JP2007265472A - Optical disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical disk device which can be made low-profile and lightweight while reduction in the strength is suppressed. <P>SOLUTION: The optical disk device is provided with a housing formed in a flat shape by a lower part case and an upper part case layered one on the other, a tray which is provided so as to be freely inserted into and extracted from an end face of the housing and which can place the optical disk thereon, a pickup module attached to the tray, a main substrate housed in the housing, and a flexible cable 91 connecting the pickup module to the main substrate, wherein the flexible cable 91 has a pair of straight line parts 103, 105 and a circular arc-shaped line-symmetric connection part 107 which connects straight line parts 103, 105, while straight line parts 103, 105 are layered by folding back the connection part 107 with a symmetry line 109 as a boundary. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an optical disc apparatus that performs recording on an optical disc or reproducing an optical disc.

  Recording on an optical disc medium such as MO, PD, CD, CD-ROM, CD-R, CD-RW, DVD-ROM, DVD-RAM, DVD ± RW, DVD ± R, and reproduction of the recorded optical disc medium are CD- This is performed by a ROM drive device, a PD drive device, and a DVD drive device. Hereinafter, in the present specification, the above-described various optical disk media are collectively referred to as an optical disk, and an apparatus for recording and reproducing the recorded optical disk medium is collectively referred to as an optical disk apparatus.

  These optical disk devices are mounted on various electronic devices such as stationary electronic devices such as desktop personal computers, notebook personal computers, portable information terminal devices, and portable video devices. As an optical disk apparatus mounted on the disk, further reduction in size and weight and reduction in thickness are required.

  As a loading method of the optical disk in the optical disk device, there are a drawer method and a slot method. In the drawer method, the user holds the optical disc by himself, attaches the optical disc directly to the turntable that rotates the optical disc, and then pushes the tray including the turntable into the drive housing by his / her hand, thereby reproducing and recording the optical disc. This is a possible state (see, for example, Patent Documents 1 to 3). In the slot system, the optical disk is transported to the front of the device, and the optical disk is inserted into a slit provided in a cover called a front bezel provided on the front of the device. The optical disk is automatically sucked into the inside of the apparatus, that is, the turntable by a loading mechanism such as a roller provided in the apparatus.

  The drawer method is advantageous for being mounted on notebook personal computers that are becoming smaller and thinner. 44 to 51 show an example of a conventional drawer type optical disc apparatus.

  44 to 51, a housing 1001 accommodates a tray 1002, and includes an upper case 1001a and a lower case 1001b. The housing 1001 has a bag-like configuration having an opening 1001c at one end, and the tray 1002 is held so as to be freely inserted and removed. The tray 1002 is made of a lightweight material such as a resin material, and a bezel 1003 is provided on the front portion thereof. The bezel 1003 is configured to close the opening 1001c when the tray 1002 is stored in the housing 1001. An eject button 1004 is exposed on the bezel 1003, and when the eject button 1004 is pressed, the tray 1002 slightly protrudes from the housing 1001 by a mechanism (not shown), and the tray 1002 can be inserted into and removed from the housing 1001. It can be.

  An opening 1005 is provided in the tray 1002, and a pickup module 1006 is attached so that the surface thereof is exposed from the opening 1005. The pickup module 1006 includes a spindle motor 1007 that rotates the optical disc 1009 and a movable carriage 1008. The carriage 1008 moves toward and away from the spindle motor 1007 and is driven by the motor 1011. An optical pickup (not shown) is mounted on the carriage 1008. By irradiating the optical disk 1009 with light, information can be recorded on the optical disk 1009 or information can be reproduced by reflected light from the optical disk 1009. It has become. A pickup cover 1010 is provided on the side of the pickup module 1006 where the optical disc 1009 is mounted.

  The rails 1012, 1013 guide the movement of the tray 1002, engage with both side portions of the tray 1002, and are locked to the tray 1002 so as to be movable within a predetermined range. Rail guides 1014 and 1015 made of a resin material or the like are fixed to the lower case 1001b, and the rails 1012 and 1013 are movably supported. The rail guides 1014 and 1015 are locked by a rail guide fixing portion 1016 formed integrally with the lower case 1001b. Further, the lower case 1001b is provided with a locking claw 1017. The locking claw 1017 abuts on a key-like portion provided at the rear end of the rail 1012 so that the rail 1012 does not protrude more than a predetermined amount. A portion corresponding to the locking claw 1017 is also provided integrally with the lower case 1001b on the rail 1013, but it is not shown.

  A circuit board 1018 on which electronic components such as integrated circuits 1019 and 1020 are mounted is attached to the rear end of the lower case 1001b. Further, when the tray 1002 is stored in the housing 1001, a part of the circuit board 1018 and a part of the tray 1002 overlap each other.

  A flexible cable 1021 having flexibility electrically connects the circuit board 1018 and the tray 1002, supplies driving power to the spindle motor 1007 and the carriage 1008, and sends control signals to the spindle motor 1007 and the carriage 1008. Various signals for transmitting or controlling the optical pickup mounted on the carriage 1008 are transmitted in both directions.

As shown in FIGS. 48, 50, and 51, the spindle motor 1007 is fixed to the pickup module 1006, a spindle motor frame 1070 fixed to the spindle motor frame 1070, and a stator 1071 rotatably. Rotor 1072. The rotor 1072 holds the optical disk and rotates together with the optical disk. The holding mechanism for holding the optical disk is within a diameter of φ15 mm from the rotation center of the rotor 1072. The holding mechanism may be provided with three claw portions made of resin, or may be attracted by a magnet.

  The rotational speed of the optical disk 1009 is a maximum of 5400 rpm in the case of CD 24 times speed, and when converted to a linear speed, it is about 40 km / h at the outermost periphery of the optical disk 1009 with a diameter φ120 mm. For this reason, if it arrange | positions so that the space | interval of the upper case 1001a and the optical disk 1009 may be set to about 1 mm, a negative pressure will generate | occur | produce between the optical disk 1009 and the upper case 1001a. When the rigidity of the upper case 1001a is weak, this negative pressure becomes a suction force, and a phenomenon that the upper case 1001a is recessed occurs. In other words, as shown in FIG. 49, a concave shape in which the displacement is maximum occurs at the periphery of the spindle motor 1007 that is the rotation center of the optical disc 1009 and at the position from the rotation center to the tray insertion / extraction direction.

  Next, a description will be given focusing on the periphery of the spindle motor 1007 where the large displacement occurs. 50 and 51 are partial side cross-sectional views showing a conventional optical disc device, respectively, FIG. 50 shows a state where the optical disc 1009 is not rotating, and FIG. 51 shows that the optical disc 1009 is rotating, and the optical disc 1009 and the upper case 1001a. A state in which a negative pressure is generated between is shown. When negative pressure is generated between the optical disc 1009 and the upper case 1001a, the periphery of the spindle motor 1007 is recessed most, so when the displacement of the upper case 1001a increases, the upper surface of the rotor 1072 of the spindle motor 1007 that rotates the optical disc 1009 The upper case 1001a or the nameplate attached to the upper case 1001a comes into contact. When the upper case 1001a and the nameplate come into contact with the rotor 1072 of the spindle motor 1007, a sound due to the contact is generated, or the rotational speed of the optical disc 1009 is reduced depending on circumstances.

  In order to reduce the influence due to the generation of such negative pressure, the optical disc apparatus described in Patent Document 3 realizes weight reduction by providing a concave or convex portion substantially concentric with the optical disc in the upper case.

  On the other hand, electronic devices such as notebook personal computers are desired to be further reduced in weight, and accordingly, further reduction in the weight of the optical disk device is desired. To reduce the weight of the optical disk device, it is effective to change the material of the components such as the housing, tray, and pickup module to light and thin. However, simply changing the material of the component and making it thin will increase the strength. There is a possibility that the recording / reproduction characteristics and the like may be deteriorated due to the torsion of the member.

JP 2001-307460 A JP 2003-151199 A JP 2005-322349 A

However, the above-described conventional optical disc apparatus is desired to be further reduced in weight with the demand for reducing the weight of electronic devices such as notebook personal computers. However, when the weight of the upper case, the lower case, or the tray constituting the housing is reduced by changing the material or making the tray thinner, the upper case is caused by the negative pressure generated between the optical disc and the upper case when the optical disc rotates. The upper case comes into contact with the optical disk, spindle motor, and the like. It is also effective to change the material of each component such as rails, rail guides, pickup modules, circuit boards, flexible cables, etc. to light and thin, but simply changing the material of the component and making it thin will provide strength. There is a possibility that the recording / reproducing characteristics and the like are deteriorated due to the twist of the member. In particular, in a structure in which the tray and the circuit board are connected by a flexible cable, the flexible cable cannot be expanded and contracted in a thin laminated structure in a structure in which the bent portion of the flexible cable overlaps the straight line portion due to advancement and retraction of the tray. There was a problem in making the housing thinner.
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide an optical disc apparatus capable of realizing a reduction in thickness and weight while suppressing a decrease in strength.

The above object of the present invention is achieved by the following configuration.
(1) a housing formed in a flat shape by a lower case and an upper case stacked on each other;
A tray that can be inserted / removed from an end face of the housing, and on which an optical disk can be mounted;
A pickup module attached to the tray;
A main board housed in the housing;
A flexible cable for connecting the pickup module and the main board;
The flexible cable is substantially U-shaped having a pair of straight portions and a line-symmetric arc-shaped connecting portion that connects the straight portions,
An optical disc apparatus in which the linear portions are stacked by folding the connecting portion with a symmetry line as a boundary.

