JP2005129135A - Disk cartridge - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disk cartridge sufficiently preventing dust from adhering to accommodated disk media. <P>SOLUTION: The disk cartridge 10 has a case 14 in which an opening 74 for accessing the disk-like accommodated disk media 12 is formed. The case 14 comprises upper and lower shells 24, 26. Adhesive sheets 27R, 27L are provided at corner sections 21R, 21L at the backside of the lower shell 26 respectively, thus adsorbing dust/dirt in the case 14 by the adhesive sheets 27R, 27L at the corner sections 21R, 21L in which the dust/dirt easily stay. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a disk cartridge in which a disk-shaped disk medium used as a recording / reproducing medium for information or video is rotatably accommodated in a case.

  For example, disk-shaped disk media such as optical disks and magneto-optical disks are used as portable computer recording / reproducing media and video recording / reproducing media. When such disc media are recorded or reproduced, the laser head irradiates the recording surface with laser light while being rotated by the spindle shaft while being loaded in the disc drive device. As a result, on disk media, information is recorded by pit formation, phase change, magnetization, etc. due to decomposition of the dye layer on the recording surface, or reproduction of information recorded based on differences in the reflectance and polarization angle of laser light Is to be done.

  In order to prevent dust from adhering to the recording surface of the disk media (the cover layer that covers the recording surface) along with the increase in the recording capacity of such disk media, a disk cartridge that houses the disk media inside the case Known (for example, see Patent Documents 1 to 4). An example of such a disk cartridge will be described with reference to FIG.

  The disc cartridge 200 shown in an exploded perspective view in FIG. 10 has an opening for accessing the shaft center portion and recording surface of the disc medium 202 in the bottom plate (lower shell) 204A of the case 204 that rotatably accommodates the disc media 202. The opening 206 is opened and closed by a pair of shutter members 208 slidably disposed between the disk medium 202 and the bottom plate 204A. The pair of shutter members 208 are formed in a substantially semicircular shape having substantially the same shape.

  A pair of cam projections 227 are formed on the inner wall surface side of the bottom plate 204A facing the shutter member 208, and each shutter member 208 is provided with a cam groove 229 into which each cam projection 227 enters. Each cam groove 229 is formed in a linear slit shape, and is provided to be parallel to each other in the assembled state.

  That is, each cam groove 229 is provided so as to be symmetric with respect to a rotation center of an inner rotor 210 described later, like each cam protrusion 227. Each cam groove 229 penetrates the shutter member 208 in the plate thickness direction, and ensures an engagement depth with the cam protrusion 227.

  An inner rotor 210 is rotatably disposed between the disk medium 202 and the shutter member 208 independently of the disk medium 202. In the inner rotor 210, shaft holes 208A provided at one end of each shutter member 208 are engaged with a pair of support protrusions 210A positioned symmetrically with respect to the rotation axis thereof, and each shutter member 208 is supported by the support protrusion 210A. It is pivotally supported around it.

  With such a configuration, when the inner rotor 210 is operated and rotated by the drive device, each shutter member 208 is rotated around each support protrusion 210A by the cam mechanism provided between the bottom plate 204A and the opening 206 is opened. It moves between a closed position for closing and an open position for opening the opening 206. The inner rotor 210 is prevented from rotating by a lock member (not shown) when the disk medium 202 is not used, and holds the pair of shutter members 208 in the closed position.

By the way, in such disk cartridges, in recent years, the capacity, the recording density, and the narrowing of the track have been increasing, and even when a minute size dust or a minute amount of dust adheres to the disk media, A fatal obstacle to regeneration occurs. For this reason, measures such as improvement of the cleanliness in the assembly process of the disk cartridge and adoption of a dustproof mechanism by changing the case structure are being implemented.
JP 2003-115184 A JP 2003-115181 A JP 2003-115182 A JP 2003-115183 A

  However, such conventional measures are not sufficient to cope with higher capacity, higher recording density, and narrower tracks, which are expected to continue to advance in the future, and the quality of disk cartridges due to insufficient dust measures There is concern about the decline.

  In view of the above facts, an object of the present invention is to provide a disc cartridge that sufficiently prevents dust from adhering to the disc media accommodated therein.

  The present inventor has repeatedly studied a structure for preventing dust of minute dimensions from entering the case of the disk cartridge. However, it has been difficult to completely prevent dust sucked into the case as the disk medium rotates.

  Here, the inventor noted that the dust adhering to the inner wall of the case and the disc media was blown off by the rotation of the disc media and resuspended, and reattached to the recording area to cause a new defect. . Then, the inventors came up with an idea to prevent re-floating of dust that has entered the case, and earnestly studied to complete the present invention.

  According to the first aspect of the present invention, there is provided a disc cartridge having a case in which an opening for accessing a disc-shaped disc medium accommodated therein is formed, and an adsorbing means for adsorbing dust contained in the case is provided in the case. It is provided in.

