JP2003141849A - Slide cam for disk unit and disk unit using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve the miniaturization of a disk unit and to provide a slide cam for the disk unit having excellent durability. SOLUTION: The slide cam 51 for the disk unit is slidably mounted on the chassis 40 of the disk unit in order to move up and down a mechanism unit 42 mounting a turntable 49, etc., as a driven member and is provided with a linear receiving part 58 extending in a slide, and an inclined receiving part 59 inclined horizontally and continuously from the linear receiving part 58. The slide cam 51 includes a cam groove 51a which supports and moves the guide pin 430 of the mechanism unit 42, a cavity part 56 which is formed under the inclined receiving part 59 and enables elastic deformation of the inclined receiving part, and a stopper projecting part 57 formed almost under the tip part of the inclined receiving part 59 in the cavity part 56. The stopper projecting part 57 regulates the deformation of the inclined receiving part 59.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disc device for reproducing and recording a disc recording medium, and more particularly to a disc device for raising and lowering a mechanism such as a turntable as a disc tray moves. For slide cams.

[0002]

2. Description of the Related Art CD players, CD-ROM drives,
A disc device such as a CD-R drive or a DVD drive is a device for recording or reproducing a disc-shaped recording medium (disc) such as a compact disc or a CD-ROM.

The disc is placed on the disc tray, and the disc tray conveys the disc to the disc reproducing position. During this transportation, the mechanical unit including the turntable, the optical pickup, etc. is held at a position lower than the moving path of the disc tray so as not to interfere with the movement of the disc tray to the disc reproducing position. Then, when the disc tray is located at the disc reproducing position, the mechanical unit is raised to clamp the disc between the disc clamper and the turntable.

Generally, the lifting and lowering of this mechanical unit is
This is realized by a cam mechanism that uses the mechanical unit as a driven member. For example, a slide cam 5 as shown in FIG.
1 ', the guide pin 430' of the mechanism unit moves up and down in the cam groove 51 of the slide cam 51 '.
It is realized by moving a '.

Generally, the guide locus of the cam groove 51a 'takes the guide pin 43 into consideration in consideration of the variation in accuracy of parts.
The slide cam 51 ′ is displaced upward in relation to the actual movement trajectory of 0 ′, that is, the guide pin 430 ′ is moving.
The guide pin receiving portion 59 'is designed to receive a pressing force in the upward direction. Therefore, the slide cam 51 '
Includes the guide pin 43 that absorbs the variation in component accuracy.
In order to ensure the smooth movement of 0 ', the cavity portion 56' is formed below the guide pin receiving portion 59 ', and the guide pin receiving portion 59' is elastically deformed by the guide pin 430 '. .

[0006]

However, since the mechanical unit has a relatively large mass (for example, about 150 g in a general CD-RW drive), the guide cam is not provided in the above-described slide cam 51 'configuration. Pin receiving part 5
There is a problem that high stress is generated at the supporting end of 9 '.

When the high temperature is maintained in this state, the strain of the guide pin receiving portion 59 'increases with time (hereinafter, this phenomenon is called creep), and finally the guide pin receiving portion 59'. Is greatly deformed and slide cam 5
There was a problem that the function of 1'is not secured.

On the other hand, in order to increase the strength of the guide pin receiving portion 59 'in order to avoid the above-mentioned problems, conventionally, the stress concentration portion of the guide pin receiving portion 59' is overlaid with the guide pin receiving portion 59 'and the guide pin receiving portion 59'. Increasing the thickness of the receiving portion 59 'has been done.

However, in the former case, the guide pin 430 'is used.
This is contrary to ensuring sufficient flexibility of the guide pin receiving portion 59 'for smooth movement of the guide pin. Further, even in the latter case, the slide cam 5 increases as the thickness increases.
Since it is necessary to increase the height of 1 ′ (there is a need to increase the slide width even when maintaining the height), the requirement for the size of the slide cam 51 ′ leads to a compact disc device. There was a problem that it was an obstacle to achievement.

Therefore, it is an object of the present invention to provide a slide cam for a disk device which is compact and realizes excellent durability.

[0011]

In view of the above problems, the disk device slide cam according to claim 1 is slidably mounted on a chassis of the disk device to elevate and lower the driven member, and guides the driven member. A receiving portion that supports the pin and a cavity portion that is formed at a position facing the receiving portion to allow the receiving portion to elastically deform, and a protrusion that is formed in the cavity portion to restrict deformation of the receiving portion. And a stopper projection portion.

According to the above-mentioned invention, since a certain amount or more of the deformation of the receiving portion of the slide cam is prevented by the stopper projection portion integrally formed with the slide cam, it is flexible enough to buffer the movement of the guide pin. Even if the thickness of the receiving portion is designed to be small in order to impart the property, the slide cam can maintain the cam function while guaranteeing sufficient durability.

In particular, the receiving portion holds the guide pin of the driven member for a long time (corresponding to storing the disc tray).
In the case of a portion, this receiving portion is exposed to heat generated by the motors due to disk reproduction or the like and heat from the external environment under a load for a long time, and thus there is a high risk of causing creep. According to the above invention, such deformation that impairs the slide cam function of the receiving portion can be restricted.

Further, since the slide cam can be downsized, the disk device can be made compact.

According to the disk device of claim 2,
A disk device comprising: a chassis; and a slide cam that is slidably mounted on the chassis to move a driven member up and down and that has a receiving portion that supports a guide pin of the driven member. It is characterized by including a stopper portion for restricting deformation of the portion.

According to the above invention, since the deformation of the receiving portion is restricted by the stopper portion formed on the chassis side,
The durability of the slide cam can be further increased. As a result, the thickness of the receiving portion can be designed to be small, and the disk device can be made more compact.

Further, the slide cam for the disk device according to the first aspect can be appropriately used in the disk device. Such a disk device can exhibit a stable function for a long period of time by the slide cam having increased resistance to heat.