  According to this optical disc apparatus, since the flexible cable formed in a substantially U shape by the pair of linear portions and the arc-shaped connecting portion is folded so that the linear portions are stacked with the symmetry line as a boundary, In the structure where the straight line end is connected to the main board and the upper straight line end folded back toward the connecting part is connected to the pickup module, the upper straight part end side moves on the connecting part by the advancement and retraction of the tray. However, the bent part of the connecting part does not overlap with the lower layer of the upper straight part (that is, the connecting part has a folding line that does not overlap with the upper straight part), and the flexible cable has a thin laminated structure. Expanded and contracted.

(2) A collar portion provided on one side of the connecting portion from the symmetry line corresponding to the upper straight portion slidably contacting the tray among the straight portions is bonded to the lower case (1) The optical disk device described.

  According to this optical disc apparatus, among the connecting portions folded back with the symmetry line as a boundary, the elastic portion generated by being folded back is obtained by adhering the collar portion provided at the connecting portion in the upper linear portion to the lower case. The fold line portion to be swollen by force is restrained by the connecting portion of the upper straight portion fixed to the lower case via the collar portion, and the bulge of the fold curve portion is prevented. Thereby, the attachment strength of a flexible cable can be improved and the housing can be made thin.

(3) having a tray cover attached to the back surface of the tray;
In the range corresponding to the flexible cable on the lower surface facing the lower case in the tray cover,
The optical disc apparatus according to any one of (1) and (2), wherein a stepped portion that is separated stepwise is provided.

  According to this optical disc apparatus, since the tray cover on the back side of the tray is formed in a step shape, the housing can be made thin without hindering the followability of the flexible cable that follows the advancement and retraction of the tray. That is, the bottom of the lower case is provided with a notch for making the thickness as thin as possible. A flexible cable is attached to the bottom of the lower case near the notch, so that the structure below the tray cover has a three-layer structure consisting of two layers of straight and bottom, two layers of straight and bottom. There are three types: a layer structure part and an open part that becomes a notch. By forming stepped portions corresponding to the respective portions in the tray cover in stages, a flexible cable housing structure capable of following the advance and retreat of the tray is realized while enabling the housing to be thinned.

(4) In order to maintain the state in which the tray is stored in the housing, the storage includes an engagement pin provided in the housing and an engagement hook provided in the tray and engageable with the engagement pin. Maintenance means,
The optical disc apparatus according to any one of (1) to (3), wherein the connecting portion is disposed on a depth side along the insertion / extraction direction of the tray from the engagement pin.

  According to this optical disc apparatus, the connecting portion of the flexible cable attached to the lower case of the housing maintains the tray in the housing state in order to maintain the tray in the housing state. Therefore, mutual interference in the stacking direction of the connecting portion and the engagement pin can be prevented. Thereby, the housing can be thinned.

(5) A folded portion of one straight portion folded toward the connecting portion in a state where the tray is housed in the housing is disposed outside a planar contour of the optical disc mounted on the tray (1) ) To (4).

  According to this optical disc apparatus, since the folded portion of one straight portion of the flexible cable folded back toward the connecting portion is disposed outside the planar contour of the optical disc, the folded portion having a large thickness overlaps the optical disc. Can be prevented. Thereby, it is sufficient to secure a gap between the tray and the lower case for two layers where the pair of linear portions excluding the folded portion is overlapped, and the housing can be thinned.

  According to the optical disk apparatus of the present invention, the flexible cable formed in a substantially U shape by the pair of linear portions and the arc-shaped connecting portion is folded so that the linear portions are stacked with the symmetry line as a boundary. In the structure in which the straight line end of the lower layer is connected to the main substrate and the straight line end of the upper layer folded back toward the connecting part is connected to the pickup module, the straight line end side of the upper layer moves over the connecting part by the advancement and retreat of the tray. Even if it moves, the bent portion of the connecting portion does not overlap the lower layer of the upper straight portion. As a result, the flexible cable can be expanded and contracted with a thin laminated structure, and the housing can be thinned.

DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of an optical disk device according to the invention will be described with reference to the drawings.
1 is a perspective view showing the optical disk apparatus according to Embodiment 1 of the present invention, FIG. 2 is a perspective view of the optical disk apparatus of FIG. 1 viewed from the rear side, and FIG. 4 is an exploded perspective view of the engaging portion shown in FIG. 3, FIG. 5 is an enlarged perspective view showing a rear bent portion of the upper case, FIG. 6 is an assembled perspective view of the upper case hooking portion, and FIG. FIG. 7 is an exploded perspective view of a hook portion shown in FIG.
The optical disc device 500 includes a housing 3 having a flat shape (a ridge line is a thin box shape) having an opening 1 on an end surface. The housing 3 is formed in a flat shape so as to be easily accommodated and fixed to an attachment body such as a casing of a notebook PC. The housing 3 is formed by a lower case 5 and an upper case 7 that are stacked on each other. The housing 3 is provided with a tray 9 on which an optical disk can be mounted. The tray 9 can be inserted and removed through an opening 1 provided on an end surface of the housing 3. The optical disc is not placed directly on the tray 9, but is placed on a turntable attached to a rotating shaft of a spindle motor 95 described later, and does not contact the tray 9 itself.

  The lower case 5 includes a bottom portion 5a (see FIG. 13) having a substantially L-shaped plane, a back wall portion 5b (see FIG. 13), and a pair of side wall portions 5c and 5d (see FIG. 13). The upper case 7 includes a top plate 7a having a substantially rectangular plane shape, and covers the back wall portion 5b and the side wall portions 5c and 5d. The lower case 5 constitutes a lid, while the opening 1 is formed on one end surface. The bottom portion 5a of the lower case 5 is formed in a substantially plane shape by the relatively large cutout 6 (see FIG. 13), which corresponds to the planar contour of the pickup module 57 (see FIG. 23) described later. As a result, the tray 9 is dropped into the lower case 5 as far as possible.

  The lower case 5 and the upper case 7 are provided with engaging means 11 for engaging both members with each other. As shown in FIGS. 3 and 4, the engaging means 11 includes a protrusion 13 provided on one of the lower case 5 and the upper case 7 (upper case 7 in the present embodiment), the lower case 5, The engaging portion 15 is provided on the other of the upper cases 7 (the lower case 5 in the present embodiment) and engaged with the protruding portion 13. The protrusion 13 rises (hangs down) from the top plate 7a and protrudes toward the front or the back in the insertion / extraction direction of the tray 9 (toward the front in the present embodiment).

The housing 3 penetrates one of the lower case 5 and the upper case 7 (the upper case 7 in the present embodiment) with the protruding portion 13 and the engaging portion 15 engaged with each other. A fixing screw 17 is provided that is screwed into the other of the upper cases 7 (the lower case 5 in the present embodiment). Then, the engagement between the protrusion 13 and the engagement portion 15 is made on the front side of the line that passes through the rotation axis 19 of the optical disk in the state in which the tray 9 is housed in the housing 3 and is orthogonal to the insertion / removal direction of the tray 9. The joint point and the fixing screw 17 are adjacent to each other. That is, the lower case 5 and the upper case 7 have the protruding portion 13 and the engaging portion 15 in a temporarily engaged state (step stacking), and then the upper case 7 toward the near side (in the direction of arrow 21 in FIG. 4). After sliding to the final engagement, the main screw is fixed with the fixing screw 17.
The step stacking means that the lower case 5 and the upper case 7 are stacked, but the protruding portion 13 and the engaging portion 15 are not engaged, that is, the projected shape of the lower case 5 and the projected shape of the upper case 7. Indicates a state where the lower case 5 and the upper case 7 can be separated from each other in the thickness direction.

  In the engaging means 11 configured as described above, the protruding portion 13 and the engaging portion 15 are brought into an engaged state by engaging the protruding portion 13 with the engaging portion 15 (for example, sliding after dropping). The upper case 7 and the lower case 5 brought into the engaged state via the protruding portion 13 and the engaging portion 15 are screwed by the fixing screw 17 at a position adjacent to the engaging portion 15. Engagement (ie, slide) is restricted and disengagement is prevented. Therefore, the upper case 7 and the lower case 5 are fixed doubly, and the opening of the upper case 7 and the lower case 5 (the lifting of the upper case 7) due to the loosening of the fixing screw 17 is prevented. Further, since the engaging means 11 and the fixing screw 17 are adjacent to each other, a so-called synergistic effect is obtained in which a loosening prevention force acts on the fixing screw 17 and an engagement release preventing force acts on the engaging means 11. It is done. Further, the fixing screw 17 can reliably connect the upper case 7 and the lower case 5 on the opening 1 side of the housing 3.

  A fixing screw 23 is disposed at a corner of the plane of the housing 3, and the fixing screw 23 passes through the top plate 7 a and is screwed into the lower case 5. Therefore, compared with the case where only the center part of the side part of the housing 3 is fixed, the planar corner part of the top plate 7a can be prevented from being turned over. Further, in the combined structure with the engaging means 11, it is possible to simply fix the portion where the engaging structure by the engaging means 11 is difficult to be provided (that is, the plane corner) with only the fixing screw 23, and the housing 3. The upper case 7 and the lower case 5 on the side opposite to the opening 1 can be reliably electrically connected.

