JP2006092673A - Recording disk cartridge - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To constitute easily a recording disk cartridge in which a plurality of flexible recording disk media are housed, the number of sheets of recording disk media is changed easily, and a rotation operation is done stably. <P>SOLUTION: A cartridge case 2 housing a plurality of magnetic disk media 41 being an example of a recording disk media is provided with: a lower plate 10 constituting a lower wall being parallel to the magnetic disk media 41; an inner plate 20 laminated and fixed on this and partitioning the plurality of magnetic disk media 41; an upper plate 30 laminated and fixed on this and constituting an upper wall of the cartridge case 2; and a liner 49 for dust proof provided at a plane opposing to the plurality of magnetic disk media 41, and clearance between the magnetic disk media 41 and the plane opposing to the media is adjusted by thickness of the liner 49. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a recording disk cartridge provided with a plurality of flexible recording disk media.

  Conventionally, a flexible magnetic disk medium in which a magnetic layer is formed on both sides of a disk-shaped support made of a flexible material such as a polyester sheet is known. This magnetic disk medium has a merit that access to data is faster than a magnetic tape, but has a demerit that a storage capacity is small due to a small recording area.

  In order to solve the disadvantages of such a flexible magnetic disk medium, conventionally, a magnetic disk cartridge in which a plurality of magnetic disk media are stored in one cartridge case has been disclosed (see, for example, Patent Document 1).

By the way, a flexible magnetic disk medium has a problem that since the medium itself has low rigidity, it tends to swing in a direction perpendicular to the recording surface when rotated. For this reason, in the invention described in Patent Document 1, each magnetic disk medium is sandwiched between shutters. By arranging a plate member such as a shutter having high rigidity in the vicinity of the magnetic disk medium in this way, the recording surface can be stabilized because the magnetic disk medium follows the plate member as the magnetic disk medium rotates.
Japanese Patent Laid-Open No. 2004-22011

However, the magnetic disk cartridge disclosed in Patent Document 1 is composed of a movable shutter member in which four plate members described above are arranged with respect to one magnetic disk medium. There is a problem that it is difficult to keep parallel with the media. Further, since the magnetic disk cartridge is a product produced in large quantities, it is desirable that the magnetic disk cartridge is excellent in assembling property and productivity. Furthermore, it is desirable that the degree of freedom in design change is high so that it is easy to set a plurality of types of magnetic disk cartridges in which the number of magnetic disk media is three or five.
Further, when a plurality of magnetic disk media are provided, it is necessary to obtain a stable rotation operation.

  The present invention has been made in view of such a background. The present invention has a simple structure, is excellent in assemblability and productivity, can easily change the number of recording disk media, and An object of the present invention is to provide a recording disk cartridge that enables a stable rotational operation.

  In order to solve the above-described problems, a recording disk cartridge of the present invention is a recording disk cartridge in which a plurality of flexible recording disk media are housed in a cartridge case so as to be integrally rotatable, and the cartridge case includes the recording disk medium A lower plate constituting a lower wall parallel to the at least one inner plate, at least one inner plate stacked and fixed on the lower plate to partition the plurality of recording disk media, and stacked and fixed on the inner plate. An upper plate constituting an upper wall of the cartridge case, and a dust removal liner provided on a surface facing the plurality of recording disk media, and the plurality of recording disk media and a surface facing the recording disk media. The clearance was adjusted by the thickness of the liner.

  With such a configuration, the recording disk cartridge of the present invention has a cartridge case in which the lower plate, the inner plate, and the upper plate are stacked. For this reason, the set of the inner plate and the recording disk medium can be made into one unit, and the inner plate can be made of the same parts, which is excellent in productivity. Further, since the recording disk medium can be carried in the assembling process by using the lower plate or the inner plate as a tray, the assembling process is excellent without damaging / staining the medium. In addition, when it is desired to change the number of recording disk media, the specification can be easily changed because the number of inner plates is mainly changed. Further, since the inner plate as a partition plate is fixed as a part of the cartridge case, it is easy to obtain accuracy such as parallelism with the recording disk medium, and the recording disk medium, particularly at a high speed such as 2000 to 8000 rpm. Rotational stability can be increased.