Other objects, configurations and effects of the present invention will become more apparent from the following description of the embodiments with reference to the drawings.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the disc tray of the present invention,
And, a preferred embodiment of a disk device using the same will be described in detail with reference to the accompanying drawings.

FIG. 1 is a plan view of a disc device in which a disc tray is in a disc reproducing position according to the present invention.
FIG. 2 is a plan view of the disc device in which the disc tray is at the disc loading / unloading position. As shown in FIGS. 1 and 2,
The disc device 1 is a device such as a CD-ROM drive or a CD-R / RW drive that reproduces or records / reproduces at least an optical disc, and conveys an optical disc (not shown) to the device body 2 and the device body 2. Disc tray 70
Composed of and.

The apparatus main body 2 is formed of a hard resin or the like, has a chassis 40 having a loading mechanism 50 for moving the mechanism tray 42 in and out of the disc tray 70, and a chassis 40. A circuit board (not shown) on which (CPU) is installed,
And a mechanical unit 42 mounted on the chassis 40.
Further, the apparatus main body 2 may include a casing (not shown) that covers the components, and an opening (not shown) for loading / unloading the disc tray 70 (loading and unloading of the optical disc) is provided on the front surface of the casing. No)
Is provided.

3 and 4 are a plan view and a front view of the chassis 40, respectively. The chassis 40 has a substantially rectangular outer shape, and a metal plate that defines the bottom surface of the chassis 40 is attached to the chassis 40. A wall portion is erected in a U-shape along the left and right edges and the rear edge of the bottom surface. No wall is formed on the front surface of the chassis 40,
It is open. A front bezel having an opening for inserting and removing the disc tray 70 is attached to the open portion.

In general, the chassis 40 is provided with a loading mechanism storing portion 41 for accommodating the loading mechanism 50 in the front portion and left and right wall portions for movably supporting the disc tray 70. Left and right disc tray support surfaces 44, a mechanical unit mounting portion 45 for mounting the mechanical unit 42 behind the loading mechanism storing portion 41, and a disc installed above the mechanical unit mounting portion 45 and between the left and right wall portions. And a disk clamper storage portion 48 for mounting the clamper 80.

Further, the chassis 40 has projecting portions 43L and 43R which project from the left and right wall portions of the chassis 40 and restrict the displacement of the disc tray 70 in the upward direction (Z1 direction in FIG. 4). The left and right disc tray support surfaces 44 include substantially horizontal planes, and serve as guide members for guiding the movement of the disc tray 70 and regulating the position in the left and right directions (X1 and X2 directions in FIG. 3). Guide ribs 44b and 44c are formed, respectively.

FIG. 5 is a bottom view of the disc tray 70. The disc tray 70 is made of resin or the like and has a concave disc mounting portion 71 adapted to mount an optical disc, as shown in FIGS. 5 and 2. The optical disc is placed on the disc placing portion 71 of the disc tray 70, and is transported from the disc attaching / detaching position to the disc reproducing position in a state where the position is regulated to a predetermined position.

The disc tray 70 has a substantially rectangular opening 711 formed from the substantially central portion of the disc mounting portion 71 toward the rear portion (Y1 direction in FIG. 5). It is set so that the turntable 49 and the optical pickup 47 are located below the opening 711 when the disc tray 70 is at the reproduction position. Optical pickup 47
Can be moved in the radial direction of the optical disc through the opening 711.

As shown in FIG. 2, the disc tray 70 has left and right side portions 72L and 72R supported by the left and right disc tray support surfaces 44. The bottom surfaces of the left and right side portions 72L and 72R have the disk tray support surface 44.
Disc tray support surface 44
Main guide groove 72a and sub guide groove 72b guided by the guide protrusions 44a and the guide ribs 44b and 44c of
72c are formed respectively. With this configuration, the disc tray 70 can be guided along a predetermined path, and rattling of the disc tray 70 in the left-right direction is prevented.

As shown in FIG. 5, the disc tray 70 has a disc tray 7 on the back surface of the disc tray 70.
Restriction groove 78a that is formed along the movement direction of 0 and that has an inclined portion that engages with the protrusion 51c of the slide cam 51 and slides the slide cam 51 in the left-right direction (X1 and X2 directions in FIG. 5). , 78b and the disc tray 70
And a rack 74 formed on the back surface of the disk tray along the moving direction of the disc tray 70 for driving the disc tray 70 between the disc reproducing position and the disc attaching / detaching position.

FIG. 6 is a perspective view schematically showing the mechanism unit 42. The mechanism unit 42 is rotatably attached to the mechanism unit mounting portion 45 behind the chassis 40 (see FIGS. 7A and 7B). The mechanical unit 42 is shown in FIG.
As shown in FIG. 3, it preferably has a base frame 421 formed of hard resin and a base plate 422 supported by the base frame 421 via an elastic member 441.

In front of the base frame 421 (on the side of the loading mechanism 50), a guide pin 430 inserted into the cam groove 51a of the slide cam 51 of the loading mechanism.
The rotary shaft 431 is formed behind the base frame 421. The rotation shaft 431 is used for the chassis 4
It is rotatably inserted into the bearing portion 432 formed on the 0 side. With this configuration, the mechanism unit 42 causes the rotation shaft 43 to move between the raised position (FIG. 7A) and the lowered position (FIG. 7B) by the sliding movement of the slide cam 51, as described later.
It is rotated around 1.

The base plate 422 generally has a turntable 49 that holds an optical disk between it and a disk clamper 80 to rotate it, and reproduces or records the optical disk.
An optical pickup 47 for reproduction and a guide mechanism 4 for guiding the optical pickup 47 in the radial direction of the optical disc.
71, a spindle motor 491 that rotates the turntable 49, and a thread motor 472 that drives the movement of the optical pickup 47 via a gear mechanism (not shown).

The optical pickup 47 aligns laser light emitted from a laser light source such as a laser diode into parallel light rays by a collimation lens or the like, focuses the light on a disc surface by an objective lens, and reads the recorded information. It plays a role of separating the reflected laser light by a prism or the like and guiding it to a light receiving element such as a photo diode.

