JP2008251085A - Optical disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To engage a pinion with front/rear racks of a tray and left/right racks of a traverse movement member by riding on the both smoothly. <P>SOLUTION: In an optical disk device 10 provided with a tray 14 moving reciprocally between an optical disk insertion/discharge position and an optical disk recording/reproducing position, a traverse mechanism 20 supporting a turntable 22 and an optical pickup 24 on a traverse space 21 and moving vertically between a rising position and a dropping position, a traverse movement member 29 moving reciprocally in the left and right direction being orthogonal to a movement direction of the tray 14 to move vertically the traverse mechanism 20, a pinion 36 engaging front/rear racks 14f of the tray 14 with left/right racks 29e of the traverse movement member 29 by riding on the both, In the pinion 36, a large diameter flat gear part 36a engaging with the front/rear racks 14f and a small diameter flat gear part 36b engaging with the left/right racks 29e are formed integrally and coaxially, while the respective number of teeth of the large diameter flat gear part 36 and the small diameter flat gear part 36b are same and modules of the both flat gear parts are made different. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention provides a traverse mechanism that supports a turntable and an optical pickup on a traverse base and moves up and down between a rising position at the time of recording and reproduction and a lowering position at the time of retraction. When the tray that reciprocates between the optical disk insertion / removal position protruding into the main base and the optical disk recording / playback position stored in the main base is mounted on the upper part of the main base, the traverse mechanism and tray are mounted on the main base. The present invention relates to an optical disc apparatus that is driven using a common drive source.

  In recent years, optical disk devices have been remarkably widespread and have been widely used, but for high-speed recording for shortening the recording time and high-speed playback for trick play for improving operability, etc. Speeding up is progressing. Further, in order to use an inexpensive optical disc, a mechanism strong against surface runout and eccentric gravity center is required, and it is required to ensure the holding of the optical disc during high-speed rotation and at the same time reduce the operation sound.

Although this type of optical disk apparatus has various structural forms, as a conventional example, a turntable mounted with an optical disk and an optical pickup movable in the radial direction of the optical disk are supported on a traverse base and are recorded and reproduced. A traverse mechanism that moves up and down between an ascending position and a descending position during retraction, an optical disc insertion / removal position that protrudes forward of the main base to insert / remove the optical disc, and a main disc for recording / reproducing with respect to the optical disc 2. Description of the Related Art There is a disc player configured to drive a tray that reciprocates between an optical disc recording / reproducing position stored in a base using a single pinion that rotates forward and backward via a motor mounted on a main base. (For example, refer to Patent Document 1).
Japanese Patent Publication No. 7-7551

FIG. 12 is a plan view showing a conventional disc player,
13 (a) to 13 (e) show a state in which the pinion is connected to the left and right racks of the laterally moving member from the front and rear racks of the tray or from the left and right racks of the laterally moving member to the front and rear racks of the tray in the conventional disc player. It is the figure shown typically.

  The conventional disc player 100 shown in FIG. 12 is disclosed in the above-described Patent Document 1 (Japanese Patent Publication No. 7-7551), and will be briefly described with reference to Patent Document 1.

  As shown in FIG. 12, in the conventional disc player 100, an optical disc recording / reproducing traverse mechanism 102 is connected to the main base 101 on a rectangular plane formed by the X axis and the Y axis orthogonal to each other in the main base 101. The traverse base 103 is attached so as to be rotatable in the vertical direction around a fulcrum (not shown) provided at each rear left and right part of the traverse base 103.

  In the traverse mechanism 102 described above, a turntable 104 that rotates by mounting an optical disk (not shown) is attached to the front side of the traverse base 103, and the optical pickup unit 105 is installed in the rectangular hole 103a of the traverse base 103. It is attached so as to be movable in the radial direction.

  Further, a laterally moving member 106 is attached to the front portion in the main base 101 so as to be movable in the left-right direction (arrow Y3, Y4 direction). The laterally moving member 106 has left and right racks 106a formed along the Y-axis direction, and a boss 106b that is movably fitted in a cam groove 107b of a tray 107 (to be described later) is implanted on the upper surface. A cam groove (not shown) for vertically moving the entire traverse mechanism 102 by fitting with a boss (not shown) horizontally provided on the front side of the traverse base 103 is formed on a surface perpendicular to the traverse base 103.

  When the lateral movement member 106 moves in the direction of the arrow Y3, the traverse mechanism 102 rotates downward, so that the traverse mechanism 102 reaches a lowered position where it is retracted from a tray 107 described later, while the lateral movement member 106 is When the traverse mechanism 102 moves in the Y4 direction, the traverse mechanism 102 rotates upward, so that the traverse mechanism 102 reaches an ascending position at which recording / reproduction with respect to the optical disc is performed.

  Further, a tray 107 is attached to an upper portion of the main base 101 so as to be movable in the front-rear direction (arrow X1, X2 direction), and the tray 107 moves in the arrow X1 direction and protrudes forward of the main base 101. Sometimes the optical disk insertion / removal position for inserting / removing the optical disk is reached, while the tray 107 moves in the direction of the arrow X2 to reach the optical disk recording / reproducing position for recording / reproducing with respect to the optical disk when stored in the main base 101. Yes.