  As a result, dust that has entered the case mainly through the opening is adsorbed by the adsorbing means. Accordingly, it is possible to greatly reduce the amount of dust that adheres to the case inner wall or the disk media and re-suspends. Further, dust having a larger size is more likely to be adsorbed by this adsorbing means. Therefore, it is possible to sufficiently prevent large-sized dust from re-floating.

  The invention according to claim 2 is characterized in that the case has a substantially quadrangular shape in plan view, and an adhesive sheet is provided as the adsorbing means in at least one of the corner portions of the case.

  As a result, dust that has fallen on the adhesive sheet due to its own weight can be adsorbed, so that the configuration of the adsorbing means can be simplified and a significant cost reduction can be realized. Moreover, since a puddle is easy to be formed in a case corner part, dust tends to stagnate. Therefore, dust can be adsorbed efficiently.

  The invention according to claim 3 is characterized in that the pressure-sensitive adhesive sheet has adhesive surfaces on both sides and is attached to the bottom surface of the corner portion.

  Thereby, an adhesive sheet can be arrange | positioned remarkably easily.

  The invention according to claim 4 includes a shutter member that opens and closes the opening, and a disk portion on which the disk medium is rotatably mounted, and is rotated by receiving rotational force from a drive device. An inner rotor that applies an opening / closing force to the shutter member is a disk cartridge provided in the case, and a plurality of apertures are formed in the disk portion.

  Thereby, the dust floating in the inner rotor is easily discharged downward from the opening due to its own weight or the air flow in the case. Further, the inner rotor can be reduced in weight. Further, when the inner rotor is manufactured by molding, the inner rotor can be easily cooled by forming the opening, so that the time required for molding can be shortened.

  By the way, in the inner rotor, dust floats toward the outer periphery. Therefore, the invention according to claim 5 is characterized in that the number of holes per unit area of the disc portion is larger in the outer peripheral portion than in the inner peripheral portion of the disc portion.

  Thereby, dust can be efficiently discharged downward from the inner rotor.

  According to a sixth aspect of the present invention, the inner rotor includes the disc portion and a ring-shaped guide rib standing on an outer peripheral portion of the disc portion, and the shutter member is opened among the guide ribs. When it is in a state, a notch is formed in an adjacent rib portion adjacent to the corner portion where the adhesive sheet is provided.

  Thereby, dust can be efficiently discharged from the inner rotor to the side.

  Since the present invention has the above-described configuration, a disk cartridge that sufficiently prevents dust from adhering to the stored disk media is realized.

  A disk cartridge 10 according to an embodiment of the present invention will be described with reference to FIGS. An arrow A appropriately shown in each drawing indicates the loading direction of the disk cartridge 10 into the drive device, and for convenience, the side indicated by the arrow A that is the loading direction into the drive device will be described as the front side. The direction indicated by arrow B is the upper side, and the direction indicated by arrow C is the right side.

(Overall configuration of disk cartridge)
FIG. 1 shows an external appearance of the disk cartridge 10 in a perspective view, and FIG. 2 shows the disk cartridge 10 in an exploded perspective view. As shown in these drawings, the disk cartridge 10 includes a disk medium 12 as an information recording / reproducing medium formed in a disk shape, an upper shell 24 and a lower shell 26, and rotatably accommodates the disk medium 12. A case 14, a pair of shutter members 18 that can open and close the opening 16 formed in the lower shell 26 for accessing the disk medium 12, and a drive device that is rotated to drive the shutter member 18 to open and close the opening 16. The inner rotor 20 and a lock member 22 for preventing the rotation of the inner rotor 20 and maintaining the closed state of the opening 16 when the disk medium 12 is not used are configured as main components.

  The disk medium 12 has a center hole 12A engaged with and held by a rotating spindle shaft of a disk drive device (not shown) at its axial center, and a recording surface 12B formed on the lower surface thereof is a cover layer (both not shown). Protected by coating.

  The recording surface 12B is formed in an annular shape in the vicinity of the outer periphery of the lower surface of the disk medium 12 and in a portion excluding a predetermined range around the center hole 12A, and an area between the center hole 12A and the recording surface 12B on the lower surface of the disk medium 12 The rotating spindle shaft of the drive device is a chucking area 12C for holding the disk medium 12. In the present embodiment, the diameter (outer diameter) of the disk medium 12 is approximately 120 mm.

(Case)
The case 14 that accommodates the disk media 12 is formed in a substantially rectangular flat container shape by joining an upper shell 24 and a lower shell 26. Specifically, the case 14 is formed in a shape in which the front edge portion is formed in a substantially symmetrical arc shape in plan view, and the rear end corner portions are obliquely cut out. This prevents erroneous loading of the drive device.

  Hereinafter, the case 14 will be specifically described.

  As shown in FIG. 3, the upper shell 24 includes a top plate 28 having a shape corresponding to the shape of the case 14 in plan view, and a peripheral wall 30 erected downward substantially along the outer edge of the top plate 28. ing.

