JPH07240052A - Emergency ejection mechanism for disk device - Google Patents

Abstract

PURPOSE:To perform emergency ejection of a disk tray with a simple structure. CONSTITUTION:A pinion 38 is freely rotatably fitted to an outer circumference of a guide pin 39 provided on a freely rotatable gear base 41, and the guide pin 39 and the pinion 38 are engaged with a guide groove 37 and a rack 36, provided on the lower surface of the disk tray 4 to be parallel to each other having approximately J-shapes respectively. Then, a radius of curvature of a 1st circular-arcuate part 37b of the guide groove 37 is made smaller than a rotary radius of the guide pin 39, and an ejecting cam mechanism 60 is composed of the 1st circular-arcuate part 37b and the guide pin 39.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an emergency eject mechanism of a disc device, which is most suitable for a CD player, a CD-ROM drive or the like.

[0002]

2. Description of the Related Art The applicant of the present invention has disclosed, for example, in Japanese Unexamined Patent Publication No. Hei 2 (1999) -26,088 as a disk device capable of power loading and ejecting a disk tray from a disk device body.
An earlier application example as seen in Japanese Patent Publication No. 66772 is filed first.

[0003]

However, in this prior application, the disc tray is manually ejected in an emergency such as when the power cannot be turned on due to a power failure or an electric system failure while the disc tray is being loaded. hand,
There was no emergency eject mechanism to remove the disc.

The present invention has been made to solve the above problems, and it is an object of the present invention to provide an emergency eject mechanism for a disk device which has a simple structure and can perform an emergency eject of a disk tray. I am trying.

[0005]

In order to achieve the above object, an emergency eject mechanism of a disc device of the present invention loads and ejects a recording and / or reproducing disc into the disc device main body. A disc tray, a rack and a guide groove provided on the lower surface of the disc tray and parallel to each other and formed in a substantially J shape, and a gear base provided in the disc device body and rotated about a fulcrum shaft. A guide pin that is loosely fitted in the guide groove provided on the gear base and is rotated about a fulcrum shaft of the gear base, and is rotatably attached to the outer periphery of the guide pin and meshed with the rack. A pinion driven to rotate forward and backward by a motor provided in the disk device main body, and the rack and guide parallel to each other. Connected to the ends of the straight part of the groove on the eject direction side, the guide grooves are formed in arcs parallel to each other so that they are inside, and the radius of curvature of the guide groove is smaller than the radius of rotation of the guide pin. By the ejecting cam mechanism configured by the configured first arc portion, the guide pin and the first arc portion of the guide groove, and the gear base being rotationally driven in the eject direction, It is provided with an emergency eject means for pushing the disc tray from the inside of the disc device main body in the eject direction by a cam action.

[0006]

According to the emergency eject mechanism of the disk device of the present invention constructed as described above, a rack and a guide groove which are parallel to each other and are formed in a substantially J-shape are provided on the lower surface of the disk tray, and are provided in the disk device main body. A guide pin is provided on a gear base that is provided and is rotated around a fulcrum shaft, and the guide pin is loosely fitted in the guide groove, and a pinion rotatably attached to the outer periphery of the guide pin is attached to the rack. Since the radius of curvature of the first circular arc portion of the guide groove is made smaller than the radius of rotation of the guide pin and the ejecting cam mechanism is constituted by the guide pin and the first circular arc portion of the guide groove, the emergency is achieved.・ The eject mechanism can rotate the gear base in the eject direction, and the ejecting cam mechanism can act as a cam. Kutore can the extruded manually operated ejection direction from the disk apparatus body, it is not necessary to provide the emergency eject dedicated mechanism.

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will now be described with reference to a CD player and a CD-ROM.
Immediateness of the disk unit applied to the drive
The eject mechanism will be described with reference to the drawings.

[Explanation of Disk Device] First, referring to FIG.
The outline of the disk device will be described with reference to FIG.

This disk device is a CD or a CD-ROM.
For reproducing a disc 1 such as an optical disc or a magneto-optical disc, a center hole 1a is formed in the disc 1.

The disk device body 2 is formed in a flat box shape and has a horizontally long opening 3 in the front panel 2a.
Are formed. And the disc tray 4 has the opening 3
Is configured to be horizontally loaded and ejected from the disk device main body 2 in the arrow a direction which is the loading direction and the arrow b direction which is the eject direction.

The disc tray 4 is formed of synthetic resin or the like, and has a substantially circular recess 5 on its upper surface.
Are formed. The disc 1 is horizontally placed in the recess 5, and the disc tray 4 loads and ejects the disc 1 into the disc device main body 2. An opening 6 is formed in the disc tray 4 from the center of the recess 5 to the end on the arrow a direction side.

An eject button 7 and an emergency eject hole 8 are provided on the lower side of the front panel 2a of the disk device body 2.

