JP2006155706A - Disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disk device which can mount or demount two kinds of disks of which diameters are different and is advantageous in reduction of cost and power consumption. <P>SOLUTION: When a disk 1 of a large diameter is pushed into a mounting/demounting port 43, 1st left/right guide levers 48A/48B are moved back together with a slider 40, and in a left driving lever 52A, a pin 5204A makes resistance to an energized force of an energized member 53A and is fluctuated to its moving backward direction. In a right driving lever 52B, its pin 5204B is separated through a open section 47B from a right engaging groove 46B by backward movement of a slider 40. When the slider 40 is pushed into a back end position, the slider 40 is locked at the back end position by a locking mechanism, and a center hole of the disk 1 agrees to the center of a turntable 1202. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a disk loading / unloading mechanism in a disk device.

Information is recorded on a disc-shaped disc (disc-shaped recording medium) that is an information recording medium such as a CD, CD-ROM, DVD-ROM, etc., or the recorded information is reproduced, or recorded and reproduced. As a loading / unloading mechanism for loading and unloading (loading) a disk in a disk device that performs the above, a mechanism is known in which a tray that appears and disappears from the disk device is mounted and the disk is mounted on the tray.
Such a loading / unloading mechanism using a tray is disadvantageous in reducing the size of the disk device because a space for moving the tray is required inside the disk device, and especially portable for which a reduction in size is required. It was unsuitable for use in other disk devices.
In view of this, a loading / unloading mechanism for loading / unloading a disk via a loading / unloading slot (slot) of the disk device without using a tray has been proposed.
For example, by using the rotational driving force of a motor as such a loading / unloading mechanism, two types of disks, a large disk having a diameter of 12 cm and a small disk having a diameter of 8 cm, can be used as a loading / unloading port of the disk device. There has been proposed one that moves with a turntable of a spindle motor for rotating a disk provided in the disk device (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 7-44965

However, in the prior art, since it is necessary to secure electric power for driving the motor for moving the disk, there is a disadvantage in reducing power consumption, especially for portable devices that require low power consumption. There is a disadvantage in adopting the disk device.
In addition, since it is necessary to control the amount of movement of the disk according to the diameter of the disk in order to load and unload two types of disks having different diameters, the amount of drive of the sensor or motor that detects the diameter of the disk must be set. Since a control circuit for controlling in accordance with the diameter of the disk is required, an increase in the number of parts is unavoidable, which is disadvantageous in terms of cost reduction.
The present invention has been devised in view of the above circumstances, and an object of the present invention is to be able to mount and dismount two types of disks having different diameters, which is advantageous in reducing power consumption and cost. It is an object to provide a disk loading / unloading mechanism in a disk device.

  In order to achieve the above object, the present invention provides a disk loading / unloading mechanism in a disk apparatus for loading / unloading a large-diameter disk and a small-diameter disk having different sizes, which are disk-shaped information recording media, A lower frame provided with a spindle motor, a base plate pivoted up and down with respect to the lower frame and pivoted up and down with respect to the lower frame, and an upper lid attached to the base plate so as to cover the upper side of the base plate And a slider coupled to the base plate so as to be movable between a front end position below the upper lid and above the base plate, where the disk is loaded and unloaded, and a rear end position where the disk is mounted on the spindle motor. Provided on the slider, the slider is positioned at the rear end position, and the upper lid is closed to spin the disc. A chuck plate that is pressed against a disk mounting portion of a dollar motor and is separated from the disk when the upper lid is opened, a disk storage space formed above the base plate and below the slider and the chuck plate, and the disk storage space A loading / unloading port provided at a front end and exposed when the upper lid is opened and closed when the upper lid is closed, and the loading / unloading mechanism is configured such that the disk loaded into the loading / unloading port is a large-diameter disk or a small-diameter disk. Regardless of whether it is a disk, the disk is positioned at a loading position where the center of the disk matches the center of the disk mounting portion at the rear end position of the slider, and a part of the disk is positioned at the front end position of the slider. A disk positioning mechanism for positioning the disk at a discharge position protruding outward from the loading / unloading port; A large-diameter disk slider drive mechanism for moving the slider from the front end position to the rear end position and moving the slider from the rear end position to the front end position when the disk loaded into the recording / removal port is a large-diameter disk; When the disk loaded in the loading / unloading port is a small-diameter disk, the slider is moved from the front end position to the rear end position and moved from the rear end position to the front end position. A locking mechanism that engages with the slider when positioned at the end position, holds the slider at the rear end position, closes the upper lid and then opens and then disengages from the slider, and is inserted into the loading / unloading port. When the disc is a large-diameter disc, the large-diameter disc slider drive mechanism is operated and the disc loaded in the loading / unloading port is a small-diameter disc. A switching mechanism for switching between the large-diameter disk slider driving mechanism and the small-diameter disk slider driving mechanism so as to operate the small-diameter disk slider driving mechanism, and the disk positioning mechanism The first left and right guide levers that are supported so as to be swingable and are capable of coming into contact with two circumferentially spaced locations on the outer periphery of the disk and biased in the closing direction, and the first left and right guide levers The large-diameter disk slider driving mechanism includes a guide groove that engages and determines the opening of the first left and right guide levers following the size of the disk and the back-and-forth movement of the slider. The first left and right guide levers, the guide groove, and the slider are detachably engaged with each other and rocked in conjunction with the back and forth movement of the slider. And a spring means for biasing the first drive lever in a direction for biasing the slider to the front end position. The small-diameter disk slider drive mechanism includes the first left and right sliders. A guide lever, a guide groove, a second drive lever that is detachably engaged with the slider and swings in conjunction with the back-and-forth movement of the slider; The second drive lever is urged so that the slider reaches the front end position, and the slider moves when the slider passes the intermediate position toward the rear end position. A toggle spring that urges the second drive lever to reach the rear end position, and the second drive lever to return the slider from the rear end position to the intermediate position. When the disk is a large-diameter disk, the switching mechanism engages the first drive lever with the slider and moves the second drive lever from the slider. When the disk is a small-diameter disk, the first drive lever is detached from the slider and the second drive lever is engaged with the slider.

According to the present invention, since both of the large and small diameter disks are mounted / removed without using a motor, it is advantageous in reducing power consumption, and particularly portable for which low power consumption is required. This is advantageous in adopting the disk device.
In addition, when a motor is used, in order to load and unload two types of discs having different diameters, it is necessary to control the amount of movement of the disc according to the disc diameter. In addition, it is necessary to provide a control circuit that controls the drive amount of the motor according to the diameter of the disk, but in this embodiment, such a control circuit is not required, so the increase in the number of parts can be suppressed and the cost can be reduced. This is advantageous in achieving this.