  At this time, on the back surface of the tray 107, a front and rear rack 107a is formed in the vicinity of the lateral movement member 106 along the X-axis direction so as to be long and perpendicular to the left and right racks 106a of the lateral movement member 106. A cam groove 107b in which a 45 ° inclined groove portion 107b1 and a Y-axis direction groove portion 107b2 are connected to each other is formed at the center portion on the front side of the back surface, and a vertical / horizontal rack connecting mechanism 114 (to be described later) is connected to and separated from the front and rear rack 107a. A stopper piece 107c is formed.

  Further, a pinion 113 can be rotated forward and backward via a first pulley 109, a belt 110, a second pulley 111, and a gear train 112 fixed to the shaft of the motor 108 at a front portion in the main base 101 and below the tray 107. It is pivotally supported.

  Further, in the vicinity of the pinion 113, a vertical and horizontal rack connecting mechanism 114 is disposed in the vicinity of the intersection of the left and right racks 106a of the horizontal moving member 106 and the front and rear racks 107a of the tray 107. It has a function of transferring the pinion 113 from one of the racks 106a and 107a to the other.

  In the conventional disc player 100 having the above configuration, the tray 107 moves from the optical disc insertion / removal position to the intermediate position by the engagement of the front and rear racks 107a of the tray 107 and the pinion 113, and then the vertical / horizontal rack connecting mechanism 114 causes the pinion 113 to move. Is engaged with the left and right racks 106a of the laterally moving member 106 instead of the front and rear racks 107a of the tray 107, whereby the bosses 106b of the laterally moving member 106 enter the cam grooves 107b of the tray 107 to bring the tray 10 from the intermediate position into the optical disk. The horizontal movement member 106 operates to raise the turntable 104 and the pickup unit 105 while moving to and fixed to the recording / reproducing position, so the burden on the drive system components for the tray 107 is reduced, and the disc player The fact that 100 can be miniaturized is disclosed To have.

  Incidentally, in the conventional disc player 100 described above, the tray 107 can reciprocate between the optical disc insertion / removal position side shown in FIG. 13A and the optical disc recording / playback position side shown in FIG. It has become.

  At this time, the tray 107 moves in order toward FIG. 13A to FIG. 13E or FIG. 13E to FIG. From 107a to the left and right racks 106a of the lateral movement member 106, or from the left and right racks 106a of the lateral movement member 106 to the front and rear racks 107a of the tray 107, a boss 106b implanted on the upper surface of the lateral movement member 106 is connected with this operation. The cam groove 106b formed on the back surface of the tray 107 is connected to the 45 ° inclined groove portion 107b1 and the Y-axis direction groove portion 107b2 as described above when moving back and forth in the cam groove 107b formed on the back surface of the tray 107. The boss 106b planted on the upper surface of the lateral movement member 106 in cooperation with the movement of the tray 107 and the movement of the lateral movement member 106 is the back of the tray 107. The cam groove 106b formed in the forward / backward movement of the 45 ° inclined groove portion 107b1 advances and retracts, but the 45 ° inclined groove portion 107b1 is steeply inclined during this advancement / retraction, which causes a problem that a large impact force is applied and the operation noise increases. ing.

  Further, when the tray 107 is moved in the front-rear direction by the pinion 113 and the lateral movement member 106 is moved in the left-right direction, the vertical / horizontal rack connecting mechanism 114 must be provided, so that the rack switching structure is complicated.

  Therefore, the pinion can be smoothly connected and engaged from the front and rear racks of the tray to the left and right racks of the horizontal movement member, or from the left and right racks of the horizontal movement member to the front and rear racks of the tray with a simple mechanism, and the disk clamp. The release force and the driving force when the traverse mechanism moves up and down can be increased, and there is no impact force when the boss planted on the top surface of the laterally moving member is fitted into the cam groove formed on the back surface of the tray. Therefore, there is a demand for an optical disc device having a small size and high quality.

This invention is made | formed in view of the said subject, The invention of Claim 1 is a main base,
The optical disk has a mounting portion for mounting at least one of a bare optical disk and a disk cartridge containing the optical disk on the upper surface, and has a front and rear rack and a cam groove on the rear surface, and protrudes forward of the main base. A tray that reciprocates back and forth between a disengagement position and an optical disc recording / reproduction position stored in the main base;
A traverse mechanism that is provided in the main base, supports the turntable and the optical pickup unit on the traverse base, and moves up and down between an ascending position during recording and reproduction and a descending position during retraction;
A boss that advances and retreats in the cam groove of the tray as the tray reciprocates, a cam groove that moves the traverse mechanism up and down, and a left and right rack that is orthogonal to the front and rear racks of the tray, A laterally moving member that reciprocates in the left-right direction orthogonal to the moving direction of the tray;
The left and right racks of the laterally moving member from the front and rear racks of the tray or the left and right racks of the laterally moving member are supported by a rotational drive mechanism provided in the main base and decelerated by being able to rotate forward and backward. In an optical disc device comprising: a pinion that connects and meshes with the front and rear racks of the tray from
The pinion coaxially and integrally forms a large-diameter spur gear portion that meshes with the front and rear racks of the tray and a small-diameter spur gear portion that meshes with the left and right racks of the lateral movement member, and the large-diameter spur gear And the small-diameter spur gear portion have the same number of teeth, and the spur gear portions have different modules.

According to a second aspect of the present invention, there is provided the optical disc apparatus according to the first aspect,
The cam groove of the tray has a front and rear groove along the moving direction of the tray, a first inclined groove inclined by an inclination angle θ1 with respect to the Y axis in the horizontal direction, and an inclination angle θ1 smaller than the Y axis. A second inclined groove inclined at an inclination angle θ2 and a left and right groove along the moving direction of the lateral movement member are connected in this order, and the inclination angle θ1 of the first inclined groove is set to a large diameter flat surface of the pinion. The optical disk apparatus is characterized in that the ratio of the module Ma of the gear portion to the module Mb of the small-diameter spur gear portion of the pinion is set in advance as θ1 = tan ⁻¹ Ma / Mb.