  Further, the protruding portion 13 rises along the stacking direction of the lower case 5 and the upper case 7 and protrudes along the insertion / extraction direction of the tray 9. The engaging portion 15 can be relatively inserted between one of the lower case 5 and the upper case 7 and the protruding portion 13. Then, the lower case 5 and the upper case 7 are moved relative to each other along the insertion / removal direction from the temporary engagement state in which the lower case 5 and the upper case 7 are layered so that the engagement portion 15 is disposed on the extension line on the upper portion of the protrusion 13. Thus, the lower case 5 and the upper case 7 are not separated from each other in the stacking direction.

  According to the housing 3 configured in this manner, the protruding portion 13 and the engaging portion 15 are engaged with each other, and the lower case 5 and the upper case 7 can be in a fixed state in which they are not separated from each other in the stacking direction. Further, at the time of disengagement, the lower case 5 and the upper case 7 can be easily separated by disengaging the protruding portion 13 and the engaging portion 15 by relatively moving in a direction away from each other.

  As shown in FIG. 5, the upper case 7 is attached to the lower case 5 by a hooking portion 25. The hook portion 25 includes a hook claw 25 a that is bent and raised on the inner wall portion 5 b of the lower case 5 and a hook hole 25 b formed in the upper case 7 on which the hook portion 25 is hooked. Thereby, the opening of the side part on the back side of the housing 3 is prevented.

The lower case 5 and the upper case 7 seem to be fixed by only four fixing screws 17 and 17 and fixing screws 23 and 23 at first glance. It is fixed. Accordingly, the engaging portion 15 and the hooking portion 25 of the upper case 7 having low strength receive the vertical load applied between the upper case 7 and the lower case 5 in the shear direction of the material (the direction perpendicular to the plate thickness). When the protrusion 13 and the engagement portion 15 of the engagement portion 11 are engaged with each other, the case 7 and the lower case 5 are aligned along the direction (thickness direction) perpendicular to the arrow 21 (see FIG. 4). It is possible to prevent so-called mouth opening.
In such an optical disc apparatus 500, since many movable parts are arranged on the opening 1 side of the housing 3, fixing screws for fixing the upper case 7 and the lower case 5 on the opening 1 side of the housing 3 are provided. There is a desire to use as small a fixing screw as possible.
In response to such a demand, in the optical disc apparatus 500 according to the present embodiment, the upper case 7 and the lower case 5 on the opening 1 side of the housing 3 are fixed by the cooperation of the engaging portion 11 and the fixing screws 17 and 17. Therefore, the fixed screws 17 and 17 having a smaller diameter can be adopted as compared with the fixed screws 23 and 23 independently employed at two positions on the rear end side when viewed from the bezel 27 side of the tray 9.
Further, the head height and diameter of the fixing screws 17 and 17 are within the range of the height R and the width S of the reinforcing rib 7 b of the upper case 7.

The fixing closer to the bezel side is also performed by the engaging portions 11, 11, but with this alone, the contact between the protruding portion 13 of the upper case 7 and the lower case 5 is weak, and the upper case 7 of the bezel side portion is fixed. The electrical continuity state with the lower case 5 cannot be maintained completely. In such a case, the portion that is not electrically conductive becomes an antenna, which causes unnecessary radiation. In the structure of the present embodiment, the upper case 7 and the lower case 5 are electrically contacted by fixing the two portions closer to the bezel side with the engaging portions 11 and 11 and the fixing screws 17 and 17. Is also certain.
As a result, the upper case 7 and the lower case 5 ensure that the four corners are in electrical contact with the fixing screws 17 and 23 to prevent unnecessary radiation.

  Further, in the hook portion 25 in the back wall portion 5 b of the lower case 5, the vertical load applied between the upper case 7 and the lower case 5 on the rear surface portion of the housing 3 is increased by the hook hole 25 b of the upper case 7. It is configured to receive in the vertical direction. Since the side surface portion and the rear surface portion of the housing 3 are configured as described above, the protrusions 13 provided on both side surfaces of the bezel side of the upper case 7 are first inserted into the engaging portions 15 of the lower case 5 during assembly. Then, the entire upper case 7 is slid to the bezel side. If the hooking portion 25 as shown in FIG. 5 is provided in at least one place on the rear surface portion, so-called opening of the mouth in which the central portion of the back wall portion 5b of the upper case 7 is separated from the lower case 5 can be prevented.

  According to the optical disc apparatus 500 according to the present embodiment, the optical disc device 500 passes through the rotation axis 19 of the optical disc in the state in which the tray 9 is housed in the housing 3 and is closer to the front side than the line perpendicular to the insertion / extraction direction of the tray 9. Since the engaging portion of the projecting portion 13 and the engaging portion 15 and the fixing screw 17 are adjacent to each other, the upper case 7 and the lower case 5 that are engaged via the projecting portion 13 and the engaging portion 15. Is screwed by the fixing screw 17 at a position adjacent to the engaging portion 15, thereby disengaging the engaging means 11. Accordingly, the upper case 7 and the lower case 5 are fixed doubly, and the opening of the upper case 7 and the lower case 5 due to the loosening of the fixing screw 17 can be prevented. Further, since the engaging means 11 and the fixing screw 17 are adjacent to each other, a so-called synergistic effect is obtained in which a loosening prevention force acts on the fixing screw 17 and an engagement release preventing force acts on the engaging means 11. be able to. As a result, the upper case 7 and the lower case 11 can be assembled with high rigidity, and the housing 3 can be thinned. Furthermore, a reliable grounding action can be obtained between the upper case 7 and the lower case 5 by the fixing screw 17.

FIG. 8 is a plan view showing the dent range of the upper case, FIG. 9 is a cross-sectional view showing the dent range of the upper case, and FIG. 10 is a tray plan view (a) and its AA cross-section view is (b). 11 is a tray configuration diagram in which a plan view of a tray on which an optical disk is mounted is shown in (a), and a cross-sectional view taken along the line BB is shown in (b). FIG. 12 is a view in the direction of arrows CC in FIG. It is the housing side view which represented ab, DD arrow view to (b), and EE arrow view to (c).
The housing 3 in which the upper case 7 is fixed to the lower case 5 is configured in a bag shape having an opening 1, and the opening 1 is closed by a bezel 27 when the tray 9 is stored.

  The upper case 7 is made of a plate material or a thin plate material containing a lightweight metal material, and aluminum, aluminum alloy, magnesium alloy, titanium, titanium alloy, etc. are suitably used as the lightweight metal material, and at least of these materials It is constructed by processing a single plate. Moreover, it is good also as a multilayer structure by mutually joining the board | plate material comprised with the said lightweight metal material. For example, an aluminum thin plate and an aluminum alloy thin plate may be joined to each other, or a plurality of aluminum thin plates and a thin plate mainly composed of another metal material may be laminated. Furthermore, you may use the composite lightweight board which affixed the thin board comprised with nickel or nickel alloy on both the main surfaces of a resin sheet or a resin board (a plating process is included).

The distance between the optical disk 29 (see FIG. 9) and the upper case 7 is, for example, about 0.5 mm to 2 mm when thinning. The optical disk 29 rotates at 5000 RPM or more at high speed. At this time, when the Reynolds number of air in the gap between the optical disk 29 and the upper case 7 is obtained,
Re = V · L / ν.
Re is the Reynolds number, V is the flow velocity, L is the representative length, and ν is the kinematic viscosity coefficient.
The diameter of the optical disk 29 is 12 cm, the rotation speed is 5400 RPM, the representative length is 1/2 of the optical disk 29 and the upper case 7, and ν is 0.15 [cm ² / sec] as air, and the Reynolds number on the outer periphery of the optical disk is Asking
Re = (12 × π × 5400/60) · (0.025 to 0.1) /0.15
= 565-2262
It becomes.
It is generally known that when the Reynolds number is 3000 or less, the flow becomes laminar. Therefore, in this case, air is moving at high speed in a laminar flow state, and a strong suction force is generated between the optical disc and the upper cover.

  The upper case 7 is subjected to a negative pressure due to the rotation of the optical disk 29, and acts to dent into the apparatus. On the other hand, in order to reduce the weight, the upper case 7 is thin and has a relatively low mechanical strength. Therefore, in order to counter this negative pressure, it is preferable to adopt a structure in which the portion facing the center of the optical disc is recessed in advance from the peripheral portion in order to increase the rigidity of the upper case 7. However, the optical disk 29 is warped so that it can be said that there is a possibility that the optical disk 29 may come into contact if the bottom surface of the upper case 7 is too close to the optical disk 29.

  For example, it is assumed that there is a requirement specification that “the curvature of the outer edge of the disk corresponds to ± 0.55 mm with respect to the center of the optical disk 29”. In this case, if it is assumed that the optical disk 29 is essentially a flat surface, the bottom surface of the upper case 7 is below the line connecting the center of the optical disk and a point shifted by 0.55 mm above the reference surface at the outer edge of the disk. It would be good if the department was on top. Further, assuming that the upper case 7 is subjected to a load from above, the upper case 7 has a higher strength when it has as many irregularities as possible.

  Therefore, in the present embodiment, as shown in FIG. 8, the upper case 7 has a plurality of concavo-convex portions 31 that are continuous in the circumferential direction around the line along the rotation axis 19 of the optical disk 29 and are concentrically arranged. is doing. The concavo-convex portion 31 includes, for example, concave portions 31a, 31b, 31c having a rectangular cross section that are recessed in a direction approaching the optical disc 29, and convex portions 31d, 31e having, for example, a rectangular cross section protruding in a direction away from the optical disc 29. The concave portions 31a, 31b, 31c and the convex portions 31d, 31e of the concavo-convex portion 31 have different step sizes. Moreover, among each uneven | corrugated | grooved part 31, the level | step difference dimension of 31 A of inner peripheral side uneven | corrugated | grooved parts is set more than the step size of outer peripheral side uneven | corrugated part 31B. More specifically, as shown in FIGS. 8 and 9, the range of the inner circumferential uneven portion 31 </ b> A is formed inside a circle of approximately φ80, which is the central portion of the optical disc 29, in the case of the φ120 optical disc 29.