  The present invention achieves the above object by providing a disk positioning mechanism, a large-diameter disk slider driving mechanism, a small-diameter disk slider driving mechanism, a lock mechanism, and a switching mechanism.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a perspective view of the disk device 100, FIG. 2 is an exploded perspective view of the disk device 100, FIG. 3 is a perspective view of the slider when the slider is turned upside down, and FIG. FIG. 5 to FIG. 7 are explanatory views of the mounting operation of a large-diameter disk, and FIGS. 8 to 10 are explanatory views of the mounting operation of a small-diameter disk.

  As shown in FIGS. 1 and 2, the disk device 100 according to the present embodiment records and / or reproduces a disk-shaped disk 1 (disk-shaped recording medium) that is an information recording medium such as a CD or a DVD. It includes a lower frame 10, an upper lid 20, a base plate 30, a slider 40, and the like. In this embodiment, the direction in which the disk 1 is inserted into and removed from the disk device 100 is the front-rear direction, the direction perpendicular to the front-rear direction is the left-right direction, and the device in which the disk 1 is inserted into the disk device 100 is used. The outlet 43 side is the front, and the side opposite to the loading / unloading port 43 is the rear.

As shown in FIG. 2, the lower frame 10 includes a disk-shaped bottom wall 1002 and a peripheral wall 1004 that stands up from the periphery of the bottom wall 1002.
A spindle motor 12 and an optical pickup 14 are provided on the upper surface of the bottom wall 1002.
The spindle motor 12 rotationally drives the disk 1 loaded in the disk device 100, and the spindle motor 12 has a turntable 1202 on which the disk 1 is mounted (corresponding to the disk mounting portion in the claims). Is provided.
The optical pickup 14 irradiates the disk 1 with a light beam and detects the reflected light beam.
The optical pickup 14 is configured to reciprocate in the radial direction (tracking direction) of the disk 1 mounted on the turntable 1202 along the guide portion 1402 by a drive mechanism (not shown).
The optical pickup 14 is configured to record and / or reproduce information on the recording surface of the disk 1 while moving in the radial direction by the drive mechanism.
For convenience of explanation, a virtual line that passes through the center of the spindle motor 12 and extends in the front-rear direction is defined as a central axis O1.
A pair of shaft portions 1004 is provided at a location facing the rear of the peripheral wall 1004 of the bottom wall 1002 at a location that is substantially line-symmetric about the central axis O1.
Two lock claws 1602 urged in a normally closing direction are swingably provided at a position that faces the front of the peripheral wall 1004 and is substantially line-symmetric with respect to the central axis O1. An opening button 1604 that opens the two lock claws 1602 by being connected and pressed is provided.

As shown in FIG. 2, the upper lid 20 has an upper wall 2002 formed with substantially the same contour as the bottom wall 1002 of the lower frame 10, and a peripheral wall 2004 suspended from the periphery of the upper wall 2002.
The base plate 30 includes a front plate portion 32, a rear plate portion 34 formed with a larger outline than the front plate portion 32 and positioned behind the front plate portion 32, a rear portion of the front plate portion 32, and a front portion of the rear plate portion 34. And a guide plate 36 spanned between the two. The front end of the guide plate 36 is connected to the rear portion of the front plate portion 32 via a long groove and a pin, and the rear end thereof is swingably coupled to the front end of the rear plate portion 34.
As shown in FIGS. 2 and 4, the front plate portion 32 is disposed on the two lock claws 1602 at the front portion of the bottom wall 1002 of the lower frame 10, and is attached to the front portion of the bottom wall 1002 via screws. It is worn.
As shown in FIG. 4, the rear plate portion 34 is fixed to the holder 21 near the periphery of the upper wall 2002 of the upper lid 20 by welding or the like at a position near the periphery.
Further, a bearing hole 3402 formed in the rear portion of the rear plate portion 34 is inserted into the shaft portion 1004 of the lower frame 10, whereby the upper lid 20 and the base plate 30 swing with the shaft portion 1004 as a fulcrum and move relative to the lower frame 10. It is attached so that it can be opened and closed.

As shown in FIG. 2, between the rear plate portion 34 and the bottom wall 1002 of the lower frame 10, the upper lid 20 and the rear plate portion 34 are opened in a direction in which the rear plate portion 34 is separated from the bottom wall 1002. A biasing member 31 that constantly biases in the direction to be provided is provided.
An accommodation space for accommodating the disk 1 and the slider 40 is formed between the base plate 30 and the upper wall 2002, and an open notch 3404 is formed in the rear plate portion 34 on the rear side. The pickup 14 faces the accommodation space through the notch 3404.
Then, by opening the upper lid 20 with respect to the lower frame 10, as shown in FIG. 1, the upper edge of the portion where the peripheral wall 1002 of the lower frame 10 faces forward and the portion of the portion where the peripheral wall 2002 of the upper lid 20 faces forward are provided. A loading / unloading port 43 through which the disk 1 is loaded / unloaded is formed by the lower edge, and the loading / unloading port 43 is closed by pushing down the upper lid 20.
Guide grooves 38 are respectively formed at substantially line-symmetrical locations around the central axis O1 at both sides of the upper surface across the notch 3404 of the rear plate portion 34.
Each guide groove 38 is connected to an outer end of the lateral groove portion 3802 and a lateral groove portion 3802 extending obliquely in the left-right direction so that the inner side is located forward and the outer side located rearward at the front portion of the rear plate portion 34. The first vertical groove portion 3804 that extends and a second vertical groove portion 3806 that extends rearward from the inner portion of the outer end of the horizontal groove portion 3802 are configured.

As shown in FIGS. 2 and 4, engagement convex portions 3406 are respectively formed at two positions where the rear plate portion 34 sandwiches the guide plate 36 in the left-right direction. The lock claw 1602 is configured to be engaged and disengaged.
Specifically, each engagement convex portion 3406 has a side surface 3406A that faces in a direction away from each other in the left-right direction, and an engagement surface 3406B that is connected to the upper portion of the side surface 3406A and faces upward.
In a state where the upper lid 20 is opened with respect to the lower frame 10, the two lock claws 1602 are in an open state by contacting each side surface 3406 </ b> A.
Here, when the upper lid 20 is closed with respect to the lower frame 10, the two lock claws 1602 are disengaged from the upper ends of the side surfaces 3406A and closed, and are engaged with the engagement surfaces 3406B, thereby maintaining the closed state of the upper lid 20. Thus, the closed state of the loading / unloading port 43 is maintained.
Further, when the release button 1604 is pressed while the closed state of the upper lid 20 is maintained, the two lock claws 1602 are opened, and the engagement between the lock claws 1602 and the engagement surface 3406B is released. 1602 is brought into an open state by abutting against each side surface 3406A, and the upper lid 20 is opened upward by the urging force of the urging member 31, whereby the open / close state of the loading / unloading port 43 is maintained.