  And because the dust removal liner is provided on the surface facing the plurality of recording disk media, the effect of removing dust adhering to the surface of the recording disk media is high, and the surface is always kept clean, A recording disk cartridge excellent in dust resistance can be obtained. Therefore, it is possible to avoid the occurrence of a data error at the time of recording or reproducing the recording disk medium, and it is possible to improve the reliability.

  Further, since the clearance between the plurality of recording disk media and the surface facing the plurality of recording disk media is adjusted by the thickness of the liner, the thickness of the liner can be adjusted even if there is a difference in the clearance. Can solve this. As a result, it is possible to avoid the occurrence of surface shake or the like on the rotating recording disk medium, and a stable rotation operation of the recording disk medium can be realized.

  Of the plurality of recording disk media, the lowermost layer and the liner provided to face the uppermost recording disk medium are thicker than the other liners provided to face the other recording disk media. It is good to have the structure formed.

  By adopting such a configuration, the clearance of the lowermost and uppermost recording disk media, which may be difficult to obtain accuracy, can be suitably adjusted by forming a thicker liner. It is possible to avoid surface blurring or the like that tends to occur in the recording disk medium. Therefore, a stable rotation operation of the recording disk medium can be realized.

  Furthermore, the liner can be formed from a combination of a woven fabric and a non-woven fabric, or a woven fabric or a non-woven fabric, and the liner can be raised to increase the thickness and adjust the clearance.

According to the present invention, since the cartridge case is configured by stacking the lower plate, the inner plate, and the upper plate, it becomes possible to improve productivity by sharing the parts, and the recording disk medium is mounted on the inner plate or the like. This makes it easy to assemble without damaging / staining the recording disk media.
Further, the number of recording disk media can be easily changed mainly by changing the number of inner plates.
Further, since dust removing liners are respectively provided on the surfaces of the inner plate, the lower rotor, and the upper rotor that face the recording disk media, the dust resistance is excellent.
In addition, a stable rotation operation of the recording disk medium can be realized.

Next, embodiments of the present invention will be described in detail with reference to the drawings as appropriate. In this embodiment, a case where a magnetic disk medium is employed as an example of a recording disk medium will be described.
FIG. 1 is an exploded perspective view of a magnetic disk cartridge according to an embodiment. FIG. 2 is an external perspective view of the magnetic disk cartridge according to the embodiment. FIG. 3 is a perspective view showing the inner surface of the upper plate, and FIG. 4 is a sectional view taken along the line IV-IV in FIG. 2B of the magnetic disk cartridge loaded in the magnetic disk drive. FIG. 5 is a partially enlarged view of FIG. 4, and FIG. 6 is an exploded perspective view showing a laminated structure of magnetic disk media. In the following description, the upper and lower directions are based on the typical usage state of the magnetic disk cartridge, and the direction perpendicular to the surface of the magnetic disk medium is referred to as the upper and lower directions for convenience.

  As shown in FIG. 1, a magnetic disk cartridge 1 which is an example of a recording disk cartridge includes a lower plate 10 constituting a lower wall, a plurality of, for example, four inner plates 20, and an upper plate 30 constituting an upper wall. Are sequentially laminated, and these are fastened and fixed by four screws 91 to constitute the cartridge case 2 (see FIG. 2A). Magnetic disk media 41 are arranged between the lower plate 10 and the inner plate 20, between the inner plates 20, and between the inner plate 20 and the upper plate 30. The magnetic disk medium 41 has a disk shape having an opening 41a in the center, and a metal center core 42 is attached to the edge of the opening 41a. Then, the center cores 42 are engaged with each other by the spacers 43 and 43 'so that the five magnetic disk media 41 (the stacked and integrated magnetic disk media 41 is referred to as a disk stack 40) rotate integrally. ing.

  Each inner plate 20 is formed with ribs 22 in contact with the upper and lower plates on the outer peripheral edge of a flat main plate 21. A part of the inner plate 20 on the right front side in FIG. 1 is formed with a notch 23 so that the magnetic head 63 (see FIG. 4) can easily move onto the magnetic disk medium 41. The above-described rib 22 is not formed in the notch 23. Therefore, when the inner plate 20 is stacked, an opening 3 is formed on the side surface of the cartridge case 2 as shown in FIG.

  The opening 3 is opened and closed by a shutter 4 that rotates coaxially with the disk stack 40. As shown in FIG. 1, the shutter 4 is configured by combining a lower rotor 51 and an upper rotor 52.

