63 that holds the objective lens 64, thereby realizing servo control.

  More specifically, the control device 12 realizes tracking driving and focus driving by servo control. In the tracking control, the control device 12 adjusts the position of the lens holder 63 in the radial direction of the optical disc 4 (that is, the left and right direction in FIG. 2) by adjusting the current flowing through the tracking coil 73. In the focus control, the control device 12 adjusts the current flowing through the focus coil 72 to adjust the position of the lens holder 63 in the vertical direction (that is, the vertical direction in FIG. 5). Hereinafter, this tracking drive and focus drive are collectively referred to as disk access position adjustment drive.

  Further, during the normal operation of the optical disc drive apparatus 100 (and during the cleaning mode driving described later), the control device 12 rotates the spindle motor 3 in order to rotate the turntable 2. Accordingly, the air blower 9 also generates an air flow accordingly, and the generated air flow flows into the duct 10, and a part of the air flow taking-in fin 11 takes the optical pickup as shown by an arrow 25 in FIG. 7. Device 6 is reached.

  Then, the air flow reaching the optical pickup device 6 flows into the pickup housing 61 through the filter 75. During this inflow, dust in the airflow is captured by the filter 75. Therefore, the air flow in the pickup housing 61 is kept clean.

  Since the casing of the optical pickup device 6 has no part communicating with the outside other than the opening 62 and the filter 75, the air that has flowed into the casing flows only from the opening 62 as shown by the arrow 26 in FIG. leak. Therefore, even if dust enters the casing for some reason, it is discharged to the outside through the opening 62 together with the air flow.

  In this way, the air pressure inside the optical pickup housing 61 that has risen due to the air flow that has been sent is allowed to escape above the opening 62 in the vicinity of the objective lens 64, thereby generating an upward air current in the vicinity of the objective lens 64. It is possible to prevent dust from accumulating on 64. By such an operation, it is possible to prevent deterioration of the read / write performance of the optical disc drive apparatus 100.

  However, if a sufficient amount of airflow cannot be sent into the pickup housing 61 due to clogging of the filter 75 due to long-term use, the airflow from the opening 62 is insufficiently discharged, and the optical pickup There is a possibility that dust will accumulate on the optical components inside the apparatus 6 and the objective lens 64.

  For this reason, the control apparatus 12 implement | achieves the cleaning mode drive for removing the dust collected on the filter 75 at a specific timing. The specific timing may be a timing at which the operation time of the optical disc drive device 100 after the last implementation of the cleaning mode drive (or after shipment) exceeds a predetermined time. For this purpose, the control device 12 may record the operation time of the optical disc drive device 100 after the cleaning mode drive is finally realized.

  FIG. 9 shows a flowchart of processing executed by the control device 12 by the cleaning mode drive. When the cleaning mode is entered, first, the tapping drive is executed at step 110, and then the pushing drive is executed at step 120.

  In the tapping drive, the control device 12 moves the lens holder 63 further below the movable range of the lens holder 63 in the case of the focus drive by adjusting the current flowing to the focus coil 72, and the contact portion 63a. The bottom is applied to the filter 75. Thereafter, the current flowing to the focus coil 72 is adjusted, and the lens holder 63 is returned to a position where the contact portion 63 a is sufficiently separated from the filter 75. Such control that the contact portion 63a is separated from the filter 75 is repeated a reference number of times. As a result, the filter 75 is vibrated, and dust or the like adhering to and accumulating on the surface of the filter 75 is struck down.

  The reference number may be a predetermined value (for example, 10 times) stored in advance, a value that varies based on various conditions, or a value that is randomly determined within a certain range. May be. For example, when the optical disk drive device 100 includes a detection device that detects the air volume per unit time discharged from the opening 62, the reference number increases as the air volume per unit time decreases. May be.

  Further, in the pressing drive, the control device 12 adjusts the current that flows to the focus coil 72, thereby pressing the bottom of the contact portion 63a against the filter 75 for a reference time and keeping it in close contact. This reference time is a time longer than the time during which the bottom of the contact portion 63a is in contact with the filter 75 in the tapping drive.

  By doing in this way, the airflow which goes into the pick-up housing | casing 61 from the airflow intake fin 11 is interrupted | blocked. Then, as shown in FIG. 10, the dust removed from the filter 75 descends along the slope at the bottom of the air flow intake fin 11 and escapes from the gap between the air flow intake fin 11 and the duct 10 together with the air flow. To go. Therefore, the struck dust does not adhere to the filter 75 again.