  At the right end portion of the top plate 28, an upper groove wall 32 projecting rightward from the right peripheral wall 30 is extended over substantially the entire length in the front-rear direction. The upper groove wall 32 forms a guide groove 50 which is long in the front-rear direction and opens forward and right in the right side portion of the case 14 together with a lower groove wall 48 which will be described later of the lower shell 26 shown in FIG. ing.

  Further, an inner wall 34 formed in an annular shape in a bottom view is erected on the inner side of the peripheral wall 30 on the lower surface of the top plate 28. Here, the upper shell 24 accommodates the disk media 12 inside the inner wall 34, and the outer peripheral surface of the inner wall 34 slides in the circumferential direction on an annular wall 72 (to be described later) of the inner rotor 20 shown in FIG. The guide surface is made possible.

  Further, the peripheral wall 30 is provided with a cutout portion 30A in which a central portion in the front-rear direction of the right side portion of the upper shell 24 is cut out, and the cutout portion 30A together with a cutout portion 44A described later of the lower shell 26, A shutter operation window 52 that exposes the inner rotor 20 to the outside (guide groove 50) is configured.

  Further, a lock support shaft 36 that pivotally supports the lock member 22 shown in FIG. 2 so as to swing is projected from the right front corner of the bottom surface of the top plate 28. The lock support shaft 36 is located between the peripheral wall 30 and the inner wall 34, and a cutout portion 30B is formed by cutting out the peripheral wall 30 behind the lock support shaft 36 and in front of the cutout portion 30A. ing. The notch 30 </ b> B and the notch 44 </ b> B, which will be described later, of the lower shell 26 constitute a lock release window 54 for projecting the release operation part 88 of the lock member 22 into the guide groove 50.

  A first stopper 38 is erected continuously from the front peripheral wall 30 on the left side of the lock support shaft 36 on the lower surface of the top plate 28 and is used for restricting the rotation of the inner rotor 20 on the closed side. Further, a second stopper 40 is provided continuously from the rear peripheral wall 30 at a position slightly to the right of the center in the left-right direction in the vicinity of the rear end of the lower surface of the top plate 28, so that the inner rotor 20 rotates on the open side. It is for regulatory purposes.

  On the other hand, as shown in FIGS. 2 and 4, the lower shell 26 includes a bottom plate 42 having a shape substantially corresponding to the top plate 28 of the upper shell 24 and a peripheral wall 44 having a shape substantially corresponding to the peripheral wall 30. The opening 16 is provided in the bottom plate 42. The opening 16 has a substantially circular hub hole 16A having a diameter larger than the outer diameter of the center hole 12A of the disk medium 12 and slightly smaller than the outer diameter of the chucking area 12C (the inner diameter of the recording surface 12B), and a hub. It is composed of a substantially rectangular recording / reproducing head window portion 16B continuously provided in front of the center line along the left-right direction of the hole 16A, and is formed in a substantially U-shape opening forward as a whole.

  The hub hole 16A is arranged so as to be substantially coaxial with the disk medium 12 accommodated in the inner wall 34 in a state where the upper shell 24 and the lower shell 26 are joined. The hub hole 16A is configured to have the above dimensions, so that only the center hole 12A and the chucking area 12C are exposed to the outside, and the recording surface 12B is not exposed to the outside.

  Further, the recording / reproducing head window 16B for exposing the recording surface 12B is widened so that the left edge thereof is located to the left of the tangent along the front-rear direction of the hub hole 16A, and the front portion thereof is The peripheral wall 44 is also cut out and opened to the front of the lower shell 26.

  The rotating spindle shaft of the drive device enters the hub hole 16A to rotate the disk medium 12 while engaging and holding the center hole 12A of the disk medium 12, and the recording / reproducing head window 16B. In this case, a recording / reproducing head of the drive device enters to record or reproduce information on the recording surface 12B of the disk medium 12.

  Since the recording / reproducing head window 16B is also opened forward, the recording / reproducing head can easily access the outer peripheral portion of the recording surface 12B. The hub hole 16A and the recording / reproducing head window 16B may be provided independently of each other.

  In the bottom plate 42, dust-proof ribs 46 each having a front end continuous to the peripheral wall 44 are provided in the vicinity of the front ends of the left and right edges of the recording / reproducing head window 16B. Each dust-proof rib 46 has a height equal to the thickness of the shutter member 18, and the inner rotor 20 slides on the upper surface thereof. Further, the positions of the rear end portions of the respective dustproof ribs 46 are determined so as to come into contact with the shutter member 18 closing the opening 16.

  Further, a lower groove wall 48 projecting to the right from the right peripheral wall 44 is extended at the right end of the bottom plate 42 over substantially the entire length in the front-rear direction. The lower groove wall 48 is opposed to the upper groove wall 32 of the upper shell 24 shown in FIG. 3 so that a guide groove 50 is formed on the right side of the case 14.

  The guide groove 50 is a groove bottom of the peripheral walls 30 and 44 whose upper and lower end surfaces are brought into contact with each other by joining the upper shell 24 and the lower shell 26, and is long in the front-rear direction of the case 14 and forward. In addition, it opens to the right and also opens rearward in this embodiment.