[Disc Loading Operation] Then, at the time of disc loading, as shown in FIG. 16, after the disc 1 is horizontally placed in the recess 5 of the disc tray 4, the front panel 4a of the disc tray 4 is arrowed with a finger. When it is lightly pushed in the a direction, a loading switch (not shown) is turned on, and the disc tray drive mechanism, which will be described later, causes the disc tray 4 to be power loaded into the disc device main body 2 from the direction of the arrow a as shown in FIG. .

[Disc Eject Operation] At the time of disc eject, in the disc loading state shown in FIG. 17, the eject button 7 is pressed to turn on an eject switch (not shown), or by an eject signal from the host computer. The disc tray drive mechanism, which will be described later, is operated, and the disc tray 4 is moved to the position shown in FIG.
As shown in FIG. 3, power is ejected from inside the disk device body 2 in the direction of arrow b.

[Emergency Eject Operation] In the disk loading state shown in FIG. 17, when performing an emergency eject of the disk 1 in an emergency such as when the power cannot be turned on due to a power failure or a failure of the electric system. Inserts a wire-shaped emergency eject operating member 9 such as a clip in the direction of arrow a from the emergency eject hole 8 of the front panel 2a of the disk device body 2. Then, by the emergency eject mechanism described later, the disc tray 4 is pushed out from the inside of the disc device main body 2 by a constant distance L ₁ (see FIGS. 1 and 4) in the direction of arrow b. Therefore, the disc tray 4 can be pulled out in the direction of arrow b by manually operating the front panel 4a of the disc tray 4 by hand.

[Description of Disk Device Body] Next, FIG.
The configuration of the disk device body 2 will be described with reference to FIGS.

The disk device body 2 includes a front panel 2a and a chassis 2b made of synthetic resin or the like.
And a pair of upper and lower covers 2c and 2d formed of a stainless thin plate or the like form a flat box-shaped case. A printed circuit board 2e is horizontally installed between the lower portion of the chassis 2b and the lower cover 2d.
As shown in FIGS. 7 and 9, a pair of horizontal left and right guide rails 4b integrally formed on the left and right side surfaces of the disc tray 4 are formed inside the left and right side walls 2b 'of the chassis 2b. It is slidably fitted in the pair of guide grooves 10.

[Description of Disc Chucking Mechanism] Next, referring to FIGS. 4 to 6 and 13 to 15, the disc chucking mechanism 11 provided in the disc device main body 2 will be described.
Will be explained.

The disc chucking mechanism 11 has a disc table 13 which is rotationally driven by a spindle 12a of a spindle motor 12 and a chucking pulley 14.

A pulley holder 15 is horizontally installed between upper ends of the left and right side walls 2b 'of the chassis 2b at a position above the insertion space of the disc tray 4. And
The chucking pulley 14 is loosely fitted in a circular holder hole 15a formed in the central portion of the pulley holder 15 so as to be movable vertically and horizontally within a certain range. A metal plate 14a such as an aluminum plate is horizontally embedded in the center of the chucking pulley 14, and a flange 14b integrally formed on the outer periphery of the upper end of the chucking pulley 14 is formed on the inner periphery of the holder hole 15a. It abuts on a flange 15b integrally formed at the lower end and is suspended in a position higher than the disk 1 to be loaded.

A substantially rectangular opening 16 is formed in a substantially central portion of the chassis 2b, and a chucking frame 17 is arranged in the opening 16. An arrow a of the chucking frame 17 is formed by a pair of left and right insulators 19 formed of rubber or the like and screwed onto the chassis 2b by a pair of left and right set screws 18.
Both left and right sides of the end portion 17a on the direction side are supported.

At the end of the opening 18 on the arrow b direction side, the chucking lever 20 is arranged on the chassis 2b in a state orthogonal to the arrow a and b directions. The chucking lever 20 is formed of synthetic resin or the like, and the chucking lever 20 is integrally formed at one end thereof with a pair of horizontal fulcrum shafts 2 parallel to the directions of arrows a and b.
1 on the chassis 2b through the arrows 1 and 2
Is attached rotatably in a direction, is formed of rubber or the like, and is attached to an end portion 17 of the chucking frame 17 on the arrow b direction side by an insulator 23 screwed onto the tip 20a of the chucking lever 20 by a set screw 22.
The central part of b is supported.

Therefore, the chucking frame 20 is moved downward by the chucking lever 20 as shown in FIG.
Between the raised position shown in FIG. 15, the pair of left and right insulators 19 is used as a fulcrum of rotation so as to be rotatable in the up and down directions of arrows c and d.

The spindle motor 12 is vertically fixed vertically upward at a position near the end 17b of the chucking frame 17 on the arrow b direction side, and the disk table 13 is horizontally fixed at the upper end of the spindle 12a. ing.

An opening 24 is formed behind the spindle motor 12 of the chucking frame 17, and a carriage 27 having an objective lens 26 of an optical pickup 25 is movable in the opening 24 in the directions of arrows a and b. It is located in.

The carriage 27 is guided by a pair of left and right guide shafts 28 attached to the chucking frame 17, and a pinion 31 driven by a motor 29 attached to the chucking frame 17 via a gear train 30. A linear motor mechanism 33 including a rack 32 fixed to the carriage 27 is configured to move the carriage 27 in the directions of arrows a and b.