  According to the optical disk device of the first aspect, when the pinion is transferred from the front / rear rack of the tray to the left / right rack of the lateral movement member or from the left / right rack of the lateral movement member to the front / rear rack of the tray, the pinion A large-diameter spur gear portion that meshes with the front and rear racks and a small-diameter spur gear portion that meshes with the left and right racks of the lateral movement member are integrally formed coaxially, and the number of teeth of the large-diameter spur gear portion and the small-diameter spur gear portion is Since the modules of both spur gears are the same, the pinion can be smoothly connected to the left and right racks formed on the laterally moving member from the front and rear racks formed on the tray, or from the left and right racks to the front and rear racks. Since there is no need to provide a vertical and horizontal rack connecting mechanism as described in the conventional example, the rack switching structure is simple.

Further, according to the optical disk apparatus of claim 2, the cam groove of the tray includes the front and rear grooves along the moving direction of the tray, the first inclined groove inclined by the inclination angle θ1 with respect to the Y axis in the left and right direction, and Y The second inclined groove inclined by an inclination angle θ2 smaller than the inclination angle θ1 with respect to the axis and the left and right grooves along the moving direction of the lateral movement member are connected in this order, and the inclination angle θ1 of the first inclined groove is Is set in advance to a ratio of the module Ma of the pinion large-diameter spur gear portion to the module Mb of the pinion small-diameter spur gear portion, θ1 = tan ⁻¹ Ma / Mb. When moving from the position toward the optical disc recording / reproducing position, the boss of the laterally moving member passes through the front and rear grooves in the cam groove 14 formed on the back surface of the tray 14 and from the first inclined groove having the inclination angle θ1 with respect to the Y axis. Tilt angle with respect to Y axis Since the tray enters the second inclined groove having an inclination angle θ2 smaller than 1, the tray is operated at a speed slower than tan θ2 / tan θ1 than when the large-diameter spur gear portion of the pinion is engaged with the front and rear racks. The sound can be reduced and the quality can be improved. Further, the driving force of the lateral movement member is increased by a ratio Ma / Mb between the module Ma of the pinion large-diameter spur gear part and the module Mb of the pinion small-diameter spur gear part, so that the disc clamp releasing force and the traverse mechanism The driving force during vertical movement can be increased.

  Hereinafter, an embodiment of an optical disk device according to the present invention will be described in detail with reference to FIGS.

FIG. 1 is a perspective view showing an external configuration of an optical disc apparatus according to the present invention.
FIG. 2 is an exploded perspective view showing the optical disk apparatus according to the present invention in an exploded manner,
FIG. 3 is a plan view showing the optical disc apparatus according to the present invention with the tray removed;
4 (a) and 4 (b) are front views for explaining the lateral movement state of the lateral movement member in the optical disc apparatus according to the present invention.
5 (a) and 5 (b) are side views for explaining the vertically moving state of the traverse mechanism in the optical disc apparatus according to the present invention.
FIG. 6 is a plan view showing a tray in the optical disc apparatus according to the present invention.

  As shown in FIG. 1, in the optical disc apparatus 10 according to the present invention, a front cover 12 is attached to a front upper portion of a main base 11 serving as a base, and a top cover 13 is located behind the front cover 12. It is attached to cover the whole.

  The optical disc apparatus 10 is assembled in a box shape by a main base 11, a front cover 12, and a top cover 13.

  A tray 14 is attached to the upper part of the main base 11 so as to be movable in the front-rear direction (in the directions of arrows X1 and X2). The tray 14 passes through a rectangular tray insertion / removal opening 12a formed in the front cover 12. It is possible to advance and retreat.

  When the tray 14 moves in the direction of the arrow X1 and protrudes in front of the main base 11, the optical disc D is inserted and removed, and the tray 14 moves in the direction of the arrow X2 and enters the main base 11. An optical disk recording / reproducing position for recording / reproducing with respect to the optical disk D when it is stored is reached.

  Further, a disk clamper 15 is rotatably suspended on the inner surface side of the top cover 13, and the disk clamper 15 presses the optical disk D toward the turntable 22 (FIG. 2) during recording and reproduction.

  Next, the internal structure of the optical disc apparatus 10 according to the present invention will be described with reference to FIGS.

  First, as shown in FIGS. 2 and 3, the main base 11 serving as the base of the optical disc apparatus 10 according to the present invention is integrally formed in a rectangular shape using an aluminum die-cast material or a rigid resin material. The rectangular hole 11a is largely open from the intermediate part inside this part to the rear part.

  A traverse mechanism 20 for recording and reproducing with respect to the optical disc D is mounted in the rectangular hole 11a of the main base 11 so as to be rotatable in the vertical direction.

  In the traverse mechanism 20, the traverse base 21 is formed in a substantially rectangular shape using a sheet metal material, and the turntable 22 that rotates with the optical disk D mounted on the front side of the traverse base 21 is a shaft of the spindle motor 23. The optical pickup unit 24 is mounted in the rectangular hole 21a of the traverse base 21 so as to be movable in the radial direction of the optical disc D along the guide rail 25.