  Further, the peripheral wall 44 on the right side of the lower shell 26 has a notch 44A formed corresponding to the notch 30A of the peripheral wall 30 and a notch 44B formed corresponding to the notch 30B. Is provided.

  Thus, in the case 14 where the upper shell 24 and the lower shell 26 are joined, the shutter operation window 52 that opens at the center in the longitudinal direction at the groove bottom of the guide groove 50 and the guide groove 50 in front of the shutter operation window 52 are formed. A lock release window 54 that opens to the groove bottom is formed.

  Further, cam projections 56 project from the left and right sides of the bottom plate 42 across the opening 16. The pair of cam protrusions 56 are disposed at positions symmetrical to each other with respect to the axis of the hub hole 16A, more precisely, the rotation center of the inner rotor 20.

  These cam protrusions 56 enter cam grooves 66 (described later) of different shutter members 18 to form positive cams together with the cam grooves 66, and the shutter members 18 are opened by relative rotation of the case 14 and the inner rotor 20. It is made to move between 16 closed positions and open positions.

  The lower shell 26 described above is joined to the upper shell 24 by screws to form the case 14 with the upper end surface of the peripheral wall 44 abutted against the lower end surface of the peripheral wall 30. Note that the upper shell 24 and the lower shell 26 may be joined by, for example, ultrasonic welding or the like, instead of the screws.

(Dust adsorption mechanism in the case)
As shown in FIGS. 1 and 4, the case 14 has a substantially square shape in plan view, and two corners 21 </ b> R and 21 </ b> L on the rear side of the lower shell 26 (that is, the direction opposite to the A direction) are respectively provided with the upper shell Reinforcing ribs 23R and 23L are erected along the inner wall 34 of 24. The corner zones 25R and 25L formed by the reinforcing ribs 23R and 23L and the peripheral wall 44 are provided with adhesive sheets 27R and 27L, respectively. The pressure-sensitive adhesive sheets 27 </ b> R and 27 </ b> L are commercially available pressure-sensitive adhesive sheets having pressure-sensitive adhesive surfaces on both sides, and are arranged by cutting into a predetermined shape and sticking to the bottom surface of the lower shell 26.

  Further, the reinforcing ribs 23R and 23L are formed with notches 29R and 29L so that dust in the case 14 can easily enter the corner zones 25R and 25L, respectively. The formation position of the notch 29 closer to the opening side stopper portion 82 of the inner rotor 20 is considered to be a position where the operation of the opening side stopper portion 82 is not hindered.

  Further, notches 73R and 73L are formed in the annular wall 72 of the inner rotor 20. When the inner rotor 20 is rotated to the position where the shutter member 18 is set to the open position, the notches 73R and 73L overlap the notches 29R and 29L of the reinforcing ribs 23R and 23L, respectively, so that the inner rotor 20 and the corner zones 25R and 25L are connected. The formation positions of the notches 73R and 73L are determined so as to communicate with each other. Thereby, the dust in the inner rotor 20 enters the corner zones 25R and 25L efficiently.

(Shutter member and its opening / closing mechanism)
Each of the pair of shutter members 18 is formed in a substantially semicircular plate shape, and can abut part of the opening 16 formed in the lower shell 26 by abutting the abutting portions 60 and 62 that are the chord portions of each other. It is said that.

  That is, the pair of shutter members 18 closes each other butting portions 60 and 62 and closes the hub hole 16A and a portion excluding a part near the front end of the recording / reproducing head window 16B (see FIG. 6). The abutting portions 60 and 62 are substantially aligned with the left and right edges of the opening 16 so that an opening position (see FIG. 8) for opening the opening 16 can be taken.

  Here, the pair of shutter members 18 positioned at the closed position are configured to prevent the entry of dust into the case 14 by overlapping the abutting portions 60 and 62 with each other.

  Specifically, a step portion 63 is formed in the abutting portions 60 and 62 of each shutter member 18, and a flange portion which is a thin portion along the upper surface on one side in the longitudinal direction with the step portion 63 as a boundary. 65 is formed, and a flange portion 67 which is a thin portion along the lower surface is formed on the other side.

  When the pair of shutter members 18 are positioned at the closed position, the flange 67 of the other shutter member 18 is superimposed on the lower side of the flange 65 of the one shutter member 18 and the flange of the one shutter member 18 is overlapped. The flange portion 65 of the other shutter member 18 is superposed on the upper side of the portion 67. The overlapping surface of each of the flange portions 65 and 67 with the counterpart is a gently inclined surface so as to invite the counterpart.

  On the other hand, shaft holes 64 are provided in the vicinity of one end in the longitudinal direction of the chord portion of each shutter member 18, and each shaft hole 64 is used for supporting the shutter member 18 to the inner rotor 20. Each shutter member 18 is provided with a cam groove 66 into which a cam projection 56 formed on the lower shell 26 enters.