  The reference time may be a constant value (for example, 10 seconds) stored in advance, a value that varies based on various conditions, or a value that is randomly determined within a certain range. May be. For example, when the reference number is variable in the tapping drive, the reference time may be lengthened as the reference number increases.

  As described above, in the optical disk drive device 100 of the present embodiment, the casing of the optical pickup device 6 has a structure in which air that has flowed into the casing through the filter 75 is discharged from the opening 62. As described above, the air flow is introduced into the optical pickup device 6 through the filter 75 to release the air flow from the vicinity of the objective lens 64, thereby preventing the dust from adhering to the optical components inside the optical pickup device 6. At the same time, by generating an air flow that peels off the deposit on the objective lens 64 in the vicinity of the objective lens 64, the possibility of dust collecting on the objective lens can be reduced.

  Further, the filter 75 is disposed on an extension line in the direction in which the lens holder 63 moves by focus driving, as viewed from the contact portion 63a of the lens holder 63. The control device 12 controls the focus coil 72 as a drive other than the disk access position adjustment drive, thereby realizing the tapping drive.

  As described above, when part of the lens holder 63 repeatedly hits the filter 75, dust, foreign matter, and the like attached to the filter 75 are removed. As a result, the possibility of clogging the filter 75 is reduced. In addition, the tapping drive can be realized only by changing the current value using the same mechanism as the focus drive, so that it is not necessary to provide a dedicated configuration for cleaning the filter 75.

  Further, the control device 12 executes the pressing drive after the hit driving, and keeps pressing the contact portion 63a against the filter 75 for the reference time in the pressing drive. By doing in this way, the airflow which goes into a casing is interrupted | blocked and it can avoid that the dust and the foreign material which were wiped off by the tapping drive are pushed by the airflow, and adhere to the filter 75 again.

  Further, the bottom surface of the air flow intake fin 11 has a slope shape that descends from the filter 75 toward the duct 10. Thus, since the shape of the air flow intake fin 11 is such that it does not become a sand tray, the dust and foreign matters that have been wiped off by the tapping drive of the air flow intake fin 11 along the slope. Since it falls outside, the effect that the dust struck down does not adhere to the filter 75 again increases.

  Further, the duct 10 has a groove shape opened upward (that is, in the direction of the optical pickup device 6), and a portion of the air flow intake fin 11 that is connected to the duct 10 is free to play in the groove of the duct 10. A gap is provided between the bottom surface of the duct 10 and the slope-shaped lower end portion of the airflow intake fin 11.

  As a result, the airflow from the airflow intake fin 11 into the casing is blocked, and the airflow is struck down by escaping from the gap between the airflow intake fin 11 and the duct 10. Dust that falls down from the slope also escapes from the gap. Therefore, the effect that the sand dust struck from the filter 75 does not adhere to the filter 75 is further increased.

  Further, the air blower 9 generates an air flow by the fins 92 rotated by the spindle motor 3. As described above, the air flow is generated by the rotational force of the fin 92, which is a member dedicated to air blowing, so that the momentum of the introduced air flow can be sufficiently secured. In addition, since the fins 92 are rotated by using the spindle motor 3 for rotating the turntable 2 as a power source, a motor dedicated to the fins 92 is not required, and the configuration of the optical disc drive apparatus can be simplified correspondingly.

  The turntable 2 is rotated when dust is likely to accumulate in the optical pickup device 6. According to the above configuration, a clean air flow flows into the optical pickup device 6 while the turntable 2 is rotating, and the inflow of air stops while the turntable 2 is stopped. Therefore, an efficient operation of blowing air only when dust prevention is necessary is realized, and there is no need to separately provide an operation mode for cleaning the inside of the optical pickup device 6.

  In addition, the casing of the pickup housing 61 allows the outside and the inside of the casing to communicate with each other only in the opening 62 and the filter 75.

  Thus, since the casing has a sealed structure except for the opening 62 and the filter 75, when air flows in from the filter 75, the atmospheric pressure increases in the casing, and the air flows out only from the opening 62. Therefore, the air that has flowed into the optical pickup device can be efficiently escaped from the vicinity of the objective lens 64, thereby making it difficult for dust to collect on the objective lens 64.