  Further, vibration absorbing insulators 26 are fitted into the four corners of the traverse base 21, and the two insulators 26 attached to the front left and right of the traverse base 21 are traversed by a traverse holder 28 described below by two screws 27. The two insulators 26 fixed to the front left and right inner portions of the traverse base 21 and attached to the rear left and right of the traverse base 21 protrude downward downward to the left and right in the rectangular hole 11a of the main base 11 by two screws 27. It is fixed to the two formed bosses 11b.

  At this time, the traverse holder 28 is formed in an inverted U-shaped arm shape so as to straddle the left and right front portions of the traverse base 21 using an aluminum die-cast material or a rigid resin material. Two first bosses 28a are formed on the left and right sides of the front face 28 so as to protrude into two cam grooves 29c formed on a vertical face 29a of a lateral movement member 29 described later, and the traverse holder 28 A second boss 28b is formed on each of the left and right arm-like side surfaces so as to be able to fit in each fulcrum groove 11c formed in the left and right intermediate portion in the rectangular hole 11a of the main base 11.

  Accordingly, the second boss 28b that protrudes from the left and right arm-shaped side surfaces of the traverse holder 28 is used for the fulcrum of the main base 11 in a state where the left and right front portions of the traverse mechanism 20 are fixed to the front left and right inner portions of the traverse holder 28. When fitted in the groove 11c, the entire traverse mechanism 20 is supported so as to be rotatable in the vertical direction.

  Further, a guide wall 11d is formed vertically along the left-right direction (arrow Y1, Y2 direction) in front of the rectangular hole 11a of the main base 11, and the lateral movement member 29 is moved along the guide wall 11d in the left-right direction ( It is slidably attached in the directions of arrows Y1 and Y2.

  The lateral movement member 29 described above is integrally formed in an inverted L shape with a vertical surface 29a hanging downward using a resin material and a horizontal surface 29b extending forward. At this time, two cam grooves 29c are formed on the left and right sides of the vertical surface 29a of the laterally moving member 29. These two cam grooves 29c are shown enlarged in FIGS. 4 (a) and 4 (b). As shown in FIG. 2, the upper horizontal groove 29c1, the inclined groove 29c2, and the lower horizontal groove 29c3 are connected stepwise from the left side to the right side in the figure, and project in the front of the traverse holder 28 into these cam grooves 29c. The first bosses 28a are fitted.

  As shown in FIG. 4A, when the laterally moving member 29 moves leftward (in the direction of arrow Y1) along the guide wall 11d of the main base 11, the first boss 28a of the traverse holder 28 is cammed. Since the lower horizontal groove 29c3 in the groove 29c is fitted, as shown in FIG. 5A, the traverse mechanism 20 as a whole is moved downward (in the direction of arrow Z1) with the second boss 28b of the traverse holder 28 as a rotation fulcrum. ), The traverse mechanism 20 reaches a lowered position that does not hinder the movement of the tray 14 (FIGS. 1 and 2).

  On the other hand, as shown in FIG. 4B, when the laterally moving member 29 moves rightward (in the direction of arrow Y2) along the guide wall 11d of the main base 11, the first boss 28a of the traverse holder 28 cams. Since it fits into the upper horizontal groove 29c1 in the groove 29c, as shown in FIG. 5B, the traverse mechanism 20 as a whole is moved upward (in the direction of the arrow Z2) with the second boss 28b of the traverse holder 28 as a rotation fulcrum. Therefore, the traverse mechanism 20 reaches an ascending position for recording / reproducing with respect to the optical disc D (FIGS. 1 and 2).

  2 and 3, on the horizontal plane 29b of the lateral movement member 29, a left and right rack 29d is formed toward the left front, and a first boss 29e projects upward near the right end of the left and right rack 29d. The second boss 29f is formed so as to protrude upward in front of the right end.

  A small-diameter spur gear portion 36b of the final stage pinion 36 in the rotational drive mechanism 30 (described later) can be meshed with the left and right racks 29d of the laterally moving member 29, and laterally move as the tray 14 reciprocates. The first boss 29e of the member 29 is movably fitted in a first cam groove 14g formed on the left side of the back surface of the tray 14 while the second boss 29f of the lateral movement member 29 is on the right side of the back surface of the tray 14. It fits in a second cam groove 14h formed in a short length in the rear part so as to freely advance and retract.

  Further, on the front side of the main base 11, rotational drive for moving the tray 14 in the front-rear direction (arrow X1, X2 direction) and moving the lateral movement member 29 in the left-right direction (arrow Y1, Y2 direction). A mechanism 30 is provided.

  The rotary drive mechanism 30 described above is configured to decelerate the rotation of the motor 31 and transmit it to the final stage pinion 36. Specifically, the rotation of the motor 31 is transmitted from the first pulley 32 fixed to the motor shaft to the worm 34 with a pulley formed by coaxially integrating the second pulley 34a and the worm 34b via the belt 33. The second shaft portion planted on the front side of the main base 11 via the intermediate gear 35 pivotally mounted on the first shaft portion 11e planted on the front side of the main base 11 with the rotation of the pulley-equipped worm 34 It is transmitted to the final stage pinion 36 pivotally attached to 11f.

  At this time, in the intermediate gear 35, the large-diameter helical gear portion 35a that meshes with the worm 34b of the worm 34 with pulley and the small-diameter spur gear portion 35b that meshes with the large-diameter spur gear portion 36a of the pinion 36 are coaxial. It is integrally formed with a two-stage structure.

