RU2432626C2 - Disc cartridge - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: disc cartridge comprises a jacket, an inner rotor, gate elements, and a buffer device. In the jacket there is a disc-shaped record medium arranged capable of rotation and formed with the first hole. The hole opens a part of the disc-shaped record medium. The internal rotor is installed with the possibility of rotation inside the cartridge jacket and includes a section of the main surface formed with the second hole, which complies with the first hole. The gate elements move between the closed position, in which the first hole is closed, and the open position, in which the first hole is opened, in compliance with the inner rotor rotation. The buffer device is formed on the section of the main surface of the inner rotor, and includes rotary pins, which retain gate elements with the possibility of rotation, and elastic sections of fixation, which, accordingly, support the rotary pins and may be elastically deformed relative to the section of the main surface.

EFFECT: increased stability to shocks during falls.

17 cl, 23 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a cartridge for a disk, including an internal rotor that is rotatably mounted inside the cartridge case, and a shutter device for opening and closing an opening formed in the cartridge case in accordance with the rotation of the inner rotor.

State of the art

In recent years, a disk cartridge in which a disc-shaped recording medium such as an optical disk, a magneto-optical disk and a magnetic disk is rotatably mounted is widely used. Typically, a cartridge for a disc allows you to record and / or play information signals, including music signals, video signals and programs. As such a disk-shaped recording medium on which information signals can be recorded, for example, a write-once disc and a rewritable disc on which rewriting is possible are known.

For example, Patent Document 1 describes a cartridge for a disk, including a cartridge case formed by superposing a pair of shells, an internal rotor that forms a camera for accommodating a disk inside the cartridge case, an optical disk mounted to rotate in the camera to accommodate the disk, and a pair of shutter elements designed to open and close part of the hole provided in the cartridge housing, in accordance with the rotation of the inner rotor.

In a conventional disk cartridge described above, a pair of shutter elements includes pin sections that are mounted in support holes formed on a flat portion of the inner rotor. By installing these sections of the pin in the support holes, it is possible to rotate around the respective rotating pins. In addition, part of the hole in the cartridge casing is closed by means of shutter elements that are rotated in the direction in which they are brought close to each other, and part of the hole is opened when a pair of shutter elements are rotated in the direction in which they are parted from each other.

Patent Document 1: Japanese Patent Application Laid-Open No. 2001-332057.

SUMMARY OF THE INVENTION

The tasks solved by the invention

Typically, in a conventional disk cartridge described above, when the cartridge is impacted, for example due to a fall, there is a risk that portions of the pins of the shutter members may fall out of the support holes of the inner rotor. When the engagement operation between the inner rotor and the portions of the pins cannot be supported as described above, it becomes impossible to perform the required control of the rotation of the portions of the shutter, as a result of which the disk cartridge becomes unusable.

On the other hand, there is a method of sealing under the action of heat the connection of the tip of the pin sections of the shutter elements mounted in the support holes of the inner rotor for reliable engagement between the inner rotor and the shutter elements. Since a cornice section is formed at the tips of the pin sections that does not allow the pin section to be removed from the support holes due to heat sealing, the adhesion force between the inner rotor and the shutter elements can be improved.

However, the portion of the cornice formed on the tip of the sections of the pins, as a result of compaction under the influence of heat, is unlikely to provide sufficient strength, and, depending on the impact force acting on the cartridge for the disk, the portion of the cornice may be damaged, and the elements of the pins may thus disconnect from the inner rotor. In this case, the reliability of the disk cartridge is significantly impaired.

In view of the circumstances described above, an object of the present invention is to provide a disk cartridge having high impact resistance during a fall.

Means of solving the problem

In order to achieve the above objective, in accordance with the present invention, there is provided a disk cartridge including a disk-shaped recording medium, a cartridge case, an internal rotor, a shutter and a buffer device.

A disk cartridge in which a disk-shaped recording medium is rotatably disposed, and which is formed with a first hole that opens a portion of the disk-shaped recording medium.

The inner rotor is rotatably mounted inside the cartridge housing and includes a main surface portion formed with a second hole corresponding to the first hole.

The damper can move between the closed position in which the first hole is closed and the open position in which the first hole is open, in accordance with the rotation of the inner rotor.

The buffer device is formed on a portion of the main surface of the inner rotor and includes a rotating pin that rotatably holds the shutter, and an elastic holding portion that supports the rotating pin and can be elastically deformed relative to the portion of the main surface.

In the casing of the cartridge, due to the presence of a buffer device, a rotating pin that rotatably holds the shutter relative to the inner rotor is resiliently fixed relative to the inner rotor. Therefore, it becomes possible to reduce the voltage applied to the connection portion between the inner rotor and the shutter when impact is applied to it during a fall, and to prevent the pin from being disconnected from the inner rotor. Accordingly, the strength of the opening / closing mechanism of the shutter when subjected to impact caused by a fall can be improved, and the reliability of the disk cartridge can be improved.

The elastic fastening portion can be formed as a single part with a portion of the main surface of the inner rotor. In this case, the elastic fastening portion can be separated from the main surface portion by a slot formed on the main surface portion of the inner rotor. With this design, it becomes possible to easily form a portion of the elastic mount on the portion of the main surface. It also becomes possible to impart the required elastic force to the elastic fastening section, depending on how this slot is formed.

The rotating pin can be formed as a single part with a section of elastic fastening at its tip. Accordingly, since the elastic deformation characteristics of the shutter relative to the inner rotor are improved, a shock that acts on the rotating pin can be absorbed efficiently.

The disk cartridge may further include a first engagement portion formed on the tip of the rotating pin and a second engagement portion that is formed on the shutter and engages with the first engagement portion. The second engagement portion is disconnected from the first engagement portion in a state where the elastic attachment portion is elastically deformed by a predetermined amount or more. The amount of elastic deformation of the section of elastic fastening with a given value or more can be set equal to a value exceeding the maximum value of the deformation of the section of elastic fastening of the casing for the cartridge. Accordingly, it becomes possible to constantly maintain an engagement relationship between the first engagement portion and the second engagement portion after the internal rotor and the shutter are installed in the cartridge case.

A second engagement portion may be formed in the portion of the inner contour of the hole into which the rotating pin is inserted. Accordingly, the second engagement portion may be engaged with or may be disengaged from the first engagement portion in a state where the elastic attachment portion is elastically deformed by a predetermined amount or more.

The damper may consist of a pair of damper elements that rotate between a first position in which a pair of damper elements constitutes a closed position when they are brought close together and a second position in which a pair of damper elements constitutes an open position in which they are spaced apart friend. In this state, the buffer device is integrally formed on a portion of the main surface with a pair of shutter elements. Accordingly, since the shutter elements are detached from the inner rotor, the stability of the shutter opening / closing device when exposed to impact during a fall can be improved, and the reliability of the disk cartridge can be improved.

The disk cartridge may further include an engagement device. An engagement device is provided between the cartridge housing and the shutter and maintains an engaged state between the cartridge housing and the shutter when the shutter is in the closed position. Accordingly, since the relative movement of the shutter relative to the cartridge case is limited when it is impacted upon falling, the voltage applied to the rotary shutter pin can be reduced, and the shutter can be disconnected from the inner rotor. In addition, the reliability of the opening / closing device of the shutter when subjected to impact caused by a fall can be improved, and the reliability of the disk cartridge can be improved.