As shown in FIGS. 2 and 3, the slider 40 has a slider main body 41 made of a plate material extending in the front-rear direction and the left-right direction. The slider main body 41 is a guide (not shown) provided on the rear plate portion 34. The portion is supported so as to be reciprocally movable in the front-rear direction and not movable in the up-down direction. Therefore, the slider 40 opens and closes integrally with the upper lid 10 and the base plate 30.
In the present embodiment, a disk storage space in which the disk 1 is loaded is formed above the base plate 30 and below the slider 40 and the chuck plate 44, and the front end of the disk storage space serves as the loading / unloading port 43.
In addition, the slider 40 is located at a position closest to the loading / unloading port 43 by a stopper member (not shown), that is, a front end position where the disk 1 is loaded / unloaded, and a position furthest from the loading / unloading port 43, that is, the disk. 1 is configured to be movable between a rear end position where the spindle motor 12 is mounted on the spindle motor 12.
Further, when the upper lid 20 is closed while the slider 40 is positioned at the rear end position, the slider 40 is locked at the rear end position by a lock mechanism (not shown), and the slider 40 is positioned at the rear end position. When 20 is opened, the lock mechanism is unlocked.

A base end of a chuck arm 42 extending in the front-rear direction and elastically deformable in the vertical direction is attached to the center of the slider 40, and a chuck plate 44 is attached to the tip of the chuck arm 42 so that the center passes through the central axis O1. Is provided.
The chuck plate 44 attaches the disc 1 to the turntable 1202 by being attracted by the magnetic force of a magnet incorporated in the turntable 1202 when the upper lid 20 is closed with the disc 1 placed on the turntable 1202. Is.
Left and right engagement grooves 46A and 46B extending in the left-right direction are formed in substantially line-symmetrical locations around the central axis O1 on both the left and right sides of the front side of the slider body 41 with the chuck arm 42 interposed therebetween.
Front end portions of the left and right engaging grooves 46A and 46B that are located away from the chuck arm 42 are connected to open portions 47A and 47B that are formed in an open shape in front of the slider 40.

As shown in FIG. 3, first guide levers 48 are provided on the left and right sides of the lower surface of the slider 40. The first guide lever 48 includes a left guide lever 48A and a right guide lever 48B, and these guide levers 48A and 48B are provided so as to be swingable around support shafts 4802A and 4802B, respectively.
Rollers 4804A and 4804B are provided downward at the tips of the guide levers 48A and 48B, and pins 4806A and 4806B are provided downward and coaxially with the rollers 4804A and 4804B.
The rollers 4804A and 4804B are provided so as to be able to contact the outer peripheral edge of the disk 1, and the pins 4806A and 4806B are inserted into the guide grooves 38 of the rear plate portion 34 of the base plate 30 and guided to the guide grooves 38, respectively. It is configured as follows.

As shown in FIGS. 5 to 7, link levers 50 are provided on the inner sides of the first left and right guide levers 48 </ b> A and 48 </ b> B at the left and right sides of the upper surface of the slider 40.
Each of the link levers 50 includes a left link lever 50A and a right link lever 50B extending in the front-rear direction. The link levers 50A and 50B are provided with sliders 40 whose middle portions in the longitudinal direction are centered on support shafts 5002A and 5002B, respectively. It is supported so that it can swing.
A front portion 5004A of the left link lever 50A is positioned at the left engagement groove 46A, and is configured to be able to contact a pin 5204A of the left drive lever 52A described later.
The rear end 5006A of the left link lever 50A is provided so as to be in contact with the rear end 5006B of the right link lever 50B.
The left link lever 50A is biased by the link lever spring 51A in a direction in which the rear end 5006A abuts the rear end 5006B of the right link lever 50B.
The front portion 5004B of the right link lever 50B is positioned at the right engagement groove 46B, and is configured to be able to contact the pin 5204B of the right drive lever 52B.
The rear end 5006B of the right link lever 50B is provided so as to be in contact with the rear end 5006A of the left link lever 50A.
An engagement piece 5008B that can be engaged with an engagement piece 5402 of the detection member 54 described later is provided on the right side of the right link lever 50B near the front portion 5004B.
The right link lever 50B is biased by a link lever spring 51B in a direction in which a front portion 5004B engages with a pin 5204B of the right drive lever 52B.

As shown in FIGS. 5 to 7, a drive lever 52 is provided on the upper plate 1002 of the upper lid 10 on the outer side in the left-right direction of each first guide lever 48.
The drive lever 52 includes a left drive lever 52A (corresponding to the first drive lever in the claims) and a right drive lever 52B (corresponding to the second drive lever in the claims). 52A and 52B are supported by the upper lid 10 so that the intermediate portions in the longitudinal direction can swing around the supporting shafts 5202A and 5202B, respectively.
A pin 5204A (corresponding to the engaging portion of the first driving lever in the claims) projects downward from the front end of the left driving lever 52A, and this pin 5204A is the left engaging groove of the slider 40. 46A (equivalent to the first engaging groove in the claims) is configured to be detachable.
The left drive lever 52A is biased by a biasing member 53A (corresponding to the spring means in the claims) so that the pin 5204A moves forward.
A pin 5204B (corresponding to the engagement portion of the second drive lever in the claims) is projected downward from the front end of the right drive lever 52B, and this pin 5204B is the right engagement groove of the slider 50. 46B (equivalent to the second engagement groove in the claims) is configured to be detachable.
At the rear end of the right drive lever 52B, a pin 5206 that can be engaged with an eject lever 58 described later is projected downward.
The right drive lever 52B moves the pin 5204B forward when the slider 40 is positioned closer to the front, and moves the pin 5204B rearward when the slider 40 is positioned closer to the rear. It is urged by a toggle spring 53B so as to be moved to. Therefore, the right drive lever 52B is configured such that the direction urged by the toggle spring 53B is reversed as the slider 40 moves.