Further, the above-described pinion 36 is a main part of the present invention. Unlike the conventional example, the pinion 36 is a large-diameter spur gear that meshes with a small-diameter spur gear portion 35b of the intermediate gear 35 and a front and rear rack 14f of the tray 14 described later. The portion 36a and the small-diameter spur gear portion 36b that meshes with the left and right racks 29d of the lateral movement member 29 are integrally formed in a two-stage structure coaxially. Further, although the large diameter spur gear portion 36a and the small diameter spur gear portion 36b of the pinion 36 have the same number of teeth, for example, 17 teeth, both spur gear portions 36a, 36b have different modules, and the large diameter The module Ma of the spur gear portion 36a is set to 1.25, for example, while the module Mb of the small diameter spur gear portion 36b is set to 0.8, for example.

  A first switch 38 is mounted on the first plate 37 on the lower left side of the lateral movement member 29, and a rib (not shown) formed on the lower left side of the movement member 29 is in contact with and separated from the first switch 38. It is possible to detect that the tray 14 has reached the optical disk insertion / removal position when the lateral movement member 29 moves to the left (in the direction of arrow Y1) and presses the first switch 38 with the left rib. The rotation of 31 is stopped.

  Further, a second switch 40 is mounted on the second plate 39 on the lower right side of the lateral movement member 29, and a rib (not shown) formed on the lower right side of the movement member 29 is connected to and separated from the second switch 40. A motor that detects that the tray 14 has reached the optical disk recording / reproducing position when the lateral movement member 29 moves to the right (in the direction of the arrow Y2) and presses the second switch 40 with the right rib. The rotation of 31 is stopped.

  Next, as shown in FIGS. 2 and 6, the tray 14 into which the optical disk D is inserted and removed is integrally formed in a substantially rectangular shape using a resin material, and the diameter is 12 cm on the upper surface 14a side. A large-diameter mounting portion 14b for placing the bare optical disc D and a small-diameter placing portion 14c for placing a bare optical disc (not shown) having a diameter of 8 cm are formed concentrically in steps. A long hole 14d for allowing the turntable 22 and the optical pickup unit 24 in the traverse mechanism 20 to face is formed penetrating along the X-axis direction.

  The tray 14 is formed so as to place the bare optical disk D, but is not limited thereto, and is formed so as to place a disk cartridge (not shown) containing the optical disk D. Further, at least one of a bare optical disk and a disk cartridge (not shown) may be placed. In this case, the disk cartridge is inserted into and removed from the tray. A shutter opening / closing mechanism for opening / closing the shutter of the disk cartridge may be provided.

  Further, on the back surface 14e side of the tray 14, a front / rear rack 14f that meshes with the final stage pinion 36 in the rotation drive mechanism 30 and moves in the front / rear direction (arrow X1, X2 direction) is formed in a long portion on the left side. In addition, a first cam groove 14g into which the first boss 29e of the lateral movement member 29 is movably fitted is formed in the vicinity of the front and rear rack 14f, and the second boss 29f of the lateral movement member 29 is formed at the right rear portion. A second cam groove 14h is formed in which the second cam groove 14 is movably fitted.

  At this time, the first cam groove 14g formed on the back surface 14e side of the tray 14 is inclined at an inclination angle θ1 with respect to the longitudinal front and rear groove (X-axis groove) 14g1 along the X-axis and the Y-axis in the horizontal direction. The first inclined groove 14g2, the second inclined groove 14g3 inclined at an inclination angle θ2 smaller than the inclination angle θ1 with respect to the Y axis, and the short left and right grooves (Y axis grooves) 14g4 are formed in this order. In addition, the long front and rear grooves 14g1 and the left and right grooves 14g4 are orthogonal to each other via the first and second inclined grooves 14g2 and 14g3.

Further, the inclination angle θ1 of the first inclined groove 14g2 in the first cam groove 14g is such that the module Ma = 1.25 of the large-diameter spur gear portion 36a of the pinion 36 and the module of the small-diameter spur gear portion 36b of the pinion 36 described above. Since the ratio to Mb = 0.8, that is, θ1 = tan ⁻¹ Ma / Mb is preset, even if the pitch diameters of the large diameter spur gear portion 36a and the small diameter spur gear portion 36b of the pinion 36 are different, The large-diameter spur gear portion 36a smoothly meshes with the front and rear racks 14f of the tray 14, and the small-diameter spur gear portion 36b smoothly meshes with the left and right racks 29d of the lateral movement member 29, so that the pinion 36 The rack 14f can be reliably connected to the left and right racks 29d of the lateral movement member 29 or from the left and right racks 29d of the lateral movement member 29 to the front and rear racks 14f of the tray 14. ing.

  Next, the operation of the optical disc apparatus 10 according to the present invention having the above configuration will be described with reference to FIGS.

FIG. 7 is a first operation process diagram showing a state in which the tray has reached the optical disc insertion / removal position in the optical disc apparatus according to the present invention;
FIG. 8 shows an optical disc apparatus according to the present invention, in which, when the tray moves from the optical disc insertion / removal position toward the optical disc recording / reproducing position, the first boss of the lateral movement member is moved from the front and rear grooves in the first cam groove of the tray. 2nd operation | movement process figure which showed the state which started entering into 1 inclination groove | channel,
FIG. 9 shows an optical disk apparatus according to the present invention, wherein when the tray moves from the optical disk insertion / removal position toward the optical disk recording / playback position, the first boss of the lateral movement member is a first inclined groove in the first cam groove of the tray. 3rd operation process figure which showed the state which began to enter into the 2nd inclined groove from,
FIG. 10 is a fourth operation process diagram showing a state where the tray reaches the optical disk recording / reproducing position in the optical disk apparatus according to the present invention;
11 (a) to 11 (e), in the optical disc apparatus according to the present invention, the pinion is connected to the left and right racks of the laterally moving member from the front and rear racks of the tray or from the left and right racks of the laterally moving member to the front and rear racks of the tray. It is the figure which showed the state typically.