The engaging device may disengage the cartridge housing and the shutter when the shutter moves to the open position from the closed position. Accordingly, a device for disengaging between the cartridge housing and the shutter becomes unnecessary, and it becomes possible to engage with the cartridge housing and disengage the cartridge housing using the normal operation of turning the shutter.

One embodiment of the engagement device may include an engagement protrusion and an engagement groove. The engagement protrusion is formed on the shutter and has an arcuate shape corresponding to the direction of rotation of the shutter. An engagement groove is formed on a portion of an edge of the first hole and has an arcuate shape that allows the engagement protrusion to be placed therein. In addition, the engagement protrusion is provided in close proximity to the center of rotation of the shutter, relative to the inner rotor.

The inner rotor may include a toroidal circular wall portion and a joint portion. A circular wall portion is formed on one surface of the main surface portion. The joint portion is located in the portion where the second hole of the portion of the round wall portion is formed. The engagement portion includes a first end surface on a main side of a portion of a main surface that is formed with a first width, and a second end surface on a different side of a side of a portion of a main surface that is formed with a second width smaller than the first width. In addition, the cartridge housing includes a guide groove. The guide groove engages in sliding with the connecting portion by the side of the second end surface and directs the rotation rotation of the inner rotor relative to the cartridge case. Due to this increase in the width of the formation of the connecting portion on the side of the first terminal surface, the mechanical strength of the connecting portion can be improved. As a result, it is possible to improve the stability of the connecting portion when exposed to impact when dropped, and the reliability of the cartridge can be improved.

In addition, the connecting portion engages with sliding in a guide groove formed on the inner surface of the cartridge casing together with the circular wall portion that directs its rotation operation relative to the cartridge casing. Due to the fact that the connecting portion engages with the guide groove on the side of the second end surface, the present invention can be implemented without changing the width of the groove in the lower portion of the guide groove. In this case, the inner surface of the side wall of the guide groove may be formed as a wedge-shaped or curved surface, which corresponds to the cross-sectional shape of the connecting section.

The guide groove may have an inner surface configuration corresponding to an outer surface configuration of the connecting portion. As one embodiment, the connecting portion includes an outer circumference and an inner circumference, and at least one of the circumference and the inner circumference is formed as a wedge-shaped or curved surface. Accordingly, the first end surface may be formed with a greater width than the second end surface.

In addition, in accordance with another embodiment of the present invention, there is provided a cartridge for a disk, including: a disk-shaped recording medium; a casing for a cartridge in which a disk-shaped recording medium is rotatably disposed, and which is formed with a first hole that opens a portion of the disk-shaped recording medium; an internal rotor that is rotatably mounted inside the cartridge housing and includes a second hole corresponding to the first hole; a shutter that moves between the closed position in which the first hole is closed and the open position in which the first hole is open, in accordance with the rotation of the inner rotor; and a buffer device that is formed on the main surface of the shutter and includes a rotating pin that rotatably supports the shutter relative to the inner rotor, and an elastic fastening portion that holds the rotary pin and can elastically deform relative to the main surface.

Also, using such a structure, the same operation and effect can be achieved as described above.

Effect of the invention

As described above, in accordance with the present invention, since the shutter detachment from the inner rotor can be effectively prevented, impact resistance upon falling can be improved, and the reliability of the disk cartridge can be improved.

Brief Description of the Drawings

Figure 1. A perspective view from the side of the upper shell of a disk cartridge in accordance with an embodiment of the present invention.

Figure 2. Perspective view with exploded view of disk cartridge parts.

Figure 3. A perspective view of a disk cartridge from the bottom shell side.

Figure 4. Top view from the side of the inner surface of the upper shell constituting the disk cartridge.

Figure 5. Top view from the side of the inner surface of the lower shell constituting the disk cartridge.

6. A perspective view of an internal rotor constituting a disk cartridge.

7. Cross section diagram of a cartridge for a disk.

Fig. 8. A top view representing a state in which the inner rotor rotates in a direction in which the opening of the lower shell is closed.

Fig.9. A top view representing a state in which the inner rotor rotates in a direction in which the opening of the lower shell is open.

Figure 10. A perspective view of a pair of shutter members constituting a shutter of a disk cartridge.

11. A perspective view representing a state in which an opening of an internal rotor is opened by a shutter.

Fig. 12. A perspective view representing a state in which the bore of the inner rotor is closed by a shutter.

Fig.13. A top view of the main areas within the cartridge case, a plan view representing a state in which the first opening of the cartridge case is closed.

Fig.14. A top view of the main areas within the cartridge case, a top view representing a state in which the first opening of the cartridge case is open.

Fig.15. A diagram illustrating a portion of the center of rotation of the shutter formed on the inner rotor, in which (A) represents a portion of a flat surface, and (B) represents a cross-sectional diagram.

Fig.16. Schemes illustrating a portion of the center of rotation formed on the shutter, in which (A) is a plan view and (B) is a cross-sectional diagram.

Fig.17. A cross-sectional diagram representing a process performed with main sections to explain the task of installing a shutter on an internal rotor.

Fig. 18. A perspective view of the main sections to explain the task of installing the shutter on the inner rotor.

Fig.19. A perspective view of the engagement protrusion formed in close proximity to a portion of the center of rotation of the damper.

Fig.20. A perspective view of an engagement groove that is formed on an inner surface of a cartridge housing and that engages with an engagement protrusion.

Fig.21. A cross-sectional diagram representing an enlarged state between the engagement protrusion and the engagement groove.

Fig.22. Cross-sectional diagrams of the connection of the inner rotor engaged with the guide groove of the cartridge case.

Fig.23. Cross-sectional diagrams representing another constructive example of a connecting portion of an inner rotor.

Description of Reference Number Numbers

1 disk cartridge

2 cartridge case

3 optical disc

4 inner rotor

5a, 5b elements of the shutter

6 upper shells

7 lower shells

7a, 7b half shell details

23 first hole

41 ring section (round wall section)

41a connecting section

42 second hole

49a, 49b holding pin (rotatable pin)

50a, 50b pin hole

55 slot

56 elastic holding portion

57 first engagement portion

58 second engagement portion

59 engagement protrusion

60 engagement groove

DETAILED DESCRIPTION OF THE INVENTION

An embodiment of the present invention will be described below with reference to the drawings.

Each of FIGS. 1-3 shows a cartridge for the disc as a whole, in accordance with an embodiment of the present invention. In particular, FIG. 1 shows a perspective view of a disk cartridge from an upper shell side, FIG. 2 shows a perspective view with an exploded view of parts of a disk cartridge, and FIG. 3 shows a perspective view of a disk cartridge from a lower side shell.

The cartridge 1 for the disk in accordance with this embodiment is configured to rotate the optical disk 3 inside the casing 2 of the cartridge. In particular, the disk cartridge 1 includes, inside the cartridge case 2, an optical disk 3, an inner rotor 4 (an intermediate shell), and a pair of shutter members 5a and 5b.