As shown in FIG. 5 to FIG. 7, detection for detecting the size of the disc 1 loaded on the upper plate 1002 of the upper lid 10 in the vicinity of the right guide lever 48 </ b> B of the first guide lever 48. A member 54 is provided.
The detection member 54 extends in the left-right direction, and is provided so as to be reciprocally movable in the left-right direction by a guide portion (not shown).
As described above, the engagement piece 5402 that can be engaged with both the engagement piece 5402 of the right link lever 50B and the pin 5204B of the right drive lever 52B protrudes rearward from the detection member 54 on the left side. At the right end of the detection member 54, a pin 5404 that can be engaged with the engaging portion 5606B of the right guide lever 56 of the second guide lever 56 projects downward.
The detection member 54 is urged by the urging member 55 in the direction (left direction) in which the pin 5404 is engaged with the engagement portion 5606B of the right guide lever 56, and the engagement piece 5402 is urged by the right drive lever 52B. The pin 5204B is biased in the direction of engagement.

As shown in FIGS. 5 to 7, a second guide lever 56 is provided on the upper plate 1002 of the upper lid 10 above the left and right sides of the slider 50.
The second guide lever 56 includes a left guide lever 56A and a right guide lever 56B. Each of the guide levers 56A and 56B has a middle portion in the longitudinal direction thereof swingable around the support shafts 5602A and 5602B, respectively. It is supported by.
Rollers 5604A and 5604B are provided downward at the front ends of the guide levers 56A and 56B, and the rollers 5604A and 5604B can contact the outer peripheral edge of the disk 1.
By inserting a pin 5608A provided at the rear end of the left guide lever 56A into a long groove 5608B provided at the rear end of the right guide lever 56B, the guide levers 56A and 56B are connected at the rear end.
These second left and right guide levers 56 </ b> A and 56 </ b> B are urged in a normally closing direction by a urging member 57 as shown in FIG. 5.

As shown in FIGS. 5 to 7, an eject lever 58 is provided on the upper plate 1002 of the upper lid 10 above the right side of the slider 50.
The eject lever 58 is supported by the upper lid 10 so as to be movable in the front-rear direction by a guide portion (not shown).
As shown in FIG. 1, an operation portion 5802 is provided at the front end of the eject lever 58 so as to be exposed outward from the opening of the peripheral wall 1002 of the upper lid 10.
An engagement piece 5804 that can be engaged with the pin 5206B of the right drive lever 52B protrudes from an intermediate portion in the longitudinal direction of the eject lever 58.
The eject lever 58 is urged by the urging member 59 in a direction in which the engagement piece 5804 is separated from the pin 5206 of the right drive lever 52A.

Next, the operation of loading / unloading the disk 1 in / from the disk device 100 will be described.
First, a case where a large-diameter disk 1 having a diameter of 12 cm is inserted into the disk device 100 will be described.
For convenience of explanation, the disc device 100 does not contain the disc 1, and the upper lid 20 is closed with respect to the lower frame 10 in this state, and the slider 40 is positioned at the front end position as shown in FIG. The urging member 53A has a natural length, and the pin 5204A of the left drive lever 52A is positioned by the urging member 53A at a location facing the opening 47A in the left engagement groove 46A. Further, the biasing member 55 that moves the detection member 54 to the left is also a natural length, and the pin 5204B of the right drive lever 52B is located at a position facing the opening 47B in the right engagement groove 46B. ing.
First, each lock claw 1602 is opened by pressing the release button 1604, and the upper lid 20 is opened upward by the urging force of the urging member 31, so that the loading / unloading port 43 is opened.

Here, the disk 1 is loaded from the loading / unloading port 43, and the disk 1 is moved below the slider 40 along the upper surface of the guide plate 36 and the upper surface of the rear plate 34 into the disk housing space.
As a result of this movement, first, as shown in FIG. 5, the outer peripheral edge of the disk 1 has rollers 4804A and 4804B of the first left and right guide levers 48A and 48B, and rollers 5604A of the second left and right guide levers 56A and 56B. The slider 40 is moved in contact with the four positions 5604B.
Thereafter, until the disc 1 is taken out from the disc device 100, the contact state of the four rollers 4804A, 4804B, 5604A, 5604B with respect to the outer peripheral edge of the disc 1 is maintained, and mainly the first left and right guide levers 48A. , 48B rollers 4804A and 4804B come into contact with the outer peripheral edge of the disk 1 so that the disk 1 is positioned with respect to the slider 40.
When the disk 1 is further pushed in this state, the pins 4806A and 4806B move in the lateral groove portion 3802 of the base plate 30 as the disk 1 is pushed, so that the first left and right guide levers 48A as shown in FIG. , 48B are swung in the opening direction when the rollers 4804A, 4804B are pressed against the outer peripheral edge of the disk 1. The second left and right guide levers 56A and 56B are also swung in a direction to open against the urging force of the urging member 57 when the rollers 5604A and 5604B are pressed against the outer peripheral edge of the disk 1.

At this time, the first left and right guide levers 48A and 48B swing in the opening direction while the pins 4806A and 4806B move in the lateral groove portion 3802 of the base plate 30 as the disk 1 is pushed, and the pins 4806A and 4806B are swung. Moves from the horizontal groove portion 3802 to the first vertical groove portion 3804, the first left and right guide levers 48A and 48B cannot swing, and the pins 4806A and 4806B are moved into the first vertical groove portion 3804 as the disk 1 is pushed. The first left and right guide levers 48A and 48B move rearward together with the slider 40 in an open state.
Further, when the second right guide lever 56B swings, the detection member 54 engaged with the engaging portion 5606B of the right guide lever 56B via the pin 5404 is subjected to the urging force of the urging member 55. It moves against the right.

By moving the detection member 54 to the right, when the right link lever 50B engaged with the engagement piece 5402 of the detection member 54 via the engagement piece 5008B is swung, the right link lever 50B is moved. The rear end 5006B presses the rear end 5006A of the left link lever 50A, the front end 5004A of the left link lever 50A moves the pin 5204A of the left drive lever 52A to the right, and the pin 5204A moves to the left engagement groove. It is moved to a position on the right side of the opening 47A within 46A.
Further, the pin 5204B of the right drive lever 52B is in contact with the engagement piece 5402 of the detection member 54 urged to the left by the urging member 55, so that the right engagement groove 46B faces the opening 47B. Stay on.