[Disc chucking operation] First, referring to FIG.
As shown in FIG. 4, while the chucking frame 17 is lowered to the lowered position in the arrow c direction by its own weight, the disc tray 4 horizontally moves the disc 1 into the disc device main body 2 from the arrow a direction as described later. When loaded, the disc 1 is inserted between the disc table 13 and the chucking pulley 14.

After this loading is completed, the chucking lever 20 is driven in the direction of arrow d as described later, and the chucking frame 17 is raised in the direction of arrow d to the raised position as shown in FIG. Become.

At this time, the disc table 13 is inserted into the opening 6 of the disc tray 4 from the direction of arrow d, fitted in the center hole 1a of the disc 1 from the direction of arrow d, and the disc table 13 is moved. The disc 1 is pushed upward in the recess 5 of the disc tray 4.

At this time, the disc table 13 raises the chucking pulley 14 together with the disc 1, and at the same time, the chucking pulley 14 is moved by a chucking magnet (not shown) embedded in the upper surface of the disc table 13. The metal plate 14a is sucked downward. Then, the chucking pulley 14 is attached to the center hole 1 of the disc 1.
The outer periphery of a is magnetically chucked on the disk table 13.

[Disc Reproducing Operation] After chucking the disc 1, the disc 1 is rotationally driven integrally with the disc table 13 which is rotationally driven by the spindle motor 12, and the carriage 27 of the optical pickup 25 is driven.
Is moved in the directions of arrows a and b by the linear motor mechanism 33, and the objective lens 26 reproduces the disc 1.

[Disc chucking release operation] After the disc 1 is reproduced, the chucking lever 20 is driven in the direction of arrow c as described later, and the chucking frame 17 is driven by its own weight in the direction of arrow c as shown in FIG. When the disc table 13 is lowered, the disc table 13 is detached from the center hole 1a of the disc 1 and lowered in the direction of arrow c to a position below the disc tray 4. Then, the disc 1 is placed on the recess 5 of the disc tray 4 again, and the chucking pulley 14 is brought into contact with the flange 15b of the pulley holder 15 by the flange 14b so that the disc 1 is suspended in the air above the disc 1 again. Becomes

After the chucking is released, the disc 1 is ejected from the disc device main body 2 in the direction of arrow b by the disc tray 4 as described later.

[Description of Disc Tray Drive Mechanism] Next,
1 to 15, a disc tray drive mechanism 3 for loading and ejecting the disc tray 4
5 will be described.

The disc tray drive mechanism 35 is formed along the inner surface of the disc tray 4 and is formed in parallel with each other in a substantially J-shaped rack 36 and a guide groove 37, and a pinion 38 and a guide groove 37 for driving the rack 36. The guide pin 39, which is moved by the guide pin 39, the motor 40 which drives the pinion 38 to rotate forward and backward, the gear base 41 which is driven to rotate by the guide pin 39, and the cam lever 41 which drives the chucking lever 20 to rotate. It has a cam lever 42 and the like.

As shown in FIGS. 1 to 6 and 10, the gear base 41 is made of synthetic resin or the like,
The cylindrical boss 41a integrally formed on the base end of the gear base 41 is inserted into the outer periphery of the vertical fulcrum shaft 43 integrally formed on the chassis 2b, and the gear base 41 is centered on the fulcrum shaft 43. It is attached rotatably in the e and f directions. A guide pin 39 is vertically integrally formed on the upper end of the gear base 41, and a pinion 38 is inserted around the guide pin 39 and rotatably attached.

A belt is provided between the drive pulley 44 fixed to the outer circumference of the motor shaft 40a of the motor 40 mounted upward on the chassis 2b and the driven pulley 45 rotatably mounted to the outer circumference of the boss 41a. 46 is wrapped around. An intermediate gear 47 composed of a two-stage gear is inserted and rotatably attached to the outer periphery of a vertical support shaft 41b integrally formed on the intermediate portion of the gear base 41. Then, the intermediate gear 47 is the driven pulley 4
5, the input gear 48 integrally formed on the lower surface of the pinion 3, and the pinion 3
8 is meshed with an output gear 49 integrally formed on the lower surface of the gear 8, and these gears 48, 47 to 49 form a deceleration gear train. The gear train and the belt 46 constitute a pinion drive mechanism 50.

The input gear 48 is a sun gear, and the pinion 38, the output gear 49, and the intermediate gear 47 are planet gears that move circularly along the outer circumference of the input gear 48.

As shown in FIGS. 8 and 9, the pinion 38 is engaged with the rack 36, and the upper end of the guide pin 39 is loosely fitted in the guide groove 37.

Then, as shown in FIGS. 10 and 11,
The cam lever 42 is made of synthetic resin or the like, and the cylindrical boss 42a integrally formed on the intermediate portion of the cam lever 42 is inserted into the outer periphery of the vertical fulcrum shaft 52 integrally formed on the chassis 2b. , The cam lever 42 is the fulcrum shaft 5
It is attached so as to be rotatable in the directions of arrows g and h around 2. Partial gears 53 and 54 integrally formed with the side surface of the base of the gear base 41 and the side surface of one end of the cam lever 42 are meshed with each other.