  Each cam groove 66 is formed in a linear slit shape that is long in a linear direction passing through the axis of the shaft hole 64 in each shutter member 18 and is provided so as to be parallel to each other in the assembled state.

  That is, each cam groove 66 is provided so as to be symmetrical with respect to the rotation center of the inner rotor 20, as with each cam protrusion 56. Each cam groove 66 penetrates the shutter member 18 in the plate thickness direction, and ensures the engagement depth with the cam projection 56.

  Furthermore, at least one shutter member 18 is provided with a dust-proof portion 68 protruding from the arc portion. When the one shutter member 18 is disposed at the closed position, the dust-proof portion 68 abuts against the rear end surface of the dust-proof rib 46 located on the right edge side of the opening 16 and the upper surface of the bottom plate 42 and the disc portion 70 of the inner rotor 20. The gap with the lower surface (described later) is filled (see FIG. 6).

  Further, the end of the one shutter member 18 near the shaft hole 64 abuts against the rear end surface of the other dust-proof rib 46 when the shutter member 18 is disposed at the closed position, and the clearance between the upper surface of the bottom plate 42 and the lower surface of the disk portion 70 is reached. Is supposed to be filled. In addition, you may provide the dust-proof part 68 in each shutter member 18, respectively.

  On the other hand, as shown in FIG. 2, the inner rotor 20 includes a disc portion 70 formed in a disc shape and an annular wall 72 erected upward along the outer periphery of the disc portion 70. Further, the disk portion 70 is provided with an opening 74 having substantially the same shape as the opening 16. The opening 74 is formed at the end portion on the outer peripheral side of the disk portion 70 so that the lower portion of the annular wall 72 is located on the lower shell 26. A portion corresponding to the height of the peripheral wall 44 is cut out so as to open to the radially outer side of the inner rotor 20.

  As described above, the inner rotor 20 is externally fitted to the inner wall 34 of the upper shell 24 so as to be slidable in the circumferential direction, and is supported rotatably on the case 14 independently of the disk medium 12. The inner rotor 20 rotates between the closed position and the open position while sliding the pair of shutter members 18 disposed between the inner rotor 20 and the bottom plate 42 of the case 14 between them. It is designed to move.

  In addition, support protrusions 76 project from two locations on the lower surface of the disc portion 70 that are symmetrical with respect to the center of rotation of the inner rotor 20, and shaft holes 64 of different shutter members rotate on the support protrusions 76. It engages freely.

  That is, each shutter member 18 is pivotally supported by the inner rotor 20 so as to be rotatable around each support protrusion 76, and can be rotated around each support protrusion 76 to take a closed position and an open position. It has become.

  As described above, the cam projections 56 of the case 14 are inserted into the cam grooves 66 of the shutter members 18 to form positive cams, respectively, and the pair of shutter members 18 are closed by the relative rotation of the inner rotor 20 with respect to the case 14. And an open position.

  Specifically, as shown in FIG. 6, when the pair of shutter members 18 are arranged at the closed position, the inner rotor 20 has an opening 74 on the left side with respect to the opening 16 at a predetermined angle (approximately 50 ° to 60 °). The disc is rotated to a shifted position, and the front portion of the opening 16 (the portion not closed by the shutter member 18) is closed from the inside by the disk portion 70 and the annular wall 72. At this time, each cam projection 56 enters the end portion of the guide rib closer to the inner rotor 20.

  7, when the inner rotor 20 is rotated in the direction of arrow D with respect to the case 14 as shown in FIG. 7, each shutter member 18 has a groove wall of each cam groove 66 in a direction substantially opposite to the arrow D by the cam projection 56. It is configured to be pressed in the direction of the arrow E and rotate in directions away from each other around the respective support protrusions 76.

  Then, as shown in FIG. 8, when the inner rotor 20 rotates to a position where the opening 74 coincides with the opening 16 of the case 14, the butted portions 60 and 62 of the shutter members 18 are substantially aligned with the left and right edges of the openings 16 and 74. The opening 16 is completely opened (each shutter member 18 reaches the open position). In this state, each cam projection 56 enters the end portion closer to the shaft hole 64 in the cam groove 66.

  On the other hand, when the inner rotor 20 is rotated in the direction of the arrow F opposite to the arrow D from the open state of the opening 16, the pair of shutter members 18 are moved to the closed position (the state shown in FIG. 6) by the operation opposite to the above operation. ) To return.

  As can be seen from FIGS. 6 to 8, the pair of shutter members 18 overlap the case 14 with the rotation associated with the rotation of the inner rotor 20 and the rotation around the support protrusion 76 with respect to the inner rotor 20. However, when viewed with the shutter members 18, the abutting portions 60 and 62 (mutual cam grooves 66) are kept in contact with each other while being kept parallel to each other.

  Further, as shown in FIGS. 5 and 6, a driven gear portion 78 protrudes radially outward from a part of the outer circumferential portion of the annular wall 72 of the inner rotor 20. A part of the driven gear portion 78 protrudes from the shutter operation window 52 into the guide groove 50.