When the disc 1 is further pushed in from this state, the first left and right guide levers 48A and 48B are not allowed to swing by the first vertical groove portion 3804. Therefore, as shown in FIG. The guide levers 48A and 48B are moved backward together with the slider 40.
As the slider 40 moves backward, the pin 5204A of the left drive lever 52A is engaged with the left engagement groove 46A, so that the pin 5204A moves backward against the urging force of the urging member 53A. Is swung in the moving direction. For this reason, the biasing force that swings the drive lever 52A in the direction in which the pin 5204A is moved forward is stored in the biasing member 53A.
On the other hand, the pin 5204B of the right drive lever 52B is disengaged from the right engagement groove 46B through the opening 47B due to the backward movement of the slider 40, so that the pin 5204B portion of the right drive lever 52B is moved by the toggle spring 53B. It opens slightly outward and is held in a state regulated by the toggle spring 53B.
When the slider 40 is pushed to the rear end position, the slider 40 is locked at the rear end position by the locking mechanism, and the disc 1 is moved between the center hole of the disc 1 and the turntable by the first left and right guide levers 48A and 48B. The loading position where the center of 1202 matches is set.
When the upper lid 20 is moved downward in this state to close the loading / unloading port 43, the chuck plate 44 comes into contact with the periphery of the center hole of the disk 1 and is attracted by the magnetic force of the turntable 1202, thereby completing the mounting of the disk 1. The disk device 100 performs a reproduction or recording operation on the disk 1.

Next, a case where the large-diameter disk 1 is taken out from the disk device 100 will be described.
First, when the upper cover 20 is moved upward by pressing the release button 1604 and the loading / unloading port 43 is opened, the slider 40 is unlocked by the locking mechanism, so that the slider 40 is moved from the rear end position to the front end position. It becomes possible to move. As described above, since the urging force in the direction of swinging the left drive lever 52A in the direction in which the pin 5204A is moved forward is stored in the urging member 53A, the left drive lever 52A is urged by the urging member 53A. As the pin 5204A is swung forward by the urging force, the slider 40 is moved from the rear end position to the front end position.

At this time, the first left and right guide levers 48A and 48B cannot swing while the pins 4806A and 4806B move in the first vertical groove portion 3804 of the base plate 30 as the slider 40 moves forward. The first left and right guide levers 48A and 48B move forward together with the slider 40 in an open state.
When the pins 4806A and 4806B move from the first vertical groove portion 3804 to the horizontal groove portion 3802, the first left and right guide levers 48A and 48B swing in the closing direction as the slider 40 moves forward. The outer peripheral edge of the disk 1 is pushed forward by the rollers 4804A and 4804B of the left and right guide levers 48A and 48B, and the state shown in FIG. 5 is restored.
As a result, the slider 40 becomes the front end position, and a discharge position in which a part of the disk 1 protrudes outward from the loading / unloading port 43 by the rollers 4804A and 4804B of the first left and right guide levers 48A and 48B.
Here, a part of the disk 1 protruding from the loading / unloading port 43 is grasped and removed.
The second left and right guide levers 56A and 56B biased in the closing direction follow the forward movement of the disk 1 because the rollers 5604A and 5604B are in contact with the outer peripheral edge of the disk 1. When the disk 1 is positioned on the diameter of the disk 1, the disk 1 opens greatly, and then swings in the closing direction to return to the state shown in FIG. 5.

Next, a case where a small-diameter disk 1 having a diameter of 8 cm is loaded into the disk device 100 will be described.
Also in the case of the small-diameter disc 1, for convenience of explanation, the disc device 100 does not contain the disc 1, and the upper lid 20 is closed with respect to the lower frame 10 in this state, and the slider 40 has the front end. The biasing member 53A has a natural length, and the pin 5204A of the left drive lever 52A is positioned by the biasing member 53A at a position facing the opening 47A in the left engagement groove 46A. Yes. Further, the biasing member 55 that moves the detection member 54 to the left is also a natural length, and the pin 5204B of the right drive lever 52B is located at a position facing the opening 47B in the right engagement groove 46B. ing.
First, each lock claw 1602 is opened by pressing the release button 1604, and the upper lid 20 is opened upward by the urging force of the urging member 31, so that the loading / unloading port 43 is opened.

Here, the disk 1 is loaded from the loading / unloading port 43, and the disk 1 is moved below the slider 40 along the upper surface of the guide plate 36 and the upper surface of the rear plate 34 into the disk housing space.
As a result of this movement, first, as shown in FIG. 8, the outer peripheral edge of the disk 1 has rollers 4804A and 4804B of the first left and right guide levers 48A and 48B, and rollers 5604A of the second left and right guide levers 56A and 56B. The slider 40 is moved in contact with the four positions 5604B.
When the disk 1 is further pushed in this state, the pins 4806A and 4804B move in the lateral groove portion 3802 of the base plate 30 as the disk 1 is pushed, so that the first left and right guide levers 48A as shown in FIG. , 48B are swung in the opening direction when the rollers 4804A, 4804B are pressed against the outer peripheral edge of the disk 1. The second left and right guide levers 56A and 56B are also swung in a direction to open against the urging force of the urging member 57 when the rollers 5604A and 5604B are pressed against the outer peripheral edge of the disk 1.
Unlike the case of the large-diameter disk 1, the rollers 4804 A and 4804 B of the first left and right guide levers 48 A and 48 B are provided on the disk 1 until the disk 1 is inserted into the disk device 100 and pushed out and removed. The disk 1 is always in contact with the outer peripheral edge, whereby the disk 1 is positioned with respect to the slider 40. The rollers 5604A and 5604B of the second left and right guide levers 56A and 56B come into contact with the outer peripheral edge of the disk 1 until they are positioned on the diameter of the disk 1 as the disk 1 moves rearward. The rollers 5604A and 5604B are separated from the outer peripheral edge of the disk 1 by the backward movement of the disk 1.

The first left and right guide levers 48A and 48B swing in the opening direction while the pins 4806A and 4806B move in the lateral groove portion 3802 of the base plate 30 as the disk 1 is pushed, and eventually the pins 4806A and 4806B Unlike the case of the large-diameter disk 1, since the diameter of the disk 1 is small, the disk 1 moves from the horizontal groove portion 3802 to the second vertical groove portion 3806.
When the pins 4806A and 4806B move from the lateral groove portion 3802 to the second vertical groove portion 3806, the first left and right guide levers 48A and 48B cannot swing, and the pins 4806A and 4806B become the second The first left and right guide levers 48A and 48B move rearward integrally with the slider 40 while moving in the vertical groove portion 3804 rearward.
Further, since the second right guide lever 56B is swung but has a small amount of rocking compared to the case of the large-diameter disk 1, the detection member 54 is located with respect to the engaging portion 5606B of the right guide lever 56B. The urging member 55 has a natural length without being engaged, and the detection member 54 remains at a position regulated by the urging member 55.
Therefore, unlike the case of the large-diameter disc 1, the left and right link levers 50A and 50B do not swing, and therefore the pin 5204A of the left drive lever 52A faces the opening 47A in the left engagement groove 46A. It stays in a state where it is located.
On the other hand, the right drive lever 52B remains at the position where the detection member 54 is regulated by the biasing member 55.