As shown in FIG. 2, the optical disk 3 includes, in its central portion, a central hole 3a that is connected to the disk drive device in rotation on the side of the recording / reproducing device. Various disk-shaped recording media can be represented as an example, as an optical disk 3. As a disk-shaped recording medium, as an example, an optical disk, intended only for playback, on which various information signals, such as music signals, are preliminarily recorded, can be represented. like audio information, image signals such as video signals, and music signals. In addition, as a disk-shaped recording medium, as an example, it is possible to imagine an optical disc with a write once onto which such information signals can be recorded only once, and a rewritable optical disc to which information can be repeatedly rewritten can be presented as an example. It should be noted that as a disk-shaped recording medium, in addition to the optical disk 3 described above, a magneto-optical disk and a magnetic disk can be presented as an example.

As for the optical disc 3, optical beams having a wavelength of approximately 400 nm can be used for recording and / or reproducing information, and lenses having a larger digital aperture than the lenses used for CD or DVD can be used as lenses lens for picking up optical information. Accordingly, still image data, moving image data, melody data, processing data processed by a computer, and the like. can be recorded at a higher density than with a CD or DVD.

As shown in FIG. 3, the disk cartridge 1 according to this embodiment is formed on the lower surface of the cartridge case 2 from its front side to the rear side, with a first opening 23 for recording and / or for reproduction. The first hole 23 provides the possibility of recording or reproducing an optical disk 3 using two optical data pickup heads when a part of the signal recording surface of the optical disk 3 is opened when the disk cartridge 1 is installed in the installation area of the recording / reproducing device and the optical head is inserted into the casing 2 of the cartridge both from its front side and from the back side. As a result, an increase in the speed or reading of the information signal can be realized.

The casing 2 of the cartridge consists of an upper shell 6 and a lower shell 7 (7a, 7b), which is divided in half and brought together with the upper shell 6. Figure 4 shows a bottom view representing the internal structure of the upper shell 6, and figure 5 shows a plan view representing the internal structure of the lower shell 7.

The upper shell 6 constituting the upper surface of the cartridge case 2 is formed using injection molding of a thermoplastic resin material such as acrylonitrile butadiene styrene (ABS, ABS) and polycarbonate. As shown in figure 4, the upper shell 6 is formed so that among the main surface, formed essentially in the form of a rectangle, in general, its front side on the side of the end of the insert relative to the recording / reproducing device 1 is formed essentially as arc. In addition, in the upper shell 6, the wall 8 of the outer circumference constituting the lateral surface of the casing 2 of the cartridge, a free section of the outer edge of the circumference of the main surface is formed.

In addition, an almost toroidal inner circular wall 11 is formed on the inner peripheral side of the outer circular wall 8, which constitutes a rotational portion of the disk for receiving the optical disk 3. The inner round wall 11 constitutes the side wall of the disk placement portion for receiving the optical disk 3, together with the inner rotor 4.

On the side of the outer contour of the inner circular wall 11, a vertical wall 10 is formed that surrounds the inner circular wall 11. A guide groove 13, which is substantially toroidal, is formed between the inner circular wall 11 and the vertical wall 10. The inner rotor 4 is rotatably engaged with guide groove 13.

In addition, in the immediate vicinity of the corner portion of the upper shell 6, a plurality of positioning pins 14 are formed, used to connect with the lower shell 7. A screw hole is formed in the central portion of each of the positioning pins 14 to screw a screw therein.

On the other hand, the lower shell 7 includes half shell shells 7a and 7b obtained by dividing the lower shell 7 in half, as shown in FIGS. 2, 3 and 5. When connected to the upper shell 6 of the shell body, the half shell 7a and 7b comprise the lower surface of the casing 2 of the cartridge. It should be noted that in the description below, the half-shell bodies 7a and 7b are also collectively called the lower shell 7.

Similarly to the upper shell 6 described above, the lower shell 7 is formed by injection molding a thermoplastic polymer resin material such as acrylonitrile butadiene styrene (ABS) and polycarbonate. The front sides of the shell-shaped housings 7a and 7b are formed substantially in the form of an arc so that they approximately correspond to the arc shape of the upper shell 6 on the front side. On the semicircular housings 7a and 7b, an outer circular wall 21 constituting the side surface of the cartridge case 2 is formed along the outer circumference of the main surface.

In addition, the corner walls 24, which make up approximately an arc, are formed on the corresponding corner sections of the lower shell 7. The corner walls 24 have a structure that allows them to be placed on the outside of the inner circular wall 11 of the upper shell 6 when the parts 7a and 7b are in the shape of the half-shells is brought together with the upper shell 6. In accordance with this, the ingress of foreign substances into the disk placement area is effectively prevented.

The approximately cylindrical concave positioning sections 22 into which the positioning pins 14 of the upper shell 6 described above are respectively mounted are formed so that they protrude from the lower shell 7. A through hole is formed in the lower surface portion of each of the concave sections 22 of the positioning, in which insert the screw. The upper shell 6 and the semi-shell parts 7a and 7b of the lower shell 7 are connected by bringing the outer round wall 8 on the side of the upper shell 6 and the outer round wall 21 of the half-shell parts 7a and 7b, which together comprise the lower shell 7, positioning pins 14 for positioning on the upper shell side 6 into the concave sections 22 of setting the position on the side of the lower shell 7, and screwing the screws into each of the screw holes in the positioning pins 14 through the through holes of the concave sections 22. Accordingly, burn 2 cartridges.

The casing 2 of the cartridge is formed with, between the parts 7a and 7b of the half-shells making up the lower shell 7, on its lower surface, a first recording and / or reproducing hole 23 through which the first and second optical heads of the recording / reproducing device and the rotary disk are mounted, which constitutes a rotation mechanism of the recording / reproducing device. The first hole 23 is made up of a hole 23a through which a first optical head is mounted on the side of the recording / reproducing device of the front side of the cartridge case 2, a hole 23b in which a second optical head is mounted on the side of the recording / reproducing device of the back side of the cartridge case 2, and holes 23c for driving a rotary disk provided in a substantially central position on the underside of the cartridge case 2, between the hole 23a and the hole 23b. In particular, the holes 23a and 23b are formed large enough to install the first and second optical heads of the recording / reproducing device in the cartridge case 2, and the hole for the drive to rotate the disk is formed large enough so that the rotary disk constituting the drive mechanism of the disk into the rotation of the recording device / playback, could be installed in the casing 2 of the cartridge.

Then, as shown in FIG. 2, the cartridge case 2 is secured with a retainer element 26 to an angular portion of the front side of the half-shell part 7a constituting the lower shell 7. The retainer element 26 blocks the rotation of the inner rotor 4 when the inner rotor 4 and the pair of elements 5a and 5b, the gate valves, which will be described later, are installed in the closed position, in which the first opening 23 of the cartridge case 2 is closed. In particular, the latch member 26 includes a pin hole 27 that rotatably connects with a holding pin 25 formed on an angular portion of the front side of the half shell part 7a constituting the lower shell 7, the work piece 28 elongated in the direction of one of the side surface portions the casing 2 of the cartridge from the hole 27 for the pin, and the locking part 29, elongated in the direction of the inner rotor 4 from the hole 27 of the pin.