  The driven gear portion 78 is an opening / closing member on the drive device side that moves in the longitudinal direction in the guide groove 50 in the rotation range of the inner rotor 20 that moves the shutter member 18 between the closed position and the opened position. The drive rack 100 is provided in a range that can always be engaged.

  In the present embodiment, the driven gear portion 78 is provided to the extent that an engaging portion 86 (described later) of the lock member 22 can be engaged (engaged) when the shutter member 18 is disposed at the closed position.

  As a result, when the drive rack 100 moves backward in the guide groove 50 with respect to the case 14, the inner rotor 20 rotates in the direction of arrow D to open the opening 16, and the drive rack 100 moves in the guide groove 50 with respect to the case 14. When moving forward, the inner rotor 20 rotates in the direction of arrow F, and the opening 16 is closed.

  Further, an end portion on the arrow F side of the driven gear portion 78 protruding outward from the annular wall 72 is a closing side stopper portion 80. The closing-side stopper portion 80 abuts against the first stopper 38 of the case 14 when the shutter member 18 is disposed at the closing position, and prevents the inner rotor 20 from rotating in the direction of arrow F beyond the closing position. (See FIG. 6).

  On the other hand, an open-side stopper portion 82 projects from a position separated from the driven gear portion 78 on the outer surface of the annular wall 72 by a predetermined distance (angle) on the arrow D side. The opening-side stopper portion 82 abuts against the second stopper 40 of the case 14 when the shutter member 18 is positioned at the opening position, and prevents the inner rotor 20 from rotating in the direction of arrow D beyond the opening position. (See FIG. 8).

(Lock mechanism with lock member)
By the way, the lock member 22 includes a main body portion 84 formed in a substantially “h” shape or a substantially “<” shape in plan view. The main body portion 84 is inserted through the lock support shaft 36 of the case 14 in the vicinity of the bent portion, and is supported so as to be swingable around the lock support shaft 36 with respect to the case 14.

  One end of the main body 84 is an engaging portion 86 that can be engaged with the driven gear portion 78 of the inner rotor 20, and the lock member 22 is an inner rotor in a state where the engaging portion 86 is engaged with the driven gear portion 78. In this configuration, the rotation of the 20 cases 14 is prevented.

  The other end portion of the main body portion 84 is a release operation portion 88 that advances and retreats from the lock release window 54 to the guide groove 50 as the main body portion 84 rotates about the lock support shaft 36. The lock member 22 is configured to project the release operation portion 88 into the guide groove 50 in a state where the engaging portion 86 is engaged with the driven gear portion 78, and the drive rack 100 moves backward in the guide groove 50. When the release operation part 88 is pressed rearward by this, the main body part 84 swings in the direction of arrow G to release the engagement with the driven gear part 78 of the engagement part 86 (see FIG. 7).

  Further, a leaf spring portion 90 extends from the vicinity of the bent portion of the main body portion 84 so as to be parallel to the front side of the engaging portion 86 side portion. The leaf spring portion 90 is in contact with the peripheral wall 30 on the front side of the case 14 in a state of being elastically deformed in the direction approaching the main body portion 84, and always urges the main body portion 84 in the direction opposite to the arrow G. ing. Due to the urging force of the leaf spring portion 90, the lock member 22 maintains the engagement between the engaging portion 86 and the driven gear portion 78.

  Thereby, when not in use, the rotation of the inner rotor 20 is prevented, and the closed state of the opening 16 by the pair of shutter members 18 is maintained. Further, when the engagement between the release operation unit 88 and the drive rack 100 is released from the unlocked state by the drive rack 100 as described above, the lock member 22 receives the engagement portion 86 by the urging force of the leaf spring portion 90. The locked state is engaged with the drive gear portion 78.

(Function)
Next, the operation of the disk cartridge 10 configured as described above will be described.

  In this disk cartridge 10, as shown in FIG. 6, when not in use, such as during storage or transportation, a pair of shutter members 18 are located at the closed position and close the opening 16. In this state, the engaging portion 86 of the lock member 22 engages with the driven gear portion 78 of the inner rotor 20 to prevent the inner rotor 20 from rotating in the direction of arrow D, and the pair of shutter members 18 are in the closed position. Is retained. That is, the closed state of the opening 16 is maintained.

  Further, when the disk cartridge 10 is used, that is, when information is recorded on the disk medium 12 or when information recorded on the disk medium 12 is reproduced, the disk cartridge is loaded in the drive device along the arrow A direction. . With this loading operation (relative movement between the disk cartridge 10 and the drive device), the drive rack 100 of the drive device enters the guide groove 50 of the case 14 and relatively moves backward in the guide groove 50.

  As a result, as shown in FIG. 7, the release operation portion 88 of the lock member 22 is pressed by the drive rack 100, and the main body portion 84 moves in the direction of arrow G against the urging force of the leaf spring portion 90. Swing.