  A dust removing liner 49 for removing dust adhering to the surface of the magnetic disk medium 41 is provided on the surfaces of the lower rotor 51, the inner plate 20, and the upper rotor 52 facing the recording disk media.

Next, each member will be described in more detail.
The lower plate 10 is configured such that ribs 12 that contact the lower surface side of the ribs 22 of the inner plate 20 and side walls 13 are formed on the outer peripheral edge of the substantially square main plate 11. The side wall 13 is erected in a predetermined range from one corner (the front side corner in FIG. 1) of the main plate 11, for example, about one third of one side, and the inner plate 20 is stacked approximately. It is formed at a height.

A fan-shaped portion from one side 11a (one side on the right front side in FIG. 1) connected to the side wall 13 of the main plate 11 toward the center of the main plate 11 forms a recessed portion 14a that is lowered by one step, and a rib 12 on the outer peripheral edge. Is not formed and is an opening 14. This makes it easy for the magnetic head 63 to enter the cartridge case 2.
Ribs 12 are formed so that the gear 51f of the lower rotor 51, which will be described later, can be exposed in a range of approximately one third of the other side 11b (one side on the left front side in FIG. 1) that continues to the side wall 13 of the main plate 11. Without opening 15. Further, a groove 13 a is formed on the outer side of the side wall 13 on the other side 11 b side so as to be continuous with the opening 15 and along the outer periphery of the lower plate 10. The groove 13a serves as a passage through which the shutter open gear 67 (see FIG. 2A) of the magnetic disk drive enters in the direction indicated by the arrow Ar in FIG. ing.

The rib 12 described above is formed so as to protrude upward over the entire outer periphery of the main plate 11 except for the side wall 13 and the openings 14 and 15.
In the center of the main plate 11, a circular opening 16 is formed for exposing the center core 42 provided in the lowermost magnetic disk medium 41. On the upper edge of the opening 16, a rib 17 is formed over the entire circumference so that a central opening 51 c formed at the center of the lower rotor 51 is fitted. The rib 17 supports the lower rotor 51 so as to be rotatable.
A circular lower rotor support groove 18 is formed at a position corresponding to the outer peripheral edge of the lower rotor 51 on the upper surface (inner surface) of the main plate 11. The lower rotor support groove 18 engages with a rib 51 d (see FIG. 4) formed downward on the outer peripheral edge of the lower rotor 51, so that the lower rotor 51 can be rotated coaxially with the magnetic disk medium 41. To support.
Further, screw holes 19 are formed in the four corners of the main plate 11 so as to penetrate vertically and have female threads.

The main plate 21 of the inner plate 20 has an approximately square shape, and a portion corresponding to one corner of the four corners of the square has an arc shape (arc portion 24) that is slightly larger than the magnetic disk medium 41. ing. And the above-mentioned notch 23 is fan-shaped in the one side (right front side in FIG. 1) which continues to the circular arc part 24. The aforementioned ribs 22 are formed so as to protrude up and down over the entire outer periphery of the main plate 21 excluding the arc portion 24 and the notch 23. At the center of the main plate 21, a central opening 21 c is formed to expose the upper center core 42 and enable connection with the lower center core 42.
In addition, holes 29 are formed in the three corners of the main plate 21 so as to penetrate the screw plate 91a of the screw 91 through the top and bottom.

The upper plate 30 is formed approximately symmetrically with the lower plate 10. As shown in FIG. 3, the upper plate 30 includes an approximately square main plate 31, a recess 34 corresponding to the recess 14 a, a rib 37 corresponding to the rib 17, and an upper rotor corresponding to the lower rotor support groove 18. A support groove 38 is formed. Note that no opening is formed in the center of the main plate 31 and no side wall corresponding to the side wall 13 is formed.
A rib 32 protruding downward is formed on the outer peripheral edge of the main plate 31 over the entire circumference except for the recess 34.
Further, holes 39 through which the screw shaft portions 91 a of the screws 91 pass are formed in the four corner portions of the main plate 31.