A substantially Z-shaped cam groove 55 integrally formed on the side surface of the boss 42a of the cam lever 42 and one side surface of the tip of the chucking lever 20 are integrally formed and loosely fitted in the cam groove 55. A cam mechanism 57 is configured by the cam driven pin 56 thus formed. The cam groove 55 is composed of a low part 55a and a high part 55b which are horizontal steps, and an inclined part 55c which directly connects these parts, and the low part 55a is centered on the boss 42a. It is formed to be relatively long in the circumferential direction.

Then, as shown in FIG. 8, the rack 36 and the guide groove 3 integrally formed on the lower surface of the disc tray 4 are formed.
The pinions 38 are parallel to each other with a radius r of the pinion 38 and are formed in a substantially J shape. The rack 36 and the guide groove 37 are straight lines parallel to the arrow a direction which is the loading direction of the disc tray 4. The portions 36a and 37a and the arrow b which is the eject direction of the linear portions 36a and 37a
The guide groove 37 is connected to the end on the direction side smoothly in order.
First arcuate portions 36b and 37b and second arcuate portions 36c and 37c that are formed in parallel arcuate shapes so that the inside is
And have.

At this time, the first circular arc portion 37b of the guide groove 37 is formed.
The radius of curvature R ₂ of the center of the second arcuate portion 37c smoothly connected to each other is equal to the radius of gyration of the center of the guide pin 38 which is rotated about the fulcrum shaft 43 as the center O _{2 in the} directions of arrows e and f. , The first smoothly connected to the straight portion 37a
The arc portion 37b is formed in an arc shape around the virtual center O _1, and the radius of curvature R of the center of the first arc portion 37b is R.
₁ is smaller than the radius of curvature R ₂ of the center of the second arc portion 37c.

The radius of curvature of the first arc portion 36b of the rack 36 is R ₁ + r, and the radius of curvature of the second arc portion 36c is R ₂ + r.

[Explanation of Emergency Eject Mechanism] Next, referring to FIG. 1 to FIG.
The eject mechanism 59 will be described.

First, as shown in FIG. 8 in particular, the emergency eject mechanism 59 is used for the disc tray 4
The first substantially the radius of curvature R ₁ of the J-shaped guide groove 37 is small
The ejecting cam mechanism 60 includes an arc portion 37b and a guide pin 39 on the tip of the gear base 41.

As shown in FIG. 10 to FIG. 12, an emergency eject slider 61 is arranged inside the front panel 2a in the disk device main body 2 at a position just behind the emergency eject hole 8. Has been done.

The emergency eject slider 61 is formed of a synthetic resin or the like into a substantially L shape by a horizontal plate 61a and a vertical plate 61b, and is formed in the chassis 2b in a guide groove parallel to the directions of arrows a and b. 62
It is configured so that it can move linearly in the directions of arrows a and b. The vertical plate 61b is integrally formed with a recess 61c facing the emergency eject hole 8 on the side of the front panel 2b.

The arm 42b extending to the side opposite to the partial gear 54 of the cam lever 42 is in contact with the vertical plate 61b of the emergency eject slider 61 from the direction of arrow b.

Therefore, the emergency eject means is the emergency eject slider 61.
And a cam lever 42.

[Loading Operation of Disc Tray] First, when the disc tray 4 shown in FIG. 16 is completely ejected in the direction of arrow b, as shown by the two-dot chain line in FIG.
The pinion 38 and the guide pin 39 are positioned at the ends of the linear portions 36a, 37a of the rack 36 and the guide groove 37 of the disc tray 4 on the arrow a direction side.

Next, when the loading switch is turned on as described above, the motor 40 of the disc tray drive mechanism 35 shown in FIGS. 1 to 6 is driven to rotate normally, and the pinion 38 is moved through the pinion drive mechanism 50. In the position shown by the chain double-dashed line in FIG.

At this time, the guide pin 39 is engaged in the straight portion 37a of the guide groove 37, and the guide pin 39 causes the arrow e centered on the fulcrum shaft 43 of the gear base 41,
Free rotation in the f direction is restricted. Therefore, the pinion 39 smoothly rotates at the fixed position in the direction of the arrow n, and drives the linear portion 36a of the rack 36 in the direction of the arrow a smoothly.

Then, the disc tray 4 is integrally loaded with the rack 36 in the disc apparatus main body 2 in the direction of arrow a, and the pinion 38 and the guide pin 39 relatively move the straight portion 37a of the guide groove 37 in the direction of arrow b. Moving.

Then, the loading of the disc tray 4 in the direction of the arrow a progresses, and eventually, as shown by the solid line in FIGS. 1, 3 and 8, the pinion 38 and the guide pin 39 are aligned with the linear portion 37a of the guide groove 37. Center and first arc portion 37b
Reach the intersection P ₁ with the center of.