  First, as shown in FIG. 7, in the first operation process of the optical disk apparatus 10 according to the present invention, the tray 14 moves in front of the main base 11 (in the direction of the arrow X1) and protrudes in front of the main base 11. It has reached the insertion / removal position. At this time, since the traverse mechanism 20 provided in the main base 11 is moved down to the lowered position, the turntable 22 and the optical pickup unit 24 mounted on the traverse base 21 do not change anything with respect to the movement of the tray 14. It won't interfere.

  Further, since the lateral movement member 29 moves to the left (in the direction of the arrow Y1) along the guide wall 11d of the main base 11 as the traverse mechanism 20 descends, the rotational drive mechanism 30 attached on the main base 11 is used. Among them, the large-diameter spur gear portion 36a of the pinion 36 at the final stage meshes with the rear portion of the front and rear rack 14f formed on the left side portion of the back surface of the tray 14, but the small-diameter spur gear portion 36b of the pinion 36 is the lateral movement member 29. Are not meshed with the left and right racks 29d formed on the left side portion of the.

  Further, the first boss 29e formed to project to the left side portion of the laterally moving member 29 does not enter the rear end of the front and rear grooves 14g1 in the long first cam groove 14g formed on the left side portion of the back surface of the tray 14, A second boss 29f formed to project from the right side portion of the lateral movement member 29 is fitted in a short second cam groove 14h formed at the rear right side rear portion of the tray 14.

  When the tray 14 reaches the optical disk insertion / removal position, the optical disk D (FIGS. 1 and 2) is placed on the tray 14 or the optical disk D placed on the tray 14 is taken out.

  Next, when the pinion 36 is rotated clockwise from the state in which the tray 14 has reached the optical disk insertion / removal position (FIG. 7), as shown in FIG. Since the gear portion 36a is engaged, the tray 14 moves rearward (in the direction of the arrow X2), and accordingly, the first boss 29e of the lateral movement member 29 (FIGS. 2 to 5) is the length of the tray 14. It enters into the front and rear grooves 14g1 in the long first cam groove 14g. At this time, as the tray 14 moves rearward (in the direction of the arrow X2), the first boss 29e of the lateral movement member 29 reaches the front end side of the front / rear groove 14g1, but the lateral movement member 29 (FIGS. 2 to 5) does not move during this time. However, when the first boss 29e of the lateral movement member 29 enters the first inclined groove 14g2 from the front / rear groove 14g1, the lateral movement member 29 slightly moves toward the right (in the direction of the arrow Y2). The left and right racks 29d of the lateral movement member 29 start to mesh with the small diameter spur gear portion 36b. Along with this, the second boss 29f formed to protrude from the right side portion of the laterally moving member 29 is detached from the short second cam groove 14h formed at the rear right side rear portion of the tray 14.

  Next, when the pinion 36 is further rotated clockwise from the state shown in FIG. 8, as shown in FIG. 9, the left and right racks 29d of the lateral movement member 29 (FIGS. 2 to 5) are connected to the small-diameter flat surface of the pinion 36. Since the lateral movement member 29 moves further to the right (arrow Y2 direction) while meshing with the gear portion 36b, the first boss 29e of the lateral movement member 29 is in the long first cam groove 14g of the tray 14. From the first inclined groove 14g2 toward the second inclined groove 14g3. At this time, since the large-diameter spur gear portion 36a of the pinion 36 is meshed with the vicinity of the front end of the front and rear rack 14f of the tray 14, the tray 14 further moves rearward (in the direction of the arrow X2).

  Next, when the pinion 36 is further rotated in the clockwise direction from the state shown in FIG. 9, the left and right racks 29 d of the laterally moving member 29 (FIGS. 2 to 5) become smaller in diameter than the pinion 36 as shown in FIG. 10. Since the laterally moving member 29 moves further to the right (in the direction of the arrow Y2) while meshing with the spur gear portion 36b, the first boss 29e of the laterally moving member 29 is the long first cam groove 14g of the tray 14. Since the first inclined groove 14g2 and the second inclined groove 14g3 enter the left and right grooves (Y-axis grooves) 14g4, the traverse mechanism 20 provided on the main base 11 moves upward to move the optical disk D (FIG. 1, it reaches an ascending position where recording and reproduction can be performed. Accordingly, the large-diameter spur gear portion 36a of the pinion 36 meshes with the front end portion of the front and rear rack 14f of the tray 14, so that the tray 14 is stored in the main base 11 and the tray 14 Since the turntable 22 and the optical pickup unit 24 in the traverse mechanism 20 face the long hole 14d, recording / reproduction can be performed on the optical disc D (FIGS. 1 and 2) on the tray 14.

  Incidentally, when the tray 14 is moved from the optical disk recording / reproducing position to the optical disk insertion / removal position, the tray 14 may be moved in the order of FIGS. 10, 9, 8, and 7 contrary to the above.

  Here, the operation of the pinion 36, which is the main part of the present invention, connecting the front and rear racks 14f of the tray 14 and the left and right racks 29d of the lateral movement member 29 and engaging with each other will be described with reference to FIGS. 11 (a) to 11 (e). To do.