As shown in FIG. 6, the spindle motor 491 is screwed to the front rear side of the base plate 422. Further, the spindle motor 491 can rotate at a high speed, and for example, an optical disc is 180 to 3000.
It can rotate at about rpm.

The turntable 49 is fixed to the rotary shaft of the spindle motor 491. This turntable 49
Is a disk-shaped member, and a center hub 492 formed by a ring-shaped projection is formed at the center of the disk. The center hub 492 fits in the center hole of the optical disc.

A ring-shaped permanent magnet for attracting the disk clamper 80 is provided inside the center hub 492 and around the rotation shaft of the spindle motor 491. A ring-shaped pad 493 is adhered to a portion around the center hub 492 on the upper side of the turntable 49 (the side that holds the optical disc). The pad 493 is made of a material having elasticity and a relatively large friction coefficient, such as various rubbers, soft resins, and porous materials. This prevents the optical disc from slipping when the optical disc is nipped and rotated.

With this configuration, the optical disk placed on the disk tray 70 is conveyed to the reproduction position by the disk tray 70, is clamped between the turntable 49 and the disk clamper 80, and is rotated by the spindle motor 491. Rotated with 49.

The spindle motor 491 and the sled motor 472, together with the loading motor 61 described later, are controlled by the control means provided on the circuit board.

7A and 7B are side views showing a mode in which the mechanism unit 42 rotates up and down. Chassis 40
In the loading mechanism storing part 41 of the
2 for rotating the disc tray 70 between the disc reproducing position and the disc attaching / detaching position while rotating the disc tray 70 between the ascending position (FIG. 7A) and the descending position (FIG. 7B) about the rotating shaft 431. A loading mechanism 50 is provided. The loading mechanism 50 includes a mechanism unit 42.
A slide cam 51 for moving the disk up and down, and a drive mechanism 6 for driving the disc tray 70 and the slide cam 51.
Has 0 and.

The slide cam 51 is made of resin or the like, and faces the first surface 52 facing the upper surface of the loading mechanism storing portion 41 of the chassis 40 and the vertical wall behind the loading mechanism storing portion 41 of the chassis 40. Second surface 53
It has an inverted L-shaped cross section and is slidably mounted behind the loading mechanism storage portion 41 of the chassis 40.

8A and 8B are a top view and a front view of the slide cam 51, respectively. Slide cam 51
As shown in FIGS. 8A and 8B, the first surface 52 has
The rack 51b that engages with the drive mechanism 60 of the loading mechanism 50, and the regulation grooves 78a and 78b of the disc tray 70.
And a cam groove 51a into which the guide pin 430 of the base frame 421 is inserted, on the second surface 53.

The cam groove 51a is a straight line receiving portion 58 extending in the left-right direction (X1 and X2 directions in FIG. 8B), and is continuously inclined from the straight line receiving portion 58 in the upward direction (Z1 direction in FIG. 8B). And an inclined receiving portion 59.

The slide cam 51 moves in the left-right direction (X in FIG. 8B).
When sliding in the 1 and X2 directions), the guide pin 430 inserted into the cam groove 51a moves with the guide pin 430 being supported by the linear receiving portion 58 and the inclined receiving portion 59.

When the guide pin 430 moves in the straight line receiving portion 58, the mechanism unit 42 mounted on the base frame 421 is held in a lowered state, and when the guide pin 430 moves in the inclined receiving portion 59, the mechanism unit 42 moves. The front part is vertically moved up and down, and the guide pin 430 moves the tilt receiving part 59.
When located at the end point of, the mechanical unit 42 is held in the raised state.

Below the slanted receiving portion 551b of the cam groove 51a, as shown in FIG. 8B, a hollow portion 56 is formed so that the slanted receiving portion 551b is secured in order to ensure stable slidability of the guide pin 430. Direction (Z2 direction in FIG. 8B)
To be elastically deformable. As a result, when the guide pin 430 moves on the tilt receiving portion 551b, the vertical movement of the guide pin 430 is buffered.

Further, a stopper projection 57 is formed in the cavity 56 of the slide cam 51 in order to regulate downward displacement of the tilt receiving portion 551b. The stopper protrusion 57 is formed below the upper end of the inclined receiving portion 551b corresponding to the third position 553 of the guide pin 430. The stopper protrusion 57 restricts elastic deformation and deformation of the inclined receiving portion 551b due to creep, and avoids a failure of the function of the slide cam 51 due to heat.

In this embodiment, the stopper protrusion 57
As shown in FIG. 8B, is formed so as to project from the inclined receiving portion 551b, but may be formed so as to project from the hollow portion 56 toward the inclined receiving portion 551b.

Further, the chassis 40 is provided with a slide cam 51 from the lower portion of the vertical wall behind the loading mechanism storing portion 41.
It has a projecting stopper 46 projecting in the direction. The protruding stopper 46 is formed below the straight line receiving portion 58. The slide cam 51 slides on the protruding stopper 46. With this protruding stopper 46, the straight line receiving portion 58
Elastic deformation and deformation due to creep are restricted, and malfunction of the function of the slide cam 51 due to heat is avoided.

FIG. 9 shows the position of the guide pin 430, the position of the stopper projection 57 of the slide cam 51, and the chassis 4.
It is a schematic front view for showing the relation with the position of 0 of the protruding stopper 46. Slide cam 51 shown by the solid line in the figure
Shows the slide cam 51 when the mechanism unit 42 is in the raised position. Slide cam 51 shown by the broken line in the figure
Shows the slide cam 51 when the mechanism unit 42 is in the lowered position. As is clear from FIG. 9, the progress of deformation of the linear receiving portion 58 and the inclined receiving portion 551b of the slide cam 51 is restricted by the stopper members 46 and 57 corresponding to the slide position of the slide cam 51.