  The housing 3 having such a configuration increases the mechanical strength of the upper case 7 even when a relatively thin plate material is used for the upper case 7. Even if this occurs, it is difficult for the upper case 7 to be twisted or depressed. As a result, contact between the upper case 7 and the optical disk 29, damage to the optical disk 29 due to the contact, and the like are prevented, and the housing 3 that is thin, lightweight, and hardly deforms is obtained. In addition, since the step size of the inner circumferential uneven portion 31A is equal to or larger than the step size of the outer circumferential uneven portion 31B, the upper case 7 can be formed in an arc shape in which mechanical strength is easily obtained.

  Even if a negative pressure is generated inside the apparatus as the optical disk 29 rotates, the upper case 7 is easily deformed even if it receives a force in the direction toward the inside of the apparatus by providing an arc shape. Will not cause. The arc-shaped formation area is preferably 50% to 100% with respect to the φ120 optical disk projection area, that is, the ratio of the area inside the outer circumferential uneven portion 31B and the optical disk projection area. If it is less than 50%, it is difficult to give the upper case 7 a desired rigidity, and if it is more than 100%, a sufficient effect cannot be obtained even if an arc shape is formed in the upper case 7. In this embodiment, the arc-shaped contour is circular, but it may be rectangular, triangular, elliptical, or a polygonal shape of pentagon or higher. Furthermore, the cross-sectional shape of the concavo-convex portion 31 may be a semicircular shape other than a square shape. Moreover, the combination of these shapes may be sufficient.

  And since the inner peripheral side uneven part 31A protrudes toward the inside of the housing 3, the convex part 31e does not protrude to the outside of the housing 3, and the thickness of the housing 3 does not increase. Therefore, the rigidity of the housing 3 can be increased while ensuring a thin housing.

  On the other hand, the outer peripheral side uneven portion 31 </ b> B may protrude in a direction away from the optical disk 29. By projecting the outer peripheral uneven portion 31B outward, the gap between the outer peripheral side of the inner peripheral uneven portion 31A and the outer peripheral side of the optical disc 29 is increased, and the optical disc is easily deformed by the negative pressure generated by the rotation. It becomes difficult for the outer peripheral side of 29 to contact the outer peripheral side of the upper case 7. Further, by ensuring this gap, it is possible to make it difficult for contact caused by warpage of the optical disc 29 or contact due to irregular holding of the optical disc 29 to occur. The outer circumferential uneven portion 31B protrudes outward, but the tip of the convex portion 31a is disposed within the thickness of the housing 3 so as not to protrude outward from the housing 3. As a result, it is possible to simultaneously realize a reduction in the thickness of the housing 3, improvement in the rigidity of the upper case 7, and avoidance of contact with the optical disk.

  As shown in FIG. 10, in the tray 9, the facing surface 33 facing the optical disk 29 is formed so that the separation dimension on the outer peripheral side is larger than the separation dimension on the inner peripheral side in the optical disk 29. More specifically, the facing surface 33 is formed with about φ123, and as shown in FIGS. 10 and 11, the tray height from the center side to φ93 is high. Then, from a circle having a high tray height (φ93 mm in the present embodiment) to a predetermined range (φ102 mm in the present embodiment), a gentle slope 35 is formed in a direction away from the optical disk 29. Has been.

By the way, even if the housing 3 is made thinner, there is a demand for ensuring the gap dimension (GAP) of the tray 9 with respect to the optical disk 29 equivalent to the existing model. In order to satisfy such a demand, it is conceivable to reduce the thickness of the tray 9. In this case, however, the rigidity (strength) of the tray 9 cannot be sufficiently secured. There is a risk of operability deterioration and tray damage.
On the other hand, the tray 9 described above has a high center side, in other words, is formed thick, so that sufficient rigidity (strength) can be ensured.
In addition, since the surface of the tray 9 facing the outer peripheral side of the optical disc is spaced apart from the surface facing the inner peripheral side, the gap between the outer peripheral side of the optical disc and the tray 9 is increased, and the negative pressure generated as a result of rotation. Therefore, the outer peripheral side of the optical disk 29 that is easily deformed becomes difficult to contact the tray 9. Further, by increasing the gap, it is possible to make it difficult for contact caused by warpage of the optical disk 29 or contact due to irregular holding of the optical disk 29 to occur.

  According to the optical disc apparatus 500 according to the present embodiment, the upper case 7 has a plurality of concavo-convex portions 31 that are continuous in the circumferential direction around the line along the rotation axis 19 of the optical disc 29 and are concentrically arranged. Since the uneven portion 31 has different step sizes, and the step size of the inner peripheral side uneven portion 31A is equal to or larger than the step size of the outer peripheral uneven portion 31B among the uneven portions 31, the upper case 7 has a relatively thin plate material. Can be obtained, the mechanical strength of the upper case 7 can be obtained, and even if a negative pressure is generated as the optical disk 29 rotates, the upper case 7 is less likely to be twisted or depressed. . Thereby, the contact between the upper case 7 and the optical disk 29 and the damage of the optical disk 29 due to the contact can be prevented. As a result, a thin housing 3 that is lightweight and hardly deformed can be obtained. Further, by setting the step size of the inner peripheral uneven portion 31A to be equal to or larger than the step size of the outer peripheral uneven portion 31B, the upper case 7 can be formed in an arc shape that easily obtains mechanical strength. 3 can be thinned.

  Note that the housing 3 in which the upper case 7 is attached to the lower case 5 is fixed to an attachment body such as a casing of the notebook PC. The lower case 5 has a plurality of female screws 37a to 37h for screwing fixing screws (not shown) inserted through the attachment body into the side wall portion 5c shown in FIG. 12 (a) and the rear portion shown in FIG. 12 (b). The wall 5b is formed on the side wall 5d shown in FIG.

  FIG. 13 is a perspective view of the housing in which the tray has been advanced through the guide means, FIG. 14 is a perspective view of the tray in the forward state showing the PUM mechanism constituting part and the ejecting mechanism constituting part, and FIG. 15 is a view showing the rail part. FIG. 16 is an enlarged perspective view of the rail shown in FIG. 15, FIG. 17 is an enlarged perspective view of the front end surface of the rail portion, and FIG. 18 is an enlarged perspective view of the left rail stopper portion between the rail and the tray, FIG. 19 is an enlarged perspective view of the right rail stopper portion between the rail and the tray, and FIG. 20 is a left rail stopper portion between the lower case and the rail. FIG. 21 is an enlarged perspective view of the right rail stopper portion between the lower case and the rail.

  The tray 9 can be inserted into and removed from the housing 3 by guide means described later. The tray 9 is made of, for example, a resin material, and a tray cover 41 (see FIG. 24) is attached to the back side. A notch 43 is formed on the back side of the tray 9 in the insertion / extraction direction, and the notch 43 has a shape corresponding to the electronic component 47 of the main board 45. That is, when the tray 9 is retracted, interference with the electronic component 47 is avoided by the notch 43. As a result, the tray 9 can be lowered to the lower case 5 side as much as possible, and the tray 9 and the main board 45 can be disposed close to each other by the thickness of the tray 9 corresponding to the notch 43, and the housing 3 is made thinner. Yes.

  The tray 9 is provided with a pair of ribs 49 and 51 (see FIG. 10) on the mounting surface (facing surface 33) facing the optical disk 29, and the ribs 49 and 51 pass through the rotation axis 19 of the optical disk 29 and the tray. 9 is formed in an R shape that is substantially close to the outer diameter of the optical disk 29 along the insertion / removal direction at both end portions (G and H portions in FIG. 13) orthogonal to the insertion / removal direction. The tray 9 can improve the tray strength by providing the ribs 49 and 51. In general, when the tray 9 is formed in a minimum shape with respect to the outer shape of the optical disk 29, the tray width (length in the longitudinal direction of the bezel 27) perpendicular to the insertion / extraction direction of the tray 9 is equal to the diameter distance of the optical disk 29. It will be close. Further, this proximity portion (G portion and H portion in FIG. 13) has been conventionally used as a finger-hanging portion for taking out the optical disc. Therefore, when the optical disk apparatus is made thinner than before, the stress is concentrated at both ends G and H, but the side wall is not provided and only the bottom plate parallel to the optical disk 29 is provided, so that the tray is greatly reduced in strength. To do. On the other hand, according to the present configuration, the tray 9 is thinned by providing ribs 49 and 51 along the tray insertion / removal direction at the both ends G and H, respectively, according to the configuration of the finger-holding holes 53 of the optical disk 29 described later. Even so, the tray strength can be improved.

  A through hole 53 is formed in the facing surface 33 facing the optical disk in the tray 9, and the through hole 53 is disposed at a position that partially overlaps the planar contour of the optical disk 29. In the tray 9, when the optical disk 29 is mounted, the through hole 53 is partially overlapped with the planar contour 29 a of the optical disk 29. Therefore, by inserting a finger into the through hole 53, The finger can be hooked on the lower surface side, and the optical disk 29 can be easily taken out. In particular, when reinforcing ribs 49 and 51 for improving the strength of the tray are provided in the proximity portions G and H that have been conventionally used, it is difficult to take out as in the conventional case, so the through hole 53 is used. The removal of the optical disk 29 is extremely effective.