  For this reason, the engagement state of the engagement portion 86 with the driven gear portion 78 is released, and the inner rotor 20 becomes rotatable. When the drive rack 100 moves further rearward while maintaining the contact state with the release operation portion 88, the drive rack 100 rotates the inner rotor 20 in the direction of arrow D while meshing with the driven gear portion 78.

  By the rotation of the inner rotor 20 in the direction of arrow D, the pair of shutter members 18 follow the rotation in the direction of arrow D, while the groove wall of the cam groove 66 is pressed by the cam projection 56 and the arrow E around the support projection 76. It also rotates in the direction.

  That is, the pair of shutter members 18 moves in the opening direction of the opening 16. When the disk cartridge 10 is loaded into the drive device to a predetermined depth and the relative movement with respect to the drive rack 100 is lost, the pair of shutter members 18 reach the open position as shown in FIG. 8, and the opening 16 is completely opened. The

  If the inner rotor 20 is further rotated in the direction of arrow D from this state, the opening-side stopper portion 82 of the inner rotor 20 contacts the second stopper 40 of the case 14 and moves to the arrow D side beyond the opening position of the inner rotor 20. Rotation is prevented.

  Next, the disk cartridge 10 is positioned in the drive device, and in this positioning state, the rotary spindle shaft of the drive device enters from the hub hole 16A of the opening 16, and the rotary spindle shaft enters the center hole 12A (and the chuck) of the disk medium 12. The disc medium 12 is held by engaging with the king area 12C). When the rotary spindle shaft rotates, the disk medium 12 is driven to rotate in the case 14 in a non-contact manner.

  The recording / reproducing head of the drive device enters from the recording / reproducing head window 16B of the opening 16. With this recording / reproducing head, information is recorded on the recording surface 12B of the disk medium 12, or information recorded on the recording surface 12B is reproduced (the disk medium 12 is used).

  After use of the disk medium 12, the disk cartridge 10 is ejected from the drive device. With this discharge operation, the drive rack 100 moves relatively forward in the guide groove 50. As the drive rack 100 moves, the inner rotor 20 rotates in the direction of arrow F. With the rotation of the inner rotor 20 in the direction of arrow F, the pair of shutter members 18 follow the rotation in the direction of arrow F, while the groove wall of the cam groove 66 is pressed by the cam projection 56 and the arrow H It also rotates in the direction and moves to the closing side (see FIG. 7).

  When the drive rack 100 moves to a position where the meshing with the driven gear portion 78 is released, as shown in FIG. 6, the pair of shutter members 18 reach the closed position, and the opening 16 is completely closed.

  If the inner rotor 20 is further rotated in the direction of the arrow F from this state, the closing side stopper portion 80 of the inner rotor 20 contacts the first stopper 38 of the case 14 and moves to the arrow F side beyond the closing position of the inner rotor 20. Rotation is prevented.

  When the drive rack 100 moves forward and the engagement state with the release operation portion 88 of the lock member 22 is released, the main body portion 84 of the lock member 22 is in a direction opposite to the arrow G by the urging force of the leaf spring portion 90. And the engaging portion 86 engages with the driven gear portion 78. Thereby, the rotation of the inner rotor 20 is prevented, and the pair of shutter members 18 is returned to the initial state in which they are held at the closed position. In this state, the disk cartridge 10 is completely ejected from the drive device.

  When the disc cartridge 10 is used in this way, dust enters the case 14 from the opening 74 when the shutter member 18 is opened. Here, in the present embodiment, since the adhesive sheets 27R and 27L are respectively provided in the corner zones 25R and 25L of the lower shell 26, they are floating in the case 14 due to an air flow caused by the rotation of the disk media 12. Dust can be removed by adsorbing to the adhesive sheets 27R and 27L. In addition, the corner zones 25R and 25L where the adhesive sheets 27R and 27L are respectively provided are on the rear end side of the case 14 and are positions where dust entering from the front end side tends to stay. It can be removed efficiently.

  Further, notches 29R and 29L are formed in the reinforcing ribs 23R and 23L, respectively, so that dust in the case 14 can easily enter the corner zones 25R and 25L.

  Furthermore, notches 73R and 73L are also formed in the annular wall 72 of the inner rotor 20, and when the inner rotor 20 is rotated to the position where the shutter member 18 is set to the open position, the notches 73R and 73L are formed on the reinforcing ribs 23R and 23L. It is made to overlap with the notches 29R and 29L. Therefore, the dust in the inner rotor 20 can be efficiently conveyed to the corner zones 25R and 25L.

  Moreover, since the adhesive sheets 27R and 27L are commercially available double-sided adhesive sheets, when the adhesive sheets 27R and 27L are provided in the corner zones 25R and 25L, respectively, the commercially available adhesive sheets can be cut and attached to the bottom surface of the lower shell 26. good. Accordingly, the installation of the adhesive sheets 27R and 27L is remarkably easy.