The drive mechanism 60 of the loading mechanism 50 is
As shown in FIG. 3, a loading motor 61, which is provided on the rear side of the front portion of the chassis 40 and includes a forward / reverse rotation DC motor, and a transmission mechanism 65 for transmitting the rotation of the loading motor 61. .

The transmission mechanism 65 is a pulley composed of a first pulley 621, a second pulley 622 fixed to the rotating shaft of the loading motor 61, a coaxial gear A623 integrally formed under the second pulley, and a belt 624. The mechanism 62, a second gear 63 that is integrally formed on the upper portion of a gear B631 that meshes with the gear A623, is coaxial with the gear B631 and has a smaller diameter, and a third gear 64 that meshes with the gear C632.

This transmission mechanism 65 includes a disc tray 70.
Disk tray 7 when engaged with rack 74 of
The operation of moving 0 between the disc mounting position and the disc reproducing position is performed. Further, the transmission mechanism 65 performs an operation of sliding the slide cam 51 when engaged with the rack 51b of the slide cam 51, and as a result, the guide pin 430 of the mechanism unit 42 moves the tilt receiving portion 59. .

Next, the operation of the disk device 1 according to the above embodiment will be described. When the operator places an optical disc on the disc placing portion 71 of the disc tray 70 pulled out from the opening of the disc device 1 and performs a predetermined loading operation, the loading motor 61 rotates. While the protrusion 51c of the slide cam 51 is engaged with the restriction grooves 78a and 78b of the disc tray 70, the rack 74 of the disc tray 70 engaged with the third gear 64 of the transmission mechanism 65 causes the disc tray 70 to move. Is moved toward the disc loading / unloading position and the disc playing position. At this time,
Since the mechanism unit 42 is held in the lowered position, the disc tray 70 moves to the disc reproducing position without interfering with the mechanism unit 42.

When the protrusion 51c of the slide cam 51 moves from the first restricting groove 78a to the second restricting groove 78b, the guide pin 430 of the mechanism unit 42 receives the straight line from the straight line receiving portion 58 when the guide pin 430 of the mechanism unit 42 is received. It is slid so as to move to the branch portion between the portion 58 and the tilt receiving portion 59,
The rack 51b of the slide cam 51 is the second of the transmission mechanism 65.
The gear 63 is engaged.

When the protrusion 51c of the slide cam 51 reaches the point where it engages with the second restriction groove 78b, the transmission mechanism 65 is provided.
The third gear 64 is released from the engagement with the rack 74 of the disc tray 70. Second gear 6 of further transmission mechanism 65
The rotation of 3 causes the slide cam 51 to move to the mechanical unit 4
The second guide pin 430 is slid so as to move in the inclined receiving portion 59, the mechanism unit 42 is moved up, and the attracted member made of iron embedded in the disk clamper 80 is attracted to the permanent magnet embedded in the turntable 49. As a result, the optical disk is held between the disk clamper 80 and the turntable 49, and the operation for reproducing or recording the disk is completed.

After that, when the operator performs a reproducing operation or the like, the optical disk rotates on the turntable 49, and the specified operation is executed by the disk device 1.

[0056]

Since the present invention is as described above, it has the following effects. In the inclined receiving portion of the slide cam, the stopper protrusion integrally formed with the slide cam prevents the progress of deformation due to creep of a certain amount or more, and thus the function of the slide cam can be guaranteed for a long period of time.

Further, by forming the projecting stopper on the chassis, the deformation of the straight line receiving portion is similarly restricted, so that the durability of the slide cam can be further increased. Further, the thickness of the inclined receiving portion and the linear receiving portion of the slide cam can be designed to be small, and the disk device can be made more compact.

Further, the disk device using the slide cam for the disk device according to the present invention can exhibit a stable function for a long period of time by the slide cam having enhanced resistance to heat.

[Brief description of drawings]

FIG. 1 is a plan view of a disc device according to the present invention with a disc tray in a disc reproducing position.

FIG. 2 is a plan view of a disc device according to the present invention with a disc tray in a disc loading / unloading position.

3 is a plan view of the chassis of FIG. 1. FIG.

FIG. 4 is a front view of the chassis of FIG.

FIG. 5 is a bottom view of the disc tray.

FIG. 6 is a schematic perspective view of a mechanism unit.

7A and 7B are side views showing a mode in which the mechanism unit 42 rotates up and down.

8A and 8B are a top view and a front view, respectively, of a slide cam according to the present invention.

FIG. 9 is a schematic front view showing the relationship between the position of the guide pin, the position of the stopper protrusion of the slide cam, and the position of the protruding stopper of the chassis.

FIG. 10 is a front view of a conventional slide cam.

[Explanation of symbols]

1 disk device 2 device body 40 chassis 41 Loading mechanism storage area 42 mechanical unit 421 base frame 422 base plate 43L protrusion 43R protrusion 430 guide pin 431 rotation axis 432 Bearing 44 Disc tray support surface 44a Guide protrusion 44b Guide rib 44c Guide rib 441 elastic member 45 Mechanical unit mounting area 46 Projection stopper 47 Optical pickup 471 guide mechanism 472 thread motor 48 Disk clamper storage area 49 turntable 491 Spindle motor 50 loading mechanism 51 slide cam 51a cam groove 51b rack 51c protrusion 52 First side 53 Second side 56 Cavity 57 Stopper protrusion 58 Straight receiving part 59 Inclined receiving part 60 drive mechanism 61 loading motor 62 pulley mechanism 621 first pulley 622 second pulley 623 Gear A 624 belt 63 Second Gear 631 Gear B 632 Gear C 64 3rd gear 65 Transmission mechanism 70 disc tray 71 Disk mount 711 opening 72L left side 72R Right side 72a Main guide groove 72b Sub guide groove 72c Sub guide groove 74 racks 78a, 78b restriction groove 80 disk clamper

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[Procedure amendment]

[Submission date] November 7, 2001 (2001.11.
7)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction content]

[Document name] Statement

Title: Slide cam for disk device and disk device using the same

[Claims]

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disc device for reproducing and recording a disc recording medium, and more particularly to a disc device for raising and lowering a mechanism such as a turntable as a disc tray moves. For slide cams.