As shown in FIGS. 2 and 5, a working protrusion 28a is formed on the tip portion of the workpiece 28, extending beyond the blocking hole 28b formed on one of the portions of the side surfaces of the cartridge case 2. In addition, at the end portion of the blocking part 29, a blocking protrusion 29a is provided which is in sliding contact with the ring portion 41 of the inner rotor 4.

A locking member 26 is also attached to the holding pin 25, as described above, a biasing member 30, such as a torsion coil spring. One lever of the bias element 30 is fixed on the outer round wall 21, and another lever thereof is fixed on the latch element 26. Accordingly, the lug protrusion 29a is biased towards the side of the inner rotor 4 and engaged with the second concave engagement portion 45 of the inner rotor 4 (FIG. 6). Then, when the working protrusion 28a of the working part 28 is pressed, the latch member 26 moves in a direction in which the latch part 29 moves further from the annular portion 41 of the inner rotor 4, overcoming the biasing force of the biasing member 30, and thus, the engaged state between the locking protrusion 29a and the second concave engagement portion 45.

In addition, as shown in FIG. 3, a guide groove 31 is formed in one of the portions of the lateral surface of the cartridge case 2 to prevent the cartridge 1 from being erroneously inserted into the recording / reproducing apparatus, which extends from the front side to the rear side. On the lower surface portion of the guide groove 31, there is a fixing hole 28b through which the working protrusion 28a of the retainer element 26 described above and the rotor hole 28c through which the portion of the outer circumference of the inner rotor 4 is opened are formed in this order from the front side.

As shown in FIG. 2, on the inner surface of the lower shell 7, the guide pins 32, which respectively are connected to the guide holes 53 provided as long holes on the shutter elements 5a and 5b, which will be described later, are formed so that they pass through them, and are approximately cylindrical in shape. The guide pins 32 move along the guide holes 53 in accordance with the rotation of the inner rotor 4, and thus provide a corresponding rotation of the shutter members 5a and 5b around the pin holes 50a and 50b.

On the lower surface of the cartridge case 2, which constitutes the lower shell 7, a plurality of positioning holes 33a and 33b are provided for positioning during installation in the recording / reproducing apparatus, as shown in FIG. One of the positioning holes 33a is designed as a perfect circle and functions as a positioning hole, while the other positioning holes 33b is oval and acts as an alignment hole. In addition, a concave portion 34 with the front side and the bottom surface open is provided at one of the corner portions on the front side of the cartridge case 2, thereby constituting an identification portion for a disk cartridge having substantially the same external shape, but different recording format. It is also possible to fulfill the function of the concave portion 34 of the guide groove when inserting or positioning grooves by engaging the guide pin with it during insertion of the recording / reproducing device.

Next, the structure of the inner rotor 4 will be described. FIG. 6 shows a perspective view of the inner rotor 4 in a view from the bottom surface side. In addition, FIG. 7 is a schematic cross-sectional view showing main portions of a disk cartridge 1.

The inner rotor 4 is formed by injection molding a thermoplastic material from a polymer resin such as polyoxymethylene (POM, POM). An optical disk 3 is placed on a portion 4 a of the main surface of the inner rotor 4 so that it faces the signal recording surface 3 a. When the main surface portion 4a is located inside the cartridge main body 2, as shown in FIG. 7, the inner round wall 11 of the upper shell 6 and the main surface portion 4a of the inner rotor 4 constitute the disk placement portion 15 (FIG. 7).

The inner rotor 4 is formed so that it is made essentially round, as shown in Fig.6 and formed, on its portion of the outer circular edge, with a substantially toroidal annular portion (portion of the outer circular wall) 41, which engages with the guide groove 13 the upper shell 6 described above. Due to the fact that the annular portion 41 engages with the guide groove 13 of the upper shell 6, the inner rotor 4 is supported to rotate inside the casing 2 of the cartridge.

As shown in FIG. 6, the inner rotor 4 is formed with a second hole 42, substantially the same size as the first hole 23 formed on the lower shell 7. The annular portion 41 in which the second hole 42 is provided occupies the same area, as the connecting section 41A. The connecting portion 41a includes a first end surface located on the side of the portion 4a of the main surface of the inner rotor 4, and a second end surface located on the outside of the main surface portion 4a. The connecting portion 41a is engaged with the guide groove 13 on the side of its second end surface.

FIG. 22 (A) is a schematic cross-sectional view of a connecting portion 41a that is engaged with the guide groove 13. FIG. 22 (B) is a schematic cross-sectional view of a connecting portion 141a of a conventional construction, shown as a comparative example. The conventional connecting portion 141a is formed in such a way that the upper surface (first terminal surface) and the lower surface (second terminal surface) in the drawing are the same width, and the side surfaces 141s on the inner and outer edges are formed vertical relative to the main surface of the upper shell 6. C on the other hand, the connecting portion 41a in this embodiment, as shown in the drawing, is formed so that the upper surface (first terminal surface) is wider, it lower surface (second end surface). In particular, the side surface 41s1 on the outer edge side of the connecting portion 41a is wedge-shaped, and the side surface 41s2 on the inner edge side is formed vertical. Since the width of the formation of the lower surface (the width of the second formation) is the same as the width of the formation of the lower surface of the conventional connecting portion 141a, the cross-sectional area of the connecting portion 41a is larger than that of the conventional connecting portion 141a. As a result, the connecting portion 41a in this embodiment has greater mechanical strength than the connecting portion 141a having a conventional structure, and impact resistance during a fall is thus improved compared with the prior art.

In addition, since the cross-sectional area of the connecting portion 41a is increased, the formability of the connecting portion 41a can also be improved. Therefore, the inner rotor 4 can be molded with the required molding accuracy.

Furthermore, since the lower surface of the connecting portion 41a is formed with the same width as that of the conventional connecting portion 141a, the upper shell 6 can be formed without changing the width of the groove in the lower portion of the guide groove 13. Accordingly, since it becomes unnecessary to extend the interval formation between the inner round wall 11 and the vertical wall 10, it is possible to prevent a decrease in the strength of the upper shell 6. In this case, the cross-sectional shape of the groove guide 13 can be made ac to match the sectional shape of the connecting portion 41a. In the example shown in Fig. 22 (A), the surface of the inner contour of the vertical wall 10 on the side of the outer contour is wedge-shaped. As a result, the connecting portion 41a can be stably held in the groove guide 13.

FIG. 23 is a schematic cross-sectional view showing modified examples of shapes of the connecting portion 41a and the guide groove 13. FIG. 23 (A) shows an example in which both side surfaces 41s1 and 41s2 on the inner and outer contours of the connecting portion 41a are formed with a reverse wedge-shaped (with cut-outs), and FIG. 23 (B) shows an example in which the side surface 41s1 on the outer side of the connecting portion 41a is formed as a curved surface. In any case, the side of the upper surface of the connecting portion 41a may be formed with a larger width than the side on the lower surface. In addition, the side wall side of the guide groove 13 is wedge-shaped or shaped like a curved surface in accordance with a sectional shape of the connecting portion 41a.