  The tray 14 can reciprocate between the optical disk insertion / removal position side shown in FIG. 11A and the optical disk recording / playback position side shown in FIG.

  At this time, as described above, the large-diameter spur gear portion 36a and the small-diameter spur gear portion 36b of the pinion 36 have the same number of teeth, for example, 17 teeth, but both the spur gear portions 36a and 36b have different modules. The module Ma of the large diameter spur gear portion 36a is set to 1.25, for example, while the module Mb of the small diameter spur gear portion 36b is set to 0.8, for example.

Further, as described above, in the first cam groove 14g formed on the back surface of the tray 14, the first inclined groove 14g2 is inclined at the inclination angle θ1 with respect to the Y axis, and the second inclined groove 14g3 is the Y axis. Is inclined at an inclination angle θ2 smaller than the inclination angle θ1, and the inclination angle θ1 of the first inclined groove 14g2 is such that the module Ma = 1.25 of the large-diameter spur gear portion 36a of the pinion 36 and the pinion The ratio of the 36 small-diameter spur gear portion 36b to the module Mb = 0.8, that is, θ1 = tan ⁻¹ Ma / Mb is preset.

  11A, when the pinion 36 is rotated clockwise from the state where the tray 14 has reached the optical disk insertion / removal position, the large-diameter spur gear portion 36a of the pinion 36 is moved to the front and rear racks of the tray 14. 14f, the tray 14 moves rearward (in the direction of the arrow X2), and the front and rear grooves in the first cam groove 14g formed on the rear surface of the tray 14 by the first boss 29e of the laterally moving member 29 are provided. It enters from the rear end portion of 14g1 and reaches the front end portion of the front and rear groove 14g1. On the other hand, since the small-diameter spur gear portion 36b of the pinion 36 is not meshed with the left and right racks 29d of the lateral movement member 29, the lateral movement member 29 is stopped at a position moved to the left (in the direction of arrow Y1).

  Next, when the pinion 36 is further rotated clockwise from the state of FIG. 11A and the tray 14 is further moved rearward (in the direction of the arrow X2), FIGS. 11B and 11C. As shown in FIG. 4, the first boss 29e of the lateral movement member 29 has a first inclined groove 14g2 having an inclination angle θ1 with respect to the Y axis from the front and rear grooves 14g1 in the first cam groove 14g formed on the back surface of the tray 14. It enters from the rear end portion and reaches the front end portion of the first inclined groove 14g2. At this time, even if the pitch circle diameters of the large-diameter spur gear portion 36a and the small-diameter spur gear portion 36b of the pinion 36 are different, the pinion 36 is engaged with the front / rear rack 14f of the tray 14 from the large-diameter spur gear portion 36a. Since the small diameter spur gear portion 36b of the pinion 36 that meshes with the left and right racks 29d of the moving member 29 can be smoothly connected, the laterally moving member 29 moves toward the right (in the direction of arrow Y2).

  Therefore, in the present invention, it is not necessary to provide the vertical / horizontal rack connecting mechanism as described in the conventional example, so that the rack switching structure is simple.

  Next, when the pinion 36 is further rotated clockwise from the state of FIG. 11C and the tray 14 is moved further rearward (in the direction of the arrow X2), as shown in FIG. 11D. The first boss 29e of the laterally moving member 29 in the first cam groove 14g formed on the back surface of the tray 14 from the first inclined groove 14g2 having the inclination angle θ1 with respect to the Y axis from the inclination angle θ1 with respect to the Y axis. Since the tray 14 enters the second inclined groove 14g3 having a small inclination angle θ2, the tray 14 becomes slower at a speed of tan θ2 / tan θ1 than when the large-diameter spur gear portion 36a of the pinion 36 is engaged with the front and rear rack 14f. In addition, the operation sound can be reduced to improve the quality.

  Next, when the pinion 36 is further rotated clockwise from the state of FIG. 11 (d) and the tray 14 is moved further rearward (in the direction of the arrow X2), as shown in FIG. 11 (e). Since the first boss 29e of the laterally moving member 29 enters the left and right groove (Y-axis groove) 14g4 from the second inclined groove 14g3 in the first cam groove 14g formed on the back surface of the tray 14, the tray 14 has the main base. 11, the traverse mechanism 20 reaches the raised position as the lateral movement member 29 moves to the right (arrow Y2 direction).

  At this time, the driving force of the lateral movement member 29 is a ratio Ma / of the module Ma = 1.25 of the large diameter spur gear portion 36a of the pinion 36 and the module Mb = 0.8 of the small diameter spur gear portion 36b of the pinion 36. Since it becomes larger by Mb, the disc clamp releasing force and the driving force when the traverse mechanism 20 moves up and down can be increased.

  The operation of moving the tray 14 and the lateral movement member 29 from FIG. 11E to FIG.