  The duct 10 extends along the moving direction of the optical pickup device 6 and has a groove shape. The air flow intake fin 11 moves together with the optical pickup device 6, and the portion of the air flow intake fin 11 that is connected to the duct 10 is fitted in the groove of the duct 10. As the device 6 moves, it moves in the groove of the duct 10.

As described above, the duct 10 and the airflow intake fin 11 are interposed between the blower 9 and the optical pickup device 6, so that the airflow reliably reaches the optical pickup device 6. Even if the optical pickup device 6 moves, the air flow intake fin 11 moves along the groove of the duct 10, so that the connection and communication between the air flow intake fin 11 and the duct 10 are maintained, and the air flow The effect of reaching the optical pickup device 6 is also maintained.
(Second Embodiment)
Next, a second embodiment of the present invention will be described. The present embodiment is different from the first embodiment in that the optical pickup device 6, the duct 10, the arrangement relationship of the air flow intake fins 11, the configuration of the optical pickup device 6, and the optical pickup device 6 and control during the cleaning mode drive. The operation of the device 12. Hereinafter, the difference from the first embodiment will be mainly described.

  Except for the optical pickup device 6, the duct 10, and the air flow intake fin 11, the components shown in FIGS. 11 to 15 are denoted by the same reference numerals as those in FIGS. 1 to 10 of the first embodiment. Have the same functions, and description thereof will be omitted.

  FIG. 11 is a plan view of a portion around the optical pickup device 6 in the optical disc drive device 100 ′ according to the present embodiment.

  As shown in this figure, in the optical pickup device 6 of this embodiment, the position of the filter 75 is not the bottom of the optical pickup device 6 but the side of the optical pickup device 6 in the transport direction.

  Moreover, as shown in FIG. 11, the duct 10 is the same as that of the first embodiment in that the duct 10 extends in parallel with the conveying direction of the optical pickup device 6 from the blower 9 (not shown), as in the first embodiment. It is. However, the duct 10 of this embodiment does not pass through the lower part of the optical pickup device 6 as in the first embodiment, but passes through the side of the optical pickup device 6.

  Further, the duct 10 of the present embodiment has a U-shaped groove shape as in the first embodiment, but does not open upward, but in the direction of the optical pickup device 6, that is, in the lateral direction. It is open.

  Further, as shown in FIG. 11, the air flow intake fin 11 of the present embodiment is the same as that of the first embodiment in that it is connected and communicated with the duct 10 at one end and communicated with the filter 75 at the other end. is there. However, the shape is different from that of the first embodiment. Specifically, the air flow intake fin 11 of the present embodiment has a structure in which a middle portion is horizontal and extends vertically to the moving direction of the optical pickup device 6 and forms a path whose both ends are bent by 90 ° in the same direction. have.

  FIG. 12 shows the internal configuration of the optical pickup device 6 of this embodiment in the same format as FIG. In the optical pickup device 6, only the configuration of the lens holder 63 and the position of the filter 75 are different from those of the optical pickup device 6 of the first embodiment.

  As shown in FIG. 12, the filter 75 is provided on the side surface of the optical pickup device 6. More specifically, a filter 75 is provided on a side surface in a direction perpendicular to the direction of the optical disk 4 and perpendicular to the direction of the LD / PD module 65 when viewed from the hole portion for the objective lens 64 of the lens holder 63.

  Further, in the lens holder 63 of the present embodiment, the hole portion for the objective lens 64 of the lens holder 63 protrudes in the direction of the filter 75. This protruding portion (hereinafter referred to as a contact portion) 63b is a portion for contacting the filter 75, and the end surface of the contact portion 63b on the filter 75 side is a flat surface.

  Further, in the lens holder 63, the holes provided with the focus coil 72 and the tracking coil 73 are wider in the left-right direction (that is, the direction from the contact portion 63b to the filter 75 and the opposite direction) than in the first embodiment. It has become. As a result, the movable range of the lens holder 63 in the left-right direction increases.

  Next, FIG. 13 schematically shows the lens holder 63 and the airflow intake fin 14 as seen in the DD section of FIG. FIG. 14 shows only the optical pickup device 6, the duct 10, and the airflow intake fin 11 as viewed from the air blower 9 side.