It should be noted that the height dimension of the connecting portion 41a is taken smaller than the depth dimension of the guide groove 13 so as not to interfere with the path of the optical head, which is installed in the first hole 23.

Fig. 8 is a plan view showing a state in which the inner rotor 4 is rotated in a direction in which the opening 23 of the lower shell 7 is closed, and Fig. 9 is a plan view showing a state in which the inner rotor 4 is rotated in the direction in which the opening 23 of the lower shell 7 opens.

On the surface of the outer contour of the annular portion 41, a gear portion 43 is formed for rotating the inner rotor 4. As shown in FIG. 8, the gear portion 43 is formed in a region between a position in which when the inner rotor 4 is in the closed position of the first hole 23 the lower shell 7, it is open on the front side of the rotor hole 28c described above, and in a position in which, when the inner rotor 4 is in the open position shown in FIG. 9, in which the first hole 23 of the lower shell 7 is open, it is open from the rear side of the rotor hole 28c described above.

As shown in FIG. 6, a first concave engagement portion 44 that engages with a first engagement protrusion of the shutter opening member constituting the shutter opener on the recording / reproducing device side is formed on one side of the gear portion 43, and a second concave engagement portion 45 which engages with a second engagement protrusion of the shutter opening member is formed on the other side of the gear portion 43. Such concave engagement portions 44 and 45 are opened through the rotor holes 28c together with the gear section 43. The first concave engagement portion 44 is first engaged with the first engagement protrusion of the shutter hole element when the disk cartridge 1 is loaded into the recording / reproducing device. The second concave engagement portion 45 engages with the locking protrusion 29a of the retainer member 26 when the shutter members 5a and 5b, which will be described later, are in the closed position and engaged with the second engagement protrusion of the shutter opening member when the shutter members 5a and 5b are in the open position first and second holes 23 and 42.

Then, on the surface of the outer circumference of the annular portion 41, a pair of rotation limiting protrusions 46a and 46b are formed to limit the amount of rotation of the inner rotor 4 so that they protrude with a predetermined gap between them. On the other hand, the lower shells 7a and 7b are respectively formed with a pair of restriction portions 47a and 47b that come into contact with the rotation restriction protrusions 46a and 46b.

As shown in FIG. 9, by using the inner rotor 4, which rotates in one direction in which the first opening 23 opens and the restriction protrusions 46a that come into contact with the restriction portion 47a, further rotation of the inner rotor 4 is limited. When the rotation of the inner rotor 4 4 in this direction is limited, the inner rotor 4 is in the open position of the first hole 23, and the second hole 42 on the inner rotor 4 is practically the same as the first hole 23, as shown in Fig.9.

On the other hand, as shown in FIG. 8, when the inner rotor 4 is rotated in a direction in which the first opening 23 is closed and the rotation restriction protrusion 46b comes into contact with the restriction portion 47b, further rotation of the inner rotor 4 is limited. When the rotation of the inner rotor 4 in this direction is limited, the inner rotor 4 is in the closed position of the first hole 23, and the second hole 42 is maximally deflected relative to the first hole 23.

Then, as shown in FIG. 6, on the inner rotor 4, a pair of holding pins 49a and 49b are formed which rotatably support a pair of shutter elements 5a and 5b, respectively, so that they protrude on the main surface portion 4a on the other side, from the side from which the annular portion 41 protrudes. A pair of retaining pins 49a and 49b are located in positions symmetrical with respect to a point on the central portion of the inner rotor 4, that is, arranged so that they have a phase difference of 180 °.

A pair of shutter members 5a and 5b mounted on the inner rotor 4 for opening and closing the second hole 42, as described above, are mutually symmetrical, as shown in FIGS. 10-12, and rotatably mounted on the pair of retaining pins 49a and 49b of the inner rotor 4, having a phase difference of 180 °. It should be noted that the details common with the pair of shutter elements 5a and 5b will be denoted by the same reference numerals, and a detailed description will not be given here.

Below, with reference to FIGS. 10-12, shutter elements 5a and 5b will be described in detail. FIG. 10 is a perspective view of a pair of shutter members 5a and 5b, FIG. 11 is a perspective view showing a state in which an opening 42 of the inner rotor 4 is opened by shutter members 5a and 5b, and FIG. 12 is a view. in perspective, representing a state in which the opening 42 of the inner rotor 4 is closed by the shutter members 5a and 5b.

The shutter elements 5a and 5b constitute a “shutter” in accordance with the present invention. The shutter members 5a and 5b are formed by injection molding a thermoplastic material from a polymer resin, such as polyoxymethylene (POM), as well as the inner rotor 4 described above. The shutter members 5a and 5b are formed essentially as semicircular flat plates, and the end portions of their base are respectively formed with pin holes 50a and 50b that are rotatably coupled with the support pins 49a and 49b on the inner rotor 4.

In addition, on parts of the chord line that are the surfaces of the pair of damper elements 5a and 5b that are brought together, a first engagement part 51 is formed, extending in the direction of the end portion of the base from the central portion, and a second engagement part 52, extending in the direction of the tip from central site. Among them, the lower side 7 of the shell of the first engagement portion 51 is an inclined surface, and the upper side of the shell 6 of the second engagement portion 52 is formed as an inclined surface. As shown in FIGS. 11 and 12, when the pair of shutter members 5a and 5b respectively rotates around the retaining pins 49a and 49b of the inner rotor 4 in the direction in which they are brought together, the first engaging portion 51 of the shutter member 5a and the second engagement portion 52 the shutter member 5b are engaged with each other, and the first engagement portion 51 of the shutter member 5b and the second engagement part 52 of the shutter member 5a are engaged with each other.

In addition, on the shutter members 5a and 5b, the guide holes 53, which respectively engage with a pair of guide pins 32, are formed so that they protrude on the inner surface of the lower shell 7. The guide holes 53 are formed with a predetermined length while they extend from middle sections in the chord line sections in the direction of the holes for the pins 50a and 50b, respectively, therefore, the shutter elements 5a and 5b rotate between the closed position and the open position of the second hole 42.

13 and 14 show the relationship between the rotation of the inner rotor 4 and the opening / closing operation of the shutter elements 5a and 5b. Here, FIG. 13 shows the closed position of the shutter members 5a and 5b and FIG. 14 shows the open position of the shutter members 5a and 5b.

When the disk cartridge 1 is not used, the inner rotor 4 and the shutter members 5a and 5b are in the position shown in FIG. 13. In particular, the rotation of the inner rotor 4 is limited by the fixing part 29 of the member 26, which engages with the second concave engagement portion 45, and the shutter members 5a and 5b are in the closing position, thereby closing the first opening 23 of the lower shell.

On the other hand, when the disk cartridge 1 is loaded into the recording / reproducing apparatus, the shutter opening member on the side of the recording / reproducing apparatus presses the work piece 28 of the clamp member 26 and disengages the engagement between the clamp part 29 and the second concave engagement portion 45, and thereafter engages with the first concave engagement portion 44 on the inner rotor 4. Then, the shutter hole element engages with the gear portion 43 on the inner rotor 4 when performing a further feeding operation Cartridge is 1 with respect to the disk recording / reproducing apparatus, and the inner rotor 4 is rotated clockwise by 13. As a result of the rotation of the inner rotor 4, the shutter elements 5a and 5b supported by the holding pins 49a and 49b also move relative to the cartridge case.