In the lower rotor 51, a central opening 51c, a notch 51e, a rib 51d, and a gear 51f are formed in a ring-shaped lower rotor plate 51a that is approximately the same as the magnetic disk medium 41, and a shutter plate 51b is provided on the outer peripheral edge of the lower rotor plate 51a. It is constructed upright. The central opening 51c is formed in a circular shape that is fitted on the rib 17, and the notch 51e is formed in a sector shape corresponding to the recess 14a. Further, the rib 51d is provided on the outer peripheral edge of the lower surface of the lower rotor plate 51a so as to correspond to the lower rotor support groove 18 downward.
The shutter plate 51b is a shielding member that blocks the opening 3 (see FIG. 2A) and the disk stack 40, and is erected along the outer peripheral edge of the lower rotor plate 51a adjacent to the notch 51e. . The gear 51f is a portion engaged to open and close the shutter 4 (see FIG. 2A) from the outside of the magnetic disk cartridge 1, and is adjacent to the shutter plate 51b on the outer periphery of the lower rotor plate 51a. Formed within a predetermined range.

The upper rotor 52 is configured approximately symmetrically with the lower rotor 51. That is, the upper rotor plate 52a is the same as the lower rotor plate 51a. The upper rotor plate 52a includes a central opening 52c that fits around the rib 37 of the upper plate 30, a notch 52e corresponding to the recess 34, and an upper rotor. Ribs 52d corresponding to the support grooves 38 are formed. A shutter groove 52 b is formed in a portion adjacent to the notch 52 e on the outer peripheral edge of the upper rotor plate 52 a so as to correspond to the shutter plate 51 b of the lower rotor 51. By engaging the shutter groove 52b and the upper edge of the shutter plate 51b, the lower rotor 51 and the upper rotor 52 rotate together.
The upper rotor 52 is rotatably supported by the upper plate 30 with the central opening 52c fitted on the rib 37 of the upper plate 30 and the rib 52d engaging the upper rotor support groove 38. The upper rotor 52 is prevented from dropping from the upper plate 30 by the locking member 53. The locking member 53 has a cylindrical portion 53a inserted into the rib 37 (see FIG. 3), and a flange 53b formed at one end of the cylindrical portion 53a. The cylindrical portion 53a opens from the lower side of the upper rotor 52 to the central opening. The portion 52c is inserted and fixed to the rib 37 by ultrasonic welding or an adhesive.

As shown in the enlarged sectional view of FIG. 5, the upper surface of the lower rotor 51, the upper and lower surfaces of the inner plate 20, and the lower surface of the upper rotor 52 are surfaces facing the magnetic disk medium 41. A dust-removing liner 49 is affixed across the opposing portions.
The liner 49 is made of, for example, a non-woven fabric such as polyester fiber or rayon / polyester blended fiber. In the present embodiment, the liner 49 is entirely made of a non-woven fabric made of the same kind of material. Each liner 49 has a circular shape corresponding to the shape of the magnetic disk medium 41, and has a sector-shaped notch 49a (corresponding to each notch 51e, 23, 52e of the lower rotor 51, the inner plate 20, and the upper rotor 52). 1). Each liner 49 of the lower rotor 51, the inner plate 20, and the upper rotor 52 may be formed of a combination of a woven fabric and a non-woven fabric, or a woven fabric.

  Such a liner 49 is usually attached by ultrasonic welding, an adhesive, a double-sided tape or the like. Further, examples of the welding pattern (welding line) by ultrasonic welding of the liner 49 include a vertical line, a horizontal line, a diagonal line, a radial wavy line, and the like in a lattice shape, a continuous line or a wavy line.

  Each liner 49 is formed in the same shape, so that the contact resistance between each liner 49 and the magnetic disk medium 41 is equalized. Here, if there is a difference in shape between the liners 49, the contact resistance will be different for each magnetic disk medium 41, which may affect the reliability during recording or reproduction. In contrast, in the present embodiment, the contact resistance during rotation of the magnetic disk medium 41 is kept equal, so that highly reliable recording or reproduction can be realized.

  In this embodiment, the liner 49 affixed to the lower rotor 51 and the upper rotor is formed to be thicker than the liner 49 affixed to the inner plate 20, and the lowermost and uppermost magnetic disk media 41. The clearance at has been adjusted. That is, the clearance of the lowermost layer and the uppermost recording disk medium, which may be less accurate than between the inner plates 20, can be adjusted by the thickness of the liner 49.