  The component part of the ejection mechanism 55 (see FIG. 23) is arranged in the lower part (J part in FIG. 14) of the right front corner of the tray 9 when viewed from the bezel 27 side. A mechanism for moving the pickup 97 in the radial direction of the optical disk 29 is provided at the front left corner (I portion in FIG. 14) of the tray 9 when viewed from the bezel 27 side, in the mechanism component of the pickup module (PUM) 57 (see FIG. 23). Equipment).

  The tray 9 must be pulled out of the housing 3 so that the rear end portion of the mounted optical disk 29 does not contact the upper case 7 when the optical disk 29 is attached or detached. Not only this, but the optical disk device 500 is assumed to be used by being incorporated in a mounting body such as a casing of a notebook PC, for example, so that the rear end of the optical disk 29 mounted on the tray 9 is the upper case 7. It is desirable to pull out from the opening end by at least (thickness of the bezel 27) + (distance between the rear end of the bezel and the opening end of the upper case 7 when storing the tray). As a result, the rear end portion of the optical disk 29 mounted on the tray 9 is reduced from coming into contact with an opening of an attachment body such as a casing of the notebook PC.

  A tray 9 is attached to the housing 3 via guide means 59, and the guide means 59 can guide the tray 9, that is, can be inserted and removed from the opening 1. As shown in FIG. 15, the guide means 59 comprises a pair of left and right rails 61, an outer rail guide 63, and an inner rail guide 65 (see FIG. 17). As shown in FIG. 16, the rail 61 is formed in a substantially C-shaped cross section by a web 61 a and a pair of flanges 61 b and 61 c, and along the insertion / extraction direction of the tray 9 so that the cross-sectional opening 61 d faces the tray 9. Are arranged. The outer rail guide 63 is provided as a part of the lower case 5 of the housing 3, and covers the web 61 a and the flanges 61 b and 61 c along the longitudinal direction of the rail 61. The inner rail guide 65 is formed in a substantially T-shaped cross section and is provided on the tray 9, and is accommodated between the flanges 61 b and 61 c along the longitudinal direction of the rail 61.

As shown in FIG. 17 (b), the outer rail guide 63 is provided with a sliding member 87 having a substantially C-shaped cross section on the inner side, and an upright portion 67 that covers the end surface of the flange 61 c of the rail 61. Yes. Thereby, the rigidity (strength) of the lower case 5 can be improved, and the rail 61 can be prevented from being detached from the lower case 5 due to the rail 61 being bent.
Further, the flanges 61b and 61c of the rail 61 are provided with bent portions 69 and 69 that sandwich the inner rail guide 65 in cooperation with the web 61a. Thereby, when a load is applied to the tray 9 pulled out from the housing 3, it is possible to prevent the rail 61 from being detached from the inner rail guide 65 of the tray 9 due to the rail 61 being bent.
Note that either the rising portion 67 or the bent portion 69 may be provided, or both may be provided as in the present embodiment.

As described above, the outer rail guide 63 is provided in the portion of the outer rail guide 63 provided in the housing 3 so as to cover the inner rail guide flange, and the rising portion 67 that covers the end surface of the flange 61c is further provided. The rail 61 is housed inside the outer rail guide 63, and movement in the XY directions on the surface orthogonal to the tray insertion / extraction direction is restricted.
Therefore, the outer rail guide 63 holds the rail 61 and the rail 61 is prevented from falling off.

  Further, the inner rail guide 65 is sandwiched from above and below, and the pair of rail flanges 61b and 61c are provided with bent portions 69 and 69, respectively. While being held between the web 61a and the bent portions 69 and 69 and housed inside the rail 61, movement in the XY directions on the surface orthogonal to the tray insertion / removal direction is restricted. Therefore, the rail 61 holds the inner rail guide 65, and the inner rail guide 65, that is, the tray 9 to which the inner rail guide 65 is integrally fixed is prevented from falling off.

  And if both the upright part 67 and the bending parts 69 and 69 are provided like this Embodiment, while the outer rail guide 63 hold | maintains the rail 61 so that it cannot fall off, the rail 61 will support the inner rail guide 65. As a result, the tray 9 is held in the housing 3 so as to be movable in the insertion / removal direction and not to be dropped off.

  As shown in FIGS. 18 and 19, when the inner rail guide 65 formed on the rail 61 and the tray 9 moves between the rail 61 and the tray 9 in a direction away from each other along the insertion / extraction direction. The inner regulation means 71 for regulating the relative position is provided in the M and N parts in the figure. The inner side regulation means 71 is provided on the rail 61 and faces the depth side along the insertion / extraction direction, and the second abutment side provided on the inner rail guide 65 and faces the front side along the insertion / extraction direction. Surface 75. The second contact surface 75 is formed along the rotational axis 19 of the optical disk 29 and on the near side along the insertion / extraction direction with respect to the surface 77 orthogonal to the insertion / extraction direction of the tray 9.

  According to this inner regulating means 71, the first contact surface 73 provided on the rail 61 is in the insertion / extraction direction from the surface 77 along the rotation axis 19 of the optical disk 29 and orthogonal to the insertion / extraction direction of the tray 9. Since the inner rail guide 65 and the rail 61 move relative to each other as the tray 9 advances and retracts, both ends of the optical disk 29 in the diameter direction of the optical disk 29 are arranged on the first contact surface 73 constituting the restricting means. There is no possibility that the edges 29b and 29b (see FIG. 14) are in contact with each other. As a result, it is possible to prevent the optical disk 29 from coming into contact with the first contact surface 73 that is the advance / retreat restricting means of the guide means 59.

As shown in FIGS. 20 and 21, when the rail 61 and the outer rail guide 63 move between the rail 61 and the outer rail guide 63 in a direction away from each other along the insertion / extraction direction, Outer restricting means 79 for restricting the relative position is provided in the P part and the Q part of FIG. The outer regulating means 79 is provided on the first contact surface 81 which is provided on the rail 61 and faces the front side along the insertion / extraction direction, and the outer rail guide 63 which is a part of the lower case 5 and is provided along the insertion / extraction direction. And a second contact surface 83 facing the depth side. The second contact surface 83 and the second contact surface 83 are in cross contact.
In the present embodiment, the first contact surface 81 and the second contact surface 83 are arranged so as to cross each other, but the first contact surface 81 and the second contact surface 83 are horizontal to each other. You may arrange | position so that it may contact | abut.

  According to the outer regulating means 79, the rail 61 moves forward with respect to the outer rail guide 63 fixed to the housing 3 side, so that the second contact surface 83 provided on the outer rail guide 63 is brought into contact with the rail 61. The provided first contact surface 81 comes into contact, and further advancement of the rail 61 is restricted. At this time, the second contact surface 83 and the first contact surface 81 are in cross contact. For example, the second contact surface 83 is a horizontal contact end surface formed on the outer rail guide 63, and the first contact surface 81 is a vertical contact end surface formed on the rail 61. As a result, the first and second contact surfaces 81 and 83 are in cross contact with each other in the cross direction, and the outer rail guide 63 and the rail 61 are relatively displaced in the vertical direction or deformed in the horizontal direction due to deformation or the like. Even if the relative displacement (for example, the pair of left and right outer rail guides are opened due to the lowering of rigidity of the lower case bottom 5a which is U-shaped by providing the notch 6), the contact state can be maintained. The rail 61 can be prevented from falling off the outer rail guide 63.

  Further, the guide means 59 is provided with an elastic pressure contact portion 85 that elastically presses against the flange 61b of the rail 61 at the distal end portion of the inner rail guide 65 formed in the tray 9 in the insertion / extraction direction. A slit 85a is provided along the longitudinal direction of 65 (see also FIG. 15). By providing the elastic pressure contact portion 85, when the tray 9 is retracted, the inner rail guide 65 integrated with the tray 9 is retracted into the rail 61, and finally provided at the tip of the inner rail guide 65. The formed elastic pressure contact portion 85 is press-fitted between the rail flange 61b while narrowing the slit 85a. As a result, when the tray is stored, the inner rail guide 65 and the rail 61 are brought into a pressure contact state via the elastic pressure contact portion 85 due to the elasticity generated by the narrowing of the slit 85a, and there is a backlash between the rail 61 and the inner rail guide 65. Will not occur.

  Furthermore, the guide means 59 has a sliding member 87 (see FIGS. 15 and 17) formed at the tip end portion along the insertion / extraction direction of the outer rail guide 63 and on which the rail 61 slides. The rail 61 is provided with a raised portion 89 that protrudes from the distal end portion in the insertion / extraction direction toward the sliding member 87. By providing this raised portion 89, when the tray 9 is retracted into the storage state, the rail 61 is retracted into the outer rail guide 63, and finally, the raised portion 89 of the rail 61 is moved to the outer rail guide 63. The slide member 87 is pressed into contact (see FIG. 17) and is press-fitted into the outer rail guide 63. Note that a gap dimension (GAP) X is formed between the sliding member 87 of the outer rail guide 63 and the lower case 5 as a bending allowance of the sliding member 87 to reduce the pressure contact resistance (insertion resistance of the tray 9). is doing. That is, the tray 9 and the outer rail guide 63 are brought into a pressure contact state with the sliding member 87 and the raised portion 89, and no play is generated between the rail 61 and the outer rail guide 63. Thereby, coupled with the above-described configuration, when the tray is stored, the front end portion of the rail 61 is press-fitted between the inner rail guide 65 and the outer rail guide 63, and rattling of the tray 9 can be suppressed.