At this time, during the engagement operation of the guide pins 32 of the lower shell 7 (half-shell parts 7a and 7b) in the guide holes 53 of the shutter members 5a and 5b, the shutter members 5a and 5b rotate around the holding pins 49a and 49b, respectively. The rotation amount of the shutter elements 5a and 5b corresponds to the rotation amount of the inner rotor 4 at the moment when the inner rotor 4 has turned to a position in which the first hole 23 and the second hole 42 are practically coincident with each other, while the shutter elements 5a and 5b are rotated to the position in which the first hole 23 is fully open.

It should be noted that when the cartridge 1 for the disk is removed from the recording / reproducing device, this operation is performed in the opposite direction. In particular, as a result of turning the inner rotor 4 counterclockwise in FIG. 14 and moving the shutter elements 5a and 5b relative to the cartridge case, the first hole 23 is closed by the shutter elements 5a and 5b, as shown in FIG. 13. In addition, by using the fixing portion 29 of the shutter member 26, which engages with the second concave engagement portion 45 on the inner rotor 4, the rotation of the inner rotor 4 is limited.

On the other hand, as shown in FIG. 10, each of the shutter members 5a and 5b is formed with a protrusion 54 on the upper surface of the first engagement part 51. The protrusions 54 are formed when the shutter elements 5a and 5b are engaged through the first and second engagement parts 51 and 52, in positions opposite to the portion of the inner edge (the area in which the “signal recording” is not performed), in the center of the optical disk 3 located on the portion 15 disk placement. Accordingly, even when the shutter members 5a and 5b are deformed by an external force that acts on the shutter members 5a and 5b, while the disk cartridge 1 is in a state in which the first opening 23 of the cartridge 2 for the disk is closed by the shutter elements 5a and 5b, it is not used by introducing the protrusions 54 into contact with a portion of the inner contour of the optical disk 3, the contact of the recording surface of the optical disk 3 and the shutter elements 5a and 5b is prevented.

It should be noted that while the cartridge 1 is used for the disk, which is in a state in which the first hole 23 is open, the protrusions 54 of the shutter elements 5a and 5b are respectively located in the cutout portions 48a and 48b formed on the edges of the outer contour of the second hole 42 inner rotor 4.

Accordingly, the shutter elements 5a and 5b can accordingly be moved to the open position.

In addition to the structure described above, in the disk cartridge 1 configured as described above, a clamping plate 61 is provided at approximately a central portion of the inner surface of the upper shell 6, as shown in FIG. 2. The clamping plate 61 holds the optical disk 3 together with a rotary disk, which constitutes the drive portion in the rotation of the disk of the recording / reproducing device, and which is mounted on the upper shell 6 by means of a fastening ring 61a. In particular, the clamping plate 61 is fixed by welding, while it is sandwiched between the attachment ring 61a and the approximately central portion of the inner surface of the upper shell 6, while the attachment ring 61a is, for example, approximately on the central portion of the inner surface of the upper shell 6 Then, when a rotary disk is installed in the central hole 3b, and the optical disk 3 is clamped between the rotary disk and the clamping plate 61, the optical disk 3 is rotated into and a disk placement portion 2 a.

It should be noted that the method of fixing the parts 7a and 7b of the half-shell of the lower shell 7 on the upper shell 6 is not limited to such means as the screw described above, and it is also possible to integrally connect the upper shell 6 and the parts 7a and 7b of the half-shell of the lower shell 7 using glue, ultrasonic welding, etc.

In addition, as shown in FIGS. 2 and 3, the disk cartridge 1 according to this embodiment, at one of the corner portions on the rear side of the disk cartridge 2, an unintentional deletion preventing device 70 is provided that prevents unintentional deletion of information signals recorded to the optical disk 3. The device to prevent unintentional removal includes a tongue element 73, which is moved between a position in which recording is possible and a position in which recording is not possible, taking into account current 72 placement of the tongue (figure 4), designed to accommodate the element 73 of the tongue, the hole 74 of the detection (figure 3), designed to detect one of the state of recording and the state of impossibility of recording, the hole 75 of the operation (figure 4), designed to performing operations with the tongue element 73 and the like.

Next, a shock resistance improvement device used in the cartridge 1 for a disc according to this embodiment will be described.

Buffer device

The disk cartridge 1 in accordance with this embodiment includes a buffer device for resiliently attenuating impacts that act on the joint portion between the inner rotor 4 and the shutter members 5a and 5b. FIG. 15 (A) is a plan view showing a portion of the inner rotor 4 on which a holding pin 49a is formed. FIG. 15 (B) is a schematic cross-sectional view along the direction of line (B) - (B) indicated in FIG. 15 (A). In addition, FIG. 16 (A) is a plan view showing a portion of the shutter member 5a on which the shutter hole 50a is formed, and FIG. 16 (B) is a schematic cross-sectional view in the direction of line (B) - ( B) indicated in FIG. 16 (A). It should be noted that in the description below, although the designs of the holding pin 49a and the pin hole 50a will be described, the holding pin 49b and the pin hole 50b have the same structure.

The holding pin 49a has a rotating pin structure that rotatably holds the shutter member 5a relative to the inner rotor 4. The holding pin 49a is integrally formed in the main surface portion 4a of the inner rotor 4 through the elastic holding portion 56. As shown in FIG. 15 (A), the elastic holding portion 56 is configured as a section from the main surface portion 4a by a slot (groove) 55 formed on the main surface portion 4a. The elastic support portion 56, having the shape shown in the drawing, has an external shape in the form of a lever and can elastically deform relative to the portion 4a of the main surface. The supporting portion 49a of the pin is formed on the tip portion of the elastic holding portion 56.

In addition, as shown in FIG. 15 (B), a first engagement portion 57 is formed on a side portion of the outer contour of the support pin 49a. The first engagement portion 57 is formed as a groove that opens on the side of the second hole 42 of the inner rotor 4.

On the other hand, as shown in FIG. 16, a second engagement portion 58 is formed in a pin hole 50 a of the shutter member 5 a that is mounted on the holding pin 4 a. The second engagement portion 58 is formed on the inner contour portion of the pin hole 50a, in particular, is formed as a protrusion protruding inward from the lower portion of the pin hole 50a. As shown in FIG. 17, the second engagement portion 58 has a structure that allows it to engage with the first engagement portion 57 formed on the holding pin 49a.

On Fig (A) and 17 (B) schematically shows a sectional view of the main sections, which represent an example of the installation of the second section 58 of the engagement with the first section of the engagement 57. On Fig shows a perspective view of the main sections of the inner rotor 4 and element 5A shutters during the process shown in FIG. 17 (A). In a state in which the elastic holding portion 56 is elastically deformed by a predetermined amount or more with respect to the main surface portion 4a, and the shutter member 5a is inclined relative to the main surface portion 4a of the inner rotor 4, the second engagement portion 58 engages with the first engagement portion 57 so that it slides under the lower portion of the holding shaft 49a.