When the disc 1 is further pushed in from this state, the first left and right guide levers 48A and 48B are not allowed to swing by the second vertical groove portion 3806. Therefore, as shown in FIG. The guide levers 48A and 48B are moved backward together with the slider 40.
As the slider 40 moves backward, the pin 5204A of the left drive lever 52A is disengaged from the engagement groove 46A through the opening 47A, so that the left swing lever 52A has a natural length biasing member. The state regulated by 53A is maintained.

On the other hand, when the detection member 54 moves away from the right link lever 50B, the right drive lever 52B is swung by the link lever spring 51B, and the pin 5204B of the right drive lever 52B is opened by the opening 47B. To the right engagement groove 46B away from the center. Therefore, the pin 5204B is swung in the direction of moving backward by the backward movement of the slider 40.
At this time, when the slider 40 exceeds an intermediate position between the front end position and the rear end position as the slider 40 moves rearward, the toggle spring 53B moves the pin 5204B of the drive lever 52B forward. The biasing direction is switched from the state of biasing to the state of biasing in the direction by moving the pin 5204B of the drive lever 52B backward.
When the biasing force of the toggle spring 53B is switched in the direction in which the pin 5204B of the drive lever 52B is moved backward, the right drive lever 52B swings in the direction in which the pin 5204B moves backward, and the right drive lever 52B By swinging, the slider 40 is moved to the rear end position.

When the slider 40 is pushed to the rear end position, the slider 40 is locked at the rear end position by the locking mechanism. With the slider 40 positioned at the rear end position, the right drive lever 52B is moved backward by the pin 5204B by the toggle spring 53B. The state of being urged in the direction of movement is maintained.
With the upper lid 20 open, the rear plate portion 34 is inclined so that its upper surface gradually becomes lower as it goes from the front to the rear, so that the disk 1 slides rearward along the upper surface of the rear plate portion 34. Then, the outer peripheral edge (the outer peripheral edge at the tip in the direction in which the disk 1 is loaded) facing the rear of the disk 1 is positioned in contact with the rollers 4804A and 4804B of the first left and right guide levers 48A and 48B. Then, the disk 1 is set to a loading position where the center hole and the center of the turntable 1202 coincide.
When the upper lid 20 is moved downward in this state to close the loading / unloading port 43, the chuck plate 44 comes into contact with the periphery of the center hole of the disk 1 and is attracted by the magnetic force of the turntable 1202, thereby completing the mounting of the disk 1. The disk device 100 performs a reproduction or recording operation on the disk 1.

Next, a case where the small-diameter disk 1 is removed from the disk device 100 will be described.
First, when the upper cover 20 is moved upward by pressing the release button 1604 and the loading / unloading port 43 is opened, the slider 40 is unlocked by the locking mechanism, so that the slider 40 is moved from the rear end position to the front end position. It becomes possible to move. As described above, since the right drive lever 52B is biased in the direction in which the pin 5204B moves backward by the toggle spring 53B, the slider 40 remains at the rear end position.
Next, when the operation portion 5802 of the eject lever 58 is moved against the urging force of the urging member 59, the engagement piece 5804 of the eject lever 58 is engaged with the pin 5206B of the right drive lever 52B and the right drive lever 52B. Is swung in the direction in which the pin 5204B moves forward.
By swinging the right drive lever 52B, the slider 40 is moved from the rear end position toward the front end position.
When the slider 40 is moved from the rear end position toward the front end position and reaches the intermediate position, the toggle spring 53B moves from the state in which the pin 5204B of the drive lever 52B is moved rearward and biased in the direction. The pin 5204B is switched to a state in which the pin 5204B is urged forward.
Accordingly, the slider 40 is moved from the rear end position to the front end position by swinging the drive lever 52B in the direction of moving the pin 5204B forward.

At this time, the first left and right guide levers 48A and 48B cannot swing while the pins 4806A and 4806B move in the second vertical groove portion 3806 of the base plate 30 as the slider 40 moves forward. The first left and right guide levers 48A and 48B move forward together with the slider 40 in an open state.
When the pins 4806A and 4806B move from the second vertical groove portion 3806 to the horizontal groove portion 3802, the first left and right guide levers 48A and 48B swing in the closing direction as the slider 40 moves forward. The outer peripheral edge of the disk 1 is pushed forward by the rollers 4804A and 4804B of the left and right guide levers 48A and 48B, and the state shown in FIG. 8 is restored.
As a result, the disk 1 is moved toward the loading / unloading port 43, and the disk 1 is set to a discharge position where a part of the disk 1 protrudes outward from the loading / unloading port 43.
Here, the disc 1 exposed from the loading / unloading port 43 is grasped and removed.
When the second left and right guide levers 56A and 56B biased in the closing direction are brought into contact with the outer peripheral edge of the disk 1, the disk 1 follows the movement of the disk 1 forward. When it is located on the diameter, it opens wide, then swings in the closing direction, and returns to the state shown in FIG.