  As shown in FIG. 13, the vicinity of the filter 75 of the airflow intake fin 11 has an L-shaped cross-sectional shape with an open bottom. And as shown in FIG. 14, the part connected to the duct 10 of the airflow intake fin 11 has a U-shaped cross-sectional shape, and is loosely fitted in the groove of the duct 10. Further, as shown in FIG. 14, there is a gap between the portion of the air flow intake fin 11 that is farthest from the optical pickup device 6 and the portion of the duct 10 that is farthest from the optical pickup device 6. Accordingly, a part of the air flow sent from the blower 9 to the duct 10 flows into the air flow intake fin 11, enters the pickup housing 61 from the air flow intake fin 11 through the filter 75, and the light It is discharged outside only through the opening 62 of the pickup device 6. Therefore, it is possible to prevent dust from being accumulated in the pickup housing 61 and the objective lens 64.

  Next, the operation of the optical pickup device 6 and the control device 12 in this embodiment will be described. The contents of drive for data access to the optical disk 4 by the optical pickup device 6 and the control device 12, tracking drive, and focus drive are the same as in the first embodiment.

  Also, the execution timing of the cleaning mode drive and the processing according to the flowchart of FIG. 9 are the same as in the first embodiment. However, in the tapping drive and the pushing drive, the control device 12 moves the lens holder 63 by adjusting the current that flows to the tracking coil 73 instead of the focus coil 72.

  Specifically, in the tapping drive, the control device 12 adjusts the current flowing through the tracking coil 73 so that the lens holder 63 is closer to the filter 75 than the movable range of the lens holder 63 in the case of tracking drive. Is moved so that the end of the abutting portion 63 b is brought into contact with the filter 75. Thereafter, the current passed through the tracking coil 73 is adjusted, and the lens holder 63 is returned to a position where the contact portion 63 b is sufficiently separated from the filter 75. Such control that the contact portion 63a is separated from the filter 75 is repeated a reference number of times. As a result, the filter 75 is vibrated, and dust or the like adhering to and accumulating on the surface of the filter 75 is struck down.

  As described above, when part of the lens holder 63 repeatedly hits the filter 75, dust, foreign matter, and the like attached to the filter 75 are removed. As a result, the possibility of clogging the filter 75 is reduced. In addition, the tapping drive can be realized simply by changing the current value using the same mechanism as the tracking drive, so that it is not necessary to provide a dedicated configuration for cleaning the filter 75.

  Further, in the pressing drive following the hit driving, the control device 12 adjusts the current flowing through the tracking coil 73, thereby pressing the end of the contact portion 63b against the filter 75 for a reference time and keeping it in close contact. This reference time is longer than the time during which the end portion of the contact portion 63b is in contact with the filter 75 in the tapping drive.

  By doing in this way, the airflow which goes into the pick-up housing | casing 61 from the airflow intake fin 11 is interrupted | blocked. Then, as shown in FIG. 10, the dust removed from the filter 75 falls from the opening of the air flow intake fin 11. Therefore, the struck dust does not adhere to the filter 75 again.

  In this way, the shape of the air flow intake fin 11 is such that it does not become a sand tray, so that dust and foreign matters that have been wiped off by the tapping drive pass through the opening and the air flow intake fin 11. Therefore, the effect that the dust struck down does not adhere to the filter 75 again increases.

(Other embodiments)
As mentioned above, although embodiment of this invention was described, the scope of the present invention is not limited only to the said embodiment, The various form which can implement | achieve the function of each invention specific matter of this invention is included. It is.

  For example, in each of the above embodiments, rubber fins, cellophane rail cloth fins, or the like are attached to the openings of the duct 10, so that the openings are blocked at portions of the duct 10 where the airflow intake fins 11 are not provided. It may come off. If it becomes like this, the air quantity which leaks from the duct 10 will reduce, and the airflow from the air blower 9 will come to the optical pick-up apparatus 6 more reliably.

  In the second embodiment, the airflow intake fin 11 may have an L-shaped cross-sectional shape with an open bottom from an end on the filter 75 side to an end on the duct 10 side. Even in this case, the amount of airflow entering the pickup housing 61 may be reduced, but the sand dust that has been removed from the filter 75 during the cleaning mode does not fall down and reattach to the filter 75. The effect is maintained.