Here, as a method of forming the liner 49 thickly, it is common to increase the weight per unit area. However, the liner 49 may be formed by raising the side facing the magnetic disk medium 41. The raising by the raising process is preferably performed on the liner 49 having a loop-shaped fiber structure from the viewpoint of preventing the fibers from falling off. The raising treatment is preferably performed over the entire surface of the liner 49.
In addition, the liner 49 having a thickness by performing the raising process has a smaller contact resistance when the magnetic disk medium 41 is rotated than the liner 49 formed to be thick by increasing the weight per unit area. There is also an advantage that the drive torque of 41 is reduced.

  In addition, the thickness of the liner 49 subjected to the raising treatment can be adjusted by the degree of welding by the ultrasonic welding. In other words, if the number of welded portions is reduced, the portion where the liner 49 is not welded tends to rise (swell) from the attachment surface, and the clearance can be reduced as compared with the case where the number of welded portions is increased.

In addition, the liner 49 affixed on the lower rotor 51 and the upper rotor uses the fabric weight of a nonwoven fabric of 20-50 g / m < ² >, Preferably it is 30-40 g / m < ² >. This is because if it is less than 20 g / m ^2, it is too thin and easily broken, and if it exceeds 50 g / m ² , rotation of the magnetic disk medium 41 may be hindered. Therefore, it is desirable to set the dimensions and the like of each part so that the basis weight of the nonwoven fabric is within the above range.

Next, a laminated structure of the lower plate 10, the inner plate 20, and the upper plate 30 will be described.
As shown in FIG. 5, the rib 12 of the lower plate 10 is formed so that the inner side is one step higher than the outer side to form a male step 12 a. The rib 22 of the inner plate 20 forms a female step 22a protruding downward at the outermost periphery, and the outer periphery of the male step 12a and the inner periphery of the female step 22a can be fitted. ing. In addition, when the lower plate 10, the inner plate 20, and the upper plate 30 are fastened with screws 91 (see FIG. 1), the upper surface of the male step 12a and the corresponding portion of the lower surface of the inner plate 20 are in close contact with each other. It has become. In this way, the rib 12 of the lower plate 10 and the rib 22 of the inner plate 20 are so-called stamped and fitted, so that dust can be prevented from entering the cartridge case 2 from the outside.
Similarly, the inner plates 20 and the inner plate 20 and the upper plate 30 are also laminated by stamping. That is, the upper side of the inner plate 20 is formed with a male step portion 22b whose inner side is one step higher, and the rib 32 of the upper plate 30 is formed with a female step portion 32a whose outermost periphery protrudes downwardly by one step. Yes. Then, the male step 22b of the inner plate 20 and the female step 22a of the inner plate 20 adjacent on the upper plate 20 are inlayed, and the male step 22b of the inner plate 20 and the female of the upper plate 30 are female. The mold step 32a is laminated by stamp fitting. In this way, the ribs 12, 22, 32 are stamped together to prevent dust from entering the cartridge case 2 from the outside. Further, the side wall of the cartridge case 2 is formed simultaneously with the lamination of the lower plate 10, the inner plate 20, and the upper plate 30.

  The female step 22 a and the male step 22 b both protrude from the main plate 21 higher than the thickness of the liner 49. Therefore, even if the liner 49 is attached to the inner plate 20 to form an assembly, the liner 49 will not come into contact with the work table even if the assembly is placed on the work table. Therefore, the liner 49 is contaminated with dust or the like. There is nothing to do.

  Such a configuration of the cartridge case 2 by stacking the inner plates 20 makes it easy to change the number of magnetic disk media 41. Although it is necessary to change the height of the side wall 13 and the height of the shutter plate 51b, the number of accommodating portions of the magnetic disk media 41 formed in the cartridge case 2 is mainly changed only by changing the number of the inner plates 20. Because it can.

  By the way, the clearance between the lowermost magnetic disk medium 41 and the lower rotor 51 and the clearance between the uppermost magnetic disk medium 41 and the upper rotor 52 are assembling a plurality of magnetic disk media 41 as described above. It is formed so as to have a margin with a presumed cumulative error due to. Therefore, adjusting the clearance using the liner 49 as described above is particularly useful in the magnetic disk cartridge 1 in which a plurality of magnetic disk media 41 are stacked.

Next, the magnetic disk medium 41 and its laminated structure will be described.
The magnetic disk medium 41 is obtained by applying a magnetic paint on both sides of a resin sheet such as polyester.