In this embodiment, the center of the disk 1 is the center of the turntable 1202 at the rear end position of the slider 40 regardless of whether the disk 1 inserted into the loading / unloading port 43 is a large diameter disk or a small diameter disk. A disk positioning mechanism that positions the disk 1 at a matching loading position and positions the disk 1 at a discharge position where a part of the disk 1 protrudes outward from the loading / unloading port 43 at the front end position of the slider 40 swings on the slider 41. First left and right guide levers 48A and 48B, which are supported in such a manner as to be able to come into contact with two circumferentially spaced portions of the outer periphery of the disk 1 and are urged in a closing direction, and first left and right guide levers The first left and right guide levers 48A, 48 are engaged with 48A, 48B and follow the size of the diameter of the disk 1 and the back and forth movement of the slider 40. It is composed of a guide groove 38 which determines the degree of opening.
In the present embodiment, the first left and right guide levers 48A and 48B are arranged at positions that are substantially symmetrical with respect to the locus of the center of the large-diameter disk or small-diameter disk that moves between the loading position and the discharging position. ing.
In addition, when the disk 1 loaded into the loading / unloading port 43 is a large-diameter disk 1, a slider driving mechanism for a large-diameter disk that moves the slider 40 from the front end position to the rear end position and from the rear end position to the front end position is provided. The first left and right guide levers 48A and 48B, the guide groove 38, the left drive lever 52A which is detachably engaged with the slider 40 and swings in conjunction with the back and forth movement of the slider 40, and the slider 40 The urging member 53A urges the left drive lever 52A in the direction of urging the front end position.
In addition, when the disk 1 loaded into the loading / unloading port 43 is a small-diameter disk, a slider driving mechanism for a small-diameter disk that moves the slider 40 from the front end position to the rear end position and from the rear end position to the front end position is provided. The left and right guide levers 48A and 48B, the guide groove 38, the right drive lever 52B which is detachably engaged with the slider 40 and swings in conjunction with the back and forth movement of the slider 40, and the slider 40 is located at the front end position. When the slider 40 is positioned at an intermediate position with respect to the rear end position, the right drive lever 52B is urged so that the slider 40 reaches the front end position, and when the slider 40 exceeds the intermediate position toward the rear end position, the slider 40 moves. A toggle spring 53B that urges the right drive lever 52B to reach the rear end position, and a right spring so as to return the slider 40 from the rear end position to the intermediate position. It is composed of a eject lever 58 for swinging the dynamic lever 52B.
When the disk 1 loaded into the loading / unloading port 43 is a large-diameter disk 1, the large-diameter disk slider drive mechanism is operated, and when the disk 1 loaded into the loading / unloading port 43 is a small-diameter disk. The switching mechanism that switches between the large-diameter disk slider driving mechanism and the small-diameter disk slider driving mechanism so as to operate the small-diameter disk slider driving mechanism includes an outer edge of the disk on which the first left and right guide levers 48A and 48B abut. The second left and right guides that come into contact with the outer edge of the disk closer to the loading / unloading port 43 than the position and swing with a larger stroke than the first left and right guide levers 48A and 48B in conjunction with the movement of the disk. Lever 56A, 56B and the left drive lever 52A and the right drive lever attached to the slider 40 so as to be swingable 2 L of link levers 50A and 50B which can be engaged with 2B, and the link lever spring which urges | biases the engaging part of the right drive lever 52B in the direction of the 2nd engaging groove location away from the said 2nd open part. 51B and a second disc when the disc 1 inserted in the loading / unloading port 43 and disposed in the upper lid 20 so as to be movable in a direction orthogonal to the locus of the center of the large-diameter disc or the small-diameter disc is a large-diameter disc. Engage with one of the left and right guide levers 56A, 56B, keep the engaging portion of the right drive lever 52B in the second open portion, and engage with the left and right link levers to swing the left and right link levers 50A, 50B Then, the pin 5204A of the left drive lever 52A is moved to a position in the left engagement groove 46A away from the opening 47A, and the left and right link levers when the disk 1 loaded into the loading / unloading port 43 is a small-diameter disk. The left and right link levers 50A and 50B are swung by the link lever springs 51A and 51B away from 0A and 50B, and the pin 5204B of the right drive lever 52B is moved to a position in the right engagement groove 46B away from the opening 47B. And a detecting member 54 to be operated.
That is, when the disk 1 is a large-diameter disk, the switching mechanism engages the left drive lever 48A with the slider 40 and removes the right drive lever 48B from the slider 40, and when the disk 1 is a small-diameter disk. The left drive lever 48A is detached from the slider 40 and the right drive lever 48B is engaged with the slider 40.
The configuration of such a switching mechanism is not limited to the structure of the embodiment, and can be configured by a combination of various conventionally known mechanisms and structures.

According to the present embodiment, both of the large and small diameter disks are mounted / removed without using a motor, which is advantageous in reducing power consumption and is particularly portable for which low power consumption is required. Therefore, it is advantageous in adopting the disk device.
In addition, when a motor is used, in order to load and unload two types of discs having different diameters, it is necessary to control the amount of movement of the disc according to the disc diameter. In addition, it is necessary to provide a control circuit that controls the drive amount of the motor according to the diameter of the disk, but in this embodiment, such a control circuit is not required, so the increase in the number of parts can be suppressed and the cost can be reduced. This is advantageous in achieving this.

  In this embodiment, the case where an optical disc such as a CD or a DVD is used as an information recording medium (disc-shaped recording medium) on which the disc device 100 performs recording and / or reproduction is described. However, the information recording medium is such an optical disc. Of course, various information recording media such as a magneto-optical disk and a magnetic disk may be used.

1 is a perspective view of a disk device 100. FIG. 3 is an exploded perspective view of the disk device 100. FIG. It is the perspective view seen in the state where the upper and lower sides of the slider 40 were reversed. It is the perspective view seen in the state which turned the upper cover and the base plate upside down. It is explanatory drawing of the mounting | wearing operation | movement of a large diameter disc. It is explanatory drawing of the mounting | wearing operation | movement of a large diameter disc. It is explanatory drawing of the mounting | wearing operation | movement of a large diameter disc. It is explanatory drawing of the mounting | wearing operation | movement of a small diameter disc. It is explanatory drawing of the mounting | wearing operation | movement of a small diameter disc. It is explanatory drawing of the mounting | wearing operation | movement of a small diameter disc.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 ... Disk apparatus, 10 ... Lower frame, 20 ... Upper lid, 30 ... Base plate, 40 ... Slider, 48A, 48B ... First guide lever, 50A, 50B ... Link lever, 52A, 52B ... ... Drive lever, 54 ... Detection member, 56A, 56B ... Second guide lever, 58 ... Eject lever.