[0002]

2. Description of the Related Art CD players, CD-ROM drives,
A disc device such as a CD-R drive or a DVD drive is a device for recording or reproducing a disc-shaped recording medium (disc) such as a compact disc or a CD-ROM.

The disc is placed on the disc tray, and the disc tray conveys the disc to the disc reproducing position. During this transportation, the mechanical unit including the turntable, the optical pickup, etc. is held at a position lower than the moving path of the disc tray so as not to interfere with the movement of the disc tray to the disc reproducing position. Then, when the disc tray is located at the disc reproducing position, the mechanical unit is raised to clamp the disc between the disc clamper and the turntable.

Generally, the lifting and lowering of this mechanical unit is
This is realized by a cam mechanism that uses the mechanical unit as a driven member. For example, a slide cam 5 as shown in FIG.
1 ', the guide pin 430' of the mechanism unit moves up and down in the cam groove 51 of the slide cam 51 '.
It is realized by moving a '.

Generally, the guide locus of the cam groove 51a 'takes the guide pin 43 into consideration in consideration of the variation in accuracy of parts.
The slide cam 51 ′ is displaced upward in relation to the actual movement trajectory of 0 ′, that is, the guide pin 430 ′ is moving.
The guide pin receiving portion 59 'is designed to receive a pressing force in the upward direction. Therefore, the slide cam 51 '
Includes the guide pin 43 that absorbs the variation in component accuracy.
In order to ensure the smooth movement of 0 ', the cavity portion 56' is formed below the guide pin receiving portion 59 ', and the guide pin receiving portion 59' is elastically deformed by the guide pin 430 '. .

[0006]

However, since the mechanical unit has a relatively large mass (for example, about 150 g in a general CD-RW drive), the guide cam is not provided in the above-described slide cam 51 'configuration. Pin receiving part 5
There is a problem that high stress is generated at the supporting end of 9 '.

When the high temperature is maintained in this state, the strain of the guide pin receiving portion 59 'increases with time (hereinafter, this phenomenon is called creep), and finally the guide pin receiving portion 59'. Is greatly deformed and slide cam 5
There was a problem that the function of 1'is not secured.

On the other hand, in order to increase the strength of the guide pin receiving portion 59 'in order to avoid the above-mentioned problems, conventionally, the stress concentration portion of the guide pin receiving portion 59' is overlaid with the guide pin receiving portion 59 'and the guide pin receiving portion 59'. Increasing the thickness of the receiving portion 59 'has been done.

However, in the former case, the guide pin 430 'is used.
This is contrary to ensuring sufficient flexibility of the guide pin receiving portion 59 'for smooth movement of the guide pin. Further, even in the latter case, the slide cam 5 increases as the thickness increases.
Since it is necessary to increase the height of 1 ′ (there is a need to increase the slide width even when maintaining the height), the requirement for the size of the slide cam 51 ′ leads to a compact disc device. There was a problem that it was an obstacle to achievement.

Therefore, it is an object of the present invention to provide a slide cam for a disk device which is compact and realizes excellent durability.

[0011]

In view of the above problems, the disk device slide cam according to claim 1 is slidably mounted on a chassis of the disk device to elevate and lower the driven member, and guides the driven member. A receiving portion that supports the pin and a cavity portion that is formed at a position facing the receiving portion to allow the receiving portion to elastically deform, and a protrusion that is formed in the cavity portion to restrict deformation of the receiving portion. And a stopper projection portion.

According to the above-mentioned invention, since a certain amount or more of the deformation of the receiving portion of the slide cam is prevented by the stopper projection portion integrally formed with the slide cam, it is flexible enough to buffer the movement of the guide pin. Even if the thickness of the receiving portion is designed to be small in order to impart the property, the slide cam can maintain the cam function while guaranteeing sufficient durability.

In particular, the receiving portion holds the guide pin of the driven member for a long time (corresponding to storing the disc tray).
In the case of a portion, this receiving portion is exposed to heat generated by the motors due to disk reproduction or the like and heat from the external environment under a load for a long time, and thus there is a high risk of causing creep. According to the above invention, such deformation that impairs the slide cam function of the receiving portion can be restricted.

Further, since the slide cam can be downsized, the disk device can be made compact.

According to the disk device of claim 2,
A disc device including: a chassis; and a slide cam that is slidably mounted on the chassis to raise and lower a driven member and that has a receiving portion that supports a guide pin of the driven member. It is characterized in that a stopper portion for restricting deformation of the portion is provided.

According to the above invention, since the deformation of the receiving portion is restricted by the stopper portion formed on the chassis side,
The durability of the slide cam can be further increased. As a result, the thickness of the receiving portion can be designed to be small, and the disk device can be made more compact.

Further, the slide cam for the disk device according to the first aspect can be appropriately used in the disk device. Such a disk device can exhibit a stable function for a long period of time by the slide cam having increased resistance to heat.

Other objects, configurations and effects of the present invention will become more apparent from the following description of the embodiments with reference to the drawings.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the disc tray of the present invention,
And, a preferred embodiment of a disk device using the same will be described in detail with reference to the accompanying drawings.

FIG. 1 is a plan view of a disc device in which a disc tray is in a disc reproducing position according to the present invention.
FIG. 2 is a plan view of the disc device in which the disc tray is at the disc loading / unloading position. As shown in FIGS. 1 and 2,
The disc device 1 is a device such as a CD-ROM drive or a CD-R / RW drive that reproduces or records / reproduces at least an optical disc, and conveys an optical disc (not shown) to the device body 2 and the device body 2. Disc tray 70
Composed of and.

The apparatus main body 2 is formed of a hard resin or the like, has a chassis 40 having a loading mechanism 50 for moving the mechanism tray 42 in and out of the disc tray 70, and a chassis 40. A circuit board (not shown) on which (CPU) is installed,
And a mechanical unit 42 mounted on the chassis 40.
Further, the apparatus main body 2 may include a casing (not shown) that covers the components, and an opening (not shown) for loading / unloading the disc tray 70 (loading and unloading of the optical disc) is provided on the front surface of the casing. No)
Is provided.