  As shown in FIG. 6, the center core 42 is formed by drawing a metal plate with a press into a substantially hat shape. That is, it is mainly composed of a circular bottom plate 42a, a low cylindrical side wall 42b rising from the outer peripheral edge of the bottom plate 42a, and a flange 42c extending from the upper end of the side wall 42b in the outer diameter direction. A center hole 42d is formed at the center of the bottom plate 42a, and six small holes 42e are formed at intervals of 60 ° around the center hole 42d at the periphery.

The spacers 43 are interposed between the adjacent center cores 42 to maintain the distance between the center cores 42 and lock the rotation between the adjacent center cores 42 so that the stacked magnetic disk media 41 are integrated. And function to rotate. The spacer 43 includes a main body 43a formed of resin in a ring shape and a metal pin 43b press-fitted into the main body 43a. The main body 43a has a through-hole h formed of a small-diameter hole 43c into which the pin 43b is press-fitted and a large-diameter hole 43d that is coaxial with the small-diameter hole 43c and has a slightly large diameter. Are formed at positions corresponding to. The six through holes h are adjacent to each other upside down. That is, the through hole h2 adjacent to the through hole h1 where the large diameter hole portion 43d is located on the upper side is arranged so that the large diameter hole portion 43d is located on the lower side.
A pin 43b is press-fitted into each small diameter hole portion 43c from above and below, one end of the pin 43b is located at the boundary between the large diameter hole portion 43d and the small diameter hole portion 43c, and the other end to the outside of the small diameter hole portion 43c. It protrudes. The large-diameter hole 43d functions as a relief of the tip of the pin 43b of the adjacent spacer 43.

  Such a spacer 43 is interposed between the adjacent center cores 42 as shown in FIG. The pin 43b protruding to the lower side of the spacer 43 enters the small hole 42e of the lower center core 42 of the spacer 43 and locks relative rotation with the lower center core 42. When the spacer 43 is further below the lower center core 42, the spacer 43 is prevented from being lifted with respect to the center core 42 by entering the large-diameter hole 43 d in the lower spacer 43. The pin 43b protruding above the spacer 43 enters the small hole 42e of the upper center core 42 of the spacer 43 and locks the relative rotation with the upper center core 42. When the spacer 43 is further above the upper center core 42, the tip of the pin 43 b enters the large-diameter hole 43 d in the upper spacer 43.

  Since the uppermost center core 42 has no center core to be rotationally locked on the upper side, a thin top spacer 43 ′ with a pin 43 b protruding only on the lower side is disposed thereon.

The magnetic disk media 41 stacked as described above, that is, the disk stack 40, is stably supported by the connecting shaft 44, the bearing ball 45, the compression coil spring 46, and the center plate 47.
As shown in FIG. 5, the connecting shaft 44 is for reducing the center swing between the stacked center cores 42 and holding the bearing ball 45 and the compression coil spring 46. It consists of a ball holding part 44b and a spring holding part 44c. The shaft portion 44 a has a cylindrical shape that can be inserted into the center hole 42 d of the center core 42. The ball holding part 44b is formed in a bottomed cylindrical shape opening upward at the upper end of the shaft part 44a. The depth of the ball holding portion 44b is larger than the radius of the bearing ball 45, so that the bearing ball 45 is stably held by the ball holding portion 44b. The spring holding portion 44c has a shape in which a bottomed cylinder is turned down on the outer diameter side of the ball holding portion 44b, and a compression coil spring 46 is disposed in a cylindrical space between the shaft portion 44a and the spring holding portion 44c. Although the length of the connecting shaft 44 is arbitrary, in this embodiment, the length reaches the center core 42 of the second layer from the bottom, and the center hole 42d of the center core 42 in the lowermost layer is a magnetic disk drive. The spindle 65 is open for entry.

  The center plate 47 is a sliding member that is affixed to the center of the inner surface of the upper plate 30, that is, the planar portion inside the rib 37. The center plate 47 can be made of a material excellent in slipperiness and wear resistance, such as polyoxymethylene resin and ultrahigh molecular weight polyethylene.

  The bearing ball 45 is made of, for example, a steel sphere used for a ball bearing, but may be made of a resin excellent in slipperiness and wear resistance, such as polytetrafluoroethylene or polyoxymethylene resin. The bearing ball 45 is disposed in the ball holding portion 44b of the connecting shaft 44, and makes contact with the center of the bottom surface of the ball holding portion 44b and the inner surface of the upper plate 30, that is, the center plate 47, by point contact. Supports rotation.