  According to the optical disc apparatus 500 according to the present embodiment, the guide means 59 for guiding the tray 9 with respect to the housing 3 includes the rail 61, the outer rail guide 63, and the inner rail guide 65, and the outer rail. A raised portion 67 provided on the guide 63 to cover one end face of each of the flanges 61b and 61c, and a fold provided on one of the flanges 61b and 61c to sandwich the inner rail guide 65 in cooperation with the web 61a. Since one of the curved portions 69 is provided, a portion 67 of the outer rail guide 63 provided in the housing 3 that covers the inner rail guide flange is further provided with a raised portion 67 that covers the end surface of the flange 61b. In the state where the outer rail guide 63 is held and the rail 61 is accommodated inside the outer rail guide 63, the tray insertion / removal direction is Movement of the XY direction on a plane orthogonal to is restricted, dropping is prevented.

  Further, when the pair of rail flanges 61b and 61c that sandwich the inner rail guide 65 from above and below are provided with bent portions 69 and 69, the rail 61 holds the inner rail guide 65, and the inner rail guide 65 is The pair of flanges 61b, 61c, left and right are sandwiched between the web 61a and the bent portions 69, 69, and the movement in the XY directions on the surface orthogonal to the tray insertion / removal direction is restricted while being accommodated inside the rail 61. Dropout is prevented. As a result, the tray 9 can be held so as to be movable in the insertion / removal direction and cannot be removed without being affected by the deformation of the housing 3, and the housing 3 can be further thinned.

22 is a perspective view of the lower case in the tray advance state, FIG. 23 is a perspective view of the tray with the tray cover removed as viewed from the lower surface side, FIG. 24 is a perspective view of the tray cover as viewed from the lower surface side, and FIG. FIG. 26 is a perspective view of the flexible cable when the tray is closed in the assembled state, FIG. 27 is a perspective view of the flexible cable when the tray is opened in the assembled state, and FIG. 28 is the tray closed of the flexible cable. FIG. 29 is a perspective view showing the assembly state of the flexible cable when the tray is opened, FIG. 30 is a perspective view of the tray showing the lock shaft avoiding portion, and FIG. 31 is in the tray storage state. FIG. 32 is a configuration diagram showing a flexible cable in a plan view (a) and a KK cross-sectional view in (b). FIG. It is a plan view illustrating a double-sided tape applying area of the cable.
As shown in FIG. 22, a main board 45 mounted with electronic components 47 and the like is attached to the bottom 5a of the lower case 5, and the main board 45 is connected to the relay board 45a (see FIG. 23), and the pickup module 57, the eject mechanism 55, the spindle motor and the like are electrically connected to the relay board 45a.

  As shown in FIG. 23, the relay board 45a, the pickup module 57, and the ejection mechanism 55 are provided on the lower surface side of the tray 9, and are covered with the tray cover 41 shown in FIG. The tray cover 41 serves to protect the relay board 45a, the pickup module 57, the ejection mechanism 55, and other components inside the tray 9. As will be described later, the portion of the tray cover 41 facing the flexible cable 91 has a three-stage structure in order to secure a thin space.

  A carriage 97 that rotates the optical disk 29 is movably held in the pickup module 57. Reference numeral 99 denotes driving means for generating a driving force for moving the carriage 97, which is moved by a feed motor. The carriage 97 is mounted with a light source, various optical components, a lens, and the like, and an optical device that performs at least one of recording and reproducing information on the optical disk 29 is mounted. A pickup cover 101 is provided so as to cover a portion of the pickup module 57 facing the optical disk 29.

As shown in FIG. 25, the flexible cable 91 has a substantially U-shape having a pair of straight line portions 103 and 105 and a line-symmetrical substantially one-half arc-shaped connection portion 107 that connects the straight line portions 103 and 105. It is formed in a shape. As shown in FIGS. 26 and 27, the flexible cable 91 is folded into a substantially circular arc shape with the connecting portion 107 having a bent portion 107a with the symmetry line 109 as a boundary when assembled into the housing 3. The straight portions 103 and 105 are stacked.
An adhesive layer may be provided on either one or both of the straight portions 103 and 105. According to this, the lamination | stacking state of each linear part 103,105 can be maintained reliably.

The flexible cable 91 is folded so that the same signal lines are overlapped by stacking the straight portions 103 and 105 with the symmetry line 109 as a boundary, and the connecting portion 103a of the lower straight portion 103 is connected to the main board 45. Then, the connecting portion 105a of the upper straight portion 105 that is folded back toward the connecting portion 107 via the bent portion 107b is connected to the relay board 45a and then connected to the pickup module 57.
In this flexible cable 91, the lower straight portion 103 is bonded to the lower case 5 with a double-sided tape or the like.

  As shown in FIG. 28, the flexible cable 91 has a flange 111 provided on one side of the connecting portion 107 from the symmetry line 109 corresponding to the upper straight portion 105 that is in sliding contact with the tray 9 out of the straight portions 103 and 105. It is adhered to the lower case 5. The flange 111 is bonded to the lower case 5 by a double-sided tape 113a shown in FIG. Also, the connecting portion 107 can be joined by the similar double-sided tape 113b.

  In this cable connection structure, even if the connecting portion 105a of the upper straight portion 105 moves on the connecting portion 107 as shown in FIGS. 107a does not overlap with the lower layer of the upper straight portion 105 (that is, as shown in FIG. 29, the folding line 109 of the connecting portion 107 is arranged so as not to overlap with the upper straight portion 105), and the flexible cable 91 can be expanded and contracted with a thin laminated structure.

According to such a fixing structure of the flexible cable 91, the flange portion 111 provided on the connecting portion 107 in the upper linear portion 105 is bonded to the lower case 5 among the connecting portions 107 folded back with the symmetry line 109 as a boundary. As a result, the bent portion that is to be swollen by the elastic restoring force generated by being folded is restrained by the connecting portion 107 of the upper straight portion 105 fixed to the lower case 5 via the flange 111, The bulge of the bent line portion is prevented. Thereby, the attachment strength of the flexible cable 91 is improved, and the housing 3 is thinned.
Further, since the flange portion 111 is not provided with a copper foil (circuit pattern), it is thinner than the straight portions 103 and 105 and is attached to the lower case 5 at a location thinner than the end face of the connecting portion 107. Thereby, even if the tray cover 41 and the flexible cable 91 come into contact with the insertion / extraction of the tray 9 with respect to the housing 3, the risk of the flexible cable 91 peeling off from the lower case 5 can be reduced.

By the way, the tray cover 41 is provided with a stepped portion 115 that gradually separates as shown in FIG. 31B in a range corresponding to the flexible cable 91 on the lower surface facing the lower case 5. Thus, since the tray cover 41 on the back side of the tray is formed in a staircase shape, the housing 3 can be thinned without hindering the followability of the flexible cable 91 that follows the advance and retreat of the tray 9. In other words, the bottom portion 5a of the lower case 5 is provided with a notch 6 for enabling the thinning to the limit. The flexible cable 91 is attached to the lower case bottom 5a in the vicinity of the notch 6, so that the structure below the tray cover 41 is formed between the straight portions 103 and 105 and the bottom 5a shown in FIG. There are three types: a three-layer structure part, a two-layer structure part of the flange 111 and the bottom part 5a, and an open part that becomes the notch part 6.
By forming stepped portions 115a, 115b, and 115c corresponding to each part on the tray cover 41 in stages, the housing structure for the flexible cable 91 that can follow the advance and retreat of the tray 9 is maximized, and the space below the tray 9 is maximized. The housing 3 is made thinner while being reduced.

  As shown in FIG. 28, the flexible cable 91 has a maximum length secured by arranging the bent portion 107a immediately after the engaging pin 117 (back side in the insertion / removal direction). Further, as shown in FIG. 30, the tray 9 is formed with a notch portion 123. The notch portion 123 prevents the interference with the engaging pin 117 when the tray 9 is advanced and retracted, and at the same time the bent portion 107a. Interference with is also avoided.

  Further, in order to maintain the state in which the tray 9 is stored in the housing 3, the engagement pin 117 shown in FIG. 30 provided in the housing 3 and the engagement pin 117 provided in the tray 9 can be engaged. A storage maintaining means 121 having an engagement hook 119 is provided. The bent portion 107 a is disposed on the depth side along the insertion / extraction direction of the tray 9 with respect to the engagement pin 117. By arranging the bent portion 107a and the engaging pin 117 in such a positional relationship, mutual interference in the stacking direction of the bent portion 107a and the engaging pin 117 can be prevented. Thereby, the housing 3 can be thinned.

Further, as shown in FIG. 31, the flexible cable 91 has a bent portion 107 b in which one straight portion 105 is folded back toward the connecting portion 107 in the state in which the tray 9 is housed in the housing 3. The optical disc 29 is disposed outside the planar contour 29a. As the tray 9 is pulled out to the housing 3, the bent portion 107 b follows the tray 9 while changing its folding position to the outside. That is, the lower straight portion 105 becomes the bent portion 107b over the entire area and then becomes the upper straight portion 105.
Thereby, since the maximum bending radius of the bent portion 107b can be increased, there is little possibility of disconnection in the straight portion 105, and the bent portion 107b having a large thickness can be prevented from overlapping the optical disc 29. Therefore, it is only necessary to secure a gap between the tray 9 and the lower case 5 for two layers excluding the bent portion 107a so that the pair of straight portions 103 and 105 are overlapped, and the housing 3 is thinned. .