3 and 4 are a plan view and a front view of the chassis 40, respectively. The chassis 40 has a substantially rectangular outer shape, and a metal plate that defines the bottom surface of the chassis 40 is attached to the chassis 40. A wall portion is erected in a U-shape along the left and right edges and the rear edge of the bottom surface. No wall is formed on the front surface of the chassis 40,
It is open.

In general, the chassis 40 is provided with a loading mechanism storing portion 41 for accommodating the loading mechanism 50 in the front portion and left and right wall portions for movably supporting the disc tray 70. Left and right disc tray support surfaces 44, a mechanical unit mounting portion 45 for mounting the mechanical unit 42 behind the loading mechanism storing portion 41, and a disc installed above the mechanical unit mounting portion 45 and between the left and right wall portions. And a disk clamper storage portion 48 for mounting the clamper 80.

Further, the chassis 40 has projecting portions 43L and 43R which project from the left and right wall portions of the chassis 40 and restrict the displacement of the disc tray 70 in the upward direction (Z1 direction in FIG. 4). The left and right disc tray support surfaces 44 include substantially horizontal planes, and serve as guide members for guiding the movement of the disc tray 70 and regulating the position in the left and right directions (X1 and X2 directions in FIG. 3). Guide ribs 44b and 44c are formed, respectively.

FIG. 5 is a bottom view of the disc tray 70. The disc tray 70 is made of resin or the like and has a concave disc mounting portion 71 adapted to mount an optical disc, as shown in FIGS. 5 and 2. The optical disc is placed on the disc placing portion 71 of the disc tray 70, and is transported from the disc attaching / detaching position to the disc reproducing position in a state where the position is regulated to a predetermined position.

The disc tray 70 has a substantially rectangular opening 711 formed from the substantially central portion of the disc mounting portion 71 toward the rear portion (Y1 direction in FIG. 5). It is set so that the turntable 49 and the optical pickup 47 are located below the opening 711 when the disc tray 70 is at the reproduction position. Optical pickup 47
Can be moved in the radial direction of the optical disc through the opening 711.

As shown in FIG. 2, the disc tray 70 has left and right side portions 72L and 72R supported by the left and right disc tray support surfaces 44. The bottom surfaces of the left and right side portions 72L and 72R have the disk tray support surface 44.
Disc tray support surface 44
Main guide groove 72a and sub guide groove 72b guided by the guide protrusions 44a and the guide ribs 44b and 44c of
72c are formed respectively. With this configuration, the disc tray 70 can be guided along a predetermined path, and rattling of the disc tray 70 in the left-right direction is prevented.

As shown in FIG. 5, the disc tray 70 has a disc tray 7 on the back surface of the disc tray 70.
Restriction groove 78a that is formed along the movement direction of 0 and that has an inclined portion that engages with the protrusion 51c of the slide cam 51 and slides the slide cam 51 in the left-right direction (X1 and X2 directions in FIG. 5). , 78b and the disc tray 70
And a rack 74 formed on the back surface of the disk tray along the moving direction of the disc tray 70 for driving the disc tray 70 between the disc reproducing position and the disc attaching / detaching position.

FIG. 6 is a perspective view schematically showing the mechanism unit 42. The mechanism unit 42 is rotatably attached to the mechanism unit mounting portion 45 behind the chassis 40 (see FIGS. 7A and 7B). The mechanical unit 42 is shown in FIG.
As shown in FIG. 3, it preferably has a base frame 421 formed of hard resin and a base plate 422 supported by the base frame 421 via an elastic member 441.

In front of the base frame 421 (on the side of the loading mechanism 50), a guide pin 430 inserted into the cam groove 51a of the slide cam 51 of the loading mechanism.
The rotary shaft 431 is formed behind the base frame 421. The rotation shaft 431 is used for the chassis 4
It is rotatably inserted into the bearing portion 432 formed on the 0 side. With this configuration, the mechanism unit 42 causes the rotation shaft 43 to move between the raised position (FIG. 7A) and the lowered position (FIG. 7B) by the sliding movement of the slide cam 51, as described later.
It is rotated around 1.

The base plate 422 generally has a turntable 49 that holds an optical disk between it and a disk clamper 80 to rotate it, and reproduces or records the optical disk.
An optical pickup 47 for reproduction and a guide mechanism 4 for guiding the optical pickup 47 in the radial direction of the optical disc.
71, a spindle motor 491 that rotates the turntable 49, and a thread motor 472 that drives the movement of the optical pickup 47 via a gear mechanism (not shown).

The optical pickup 47 aligns laser light emitted from a laser light source such as a laser diode into parallel light rays by a collimation lens or the like, focuses the light on a disc surface by an objective lens, and reads the recorded information. It plays a role of separating the reflected laser light by a prism or the like and guiding it to a light receiving element such as a photo diode.

As shown in FIG. 6, the spindle motor 491 is screwed to the front rear side of the base plate 422. Further, the spindle motor 491 can rotate at a high speed, and for example, an optical disc is 180 to 3000.
It can rotate at about rpm.

The turntable 49 is fixed to the rotary shaft of the spindle motor 491. This turntable 49
Is a disk-shaped member, and a center hub 492 formed by a ring-shaped projection is formed at the center of the disk. The center hub 492 fits in the center hole of the optical disc.

A ring-shaped permanent magnet for attracting the disk clamper 80 is provided inside the center hub 492 and around the rotation shaft of the spindle motor 491. A ring-shaped pad 493 is adhered to a portion around the center hub 492 on the upper side of the turntable 49 (the side that holds the optical disc). The pad 493 is made of a material having elasticity and a relatively large friction coefficient, such as various rubbers, soft resins, and porous materials. This prevents the optical disc from slipping when the optical disc is nipped and rotated.