Claims (6)

A disk loading / unloading mechanism in a disk apparatus for loading / unloading a large-diameter disk and a small-diameter disk having different sizes, which are disk-shaped information recording media,
The disk device is
A lower frame provided with a spindle motor, a base plate pivoted up and down with respect to the lower frame and pivoted up and down with respect to the lower frame, and an upper lid attached to the base plate so as to cover the upper side of the base plate And a slider coupled to the base plate so as to be movable between a front end position below the upper lid and above the base plate, where the disk is loaded and unloaded, and a rear end position where the disk is mounted on the spindle motor. A chuck plate that is provided on the slider and presses the disk against a disk mounting portion of a spindle motor when the slider is positioned at the rear end position and the upper cover is closed, and is separated from the disk when the upper cover is opened; Formed above the base plate and below the slider and chuck plate. Comprising a disk accommodating space, and a loading and unloading opening the upper lid exposed by the upper cover is provided to open the front end of the disc accommodating space is closed by closing,
The loading / unloading mechanism is
Regardless of whether the disk loaded in the loading / unloading port is a large-diameter disk or a small-diameter disk, the center of the disk at the rear end position of the slider is at a loading position that matches the center of the disk mounting portion. A disk positioning mechanism that positions the disk and positions the disk at a discharge position where a part of the disk protrudes outward from the loading / unloading port at the front end position of the slider;
A large-diameter disk slider drive mechanism for moving the slider from the front end position to the rear end position and moving from the rear end position to the front end position when the disk loaded into the loading / unloading port is a large diameter disk;
A slider driving mechanism for a small-diameter disk that moves the slider from the front end position to the rear end position and moves from the rear end position to the front end position when the disk inserted into the loading / unloading port is a small-diameter disk;
A locking mechanism that engages with the slider when the slider is located at the rear end position, holds the slider at the rear end position, and closes the upper lid and then opens and then the engagement with the slider is released;
When the disk loaded into the loading / unloading port is a large diameter disk, the slider driving mechanism for the large diameter disk is operated, and when the disk loaded into the loading / unloading port is a small diameter disk, the slider driving for the small diameter disk is performed. A switching mechanism for switching between the large-diameter disk slider driving mechanism and the small-diameter disk slider driving mechanism to operate the mechanism,
The disk positioning mechanism includes a first left and right guide lever that is supported by the slider so as to be swingable and is capable of contacting the two circumferentially spaced portions of the outer periphery of the disk and biased in a closing direction. A guide groove that engages with the first left and right guide levers and determines the opening of the first left and right guide levers following the size of the disk and the back and forth movement of the slider;
The slider driving mechanism for the large-diameter disk includes a first left and right guide lever, the guide groove, and a first swinging mechanism that is detachably engaged with the slider and swings in conjunction with the back-and-forth movement of the slider. A drive lever and spring means for urging the first drive lever in a direction to urge the slider to the front end position;
The small-diameter disk slider drive mechanism includes a second drive that slidably engages with the first left and right guide levers, the guide groove, and the slider and swings in conjunction with the back-and-forth movement of the slider. When the lever and the slider are located at an intermediate position between the front end position and the rear end position, the second drive lever is urged so that the slider reaches the front end position, and the slider is moved to the intermediate position. A toggle spring that biases the second drive lever so that the slider reaches the rear end position when the position exceeds the rear end position, and the slider is returned from the rear end position to the intermediate position. And an eject lever that swings the second drive lever.
When the disk is a large-diameter disk, the switching mechanism engages the first drive lever with the slider and removes the second drive lever from the slider, so that the disk is a small-diameter disk. Is configured to disengage the first drive lever from the slider and to engage the second drive lever with the slider.
A disk loading / unloading mechanism in the disk device.   2. The disk loading / unloading mechanism according to claim 1, wherein when the upper lid is opened, an upper surface of the base plate facing the disk housing space is inclined so as to gradually become lower as it approaches the rear end. .   The first left and right guide levers swing at the positions of the slider at positions substantially symmetrical with respect to the locus of the center of the large diameter disk or small diameter disk moving between the loading position and the discharging position. 2. The disk loading / unloading mechanism according to claim 1, wherein the disk loading / unloading mechanism is movably mounted.   The first left and right guide levers are located at positions where the sliders are substantially symmetric with respect to the locus of the center of the large diameter disk or small diameter disk moving between the loading position and the discharging position, respectively. The roller is attached to the first left and right guide levers in contact with the outer peripheral portion of the disk, and is coaxial with the roller and coaxial with the roller. 2. The disk loading / unloading mechanism according to claim 1, wherein a pin provided below is engaged with the guide groove.   The first drive lever and the second drive lever are substantially bilaterally symmetrical with respect to the locus of the center of the large-diameter disk or small-diameter disk that moves between the loading position and the discharge position at the location of the upper lid. A middle portion of the longitudinal direction is attached to a place so as to be swingable, and a first part extending in a direction orthogonal to the center locus at a position substantially symmetrical with respect to the center locus at the front portion of the slider. The first engagement groove and the second engagement groove are respectively provided, and the first engagement groove and the second engagement groove are provided at the ends in the extending direction of the first engagement groove. An opening portion and a second opening portion are provided, and the engaging portion of the first drive lever is disposed in the first engaging groove portion facing the first opening portion, and the second driving lever is provided. The engaging portion of the drive lever is disposed in the second engaging groove portion facing the second opening portion. The engagement / disengagement of the first drive lever with the slider by the switching mechanism involves engaging / disengaging the engagement portion of the first drive lever with the first engagement groove via the first opening portion. The engagement and disengagement of the second drive lever with respect to the slider by the switching mechanism is performed by engaging the engagement portion of the second drive lever with the second engagement groove through the second opening portion. 2. The disk loading / unloading mechanism according to claim 1, wherein the disk loading / unloading mechanism is performed by removing the disk.   The first left and right guide levers are swingably attached to the upper lid portion that is substantially symmetrical with respect to the locus of the center of the large-diameter disk or small-diameter disk that moves between the loading position and the discharging position. The switching mechanism is swingably attached to the upper lid portion that is substantially bilaterally symmetrical with respect to the center trajectory, and is attached to the loading / unloading port more than the outer edge portion of the disc with which the first left and right guide levers abut. Second left and right guide levers that come into contact with the outer edge of the disk closer to the disk and swing with a larger stroke than the first left and right guide levers in conjunction with the movement of the disk, and swingable to the slider Left and right link levers that are attached and engageable with the first drive lever and the second drive lever, and a second engagement that separates the engagement portion of the second drive lever from the second opening portion Groove A link lever spring that is biased in the direction, and the second lid when the disk that is disposed in the upper lid so as to be movable in a direction perpendicular to the locus of the center and is inserted into the loading / unloading port is a large-diameter disk. The left and right guide levers are engaged with each other, the engaging portion of the second drive lever is fastened to the second opening portion, and the left and right link levers are swung to engage the left and right link levers. When the engaging portion of the first drive lever is moved to a location in the first engaging groove away from the first opening portion, and the disc loaded in the loading / unloading port is a small-diameter disc, the left and right The left and right link levers are swung by the link lever spring away from the link lever and the engagement portion of the second drive lever is separated from the second opening portion in the second engagement groove. And a detection member to be moved to Disk attaching and detaching mechanism in the disk apparatus according to claim 5,.

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