  According to the optical disc apparatus 500 according to the present embodiment, the flexible cable 91 formed in a substantially U shape by the pair of linear portions 103 and 105 and the arc-shaped connecting portion 107 is connected to the linear portions 103 and 105 with the symmetry line 109 as a boundary. Since the layers 105 are folded so as to be stacked, the connecting portion 103a of the lower straight portion 103 is connected to the main substrate 45, and the connecting portion 105a of the upper straight portion 105 folded back toward the connecting portion 107 is the relay substrate. Even if the connecting portion 105a of the upper straight portion 105 moves on the connecting portion 107 due to the advancement / retraction of the tray 9, the bent portion 107a of the connecting portion 107 overlaps the lower layer of the upper straight portion 105. Don't be. As a result, the flexible cable 91 can be expanded and contracted with a thin laminated structure, and the housing 3 can be thinned.

33 is a plan view of a tray in which a part of the main board is exposed, FIG. 34 is an RR sectional view of FIG. 33, FIG. 35 is an enlarged perspective view of a main board fixing screw and a board guide, and FIG. FIG.
As shown in FIG. 33, the main board 45 is attached to the lower case 5 so that the surface on which the electronic components 47 and the like are mounted faces the upper case 7. A guide piece 125 shown in FIGS. 13 and 34 is attached to the surface of the main board 45, and the guide piece 125 is arranged on the front side of the main board 45 along the insertion / extraction direction of the tray 9. The guide piece 125 is formed, for example, by molding or sheet metal processing (resin material may be used if spring property is not required) from a resin or metal material having good spring property and conductivity. The guide piece 125 has an inclined surface 125a shown in FIGS. 35 and 36 that faces the front side along the insertion / extraction direction of the tray 9. Further, the height of the top portion 125b of the slope 125a is set to a height that keeps the GAP between the tray 9 and each electronic component at a certain level or higher.

The main board 45 has mounting screws 127 that pass through the main board 45 and are screwed into the lower case 5 in order to be fixed to the lower case 5. For this reason, the guide piece 125 has an interposition part 125 c interposed between the main board 45 and the head 127 a of the mounting screw 127.
As shown in FIG. 35 (b), the guide piece 125 includes a rod-shaped detent portion 129 (see also FIG. 35 (c)) provided on the back surface corresponding to the top portion 125b, and a part of the interposition portion 125c. And a non-rotating portion 125d provided by bending.
On the other hand, the main board 45 has a rotation stop hole 45b corresponding to the rotation stop portion 129, a rotation stop recess 45c corresponding to the rotation stop portion 125d, and an accommodation recess 45d for receiving the tip of the inclined surface 125a of the guide piece 125. Is provided.

  As shown in FIG. 35 (d), such a guide piece 125 is inserted around the anti-rotation portion 129 into the anti-rotation hole 45 b to temporarily determine the relative position with respect to the main board 45, and then the anti-rotation portion 129 is the center. By rotating the plane clockwise, the non-rotating portion 125d is engaged with the non-rotating recess 45c for positioning. At this time, the tip of the inclined surface 125a of the guide piece 125 is accommodated in the accommodating recess 45d.

According to such a fixing structure of the main board 45, the mounting screw 127 inserted into the interposition part 125 c provided in the guide piece 125 is screwed into the lower case 5 through the main board 45, thereby guiding the main board 45. The attachment of the piece 125 and the fixing of the main board 45 to the lower case 5 can be performed at the same time, eliminating the need for separate attachment work and reducing the number of parts assembly work steps.
In particular, it can be positioned in a very simple and error-free procedure by inserting the rotation stop portion 129 into the rotation stop hole 45b and then rotating the guide piece 125 in a clockwise direction on the plane. Can dramatically improve performance.

  Since the main board 45 is provided with the guide piece 125, when the tray 9 is retracted, the inclined surface 125a of the guide piece 125 is brought into contact with the rear end of the tray, and the tray 9 is lifted upward. A predetermined gap GP (see FIG. 34) is secured between the tray 9 and the tray 9 is guided by the gap GP so as not to interfere with the electronic component 47. As a result, the tray 9 can be placed close to the lower case 5 (dropped) to the limit, and even if the dimensional accuracy and assembly accuracy of each member are low, such as when the rail 61 is loose, the manufacturing cost is low. The housing 3 can be thinned.

  According to the optical disc apparatus 500 according to the present embodiment, the guide piece 125 exceeding the maximum height of each electronic component is provided on the front side of the main board 45 along the insertion / extraction direction of the tray 9. When retreating, the inclined surface 125 a of the guide piece 125 is brought into contact with the rear end portion of the tray, the tray 9 is lifted upward, and the tray 9 can be guided so as not to interfere with the electronic component 47. Thus, the tray 9 can be disposed as close as possible to the lower case 5, and even if the dimensional accuracy and assembly accuracy of each member are low, such as when the rail 61 is loose, the housing 3 can be mounted at a low manufacturing cost. Thinner.

37 is an exploded perspective view of the housing provided with the upper case according to the modification as viewed from the right side, FIG. 38 is an exploded perspective view of the housing provided with the upper case according to the modification as viewed from the left side, and FIG. 39 is according to the modification. 40 is an exploded perspective view of the housing provided with the upper case as viewed from below, FIG. 40 is an exploded perspective view of the engaging portion of the housing provided with the upper case as viewed from the left side, and FIG. 42 is an exploded perspective view of the engaging portion of the housing provided with the case as viewed from the right side, and FIG. 42 is an exploded perspective view of the engaging portion of the housing provided with the upper case according to the modification as viewed from the lower left side.
In the optical disc apparatus 500 according to the above-described embodiment, the upper case 7 and the lower case 5 of the housing 3 are engaged with each other by a pair of left and right engaging means 11 and 11 as shown in FIG. As a modification, the housing of the optical disk apparatus may be one in which the upper case 7 and the lower case 5 are engaged by a plurality of engaging means.

  In the housing 3A of the optical disc apparatus 500A according to the modification shown in FIGS. 37 to 42, the upper case 7A and the lower case 5 are engaged by the pair of engaging means 11A and 11B in addition to the engaging means 11. . The engaging means 11A shown in FIGS. 40 and 42 includes a protruding portion 13A provided on the upper case 7A and a hooking portion 15A provided on the side wall portion 5c. The engaging means 11B shown in FIG. 41 includes a protruding portion 13B provided on the upper case 7 and a hooking slit 15B provided on the side wall portion 5d. In the engaging means 11A and 11B having the above-described configuration, the protrusion 13A and the protrusion 13B formed in the upper case 7A are engaged with the hook 15A and the hook slit 15B formed in the lower case 5 (for example, After dropping, the projection 13A and the hooking portion 15A, and the projection 13B and the hooking slit 15B are brought into an engaged state, similarly to the engaging means 11 and 11, by sliding to the near side.

  According to the housing 3A of the optical disc apparatus 500A according to this modification, in addition to the engaging means 11 and 11 provided on the front side of the side walls 5c and 5d, the housing 3A is also engaged with the substantially central portion in the extending direction of the side walls 5c and 5d. Since the means 11A and 11B are provided, the reaction force received from the flexible cable 91 and the lifting at the center of the side of the upper case 7A due to the dimensional variation of the upper case 7 can be effectively prevented.

  Further, in the above embodiment, the concentric uneven portion 31 shown in FIG. 8 is formed in the upper case 7, but the upper case has a linear uneven portion 31C like the upper case 7A according to the present modification. May be formed radially, and a plurality of arc-shaped uneven portions 31D connected or intersected with the uneven portions 31C may be formed concentrically. By providing such a linear concavo-convex portion 31C and an arc-shaped concavo-convex portion 31D, it is possible to further increase the rigidity of the upper case 7A and contribute to the thinning of the housing 3A.

  In the above embodiment, as shown in FIG. 31A, the pickup module area for arranging the pickup module 57 and the flexible cable area for arranging the flexible cable 91 are the thickness of the housing 3. It is arranged at a position that does not overlap along the direction. Thereby, the thickness dimension of the housing 3 can be made small and the thickness reduction of the housing 3 is achieved.

  The pickup module region is disposed at one end side in the width direction orthogonal to the insertion / extraction direction of the tray 9 with respect to the housing 3 and the other end side in the width direction orthogonal to the insertion / extraction direction of the tray 9 with respect to the housing 3. The flexible cable region is arranged in the. Thereby, the flexible cable 91 can be arrange | positioned along the insertion / extraction direction of the tray 9, and the extension / contraction of the flexible cable 91 is enabled following the insertion / extraction operation | movement of the tray 9 in space saving.

Also, as shown in FIG. 12, the optical disk device 500 described above has female screws 37a to 37h for fixing the housing 3 to a mounting body such as a casing of a notebook PC, the side wall portion 5c, the back wall portion 5b, Of the female screws 37a to 37h, the female screws 37b and 37g are orthogonal to the insertion / extraction direction of the tray 9 in the state in which the tray 9 is accommodated in the housing 3, and are formed on the side wall 5d. It is formed on the outer rail guide 63 on the near side in the insertion / removal direction with respect to the surface 77 along the 29 rotational axis 19.
Since there is nothing that reinforces the inner rail guide 65 by the notch portion 6 of the lower case 5 (because only the inner rail guide 65 protrudes alone), the bending strength of the inner rail guide 65 is low. For this reason, lack of strength is complemented by fixing a part with low bending strength to attachments, such as a case of a notebook PC.