Then, the pinion 38 is continuously driven to rotate in the direction of the arrow m, so that the pinion 38 rolls in the direction of the arrow f along the first arc portion 36b of the rack 36, and the gear base 41 moves. The fulcrum shaft 43 is rotated about the center O ₂ in the arrow f direction, and the guide pin 39 advances in the first arc portion 37b of the guide groove 37 in the arrow f direction.

At this time, the first circular arc portion 37b of the guide groove 37 is formed.
Since the radius of curvature R ₁ of the center of the guide pin 39 is smaller than the radius of rotation of the center of the guide pin 39 with the fulcrum shaft 43 as the center O ₂ , while the guide pin 39 advances along the first arc portion 37b in the direction of arrow f. Then, the moving speed of the disc tray 4 in the arrow a direction is reduced.

That is, as shown in FIG. 8, the second arc portion 37 of the guide groove 37 is formed with a radius of curvature R ₂ equal to the radius of rotation of the guide pin 39 with the fulcrum shaft 43 as the center O _2.
The intersection point P ₂ of the extension line of the center of c in the direction of arrow e and the extension line of the center of the straight line portion 37a in the direction of arrow b, and the straight line portion 37
The distance L _{1 in the} directions of arrows a and b between the intersection point P ₁ of the center of a and the center of the first arc portion 37b is set to, for example, about 10.5 mm, and within this distance L ₁ , the disc tray 4 The moving speed in the direction of arrow a is reduced.

Then, as shown by the dotted lines in FIGS. 2, 5 and 8, the pinion 38 and the guide pin 39 are connected to the guide groove 3.
When the intersection P ₃ of the center of the first circular arc portion 37 b and the center of the second circular arc portion 37 c is reached, the disc tray 4 is completely inserted into the disc device main body 2 in the direction of the arrow a, The loading operation is completed.

When the pinion 38 is continuously driven to rotate in the direction of the arrow m, the pinion 38 rolls in the direction of the arrow f along the second arc portion 36c of the rack 36. At this time, the pinion 38 rotates. The rolling distance of the arrow 38 in the direction of the arrow f within the second arc portion 36c corresponds to the advance process of the overstroke operation. The gear base 41 continues to rotate about the fulcrum shaft 43 as the center O _{2 in the} direction of the arrow f by the step of the overstroke operation of the pinion 38 in the direction of the arrow f, and the guide pin 39 moves in the second arc of the guide groove 37. Proceed in the direction of arrow f in the portion 37c.

At this time, the second circular arc portion 37c of the guide groove 37 is formed.
The radius of curvature R ₂ of the center of the guide pin 39 is equal to the radius of gyration of the center of the guide pin 39 with the fulcrum shaft 43 as the center O ₂ , so that the guide pin 39 smoothly moves in the second arc portion 37c in the direction of arrow f. Then, the disc tray 4 is held at the loading completion position as it is.

Then, as shown by the alternate long and short dash line in FIGS. 3 and 8, the pinion 38 and the guide pin 39 are connected to the guide groove 37.
The detection switch (not shown) detects that the end P ₄ of the second circular arc portion 37c has been reached from the rotation angle of the gear base 41 or the like, and the eject motor 40 is stopped.

Incidentally, as shown in FIGS. 1 to 3 and 4 to 6, while the pinion 38 advances from the intersection point P ₁ through the intersection point P ₃ to the terminal end P _{4 in the} direction of arrow f, the gear base 41 is also drawn. 1 to the position shown in FIG. 3, the cam lever 42 is rotationally driven in the direction of arrow f around the fulcrum shaft 43, and the cam lever 42 is moved from the position shown in FIGS. 6 is rotated in the direction of arrow h to the position shown in FIG. Then, the cam groove 55 of the cam lever 42 is moved in the arrow h direction with respect to the cam follower pin 56.

While the pinion 38 advances from the intersection P ₁ to the intersection P _{3 in the} direction of the arrow f, as shown in FIG. 11A, the cam follower pin 56 of the chucking lever 20 moves into the cam groove of the cam lever 42. The lower part 55a of 55 is relatively moved in the direction of arrow g.

Then, while the pinion 38 is overstroked in the direction of the arrow f from the intersection P ₃ to the terminal end P ₄ , the cam follower pin 56 moves the inclined portion of the cam groove 55 as shown in FIG. 11B. The chucking lever 20 is pushed up in the direction of the arrow d through 55c to the high place 55b, and the chucking lever 20 is rotationally driven in the direction of the arrow d.

Therefore, the chucking lever 20 causes the chucking frame 1 to move in the advancing process of the overstroke operation of the pinion 38 in the direction of arrow f after the loading of the disc tray 4 in the direction of arrow a is completed.
7 is rotationally driven in the direction of arrow d from the lowered position shown in FIG. 14 to the raised position shown in FIG. 15, the chucking operation of the disc 1 by the disc chucking mechanism 11 described above is performed, and the disc 1 moves to the disc tray 4 It is pushed up above the concave portion 5 and magnetically chucked on the disk table 13.