  In the above embodiment, each function realized by the control device 12 executing a program is realized using hardware having those functions (for example, an FPGA capable of programming a circuit configuration). You may come to do.

1 is a partial cross-sectional view of an internal configuration of an optical disc drive apparatus 100 according to a first embodiment of the present invention. 3 is a plan view of the optical pickup device 6. FIG. It is a top view of the optical pick-up apparatus 6 at the time of removing the upper surface and side surface of the pick-up housing | casing 61. FIG. It is sectional drawing which cut | disconnected the pick-up housing | casing 61 by the AA line of FIG. It is sectional drawing which cut | disconnected the pick-up housing | casing 61 by the BB line of FIG. It is a top view of the air blower 9 and the duct 10. FIG. It is sectional drawing which shows typically the attachment structure to the pick-up housing | casing 61 of the airflow intake fin 11. FIG. It is a schematic diagram which shows the connection structure of the duct 10 and the airflow intake fin 11. FIG. It is a flowchart which shows the process sequence of cleaning mode. It is a schematic diagram showing a state where the lens holder 63 is pressed against the filter 75 in the cleaning mode. It is a partial top view of an internal structure of optical disk drive device 100 'concerning 2nd Embodiment of this invention. It is a schematic diagram which shows the attachment structure to the pick-up housing | casing 61 of the airflow intake fin 14. FIG. It is a schematic diagram which shows the connection structure of the duct 13 and the airflow intake fin 14. FIG. It is a top view of the optical pick-up apparatus 6 at the time of removing the upper surface and side surface of the pick-up housing | casing 61. FIG. It is a schematic diagram showing a state where the lens holder 63 is pressed against the filter 75 in the cleaning mode.

Explanation of symbols

2 Turntable 3 Spindle motor 4 Optical disk 6 Optical pickup device 9 Blower device 10 Duct 11 Air flow intake fin 61 Pickup housing 62 Opening portion 63 Lens holder 63a, 63b Abutting portion 64 Objective lens 72 Focus coil 73 Tracking coil 75 Filter 92 Fin 100, 100 'Optical Disk Drive Device

Claims (9)