1 is a perspective view showing an external configuration of an optical disc apparatus according to the present invention. 1 is an exploded perspective view showing an exploded optical disk device according to the present invention. It is the top view which showed the optical disk apparatus based on this invention in the state which removed the tray. (A), (b) is a front view for demonstrating the left-right movement state of a lateral movement member in the optical disk apparatus based on this invention. (A), (b) is a side view for demonstrating the up-and-down movement state of a traverse mechanism in the optical disk device based on this invention. FIG. 3 is a plan view showing a tray in the optical disc apparatus according to the present invention. FIG. 6 is a first operation process diagram showing a state in which the tray has reached the optical disc insertion / removal position in the optical disc apparatus according to the present invention. In the optical disk apparatus according to the present invention, when the tray moves from the optical disk insertion / removal position toward the optical disk recording / reproducing position, the first boss of the laterally moving member moves from the front and rear grooves to the first inclined groove in the first cam groove of the tray. It is the 2nd operation | movement process figure which showed the state which began to enter in. In the optical disk apparatus according to the present invention, when the tray moves from the optical disk insertion / removal position toward the optical disk recording / playback position side, the first boss of the lateral movement member is second from the first inclined groove in the first cam groove of the tray. It is the 3rd operation | movement process figure which showed the state which started entering into an inclined groove | channel. FIG. 10 is a fourth operation process diagram showing a state in which the tray reaches the optical disc recording / reproducing position in the optical disc apparatus according to the present invention. (A) to (e) in the optical disk apparatus according to the present invention, the pinion is in a state where it is engaged from the front and rear racks of the tray to the left and right racks of the lateral movement member or from the left and right racks of the lateral movement member to the front and rear racks of the tray. It is the figure shown typically. It is the top view which showed the conventional disc player. (A)-(e) is a conventional disc player in which the pinion is connected to the left and right racks of the lateral movement member from the front and rear racks of the tray or from the left and right racks of the lateral movement member to the front and rear racks of the tray. FIG.

Explanation of symbols

  10: Optical disc apparatus.

11 ... main base, 11a ... rectangular hole, 11b ... boss, 11c ... fulcrum groove,
11d: guide wall, 11e: first shaft portion, 11f: second shaft portion,
12 ... Front cover, 13 ... Top cover,
14 ... Tray, 14a ... Upper surface, 14b ... Large diameter placement part, 14c ... Small diameter placement part,
14d ... long hole, 14e ... back surface, 14f ... front and rear rack,
14g ... 1st cam groove, 14g1 ... Front-rear groove (X-axis groove), 14g2 ... 1st inclination groove,
14g3 ... second inclined groove, 14g4 ... left and right groove (Y-axis groove), 14h ... second cam groove,
15 ... Disc clamper,
20 ... Traverse mechanism,
21 ... Traverse base, 21a ... Rectangular hole, 22 ... Turntable,
23 ... Spindle motor, 24 ... Optical pickup unit, 25 ... Guide rail,
26 ... insulator, 27 ... screw,
28 ... Traverse holder, 28a ... First boss, 28b ... Second boss,
29 ... Lateral moving member, 29a ... Vertical plane, 29b ... Horizontal plane,
29c ... cam groove, 29c1 ... upper horizontal groove, 29c2 ... inclined groove, 29c3 ... lower horizontal groove,
29d ... left and right racks, 29e ... first boss, 29f ... second boss,
30 ... Rotation drive mechanism,
31 ... motor, 32 ... first pulley, 33 ... belt,
34 ... Worm with pulley, 34a ... Second pulley, 34b ... Worm,
35 ... Intermediate gear, 35a ... Large diameter helical gear, 35b ... Small diameter spur gear,
36 ... pinion, 36a ... large diameter spur gear portion, 36b ... small diameter spur gear portion,
37 ... 1st plate, 38 ... 1st switch, 39 ... 2nd plate, 40 ... 2nd switch,
D: Optical disc.

Claims (2)

The main base,
The optical disk has a mounting portion for mounting at least one of a bare optical disk and a disk cartridge containing the optical disk on the upper surface, and has a front and rear rack and a cam groove on the rear surface, and protrudes forward of the main base. A tray that reciprocates back and forth between a disengagement position and an optical disc recording / reproduction position stored in the main base;
A traverse mechanism provided in the main base, which supports the turntable and the optical pickup unit on the traverse base and moves up and down between a rising position at the time of recording and reproduction and a lowering position at the time of retraction;
A boss that advances and retreats in the cam groove of the tray as the tray reciprocates, a cam groove that moves the traverse mechanism up and down, and a left and right rack that is orthogonal to the front and rear racks of the tray, A laterally moving member that reciprocates in the left-right direction orthogonal to the moving direction of the tray;
The left and right racks of the laterally moving member from the front and rear racks of the tray or the left and right racks of the laterally moving member are supported by a rotary drive mechanism provided in the main base and decelerated by a forward and reverse rotation. In an optical disc device comprising: a pinion that connects and meshes with the front and rear racks of the tray from
The pinion coaxially and integrally forms a large-diameter spur gear portion that meshes with the front and rear racks of the tray and a small-diameter spur gear portion that meshes with the left and right racks of the lateral movement member, and the large-diameter spur gear An optical disc apparatus characterized in that the number of teeth of the spur gear portion and the small-diameter spur gear portion are the same, and the modules of both spur gear portions are different. The cam groove of the tray has a front and rear groove along the moving direction of the tray, a first inclined groove inclined by an inclination angle θ1 with respect to the Y axis in the horizontal direction, and an inclination angle θ1 smaller than the Y axis. A second inclined groove inclined at an inclination angle θ2 and a left and right groove along the moving direction of the lateral movement member are connected in this order, and the inclination angle θ1 of the first inclined groove is set to a large diameter flat surface of the pinion. 2. The optical disk apparatus according to claim 1, wherein a ratio of the module Ma of the gear portion and the module Mb of the small-diameter spur gear portion of the pinion is preset to θ1 = tan ⁻¹ Ma / Mb.

Images