After engagement, the elastic holding portion 56 is restored in approximately the same plane as the main surface portion 4a due to its elasticity, and the engagement portion between the first and second engagement portions 57 and 58 is surrounded by the main surface portion 4a. As a result, due to the fact that the position relationship between the inner rotor 4 and the shutter member 5a does not assume the state shown in FIG. 18, inside the cartridge case 2 after being placed in the cartridge case 2, the shutter member 5a is disconnected from the inner rotor 4.

The installation of the shutter member 5a on the inner rotor 4 thus ends. Since the installation method of the shutter member 5b is the same as described above, a description thereof is not given here.

The mechanism of the buffer cartridge 1 for the disk is built as described above. Since the support pins 49a and 49b are resiliently supported relative to the portion 4a of the main surface of the inner rotor 4, due to the buffer mechanism, it becomes possible to relieve the voltage applied to the connection portion between the inner rotor 4 and the shutter elements 5a and 5b when impacted during a fall and thus preventing the shutter elements 5a and 5b from being detached from the inner rotor 4. Accordingly, the stability of the shutter opening / closing mechanism upon impact during a fall can be improved. ene, and the reliability of the disk cartridge 1 can be improved.

In addition, the elastic holding portion 56 is formed with the main surface portion 4a of the inner rotor 4 and is separated from the main surface portion 4a by a slot 55 formed in the main surface portion 4a. In such a structure, it becomes possible to easily form the elastic holding portion 56 on the main surface portion 4a. It also becomes possible to apply the required elastic force to the elastic holding portion 56, depending on how the slot 55 is formed.

In addition, since each of the support pins 49a and 49b is formed as a single piece on the tip portion of the elastic holding portion 56, the elastic deformation characteristic of the shutter elements 5a and 5b relative to the inner rotor 4 is improved, and the impact that acts on the support pins 49a and 49b, can be effectively absorbed.

Furthermore, in the structure described above, in a state where the elastic holding portion 56 is elastically deformed by a predetermined amount or more and the shutter elements 5a and 5b are deflected relative to the main surface portion 4a of the inner rotor 4, the second engagement portion 58 is disconnected from the first engagement portion 57. By setting the amount of elastic deformation of the elastic holding portion 56 to a predetermined amount or more so that it has a value greater than the maximum strain of the elastic holding portion 56 within the cartridge case 2, the interlocking relationship between the first engaging portion 57 and the second engaging portion 58 can be continuously maintained after installing the inner rotor 4 and the elements 5A and 5b in the casing 2 of the cartridge.

Gearing device

Further, the disk cartridge 1 according to this embodiment includes an engagement device that is provided between the cartridge case 2 and the shutter elements 5a and 5b and maintains an engaged state between the cartridge case 2 and the shutter elements 5a and 5b when the elements 5a and 5b, the shutters are located in the closed position.

On Fig shows a perspective view of the main sections of the element 5A of the shutter. In the immediate vicinity of the pin hole 50a, which is the pivot center of the pin element 5a, an engagement protrusion 59 is formed that protrudes on a side opposite to the side of the inner rotor 4. In addition, the engagement protrusion 59 is also formed in close proximity to the center of rotation of the damper element 5b ( Fig.14). The engagement protrusion 59 is formed in an arc shape along the rotation path of the shutter member 5a and engages with the engagement groove 60 formed on the lower shell 7 (half-shell parts 7a and 7b) in the closed position in which the first opening 23 of the lower shell 7 is closed.

As shown in FIG. 5, the engagement grooves 60 are formed into an arcuate shape at the edge portions of the hole 23 and comprise engagement protrusions 59 of the shutter members 5a and 5b turned to the closed position. FIG. 20 is a perspective view of the engagement groove 60 formed on the half-shell part 7a. 21 is a schematic cross-sectional view showing an engaged state between the engagement portion 59 and the engagement groove 60. The rib 60a is formed at the edge portion of the engagement groove 60 on the side of the inner contour, and the height of the rib 60a from the lower portion of the engagement groove 60 is set to the same height as the engagement protrusion 59. In addition, a wedge-shaped portion 60b is formed between the first hole 23 and the engagement groove 60 of the lower shell 7. Accordingly, it is easier to insert the engagement protrusion 59 into the engagement groove 60 when the shutter members 5a and 5b are turned in the closing direction.

The engagement mechanism of the disk cartridge 1 is configured as described above. In this embodiment, due to the engagement mechanism, an engaged state is maintained between the cartridge housing 2 and the shutter elements 5a and 5b when the shutter elements 5a and 5b are in the closed position in which the first opening 23 is closed.

Accordingly, since the relative movement of the shutter members 5a and 5b with respect to the cartridge case 2 is limited when a shock occurs during a fall, the voltage applied to the support pins 49a and 49b that rotatably support the shutter members 5a and 5b can be reduced and it is possible to prevent the shutter elements 5a and 5b from being detached from the inner rotor 4. In addition, the durability of the shutter opening / closing device due to impact caused by falling can be improved, and the reliability of the cartridge ja 1 the disc can be improved. In addition, since the engagement protrusions 59 are respectively formed in close proximity to the holding pins 49a and 49b, it becomes possible to stop the impact of a falling impact in close proximity to the support pins 49a and 49b and to effectively protect the support pins 49a and 49b from the impact of a fall.

Since the engagement grooves 50 are formed in separate places on the edge portions of the first opening 23 of the lower shell 7, the cartridge case 2 and the shutter members 5a and 5b are disengaged from each other when the shutter members 5a and 5b are moved to the open position from the closed position. Accordingly, there is no need for a special mechanism for disengaging the cartridge case 2 and the shutter elements 5a and 5b, while it becomes possible to engage the cartridge case 2 and disengaging during the normal operation of turning the shutter elements 5a and 5b.

In addition, the holding pins 49a and 49b can be effectively protected against impact from falling by a combination with the operation of the buffer device described above, resulting in an additional improvement in the reliability of the shutter opening / closing device. In addition, by using the engagement structure of the support pins 49a and 49b and the pin holes 50a and 50b, it becomes possible to definitely prevent the shutter elements 5a and 5b from detaching from the inner rotor 4.

Until now, an embodiment of the present invention has been described. However, the present invention is not limited to the embodiment described above, and various modifications may of course be added without departing from the spirit of the present invention.

For example, in the embodiment described above, the disk cartridge 1 in which the first hole 23 is formed, extending through the cartridge case 2 from the front to the rear, was presented as an example. Alternatively, the present invention is also applicable to a disk cartridge in which a first hole is formed from a central portion of the cartridge case 2 to its rear side.

In addition, an example has been described in which the rotating pins (support pins 49a and 49b) on the elastic holding sections 56 are mounted on the portion 4a of the main surface of the inner rotor 4, as a buffer device for resiliently supporting the rotating pins that rotatably support the elements 5a and 5b of the shutter, relative to the inner rotor 4. However, the rotating pins and sections of elastic fastening, instead, can be performed on the side of the portion of the main surface of the elements 5A and 5b of the shutter. In this case, the same effect is also provided.

In addition, as a buffer device, instead of the elastic holding portions 56, for example, an elastic plate formed of rubber or the like may be provided between a portion of the main surface of the inner rotor and a rotating pin.