Specifically, as shown in FIG. 13, female screws 37 b and 37 g are formed on the front side in the insertion / removal direction with respect to the center in the longitudinal direction in the region of the inner rail guide 65 where strength is to be complemented.
Since the female screws 37b and 37g are formed at such positions, the inner rail guide 65 alone has an upper limit in strength, but ensures a desired strength when the optical disc apparatus 500 is fixed to the mounting body. it can. Therefore, for example, when the user applies a load in the thickness direction to the tray 9 pulled out from the housing 3 of the optical disk device 500 fixed to the attachment body, damage or the like is also caused when the user applies a load in the thickness direction (at the time of erroneous operation or optical disk insertion / removal). Yield that is difficult to occur.

Further, as shown in FIG. 11, the female screws 37 a to 37 h (including the screw length portion) are not provided within the plane projection region range of the optical disk 29 in a state where the tray 9 is accommodated in the housing 3.
Thereby, since the fixing screw screwed to the female screws 37a to 37h can be arranged, the optical disc device 500 can be thinned.

FIG. 43 is an exploded perspective view showing how the main board is attached to the lower case.
Further, in the optical disc apparatus 500, the main substrate 45 is mounted on one side, and the back side is attached to the lower case 5 via a heat conductive sheet 131. As a result, a reduction in thickness and an improvement in heat dissipation, which is disadvantageous due to a reduction in thickness, are achieved at the same time.

Also, the upper cases 70a and 70b shown in FIGS. 52 and 53 are also included in the present invention.
That is, the upper case 70a shown in FIG. 52 has concave and convex portions 310A and 310B that are continuous in the circumferential direction around the line along the rotation axis 19 of the optical disc and are concentrically arranged. The convex portions 31e of the concavo-convex portion 310b are formed radially at equal intervals along the circumferential direction around the rotation axis 19 while following the radiation around the rotation axis 19.
Also in the upper case 70a, the concave portions 310a and 310b and the convex portions 310d and 310e of the concave and convex portion 310 have different step sizes, and the step size of the inner peripheral side concave and convex portion 310A is the step difference of the outer peripheral side concave and convex portion 310B. It is set to be larger than the dimension.

Next, the upper case 70b shown in FIG. 53 has concavo-convex portions 410A and 410B which are continuous in the circumferential direction around the line along the rotation axis 19 of the optical disc and are concentrically arranged. In the upper case 70b, the convex portion 410a is partially adjacent to the concave portion 410c through the radiating portion 410f centered on the rotation axis 19 in the outer circumferential uneven portion 410B.
Further, the convex portions 410e and 410g having three kinds of planar shapes are formed radially at equal intervals having a desired regularity along the circumferential direction around the rotation axis 19.
Also in such an upper case 70b, the concave portions 410b and 410g and the convex portions 410a, 410e, and 410f of the concave and convex portion 410 have different step sizes, and the step size of the inner peripheral uneven portion 410A is the outer peripheral concave and convex portion 410B. It is set to more than the step size.
In the upper cases 70a and 70b as described above, the same effects as those of the upper case 7 exemplified in the above-described embodiment can be obtained.

1 is a perspective view illustrating an optical disc device according to a first embodiment of the present invention. The perspective view which looked at the optical disk device of Drawing 1 from the rear side Assembly perspective view of upper case and lower case The disassembled perspective view of the engaging part shown in FIG. An enlarged perspective view showing a rear bent portion of the upper case Assembly perspective view of upper case hook The disassembled perspective view of the hook part shown in FIG. Plan view showing the dent range of the upper case Sectional view showing the dent range of the upper case Tray configuration diagram showing tray plan view (a) and AA cross-sectional view (b) Tray configuration diagram showing (a) a plan view of a tray on which an optical disk is mounted, and (b) a cross-sectional view taken along the line BB. 10 is a side view of the housing in which the arrow CC in FIG. 10 is (a), the arrow DD is (b), and the arrow EE is (c). A perspective view of the housing in which the tray is moved forward through the guide means The perspective view of the tray advance state showing a PUM mechanism structural part and an ejection mechanism structural part Exploded perspective view showing the rail Enlarged perspective view of the rail shown in FIG. FIG. 4A is an enlarged perspective view of the front end surface of the rail portion, and FIG. Enlarged perspective view of left rail stopper between rail and tray Enlarged perspective view of right rail stopper between rail and tray Enlarged perspective view of left rail stopper between lower case and rail Enlarged perspective view of right rail stopper between lower case and rail Perspective view of the lower case in the tray advance state The perspective view which looked at the tray from which the tray cover was removed from the lower surface side The perspective view which looked at the tray cover from the lower surface side Plan view before bending the flexible cable Perspective view of flexible cable when tray is closed in assembled state Perspective view of flexible cable when tray is opened in assembled state A perspective view showing the assembly state of the flexible cable when the tray is closed The perspective view showing the assembly state at the time of tray opening of a flexible cable Perspective view of tray showing lock shaft avoidance part Configuration view of flexible cable in a tray storage state (a) and KK cross-sectional view (b) Plan view showing double-sided tape attachment area of flexible cable Top view of the tray with a part of the main board exposed RR sectional view of FIG. Enlarged perspective view of main board fixing screw and board guide Sectional view of the substrate guide and its vicinity The exploded perspective view which looked at the housing provided with the upper case by the modification from the right side The exploded perspective view which looked at the housing provided with the upper case by the modification from the left side The exploded perspective view which looked at the housing provided with the upper case by a modification from the lower side The exploded perspective view which looked at the engaging part of the housing provided with the upper case by the modification from the left side The exploded perspective view which looked at the engaging part of the housing provided with the upper case by the modification from the right side The exploded perspective view which looked at the engaging part of the housing provided with the upper case by a modification from the lower left side An exploded perspective view showing the state of mounting the main board to the lower case Partial perspective view showing a conventional optical disc apparatus Partial perspective view showing a conventional optical disc apparatus Partial perspective view showing a conventional optical disc apparatus Partial perspective view showing a conventional optical disc apparatus (A) Partial surface view showing a conventional optical disk device, (b) Partial side sectional view showing a conventional optical disk device, and (c) Partial rear view showing a conventional optical disk device. The figure which shows the conventional optical disk device Partial side sectional view showing a conventional optical disc apparatus Partial side sectional view showing a conventional optical disc apparatus Plan view showing a modification of the upper case Plan view showing a modification of the upper case

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Opening provided in end surface of housing 3 Housing 5 Lower case 7 Upper case 9 Tray 11 Engaging means 13 Protruding part 15 Engaging part 17 Fixing screw 19 Optical disk rotation axis 29 Optical disk 31 Concentrated uneven parts 31A Inner peripheral uneven portion 31B Outer peripheral uneven portion 33 Opposite surface facing the optical disc 41 Tray cover 45 Main substrate 47 Electronic component 49, 51 Rib 53 Through hole 57 Pickup module 59 Guide means 61 Rail 61a Web 61b, 61c Flange 63 Outer rail guide 65 Inner rail guide 67 Upright part 69 Bending part 71 Inner regulating means 73, 81 First abutting surface 75, 83 Second abutting surface 79 Outer regulating means 85 Elastic pressure contacting part 87 Sliding member 89 Raised part 91 Flexible cable 103 105 pairs Line part 107 Line-symmetrical arc-shaped connecting part 111 Gutter part 115 Step part 117 Engagement pin 119 Engagement hook 121 Storage and maintenance means 125 Guide piece 125a Slope 125b Slope part 125c Interposition part 127 Mounting screw 1001 Housing 1001a Upper case 1001b Lower case 1001c Opening 1002 Tray 1002a Tray cover 1003 Bezel 1004 Eject button 1005 Opening 1006 Pickup module 1007 Spindle motor 1008 Carriage 1009 Optical disc 1010 Pickup cover 1011 Motor 1012, 1013 Rail 1014, 1015 Rail guide 1018 Circuit board 1018 Circuit board 1018 1021 Flexible cable 1022 Cover 1022a Upper case 102 b lower case 1022c, 1022d, 1022e rib 1070 spindle motor frame 1071 stator

Claims (5)

A housing formed in a flat shape by a lower case and an upper case stacked on each other;
A tray that can be inserted / removed from an end face of the housing, and on which an optical disk can be mounted;
A pickup module attached to the tray;
A main board housed in the housing;
A flexible cable for connecting the pickup module and the main board;
The flexible cable is substantially U-shaped having a pair of straight portions and a line-symmetric arc-shaped connecting portion that connects the straight portions,
An optical disc apparatus in which the linear portions are stacked by folding the connecting portion with a symmetry line as a boundary.   2. The optical disc according to claim 1, wherein a flange provided on one side of the connecting portion from the symmetry line corresponding to an upper straight portion that is in sliding contact with the tray among the straight portions is bonded to the lower case. apparatus. Having a tray cover attached to the back of the tray;
In the range corresponding to the flexible cable on the lower surface facing the lower case in the tray cover,
The optical disc apparatus according to claim 1, wherein a step portion that is separated stepwise is provided. In order to maintain the state in which the tray is stored in the housing, storage maintaining means having an engagement pin provided in the housing and an engagement hook provided in the tray and engageable with the engagement pin. Prepared,
4. The optical disc apparatus according to claim 1, wherein the connecting portion is disposed on a depth side along the insertion / extraction direction of the tray from the engagement pin. 5.   2. The folded portion of one linear portion that is folded back toward the connecting portion in a state where the tray is housed in the housing is disposed outside a planar contour of an optical disc mounted on the tray. Item 5. The optical disk device according to any one of Items 4 to 5.

Images