  One end (upper end) of the compression coil spring 46 is held by the spring holding portion 44 c of the connecting shaft 44, and the other end (lower end) is in contact with the upper surface of the uppermost center core 42. , That is, the spindle 65 side of the magnetic disk drive. As a result, the center core 42 does not rattle in the cartridge case 2, and the magnetic disk medium 41 is prevented from shaking during rotation.

As shown in FIG. 4, the magnetic disk drive that records and reproduces data with respect to the magnetic disk cartridge 1 rotates the disk stack 40 by the spindle 65. The spindle 65 adsorbs the lowermost center core 42 by magnetic force and enters the center hole 42 d of the center core 42 to align the axis with the disk stack 40. At this time, since the spindle 65 slightly lifts the center core 42 against the urging force of the compression coil spring 46, each magnetic disk medium 41 includes the lower rotor 51, the inner plate 20, and the like as shown in FIGS. It is located at the center of the space formed between the upper and lower inner plates 20 or between each of the inner plate 20 and the upper rotor 52. In other words, the magnetic disk media 41 are kept substantially the same in clearance with the liner 49 on the upper and lower surfaces.
A magnetic head 63 of the magnetic disk drive is provided at the tip of the swing arm 62. The magnetic head 63 is disposed on both surfaces of each magnetic disk medium 41.

In the magnetic disk cartridge 1 as described above, as shown in FIG. 2 (a), when not in use, the shutter 4 is rotated counterclockwise in the figure to close the opening 3, and FIG. As shown, the disk stack 40 is pressed toward the opening 16 side of the lower plate 10 by the compression coil spring 46 provided on the connecting shaft 44, and the lowermost center core 42 is pressed against the lower plate 10 (lower rotor 51). By effectively closing the opening 16, it is possible to prevent dust from entering the inside. In use, as shown in FIG. 2B, when the magnetic disk drive is loaded, the shutter open gear 67 of the magnetic disk drive is guided by being fitted in the groove 13a and meshed with the gear 51f. Turn clockwise in the figure.
Then, as the spindle 65 rotates, the disk stack 40 rotates. Thereafter, the swing arm 62 is rotated by being driven by the actuator 61, and the magnetic head 63 is moved onto the magnetic disk medium 41.

When data is recorded on the magnetic disk medium 41 by the magnetic head 63, data is recorded on the magnetic disk medium 41 by sending a signal to the magnetic head 63 by a control circuit (not shown), and the data is recorded from the magnetic disk medium 41. In reproduction, the magnetic head 63 detects a magnetic field change on the magnetic disk medium 41 and outputs a signal.
At this time, the dust on the magnetic disk medium 41 is removed by the liner 49 appropriately touching the magnetic disk medium 41.

  After the magnetic disk cartridge 1 is used, after the magnetic head 63 is retracted from the cartridge case 2, the magnetic disk cartridge 1 is ejected, whereby the gear 51 f is driven by the shutter open gear 67 and the shutter 4 closes the opening 3. .

Since the magnetic disk cartridge 1 has the plurality of magnetic disk media 41 as described above, data can be transferred at high speed by simultaneously accessing data with the plurality of magnetic heads 63.
In addition, since the cartridge case 2 is configured by stacking the inner plates 20, it is easy to change specifications so that the number of magnetic disk media 41 is different. When the magnetic disk cartridge 1 is assembled, the magnetic disk medium 41 can be mounted and handled on the inner plate 20 or the lower rotor 51 assembled to the lower plate 10. Can be made more stable.
Since the inner plate 20 is laminated and fixed on the lower plate 10 or the inner plate 20, the parallelism with the magnetic disk medium 41 can be increased, and the rotation of the magnetic disk medium 41 can be stabilized. In addition, the magnetic disk medium 41 can be rotated at a high speed, and hence the data transfer speed can be increased.

  Since the liner 49 is provided on the surface of the inner plate 20 facing the magnetic disk medium 41 and the surface of the lower rotor 51 and the upper rotor 52 facing the magnetic disk medium 41, the liner 49 adheres to the surface of the magnetic disk medium 41. The dust removing effect is high, the surface is always kept clean, and the magnetic disk cartridge 1 having excellent dust resistance can be obtained. Therefore, it is possible to avoid the occurrence of a data error at the time of recording or reproduction of the magnetic disk medium 41, and the reliability can be improved.