With this configuration, the optical disk placed on the disk tray 70 is conveyed to the reproduction position by the disk tray 70, is clamped between the turntable 49 and the disk clamper 80, and is rotated by the spindle motor 491. Rotated with 49.

The spindle motor 491 and the sled motor 472, together with the loading motor 61 described later, are controlled by the control means provided on the circuit board.

7A and 7B are side views showing a mode in which the mechanism unit 42 rotates up and down. Chassis 40
In the loading mechanism storing part 41 of the
2 for rotating the disc tray 70 between the disc reproducing position and the disc attaching / detaching position while rotating the disc tray 70 between the ascending position (FIG. 7A) and the descending position (FIG. 7B) about the rotating shaft 431. A loading mechanism 50 is provided. The loading mechanism 50 includes a mechanism unit 42.
A slide cam 51 for moving the disk up and down, and a drive mechanism 6 for driving the disc tray 70 and the slide cam 51.
Has 0 and.

The slide cam 51 is made of resin or the like, and faces the first surface 52 facing the upper surface of the loading mechanism storing portion 41 of the chassis 40 and the vertical wall behind the loading mechanism storing portion 41 of the chassis 40. Second surface 53
It has an inverted L-shaped cross section and is slidably mounted behind the loading mechanism storage portion 41 of the chassis 40.

8A and 8B are a top view and a front view of the slide cam 51, respectively. Slide cam 51
As shown in FIGS. 8A and 8B, the first surface 52 has
The rack 51b that engages with the drive mechanism 60 of the loading mechanism 50, and the regulation grooves 78a and 78b of the disc tray 70.
And a cam groove 51a into which the guide pin 430 of the base frame 421 is inserted, on the second surface 53.

The cam groove 51a is a straight line receiving portion 58 extending in the left-right direction (X1 and X2 directions in FIG. 8B), and is continuously inclined from the straight line receiving portion 58 in the upward direction (Z1 direction in FIG. 8B). And an inclined receiving portion 59.

The slide cam 51 moves in the left-right direction (X in FIG. 8B).
When sliding in the 1 and X2 directions), the guide pin 430 inserted into the cam groove 51a moves with the guide pin 430 being supported by the linear receiving portion 58 and the inclined receiving portion 59.

When the guide pin 430 moves in the straight line receiving portion 58, the mechanism unit 42 mounted on the base frame 421 is held in a lowered state, and when the guide pin 430 moves in the inclined receiving portion 59, the mechanism unit 42 moves. The front part is vertically moved up and down, and the guide pin 430 moves the tilt receiving part 59.
When located at the end point of, the mechanical unit 42 is held in the raised state.

Below the inclined receiving portion 59 of the cam groove 51a, in order to ensure stable slidability of the guide pin 430,
As shown in FIG. 8B, a cavity portion 56 is formed so that the inclined receiving portion 59 can be elastically deformed downward (Z2 direction in FIG. 8B). Thereby, the guide pin 430
When moving the tilt receiving portion 59, the vertical movement of the guide pin 430 is buffered.

A stopper projection 57 is formed in the hollow portion 56 of the slide cam 51 in order to regulate downward displacement of the tilt receiving portion 59. This stopper protrusion 5
7 is formed below the upper end of the tilt receiving portion 59 corresponding to the case where the guide pin 430 is located at the end point of the tilt receiving portion 59. The stopper protrusion 57 allows the inclination receiving portion 5
The elastic deformation of 9 and the deformation due to creep are restricted, and the functional failure of the slide cam 51 due to heat is avoided.

In this embodiment, the stopper protrusion 57
As shown in FIG. 8B, is formed so as to project toward the inclined receiving portion 59, but the stopper protruding portion 57 may be formed so as to project to the inclined receiving portion 59.

Further, the chassis 40 is provided with a slide cam 51 from the lower portion of the vertical wall behind the loading mechanism storing portion 41.
It has a projecting stopper 46 projecting in the direction. The protruding stopper 46 is formed below the straight line receiving portion 58. The slide cam 51 slides on the protruding stopper 46. With this protruding stopper 46, the straight line receiving portion 58
Elastic deformation and deformation due to creep are restricted, and malfunction of the function of the slide cam 51 due to heat is avoided.

FIG. 9 shows the position of the guide pin 430, the position of the stopper projection 57 of the slide cam 51, and the chassis 4.
It is a schematic front view for showing the relation with the position of 0 of the protruding stopper 46. Slide cam 51 shown by the solid line in the figure
Shows the slide cam 51 when the mechanism unit 42 is in the raised position. Slide cam 51 shown by the broken line in the figure
Shows the slide cam 51 when the mechanism unit 42 is in the lowered position. As is clear from FIG. 9, the progress of the deformation of the linear receiving portion 58 and the inclined receiving portion 59 of the slide cam 51 is restricted by the stopper members 46 and 57 corresponding to the slide position of the slide cam 51.

The drive mechanism 60 of the loading mechanism 50 is
As shown in FIG. 3, a loading motor 61, which is provided on the rear side of the front portion of the chassis 40 and includes a forward / reverse rotation DC motor, and a transmission mechanism 65 for transmitting the rotation of the loading motor 61. .

This transmission mechanism 65 includes a first pulley 621, a second pulley 622 fixed to the rotating shaft of the loading motor 61, a coaxial gear A (not shown) integrally formed under the second pulley, and a belt. A pulley mechanism 62 composed of 624, a second gear 63 integrally formed on the upper portion of a gear B631 meshing with the gear A, coaxial with the gear B631 and having a smaller diameter, and a third gear meshing with the gear C632.
And a gear 64.

This transmission mechanism 65 includes a disc tray 70.
Disk tray 7 when engaged with rack 74 of
The operation of moving 0 between the disc mounting position and the disc reproducing position is performed. Further, the transmission mechanism 65 performs an operation of sliding the slide cam 51 when engaged with the rack 51b of the slide cam 51, and as a result, the guide pin 430 of the mechanism unit 42 moves the tilt receiving portion 59. .