[Ejecting Operation of Disc Tray] Next, as described above, the eject switch is turned on, or the loading and disc tray drive mechanism 35 is activated by an eject signal from the host computer.
When the motor 40 is driven to rotate in the reverse direction, the disk tray 4 is ejected from the inside of the disk device main body 2 in the direction of arrow b by the reverse operation at the time of loading.

That is, the pinion 38 is shown in FIGS.
At the terminal end P ₄ of the second circular arc portion 37c of the guide groove 37 indicated by the alternate long and short dash line, when the motor 40 is reversely rotated in the direction of the arrow n, the pinion 38 moves the second circular arc portion 36 of the rack 36.
A return process of the overstroke operation is carried out in the direction of arrow e from the terminal end P ₄ to the intersection P ₃ shown by the dotted lines in FIGS. 2, 5 and 8 along c, and the gear base 41 is moved to the position shown in FIGS. To the positions shown in FIGS. 2 and 5 in the direction of arrow e.

Then, the cam lever 42 is rotated in the direction of arrow g from the position shown in FIGS. 3 and 6 to the position shown in FIGS. 2 and 5 via the partial gears 53 and 54, as shown in FIG. As described above, the cam follower pin 56 makes the high portion 5 of the cam groove 55
5b slides down to the lower part 55a through the inclined portion 55c by its own weight, and the chucking lever 20 is attached by its own weight to the arrow c.
Driven to rotate.

Then, together with the chucking lever 20, the chucking frame 17 is rotationally driven in the direction of arrow c by its own weight from the raised position shown in FIG. 15 to the lowered position shown in FIG. The chucking release operation of the disc 1 is performed, and the disc 1 is placed on the recess 5 of the disc tray 4 again.

Then, the pinion 38 is continuously driven in the reverse direction in the direction of the arrow n, and the pinion 38 and the guide pin 3 are driven.
9 is the first arc portion 36b of the rack 36 and the guide groove 37,
37b along the intersection P shown by the dotted lines in FIGS.
Proceed in the direction of arrow e from ₃ to the intersection P ₁ indicated by the solid line in FIGS.

During this time, the cam action of the ejecting cam mechanism 60 constituted by the first arc portion 37b of the guide groove 37 of the emergency eject mechanism 59 and the guide pin 39, that is, the guide pin 39 is guided. The disc tray 4 causes the disc tray 4 to move by the component force F in the arrow a direction generated by pressing the arc surface 37b 'of the first arc portion 37b of the groove 37 in the arrow e direction.
It is extruded from the inside in the direction of arrow e by a distance L ₁ .

Further, during this time, as shown in FIG. 11A, the cam follower pin 56 relatively moves in the low portion 55a of the cam groove 55 in the direction of arrow h.

Then, the pinion 38 is continuously driven to rotate in the direction of arrow n, and the pinion 39 drives the linear portion 36a of the rack 36 in the direction of arrow b.
As shown in FIG. 7, the disc tray 4 is ejected from the inside of the disc device main body 2 in the direction of the arrow b, and the pinion 38 is ejected.
Also, the guide pin 39 relatively moves the linear portion 37a of the guide groove 37 in the direction of arrow a to the position indicated by the chain double-dashed line in FIG.

Then, as shown in FIG. 14, the chassis 2
A pair of left and right stoppers 72 integrally formed at the ends of the left and right side walls 2b 'of b in the direction of the arrow b are integrally formed at the ends of the left and right sides of the disc tray 4 in the direction of the arrow a. Projection 73 of is abutted from the direction of arrow b,
The ejection of the disc tray 4 is completed, the completion of ejection of the disc tray 4 is detected by an ejection completion switch (not shown), and the motor 40 is stopped.

[Emergency Eject Operation] In the disk loading state shown in FIG. 17, when the emergency eject operation member 9 is inserted from the emergency eject hole 8 of the disk apparatus main body 2 in the direction of arrow a, FIG. As shown in
The tip of the eject operation member 8 is pressed into the recess 61c of the emergency eject slider 61, and the emergency eject slider 61 is pushed.
Is extruded in the direction of arrow a by a distance L ₂ from the position indicated by the alternate long and short dash line in FIG. 12 to the position indicated by the solid line.

Then, the vertical plate 61b of the emergency eject slider 61 pushes the arm 42b of the cam lever 42 by the same distance L _{2 in the} direction of the arrow a, and the cam lever 42 moves from the position shown in FIGS. 3 and 6 to FIG. Figure 4
Is rotated in the direction of the arrow g to the position shown in FIG.
Is rotated in the direction of the arrow e from the position shown in FIG.

Then, the cam lever 42 is rotationally driven in the direction of arrow g from the position shown in FIGS. 3 and 6 to the position shown in FIGS. 1 and 4, in the same manner as the eject operation of the disc tray 4 described above. Chucking lever 20
At the same time, the chucking frame 17 is driven downward in the direction of arrow c by its own weight from the raised position shown in FIG. 15 to the lowered position shown in FIG. 14, and the chucking release operation of the disc table 13 with respect to the disc 1 is performed.