On the other hand, an example has been described above in which engagement protrusions 59 are provided on the side of the shutter members 5a and 5b, and engagement grooves 60 are provided on the side of the lower shell 7, as a gearing mechanism that engages the shutter members 5a and 5b with the casing 2 cartridge in the closed position of the elements 5A and 5b of the shutter. However, engagement protrusions, instead, may be provided on the side of the lower shell, and engagement grooves may instead be provided on the side of the shutter members.

In addition, the engagement device is not limited to the example of its formation in close proximity to the holding pins 49a and 49b and may be provided in other areas, or the engagement section for the lower shell and the casing for the cartridge may be provided in other areas in addition to the immediate proximity to the support pins 49a and 49b.

Claims (17)

1. A cartridge for a disk, comprising: a disk-shaped recording medium;
a cartridge case in which a disk-shaped recording medium is rotatably disposed and which is formed with a first hole that opens a portion of the disk-shaped recording medium;
an internal rotor mounted rotatably inside the cartridge housing, and includes a main surface portion formed with a second hole corresponding to the first hole;
a shutter that moves between the closed position in which the first hole is closed and the open position in which the first hole is open, in accordance with the rotation of the inner rotor; and
a buffer device including a rotating pin that rotatably holds the flap, and an elastic holding portion that supports the rotating pin and can be elastically deformed relative to the main surface portion, due to a slot formed as a single piece with the main surface portion in the main portion surface. 2. The cartridge for the disk according to claim 1,
in which the rotating pin is formed as a single part with an elastic holding portion at its tip. 3. The cartridge for the disk according to claim 2,
wherein the rotating pin comprises a first engagement portion and
wherein the shutter comprises a second engaging portion configured to engage with the first engaging portion in a state where the elastic holding portion is elastically deformed by a predetermined amount or more. 4. The cartridge for the disk according to claim 3,
in which the second engagement portion is formed in the portion of the inner contour of the hole into which the rotating pin is inserted. 5. A cartridge for a disk containing a disk-shaped recording medium;
a cartridge case in which a disk-shaped recording medium is rotatably disposed and which is formed with a first hole that opens a portion of the disk-shaped recording medium;
an internal rotor mounted rotatably inside the cartridge housing, and includes a main surface portion formed with a second hole corresponding to the first hole;
a buffer device including a rotatable pin that includes a first engagement portion an elastic holding portion that supports the rotatable pin and can be elastically deformed relative to the main surface portion due to a slot formed as a single piece with the main surface portion on the main surface portion, and
a pair of shutter elements rotatably between a closed position in which a pair of shutter elements closes the first hole by bringing them close together, and an open position in which a pair of shutter elements opens the first hole by spreading them apart in accordance with rotation an internal rotor, each of a pair of shutter elements including a second engagement portion configured to engage the first engagement portion and detachable from the first portion atsepleniya in a state where the resilient retaining portion is elastically deformed by a predetermined amount or more. 6. The cartridge for the disk according to claim 5,
in which the second engagement portion is disconnected from the first engagement portion in a state in which the shutter members are deflected relative to the portion of the main surface of the inner rotor. 7. A cartridge for a disk containing:
disc-shaped recording medium;
a cartridge case in which a disk-shaped recording medium is rotatably disposed and which is formed with a first hole that opens a portion of the disk-shaped recording medium;
an internal rotor mounted rotatably inside the cartridge housing, and includes a main surface portion formed with a second hole corresponding to the first hole;
a shutter that moves between the closed position in which the first hole is closed and the open position in which the first hole is open, in accordance with the rotation of the inner rotor; and
a buffer device formed on a portion of the main surface of the inner rotor and including a rotating pin that rotatably holds the shutter and an elastic holding portion that supports the rotating pin and can be elastically deformed relative to the portion of the main surface; and
an engagement device that is provided between the cartridge housing and the shutter and maintains an engaged state between the cartridge housing and the shutter when the shutter is in the closed position. 8. The cartridge for the disk according to claim 7,
wherein the engaging device brings the cartridge housing and the shutter out of engagement with each other when the shutter moves to the open position from the closed position. 9. The disk cartridge of claim 8,
wherein the engagement device includes
an engagement protrusion in the form of an arc that is formed on the shutter, in accordance with the direction of rotation of the shutter, and
an engagement groove in the form of an arc that is formed on a portion of an edge of the first hole and which is configured to accommodate an engagement protrusion therein. 10. The cartridge for the disk according to claim 9,
wherein the engagement protrusion is provided in close proximity to the center of rotation of the shutter relative to the inner rotor. 11. A cartridge for a disk containing:
disc-shaped recording medium;
a cartridge case in which a disk-shaped recording medium is rotatably disposed and which is formed with a first hole that opens a portion of the disk-shaped recording medium;
an internal rotor including a main surface portion, a toroidal outer circular wall portion formed on one surface of the main surface portion, a second hole that is formed on the main surface portion and has a shape corresponding to the first hole, and a connecting portion that is located on the portion, where the second hole is formed, in part of the portion of the outer circular wall and includes a first terminal surface on the side of the portion of the main surface that is formed with a first width, and an opposite second end surface that is formed with a second width smaller than the first width, the connecting portion on the side of the second end surface is slidably engaged with the guide groove, which allows the rotation of the inner rotor to be directed relative to the cartridge case;
a shutter that moves between the closed position in which the first hole is closed and the open position in which the first hole is open, in accordance with the rotation of the inner rotor; and
a buffer device formed on a portion of the main surface of the inner rotor and including a rotating pin that rotatably holds the shutter, and an elastic holding portion that supports the rotating pin and may be elastically deformed relative to the portion of the main surface. 12. The cartridge for the disk according to claim 11,
in which the guide groove has an inner side configuration corresponding to the configuration of the outer surface of the connecting portion. 13. The cartridge for the disk according to item 12,
wherein the connecting portion includes an outer contour surface and an inner contour surface, and
in which at least one of the surface of the outer contour and the surface of the inner contour is made wedge-shaped. 14. The cartridge for the disk according to item 12,
wherein the connecting portion includes an outer contour surface and an inner contour surface, and
in which at least one of the surface of the outer contour and the surface of the inner contour is formed as a curved surface. 15. The cartridge for the disk according to claim 11,
in which the guide groove is formed so that it is made toroidal for engagement in this way by the surface portion of the outer circular wall and the connecting portion of the inner rotor. 16. The cartridge for the disk according to claim 11,
in which a second hole is formed over the entire region of the main surface portion in the diameter direction. 17. A cartridge for a disk containing:
disc-shaped recording medium;
a cartridge case in which a disk-shaped recording medium is rotatably disposed, and which is formed with a first hole that opens a portion of the disk-shaped recording medium;
an internal rotor that is rotatably held inside the cartridge case and includes a second hole corresponding to the first hole;
a shutter that is movable between a closed position in which the first hole is closed and an open position in which the first hole is open, in accordance with the rotation of the inner rotor; and
a buffer device formed on the main surface of the shutter and including a rotary pin that rotatably holds the shutter relative to the inner rotor, and an elastic holding portion that holds the rotary pin, and can elastically deform relative to the main surface.

Images