An optical disk drive device that performs read or write access to an optical disk (4),
An optical pickup device (6) for accessing the recording surface of the optical disc (4);
A control device (12) for controlling the optical pickup device,
The optical pickup device (6)
An objective lens (64);
A casing (61, 68, 69) that houses the objective lens (64) and has an opening (62) at the position of the objective lens (64);
A filter (75) for introducing air from the outside to the inside of the casing (61, 68, 69) and capturing dust in the introduced air;
A lens holder (63) housed in the casing (61, 68, 69) and supporting the objective lens (64);
Based on the control of the control device (12), the lens holder (63) is moved with respect to the casing (61, 68, 69), so that the position of the objective lens (64) with respect to the optical disc (4) is changed. And a drive mechanism (72, 73, 81, 82) for realizing a disk access position adjustment drive of the objective lens (64) with respect to the optical disk (4) by changing the position,
The casing (61, 68, 69) has a structure for discharging air flowing into the casing (61, 68, 69) through the filter (75) from the opening (62). ,
The filter (75) is disposed on an extension line in a direction in which the lens holder (63) moves by the disk access position adjustment drive as viewed from the lens holder (63),
The control device (12) causes the drive mechanism (72, 73, 81, 82) to perform a tapping drive as a drive other than the disk access position adjustment drive,
In the tapping drive, the drive mechanism (72, 73, 81, 82) moves the lens holder (63) in the direction of the disk access position adjustment drive by a distance longer than the distance of the disk access position adjustment drive. Accordingly, a part (63a, 63b) of the lens holder (63) is repeatedly applied to the filter (75). The control device (12) causes the drive mechanism (72, 73, 81, 82) to perform a pressing drive after the hit driving,
In the pressing drive, the driving mechanism (72, 73, 81, 82) keeps pressing the part (63a, 63b) of the lens holder (63) against the filter (75) for a reference time. The optical disk drive device according to claim 1. A blower (9) for generating an air flow;
A duct (10) for passing an air flow generated by the blower (9);
An air flow intake portion (11) that forms a passage for flowing an air flow through the duct (10) to the filter (75) of the optical pickup device (6),
3. The optical disk drive device according to claim 2, wherein the bottom surface of the air flow intake section (11) has a slope shape that descends from the filter (75) toward the duct (10). The duct (10) has a groove shape opened upward,
Of the air flow intake portion (11), the portion connected to the duct (10) is fitted in the groove of the duct (10),
The optical disk drive device according to claim 3, wherein a gap is provided between a bottom surface of the duct (10) and a slope-shaped lower end portion of the air flow intake portion (11). A blower (9) for generating an air flow;
A duct (10) for passing an air flow generated by the blower (9);
An air flow intake portion (11) that forms a passage for flowing an air flow through the duct (10) to the filter (75) of the optical pickup device (6),
The optical disk drive device according to claim 1 or 2, wherein a portion of the air flow intake portion (11) in the vicinity of the filter (75) is opened downward. An optical disk drive device that performs read or write access to an optical disk (4),
A turntable (2) that carries and rotates the optical disk (4);
A motor (3) for rotating the turntable (2);
An optical pickup device (6) for accessing the recording surface of the optical disc (4);
A blower (9) for generating an air flow;
A passage forming member (10, 11) that forms a passage for sending the air flow generated by the blower (9) to the optical pickup device (6),
The optical pickup device (6)
An objective lens (64);
A casing (61, 68, 69) that houses the objective lens (64) and has an opening (62) at the position of the objective lens (64);
A filter (75) for introducing the air sent from the passage forming member (10, 11) into the casing (61, 68, 69) and capturing dust in the introduced air;
The casing (61, 68, 69) has a structure for discharging air flowing into the casing (61, 68, 69) through the filter (75) from the opening (62). ,
The optical disk drive device, wherein the blower (9) includes a fin (92) rotated by the motor (3), and an air flow is generated by the rotation of the fin (92). An objective lens (64);
A casing (61, 68, 69) that houses the objective lens (64) and has an opening (62) at the position of the objective lens (64);
A filter (75) for introducing air from the outside to the inside of the casing (61, 68, 69) and capturing dust in the introduced air;
A lens holder (63) housed in the casing (61, 68, 69) and supporting the objective lens (64),
An optical pickup device for discharging air introduced into the casing (61, 68, 69) through the filter (75) from the opening (62),
In the casing (61, 68, 69), only the opening (62) and the filter (75) communicate with the outside of the casing (61, 68, 69). . An optical disk drive device that performs read or write access to an optical disk (4),
An optical pickup device (6) for accessing the recording surface of the optical disc (4);
Moving means (7, 8) for moving the optical pickup device (6) in the radial direction of the optical disc (4);
A blower (9) for generating an air flow;
A duct (10) for passing an air flow generated by the blower (9);
An air flow intake portion (11) that forms a passage for flowing an air flow through the duct (10) to the filter (75) of the optical pickup device (6),
The duct (10) extends along the moving direction of the optical pickup device (6) and has a groove shape,
The air flow intake part (11) moves together with the optical pickup device (6),
Of the air flow intake portion (11), the portion connected to the duct (10) is fitted in the groove of the duct (10), and along with the movement of the optical pickup device (6), An optical disc drive apparatus that moves in a groove of the duct (10). An objective lens (64);
A casing (61, 68, 69) that houses the objective lens (64) and has an opening (62) at the position of the objective lens (64);
A filter (75) for introducing air from the outside to the inside of the casing (61, 68, 69) and capturing dust in the introduced air;
A lens holder (63) housed in the casing (61, 68, 69) and supporting the objective lens (64);
By moving the lens holder (63) with respect to the casing (61, 68, 69), the position of the objective lens (64) with respect to the optical disk (4) is changed. A drive mechanism (72, 73, 81, 82) for realizing disk access position adjustment drive of the objective lens (64) with respect to
An optical pickup device for discharging air introduced into the casing (61, 68, 69) through the filter (75) from the opening (62),
The filter (75) is disposed on an extension line in a direction in which the lens holder (63) moves by the disk access position adjustment drive as viewed from the lens holder (63),
The drive mechanism (72, 73, 81, 82), as a drive other than the disk access position adjustment drive, is longer in the direction of the disk access position adjustment drive than the distance of the disk access position adjustment drive. An optical pick-up apparatus that performs tapping driving in which a part (63a, 63b) of the lens holder (63) is repeatedly applied to the filter (75) by moving the lens holder (63).

Images