After the chucking of the disc 1 is released, the guide pin 39 of the gear base 41, which is rotationally driven in the direction of the arrow e, moves the first guide groove 39 of the guide groove 37 of the disc tray 4 as shown in FIGS. Arc surface 37 of arc portion 37b
b ′ is pushed in the direction of arrow e, and the component force F in the direction of arrow a generated by the cam action at this time causes the disc tray 4 to move.
Is lightly extruded from the inside of the disk device body 2 in the direction of arrow b by a distance L ₁ .

Therefore, by simply pressing the emergency eject slider 61 with the emergency eject operation member 9 in the direction of arrow a, the disc tray 4
Can be easily pushed out from the inside of the disk device body 2 by a distance L _{1 in the} direction of arrow b.

After that, the front panel 4a of the disc tray 4 is put into a hand and the disc tray 4 is manually operated as shown in FIG.
The disc 1 is completely pulled out from the inside in the direction of the arrow b, and the emergency eject operation is completed.

The above is a description of one embodiment of the present invention.
The present invention is not limited to the above embodiments, and various modifications can be made based on the technical idea of the present invention.

[0083]

The emergency eject mechanism of the disk device of the present invention constructed as described above has the following effects.

According to a first aspect of the present invention, a rack and a guide groove which are parallel to each other and are formed in a substantially J shape are provided on the lower surface of the disc tray, and the rack and the guide groove are provided on the gear base which is provided in the main body of the disc device and is rotated around the fulcrum shaft. A guide pin is provided, the guide pin is loosely fitted in the guide groove, and a pinion rotatably attached to the outer periphery of the guide pin is meshed with the rack to change the radius of curvature of the first arc portion of the guide groove. By configuring the ejecting cam mechanism to be smaller than the turning radius of the guide pin and the guide pin and the first arc portion of the guide groove, and rotating the gear base in the eject direction by the emergency eject means,
The cam mechanism of the eject cam mechanism allows the disc tray to be pushed out manually from inside the disc device body in the eject direction, so that the power cannot be turned on due to a power failure or electrical system failure while the disc tray is being loaded. Even in such an emergency, the disc tray in the disc device main body can be safely taken out by ejecting the disc tray manually.

According to a first aspect of the present invention, there is provided a first arc portion of a guide groove formed in a substantially J shape, and a guide pin provided on a rotatably configured gear base and having a pinion rotatably attached to an outer periphery thereof. Since the ejecting cam mechanism is configured by this and the ejecting cam mechanism can perform the emergency eject, it is not necessary to provide an emergency eject dedicated mechanism, and the structure is simple and the cost is low.

According to the first aspect of the present invention, the disc tray is subjected to the emergency eject from the inside of the disc apparatus main body by the cam action of the eject cam mechanism. Therefore, a large force is not required to perform the emergency eject, and the emergency eject is performed. You can perform Sea Eject easily with a small amount of force.

According to a second aspect of the present invention, there are provided a second circular arc portion which is connected to the rack and the first circular arc portion of the guide groove which are parallel to each other, and a radius of curvature of the guide groove is equal to a radius of rotation of the guide pin. The guide pin is driven in the rotation area of the gear base rotated in the second arc portion,
Since a disk chucking mechanism for chucking and unchucking the disk table with respect to the disk is provided, at the time of an emergency eject,
The chucking of the disc table with respect to the disc and the pushing out of the disc tray from the inside of the disc device body can be performed smoothly in a timely manner.

According to a third aspect of the present invention, there is provided an input gear which is rotatably arranged on the outer periphery of the fulcrum shaft on the gear base and is driven to rotate forward and backward by the motor, and is rotatably arranged on the outer periphery of the guide pin. As the planetary gear that moves the pinion that has been moved along the outer periphery of the input gear, loading of the disc tray and driving of the eject,
Performs emergency eject operation smoothly.

According to a fourth aspect of the present invention, the emergency eject slider which is linearly moved in the loading direction of the disc tray and the cam lever which is rotationally driven by the emergency eject slider to rotationally drive the gear base are provided. Since the eject mechanism is configured and the disc chucking mechanism is driven by the cam lever, the cam lever is linearly pushed by the emergency eject operation member such as a wire-like member, so that the cam lever is driven. It is possible to smoothly rotate the gear base in the eject direction via the and to smoothly eject and eject the disc tray. Then, by simply pressing the emergency eject slider linearly by the emergency eject operation member, the chucking of the disc and the ejection of the disc tray can be performed smoothly in a timely manner.

According to a fifth aspect of the present invention, since the emergency eject hole for operating the emergency eject slider is provided in the front panel of the disk device body, the emergency eject operation member is provided on the front panel of the disk device body. You can easily insert it from the front of the, and push the emergency eject slider smoothly in a straight line.
Eject operation can be performed easily.