Next, the operation of the disk device 1 according to the above embodiment will be described. When the operator places an optical disc on the disc placing portion 71 of the disc tray 70 pulled out from the opening of the disc device 1 and performs a predetermined loading operation, the loading motor 32 rotates.

At this time, the disc tray 70 is moved toward the disc reproducing position by the rack 74 of the disc tray 70 which is engaged with the third gear 64 of the transmission mechanism 65. During this operation, the protrusion 51c of the slide cam 51 is connected to the first restriction groove 78a of the disc tray 70.
, And the mechanism unit 42 is held in the lowered position, the disc tray 70 is attached to the mechanism unit 4.
It does not interfere with 2.

When the disc tray moves further and the projection 51c of the slide cam 51 moves from the first restricting groove 78a to the second restricting groove 78b, the sliding movement of the slide cam 51 is started. By this sliding movement, the position of the guide pin 430 of the mechanism unit 42 is changed to the linear receiving portion 5.
8 to the branch portion between the straight line receiving portion 58 and the inclined receiving portion 59, and the rack 51b of the slide cam 51 moves to the transmission mechanism 6.
The position immediately before the engagement with the second gear 63 of No. 5 is set.

When the disc tray further moves, the third gear 64 of the transmission mechanism 65 causes the rack 7 of the disc tray 70 to move.
4 is released from the engagement with the rack 5 of the slide cam 51.
1b engages with the second gear 63 of the transmission mechanism 65. After that, the slide cam 51 receives the second gear 63 of the transmission mechanism 65.
Rotation causes the guide pin 430 of the mechanism unit 42 to move along the tilt receiving portion 59. This raises the mechanism unit 42,
The attracted member made of iron embedded in the disc clamper 80 is attracted by the permanent magnet embedded in the turntable 49, so that the optical disc is securely held between the disc clamper 80 and the turntable 49, and the disc is reproduced. Alternatively, the loading operation for recording is completed.

After that, when the operator performs a reproducing operation or the like, the optical disk rotates on the turntable 49, and the specified operation is executed by the disk device 1. still,
When the operator performs a predetermined unloading (ejecting) operation, the above operation is reversed.

[0057]

Since the present invention is as described above, it has the following effects. In the inclined receiving portion of the slide cam, the stopper protrusion integrally formed with the slide cam prevents the progress of deformation due to creep of a certain amount or more, and thus the function of the slide cam can be guaranteed for a long period of time.

Further, by forming the protruding stopper on the chassis, the deformation of the straight line receiving portion is similarly restricted, so that the durability of the slide cam can be further increased. Further, the thickness of the inclined receiving portion and the linear receiving portion of the slide cam can be designed to be small, and the disk device can be made more compact.

Further, the disk device using the slide cam for the disk device according to the present invention can exhibit a stable function for a long period of time by the slide cam having enhanced resistance to heat.

[Brief description of drawings]

FIG. 1 is a plan view of a disc device according to the present invention with a disc tray in a disc reproducing position.

FIG. 2 is a plan view of a disc device according to the present invention with a disc tray in a disc loading / unloading position.

3 is a plan view of the chassis of FIG. 1. FIG.

FIG. 4 is a front view of the chassis of FIG.

FIG. 5 is a bottom view of the disc tray.

FIG. 6 is a schematic perspective view of a mechanism unit.

7A and 7B are side views showing a mode in which the mechanism unit 42 rotates up and down.

8A and 8B are a top view and a front view, respectively, of a slide cam according to the present invention.

FIG. 9 is a schematic front view showing the relationship between the position of the guide pin, the position of the stopper protrusion of the slide cam, and the position of the protruding stopper of the chassis.

FIG. 10 is a front view of a conventional slide cam.

[Explanation of symbols] 1 disk device 2 device body 40 chassis 41 Loading mechanism storage area 42 mechanical unit 421 base frame 422 base plate 43L protrusion 43R protrusion 430 guide pin 431 rotation axis 432 Bearing 44 Disc tray support surface 44a Guide protrusion 44b Guide rib 44c Guide rib 441 elastic member 45 Mechanical unit mounting area 46 Projection stopper 47 Optical pickup 471 guide mechanism 472 thread motor 48 Disk clamper storage area 49 turntable 491 Spindle motor 50 loading mechanism 51 slide cam 51a cam groove 51b rack 51c protrusion 52 First side 53 Second side 56 Cavity 57 Stopper protrusion 58 Straight receiving part 59 Inclined receiving part 60 drive mechanism 61 loading motor 62 pulley mechanism 621 first pulley 622 second pulley 624 belt 63 Second Gear 631 Gear B 632 Gear C 64 3rd gear 65 Transmission mechanism 70 disc tray 71 Disk mount 711 opening 72L left side 72R Right side 72a Main guide groove 72b Sub guide groove 72c Sub guide groove 74 racks 78a, 78b restriction groove 80 disk clamper

   ─────────────────────────────────────────────────── ─── Continued front page    F term (reference) 5D046 AA16 CA03 CB16 CC03 EB04                       HA05 HA10                 5D138 RA05 RA11 SA01 TA02 TA12                       TA23 TC05 TC22 TD04 TD05                       TD06 TD14 TD16

Claims (3)

[Claims] 1. A receiving part that is slidably mounted on a chassis of a disk device to move a driven member up and down, and is formed at a position facing a receiving part that supports a guide pin of the driven member. A slide cam for a disk device, which includes a hollow portion that allows the receiving portion to be elastically deformed, and a stopper projection portion that is formed in a protruding manner in the hollow portion and that restricts the deformation of the receiving portion. 2. A disk device comprising: a chassis; and a slide cam, which is slidably mounted on the chassis so as to move the driven member up and down, and has a receiving portion that supports a guide pin of the driven member. The disk device, wherein the chassis includes a stopper portion that restricts deformation of the receiving portion. 3. A disk device comprising the disk device slide cam according to claim 1.