[Modification]
Next, a modification of the above embodiment will be described. In the present modification, the same components as those in the above embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIG. 9, in the disc cartridge 110 of this modification, a large number of apertures 116 are formed in the disc portion 114 that constitutes the inner rotor 112.

  The diameters of the apertures 116 are all about 1 mmφ, and the number of apertures per unit area is larger in the outer peripheral portion 114E than in the inner peripheral portion 114I of the disc portion 114.

  Thereby, dust can be discharged | emitted below from an inner rotor. Further, since the dust floats toward the outer peripheral portion 114E in the inner rotor 112, the dust can be efficiently discharged downward from the outer peripheral portion 114E having a large number of holes per unit area.

  It should be noted that dust can be more efficiently discharged by providing an opening in the shutter member 18 as well. In this case, when the opening 74 is in the closed state, the shutter member located below the opening 74 is not provided with an opening, so that dust enters the case 14 when the disk cartridge 110 is not used. It is preferable to prevent this.

  The embodiments of the present invention have been described above with reference to the embodiments. However, the embodiments described above are only one embodiment, and various modifications can be made without departing from the scope of the invention. For example, it is possible to change the arrangement position of the pressure-sensitive adhesive sheets 27R and 27L, and to change the diameter and number of the apertures 116. Furthermore, it is possible to make the diameter of the opening 116 non-uniform.

  In the above embodiment, the opening 16 is formed only below the case 14, but the present invention is not limited to this. For example, a disk medium having recording surfaces 12B on both upper and lower surfaces is used. In the case 14 to be accommodated, an opening 16 that can be opened and closed by a pair of shutter members 18 may also be provided on the top plate 28. On the other hand, in the case 14 that accommodates the disk medium 12 having the recording surface 12 </ b> B provided only on the lower surface, a replacement opening that allows the disk medium 12 to be replaced may be provided in the top plate 28.

  In the above embodiment, the diameter of the disk medium 12 is approximately 120 mm. However, the present invention is not limited to this, and the present invention is also applied to the disk cartridge 10 including the disk medium 12 of any size. It goes without saying that it is possible.

1 is a perspective view showing an external appearance of a disk cartridge according to an embodiment of the present invention. 1 is an exploded perspective view of a disk cartridge according to an embodiment of the present invention. It is a bottom view of the upper shell which constitutes the disc cartridge concerning an embodiment of the invention. It is a top view of the lower shell which comprises the disk cartridge which concerns on embodiment of this invention. It is the perspective view which looked at the inner rotor and shutter member which constitute the disk cartridge concerning an embodiment of the invention from the upper part. It is the bottom view which removed the lower shell which shows the opening obstruction | occlusion state of the disc cartridge concerning embodiment of this invention, and was seen. FIG. 6 is a bottom view of the disc cartridge according to the embodiment of the present invention, viewed from the bottom shell showing the process of closing or opening the opening. FIG. 5 is a bottom view of the disc cartridge according to the embodiment of the present invention, viewed from a state where the lower shell showing an open state of the disc cartridge is removed. It is a disassembled perspective view of the disc cartridge which concerns on the modification of embodiment of this invention. It is a disassembled perspective view of the conventional disc cartridge.

Explanation of symbols

10 Disc cartridge 12 Disc media 14 Case 16 Opening 18 Shutter member 20 Inner rotor 21R, L Corner portion 27R, L Adhesive sheet 70 Disc portion 72 Annular wall (guide rib)
73R, L Notch 110 Disc cartridge 112 Inner rotor 114 Disc portion 114E Outer portion 114I Inner portion 116 Opening 200 Disc cartridge 202 Disc media 204 Case 206 Opening 208 Shutter member 210 Inner rotor

Claims (6)

In a disc cartridge having a case in which an opening for accessing a disc-shaped disc medium accommodated is formed,
2. A disk cartridge according to claim 1, wherein a suction means for sucking dust contained in said case is provided in said case.   2. The disk cartridge according to claim 1, wherein the case has a substantially quadrangular shape in plan view, and an adhesive sheet is provided as the suction means at at least one corner portion of the case.   The disk cartridge according to claim 2, wherein the adhesive sheet has adhesive surfaces on both sides and is attached to a bottom surface of the corner portion. A shutter member for opening and closing the opening;
An inner rotor that has a disc portion on which the disk medium is rotatably mounted, and that gives an opening / closing force to the shutter member by rotating by receiving rotational force from a drive device;
Is a disc cartridge provided in the case,
4. The disk cartridge according to claim 1, wherein a plurality of apertures are formed in the disk portion.   5. The disk cartridge according to claim 4, wherein the number of apertures per unit area of the disk portion is larger in the outer peripheral portion than in the inner peripheral portion of the disk portion. The inner rotor is composed of the disk part and a ring-shaped guide rib standing on the outer periphery of the disk part,
The notch is formed in the adjacent rib part adjacent to the said corner part in which the said adhesive sheet was provided among the said guide ribs when the said shutter member is made into an open state, The Claim 4 or 5 characterized by the above-mentioned. Disc cartridge.

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