[Brief description of drawings]

FIG. 1 is a partially cutaway plan view for explaining an emergency eject operation of a disc tray in an embodiment of an emergency eject mechanism of a disc device of the present invention.

FIG. 2 is a partially cutaway plan view of an essential part for explaining a loading completion state of the above disc tray.

FIG. 3 is a partially cutaway plan view of an essential part for explaining a disk chucking completion state of the above.

FIG. 4 is a partially cutaway plan view showing the entire disk device main body in the state of FIG. 1;

5 is a partially cutaway plan view showing the entire disk device main body in the state of FIG. 2. FIG.

FIG. 6 is a partially cutaway plan view showing the entire disc device main body in the state of FIG. 3;

FIG. 7 is a partially cutaway perspective view of a disc tray.

FIG. 8 is a partially cutaway plan view illustrating a relative positional relationship between a rack and a guide groove of a disc tray and a pinion and a guide pin.

9 is an enlarged sectional view taken along the line AA of FIG.

FIG. 10 is an exploded perspective view illustrating a disc tray drive mechanism.

11 is a cross-sectional side view taken along the line BB of FIG. 10 for explaining the rotational driving of the chucking lever.

12 is a cross-sectional side view taken along the line CC in FIG. 10 for explaining the emergency eject operation.

FIG. 13 is a plan view of the disk device body with an upper cover removed.

14 is a sectional side view taken along the line DD of FIG. 14 showing a disc chucking release state of the disc chucking mechanism.

FIG. 15 is a cross-sectional side view taken along the line DD of FIG. 14 showing a disk chucking state of the disk chucking mechanism.

FIG. 16 is a perspective view of the entire disc device showing a state where the disc tray has been ejected.

FIG. 17 is a perspective view of the entire disc device showing a state where loading of the disc tray is completed.

[Explanation of symbols]

1 disc 2 disc device body 2a disc device body front panel 2b disc device body chassis 4 disc tray 4a disc tray front panel 5 disc tray recess 8 emergency eject hole 9 emergency eject operation member 11 disc Chucking mechanism 12 Motor 13 Disc table 14 Chucking pulley 17 Chucking frame 20 Chucking lever 35 Disc tray drive mechanism 36 Rack 36a Rack straight portion 36b Rack first arc portion 36c Rack second arc portion 37 Guide groove 37a Straight part of guide groove 37b First arc part of guide groove 37c Second arc part of guide groove 38 Pinion 40 Loading and ejecting motor 41 Gear base 42 Cam lever -(Emergency eject means) 50 Pinion drive mechanism 59 Immediate eject mechanism 60 Eject cam mechanism 61 Immediate eject slider R ₁ Radius of curvature of the first arc portion of the cam groove R ₂ Second arc portion of the cam groove Radius of curvature of

Claims (5)

[Claims] 1. A disk tray for loading and ejecting a recording and / or reproducing disk into and from a disk device main body, a rack provided on the lower surface of the disk tray, parallel to each other, and formed in a substantially J-shape. A guide groove, a gear base provided in the disc device main body and rotated about a fulcrum shaft, and a guide groove provided on the gear base loosely fitted so that the fulcrum shaft of the gear base is A guide pin that rotates about the center, a pinion that is rotatably attached to the outer periphery of the guide pin, meshes with the rack, and is driven to rotate in the forward and reverse directions by a motor provided in the disk device body, and the pinion that is parallel to each other. Connected to the ends of the straight part of the rack and the guide groove on the eject direction side, and parallel to each other so that the guide groove is on the inside. It is formed in an arc shape, and,
A first arc portion having a radius of curvature of the guide groove smaller than a radius of rotation of the guide pin; an ejecting cam mechanism including the guide pin and the first arc portion of the guide groove; And a drive mechanism for ejecting the disc tray in the eject direction from the inside of the disc device main body by a cam action of the ejecting cam mechanism. -Eject mechanism. 2. A second circular arc portion which is connected to the mutually parallel rack and the first circular arc portion of the guide groove, and a radius of curvature of the guide groove is equal to a radius of rotation of the guide pin, and the guide pin. And a disc chucking mechanism that is driven in a rotation region of a gear base rotated in the second arc portion to chuck and dechuck the disc table with respect to the disc. 1. The emergency eject mechanism of the disk device described in 1. 3. An input gear, which is rotatably arranged on the outer periphery of the fulcrum shaft on the gear base and is driven to rotate in the forward and reverse directions by the motor, and is rotatably arranged on the outer periphery of the guide pin. The emergency eject mechanism for a disk device according to claim 1 or 2, wherein the pinion is a planetary gear that moves along the outer periphery of the input gear. 4. The emergency eject means comprising an emergency eject slider which is linearly moved in a loading direction of the disc tray, and a cam lever which is rotationally driven by the emergency eject slider to rotationally drive the gear base. 3. The emergency eject mechanism of the disk device according to claim 2, wherein the cam chuck drives the disk chucking mechanism. 5. The emergency eject mechanism for a disk device according to claim 4, wherein an emergency eject hole for operating the emergency eject slider is provided in a front panel of the disk device main body.