  Further, since the clearance between the lower rotor 51 and the magnetic disk medium 41 and the clearance between the upper rotor 52 and the magnetic disk medium 41 are respectively adjusted by the thickness of the liner 49, the clearance is temporarily assumed in the assembled state. Even if there is a difference between the two, this can be solved by adjusting the thickness of the liner 49. As a result, it is possible to avoid the occurrence of surface shake or the like in the lowermost layer and the uppermost magnetic disk medium 41, and a stable rotation operation of the magnetic disk medium 41 can be realized.

Although the embodiment of the present invention has been described above, the present invention is not limited to the above-described embodiment, and can be appropriately modified and implemented. For example, in the embodiment, the magnetic disk medium 41 is applied as the recording disk medium, but the present invention can be similarly applied to an optical disk medium that records data by light.
In the embodiment, the lower plate 10, the inner plate 20, and the upper plate 30 are fastened and fixed by the screws 91. However, they can be fixed integrally by adhesion or welding.
Further, in the above-described embodiment, the clearance between the lower rotor 51 and the magnetic disk medium 41 and the clearance between the upper rotor 52 and the magnetic disk medium 41 are respectively adjusted by the thickness of the liner 49. However, the present invention is not limited to this. However, the clearance between the other liner 49 and the magnetic disk medium 41 may be adjusted by the liner 49.
In the magnetic disk cartridge 1 of the above embodiment, the lower rotor 51 and the upper rotor 52 are provided. However, the present invention is not limited to this. For example, the side of the cartridge case 2 is not slidable. By providing a shutter, the lower rotor 51 and the upper rotor 52 may be excluded. In this case, the liner 49 can be configured to be attached to the inner surfaces of the lower plate 10 and the upper plate 30. Accordingly, the clearance between the lowermost layer and the uppermost magnetic disk medium 41 can be suitably adjusted by forming the liner 49 thick.

1 is an exploded perspective view of a magnetic disk cartridge according to an embodiment. FIG. 2A is a perspective view of an external appearance of a magnetic disk cartridge according to an embodiment, and FIG. 3B shows a state in which the shutter is closed, and FIG. It is a perspective view which shows the inner surface of an upper plate. FIG. 4 is a cross-sectional view taken along the line IV-IV in FIG. 2B of the magnetic disk cartridge loaded in the magnetic disk drive. It is the elements on larger scale of FIG. It is a disassembled perspective view which shows the laminated structure of a magnetic disc medium.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Magnetic disk cartridge 2 Cartridge case 3 Opening part 4 Shutter 10 Lower plate 20 Inner plate 23 Notch 30 Upper plate 34 Opening 40 Disk stack 41 Magnetic disk media 42 Center core 43 Spacer 44 Connecting shaft 45 Bearing ball 47 Center plate 49 Liner 49a Notch 51 Lower rotor 52 Upper rotor 61 Actuator 62 Swing arm 63 Magnetic head 65 Spindle

Claims (4)

A recording disk cartridge in which a plurality of flexible recording disk media are housed in a cartridge case so as to be integrally rotatable,
The cartridge case includes a lower plate constituting a lower wall parallel to the recording disk medium, at least one inner plate stacked and fixed on the lower plate to partition the plurality of recording disk media, and the inner case An upper plate which is stacked and fixed on the plate to form an upper wall of the cartridge case, and a dust removal liner provided on a surface facing the plurality of recording disk media,
A recording disk cartridge, wherein a clearance between the plurality of recording disk media and a surface facing the plurality of recording disk media is adjusted by a thickness of the liner.   Of the plurality of recording disk media, the liner provided opposite to the recording disk medium in the lowermost layer and the uppermost layer is formed thicker than the liner provided opposite to the other recording disk media. The recording disk cartridge according to claim 1, wherein the recording disk cartridge is a recording disk cartridge.   3. The recording disk cartridge according to claim 1, wherein the liner is a combination of a woven fabric and a non-woven fabric, or a woven fabric or a non-woven fabric.   The recording disk cartridge according to any one of claims 1 to 3, wherein the liner is brushed.

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